﻿PT	AU	BA	BE	GP	AF	BF	CA	TI	SO	SE	BS	LA	DT	CT	CY	CL	SP	HO	DE	ID	AB	C1	C3	RP	EM	RI	OI	FU	FP	FX	CR	NR	TC	Z9	U1	U2	PU	PI	PA	SN	EI	BN	J9	JI	PD	PY	VL	IS	PN	SU	SI	MA	BP	EP	AR	DI	DL	D2	EA	PG	WC	WE	SC	GA	PM	OA	HC	HP	DA	UT
J	UCHIDA, A; EBATA, S; WADA, K; MATSUBARA, H; ISHIDA, Y				UCHIDA, A; EBATA, S; WADA, K; MATSUBARA, H; ISHIDA, Y			COMPLETE AMINO-ACID SEQUENCE OF FERREDOXIN FROM PERIDINIUM-BIPES (DINOPHYCEAE)	JOURNAL OF BIOCHEMISTRY			English	Article								The amino acid sequence of the major ferredoxin component isolated from a dinoflagellate, Peridinium bipes, was completely determined. Staphylococcus aureus V8 proteolytic, tryptic and chymotryptic peptides of Cm-ferredoxin were prepared and sequenced. The sequence was Phe-Lys-Val-Thr-Leu-Asp-Thr-Pro-Asp-Gly-Lys-Lys-Ser-Phe-Glu-Cys-Pro-Gly-Asp-Ser-Tyr-Ile-Leu-Asp-Lys-Ala-Glu-Glu-Glu-Gly-Leu-Glu-Lea-Pro-Tyr-Ser-Cys-Arg-Ala-Gly-Ser-Cys-Ser-Ser-Cys-Ala-Gly-Lys-Val-Leu-Thr-Gly-Ser-Ile-Asp-Gln-Ser-Asp-Gln-Ala-Phe-Leu-Asp-Asp-Asp-Gln-Gly-Gly-Asp-Gly-Tyr-Cys-Leu-Thr-Cys-Val-Thr-Tyr-Pro-Thr-Ser-Asp-Val-Thr-Ile-Lys-Thr-His-Cys-Glu-Ser-Glu-Leu. It was composed of 93 amino acid residues with 7 cysteine residues, the highest number found among the chloroplast-type ferredoxins so far sequenced. A cysteine residue was found for the first time at the 89th position in a chloroplast-type ferredoxin. Calculation of the numbers of amino acid differences among chloroplast-type ferredoxins indicates that the Peridinium ferredoxin is far divergent not only from higher plant ferredoxins but also from blue-green algal ferredoxins.	KYOTO UNIV, FAC AGR, DEPT FISHERIES, MICROBIOL LAB, SAKYO KU, KYOTO 606, JAPAN; OSAKA UNIV, FAC SCI, DEPT BIOL, TOYONAKA, OSAKA 560, JAPAN	Kyoto University; Osaka University								CRESTFIELD AM, 1963, J BIOL CHEM, V238, P622; Dayhoff M., 1978, Atlas of protein sequence and structure, V5, P345; DODGE JD, 1983, BRIT PHYCOL J, V18, P335, DOI 10.1080/00071618300650341; Dodge JD., 1965, Expcerpta Med Int Congr Ser, V91, P339; EDMAN P, 1967, EUR J BIOCHEM, V1, P80, DOI 10.1111/j.1432-1033.1967.tb00047.x; GOAD WB, 1982, NUCLEIC ACIDS RES, V10, P247, DOI 10.1093/nar/10.1.247; HASE T, 1976, J BIOCHEM, V79, P329, DOI 10.1093/oxfordjournals.jbchem.a131076; HASE T, 1983, BIOCHIM BIOPHYS ACTA, V744, P46, DOI 10.1016/0167-4838(83)90338-2; HAYHOME BA, 1983, AM J BOT, V70, P1165, DOI 10.2307/2443286; HERZOG M, 1984, ORIGINS LIFE EVOL B, V13, P205, DOI 10.1007/BF00927172; HINNEBUSCH AG, 1980, BIOCHEMISTRY-US, V19, P1744, DOI 10.1021/bi00550a004; HINNEBUSCH AG, 1981, J MOL EVOL, V17, P334, DOI 10.1007/BF01734355; HOCHMAN A, 1982, ARCH MICROBIOL, V133, P62, DOI 10.1007/BF00943771; HOCHMAN A, 1985, ARCH BIOCHEM BIOPHYS, V243, P161, DOI 10.1016/0003-9861(85)90784-2; Kadota H., 1984, MEM COLL AGR KYOTO U, V123, P27; KUBAI DF, 1969, J CELL BIOL, V40, P508, DOI 10.1083/jcb.40.2.508; KULBE KD, 1974, ANAL BIOCHEM, V59, P564, DOI 10.1016/0003-2697(74)90310-8; Loeblich A.R. III, 1983, P39; LOEBLICH AR, 1976, J PROTOZOOL, V23, P13, DOI 10.1111/j.1550-7408.1976.tb05241.x; MAROTEAUX L, 1985, BIOSYSTEMS, V18, P307, DOI 10.1016/0303-2647(85)90031-0; MATSUBARA H, 1968, J BIOL CHEM, V243, P1732; MATSUBARA H, 1980, EVOLUTION PROTEIN ST, P245; MATSUBARA HIROSHI, 1968, J BIOL CHEM, V243, P370; RAO KK, 1981, 32ND S SOC GEN MICR, P175; REDDY R, 1983, J BIOL CHEM, V258, P3965; RIZZO PJ, 1979, J PROTOZOOL, V26, P290, DOI 10.1111/j.1550-7408.1979.tb02783.x; SONNENBORN U, 1982, BIOCHIM BIOPHYS ACTA, V712, P523, DOI 10.1016/0005-2760(82)90280-6; SPACKMAN DH, 1958, ANAL CHEM, V30, P1190, DOI 10.1021/ac60139a006; TAKAHASHI Y, 1981, J BIOCHEM, V90, P1825, DOI 10.1093/oxfordjournals.jbchem.a133662; Taylor F.J.R., 1985, P11; TAYLOR FJR, 1979, TOXIC DINOFLAGELLATE, V1, P47; TSUKIHARA T, 1981, J BIOCHEM, V90, P1763, DOI 10.1093/oxfordjournals.jbchem.a133654; WATSON DA, 1983, BIOCHEM SYST ECOL, V11, P67, DOI 10.1016/0305-1978(83)90001-7; WERNERSCHLENZKA H, 1978, COMP BIOCHEM PHYS B, V61, P587, DOI 10.1016/0305-0491(78)90054-8; ZIMMERMAN CL, 1977, ANAL BIOCHEM, V77, P569, DOI 10.1016/0003-2697(77)90276-7	35	6	7	0	4	OXFORD UNIV PRESS	OXFORD	GREAT CLARENDON ST, OXFORD OX2 6DP, ENGLAND	0021-924X	1756-2651		J BIOCHEM	J. Biochem.	NOV	1988	104	5					700	705		10.1093/oxfordjournals.jbchem.a122536	http://dx.doi.org/10.1093/oxfordjournals.jbchem.a122536			6	Biochemistry & Molecular Biology	Science Citation Index Expanded (SCI-EXPANDED)	Biochemistry & Molecular Biology	Q7440	3235446				2025-03-11	WOS:A1988Q744000006
J	COATS, DW				COATS, DW			DUBOSCQUELLA-CACHONI N-SP, A PARASITIC DINOFLAGELLATE LETHAL TO ITS TINTINNINE HOST EUTINTINNUS-PECTINIS	JOURNAL OF PROTOZOOLOGY			English	Article								The parasitic dinoflagellate Duboscquella cachoni n. sp. is described from infestations of the tintinnine ciliate Eutintinnus pectinis collected from the Chesapeake Bay, a major North American estuary located on the east coast of the United States. Examination of parasite life history, morphology, and developmental processes reveals that D. cachoni differs from other members of the genus by the structure of the trophont, the pattern of sporogenesis, and spore morphology. Sporogenesis results in the production of either biflagellated macrospores, microspores with a single flagellum, or a cyst-like stage. The number of spores formed per infestation and their survival outside the host vary with spore type. Infested ciliates are apparently unable to reproduce, and infestations are always fatal to E. pectinis. Aspects of parasite biology and observations of a natural host-parasite assemblage suggest that D. cachoni may have a significant impact on its host''s population dynamics.	JOHNS HOPKINS UNIV, CHESAPEAKE BAY INST, 4800 ATWELL RD, SHADY SIDE, MD 20764 USA	Johns Hopkins University				Coats, D Wayne/0000-0002-0636-189X				ANDERSON RM, 1981, PHILOS T R SOC B, V291, P451, DOI 10.1098/rstb.1981.0005; Cachon J., 1964, Annales des Sciences Naturelles (12), V6, P1; Cachon J., 1987, The Biology of Dinoflagellates, P571; Chatton E., 1920, Archives de Zoologie Experimentale Paris, V59; Chatton E., 1952, TRAITE ZOOL, P309; COATS DW, 1982, MAR BIOL, V67, P71, DOI 10.1007/BF00397096; Duboscq O, 1910, CR HEBD ACAD SCI, V151, P340; Entz G xEza jun., 1909, Archiv fuer Protistenkunde Jena, V15; Galigher A.E., 1971, Essentials of practical microtechnique, V1st; HOFKER J., 1931, ARCH PROTISTENK, V75, P315; Lee J.J., 1985, P1; Parducz B., 1967, International Review of Cytology, V21, P91, DOI 10.1016/S0074-7696(08)60812-8; STOECKER D, 1983, MAR BIOL, V75, P293, DOI 10.1007/BF00406015; Utermohl H., 1931, Verhandlungen der Internationalen Vereinigung fuer Theoretische Limnologie Stuttgart, V5, P567; VONLOHMANN H, 1908, WISS MEERESUNTERS, V10, P296	15	30	31	1	3	SOC PROTOZOOLOGISTS	LAWRENCE	810 E 10TH ST, LAWRENCE, KS 66044 USA	0022-3921			J PROTOZOOL		NOV	1988	35	4					607	617		10.1111/j.1550-7408.1988.tb04159.x	http://dx.doi.org/10.1111/j.1550-7408.1988.tb04159.x			11	Zoology	Science Citation Index Expanded (SCI-EXPANDED)	Zoology	Q8276					2025-03-11	WOS:A1988Q827600034
J	MONTRESOR, M; ZINGONE, A				MONTRESOR, M; ZINGONE, A			SCRIPPSIELLA-PRECARIA SP-NOV (DINOPHYCEAE), A MARINE DINOFLAGELLATE FROM THE GULF OF NAPLES	PHYCOLOGIA			English	Article								Scrippsiella precaria sp. nov. (Dinophyceae) is described from coastal waters of the Gulf of Naples; it shows a plate formula which is typical for the genus (Po, X, 4'', 3a, 7'''', 6C, 5S, 5'''''', Op, 2''''''''). The shape and arrangement of the intercalary plates are distinctive characters for the species. Plates 1a and 3a are connected and similar in shape and size whereas plate 2a is much smaller and located at the posterior end of the suture between 1a and 3a. A general asymmetry in the plate pattern is evident, particularly in the epitheca. Spiny calcareous resting cysts, formed in clonal cultures, are described. Relationships with other species in the genus also are discussed.			STAZ ZOOL ANTON DOHRN, VILLA COMUNALE, I-80121 NAPOLI, ITALY.		Zingone, Adriana/E-4518-2010	Zingone, Adriana/0000-0001-5946-6532				ANDERSON DM, 1984, J PHYCOL, V20, P418, DOI 10.1111/j.0022-3646.1984.00418.x; Balech E., 1967, Revista Mus argent Cienc nat Bernardino Rivadavia Inst nac Invest Cienc nat (Hidrologia), V2, P77; BALECH E, 1959, BIOL BULL-US, V116, P195, DOI 10.2307/1539204; BALECH E., 1963, NOTAS MUS LA PLATA ZOOL, V20, P111; Balech E., 1974, Revista Mus argent Cienc nat Bernardino Rivadavia Inst nac Invest Cienc nac (Hydrobiol), V4, P1; Balech E., 1966, NEOTROPICA, V12, P103; BRAARUD T., 1958, NYTT MAG BOT, V6, P39; DALE B, 1977, BRIT PHYCOL J, V12, P241, DOI 10.1080/00071617700650261; Dodge J.D., 1982, P1; GUILLARD RR, 1962, CAN J MICROBIOL, V8, P229, DOI 10.1139/m62-029; HORIGUCHI T, 1983, BOT MAG TOKYO, V96, P351, DOI 10.1007/BF02488179; INDELICATO S R, 1986, Japanese Journal of Phycology, V34, P153; INDELICATO S R, 1985, Japanese Journal of Phycology, V33, P127; Loeblich A.R. III, 1979, Proceedings of the Biological Society of Washington, V92, P45; LOEBLICH AR, 1976, J PROTOZOOL, V23, P13, DOI 10.1111/j.1550-7408.1976.tb05241.x; MOESTRUP O, 1980, HDB PHYCOLOGICAL MET, P386; MUNOZ-S P, 1983, Revista de Biologia Marina, V19, P63; SCHMIDT RJ, 1978, J PHYCOL, V14, P5, DOI 10.1111/j.0022-3646.1978.00005.x; Scotto diCarlo., 1985, Nova Thalassia, V7, P99; STEIDINGER K A, 1977, Phycologia, V16, P69, DOI 10.2216/i0031-8884-16-1-69.1; TAYLOR FJR, 1980, BIOSYSTEMS, V13, P65, DOI 10.1016/0303-2647(80)90006-4; VONSTOSCH HA, 1969, HELGOLAND WISS MEER, V19, P558; WALL D, 1968, Journal of Paleontology, V42, P1395; WALL D, 1970, Phycologia, V9, P151, DOI 10.2216/i0031-8884-9-2-151.1; ZINGONE A, 1983, RAPP COMM INT MER ME, V29, P103	25	48	50	0	6	TAYLOR & FRANCIS LTD	ABINGDON	2-4 PARK SQUARE, MILTON PARK, ABINGDON OR14 4RN, OXON, ENGLAND	0031-8884	2330-2968		PHYCOLOGIA	Phycologia	SEP	1988	27	3					387	394		10.2216/i0031-8884-27-3-387.1	http://dx.doi.org/10.2216/i0031-8884-27-3-387.1			8	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	Q0317					2025-03-11	WOS:A1988Q031700011
J	BARLOW, SB; TRIEMER, RE				BARLOW, SB; TRIEMER, RE			ALTERNATE LIFE-HISTORY STAGES IN AMPHIDINIUM-KLEBSII (DINOPHYCEAE, PYRROPHYTA)	PHYCOLOGIA			English	Article								October field collections from a salt water marsh maintained in the laboratory revealed stages of cell fusion and nuclear cyclosis in Amphidinium klebsii Kofoid and Swezy. Cells were observed with one enlarged nucleus and two epicones oriented at 90.degree. to 180.degree. relative to each other. Such a configuration is not typical of dividing cells, suggesting that these cells represent planozygotes. Over time, the two epicones fuse. The product of the fusion is a pigmented cell exhibiting the normal vegetative cell morphology but possessing two trailing flagella. These latter cells enlarge in size and exhibit nuclear cyclosis (rotation of the contents of the nucleus). This rotation has been linked to meiosis I in other dinoflagellate zygotes. Within this same field collection, cells enclosed by a smooth cyst wall composed of a single layer of electron-translucent material were observed. These encysted cells exhibited the same morphology as free-swimming forms of Amphidinium observed in the collection. Transfer of cysts into fresh media produced free-swimming Amphidinium cells which were capable of subsequently forming cysts. Representatives of Amphidinium klebsii are therefore able to cycle between a free-living stage and an encysted stage. Although mitosis in Amphidinium normally occurs in the motile stage, cyst contained up to eight daughter cells, suggesting that the cysts are vegetative division cysts.	RUTGERS STATE UNIV, DEPT BIOL SCI, BUR BIOL RES, PISCATAWAY, NJ 08855 USA		UNIV TEXAS, HLTH SCI CTR, DEPT PHARMACOL, POB 20708, HOUSTON, TX 77225 USA.							[Anonymous], 2001, Acta Bot. Hung, DOI DOI 10.1556/ABOT.43.2001.1-2.9; Beam C. A., 1980, BIOCH PHYSL PROTOZOA, V3, P171; Biecheler B., 1952, Bull. Biol. Fr. Belg., V36, P1; Dodge J.D., 1982, P1; DODGE JD, 1974, FINE STRUCTURE ALGAL; HARRISON PJ, 1980, J PHYCOL, V16, P28, DOI 10.1111/j.1529-8817.1980.tb00724.x; HIMES M, 1975, P NATL ACAD SCI USA, V72, P4546, DOI 10.1073/pnas.72.11.4546; Jensen W.A., 1962, BOT HISTOCHEMISTRY P; Kofoid C. A., 1921, Memoirs of the University of California, V5, P1; Larsen J., 1985, OPERA BOT, V79, P14; Lebour M.V., 1925, DINOFLAGELLATES NO S; Loeblich A.R. III, 1984, P443; NAKAJIMA I, 1981, B JPN SOC SCI FISH, V47, P1029; Pfiester L.A., 1984, P181; ROBERTS TM, 1974, NATURE, V248, P446, DOI 10.1038/248446a0; Sampayo M.A. de M., 1985, P125; SILVA ES, 1978, PROTISTOLOGICA, V14, P113; SILVA SE, 1982, MARINE ALGAE PHARM S, V2, P269; SOYER MO, 1981, BIOSYSTEMS, V14, P299, DOI 10.1016/0303-2647(81)90036-8; Spector D.L., 1984, P107; SPECTOR DL, 1981, BIOSYSTEMS, V14, P289, DOI 10.1016/0303-2647(81)90035-6; STONE J, 1982, MICRON, V13, P335, DOI 10.1016/0047-7206(82)90046-2; Taylor D., 1971, British Phycological Journal, V6, P129; TUTTLE RC, 1974, SCIENCE, V185, P1061, DOI 10.1126/science.185.4156.1061; VIEN C, 1968, CR ACAD SCI D NAT, V267, P701; VIEN C, 1967, CR ACAD SCI D NAT, V264, P1006; von Stosch H.A., 1972, MEM SOC BOT FR, V1972, P201; Von Stosch HA., 1973, Br Phycol J, V8, P105; WEDEMAYER GJ, 1982, J PHYCOL, V18, P13, DOI 10.1111/j.1529-8817.1982.tb03152.x; WILCOX LW, 1986, PROTOPLASMA, V135, P71, DOI 10.1007/BF01277000; ZINGMARK RG, 1970, J PHYCOL, V6, P122, DOI 10.1111/j.0022-3646.1970.00122.x	31	20	22	0	5	TAYLOR & FRANCIS LTD	ABINGDON	2-4 PARK SQUARE, MILTON PARK, ABINGDON OR14 4RN, OXON, ENGLAND	0031-8884	2330-2968		PHYCOLOGIA	Phycologia	SEP	1988	27	3					413	420		10.2216/i0031-8884-27-3-413.1	http://dx.doi.org/10.2216/i0031-8884-27-3-413.1			8	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	Q0317					2025-03-11	WOS:A1988Q031700014
J	BRINKHUIS, H; LEEREVELD, H				BRINKHUIS, H; LEEREVELD, H			DINOFLAGELLATE CYSTS FROM THE CRETACEOUS TERTIARY BOUNDARY SEQUENCE OF EL KEF, NORTHWEST TUNISIA	REVIEW OF PALAEOBOTANY AND PALYNOLOGY			English	Article								Rich dinoflagellate cysts associations have been studied from the Cretaceous/Tertiary (K/T) boundary interval of the E1 Haria section, near E1 Kef, northwest Tunisia. No sharp qualitative changes in the dinoflagellate cyst associations coincide with that boundary. A latest Maastrichtian-earliest Danian (unnamed) interval and an early Danian Danea californica Biozone is recognized. The biostratigraphic value of the first appearance datum of Danea californica for discriminating between latest Maastrichtian and the earliest Danian associations is supported.			STATE UNIV UTRECHT, PALAEOBOT & PALYNOL LAB, HEIDELBERGLAAN 2, 3584 CS UTRECHT, NETHERLANDS.		Brinkhuis, Henk/B-4223-2009	Brinkhuis, Henk/0000-0003-0253-6610				ALVAREZ LW, 1980, SCIENCE, V208, P1095, DOI 10.1126/science.208.4448.1095; ALVAREZ LW, 1984, SCIENCE, V223, P1179; Benson D.G. Jr., 1976, Tulane Stud Geol Paleont, V12, P169; Berggren WA., 1985, Geological Society, London, Memoirs, V10, P141; BRINKHUIS H, 1988, MAR MICROPALEONTOL, V13, P153, DOI 10.1016/0377-8398(88)90002-3; Burrollet P.F., 1956, ANN MINES GEOL TUNIS, P18; CHATEAUNEUF JJ, 1980, MEM BRGM, V116; Cookson I. C., 1965, Proceedings of the Royal Society of Victoria, V79, P133; De Coninck J., 1975, Geologiska Foereningen i Stockholm Foerhandlingar, V97, P326; DECONINCK J, 1982, GEOL MIJNBOUW, V61, P173; DECONINCK J, 1969, MEM I R SCI NAT BELG, V161; DECONINCK J, 1971, B SOC BELG GEOL PALE, V81, P1; DONZE P, 1980, 26EME C GEOL INT RES, V1, P225; DRUGG W.S., 1967, PALAEONTOGRAPHICA B, V120, P1; DRUGG WS, 1970, 1969 P S N AM PAL G, P809; FECHNER G G, 1986, Palaeontologische Zeitschrift, V60, P181; Grigorovich AS., 1969, PALEONTOL SB, V6, P74; HANSEN H J, 1986, Bulletin of the Geological Society of Denmark, V35, P75; HANSEN J M, 1977, Bulletin of the Geological Society of Denmark, V26, P1; Hansen J. M., 1979, CRETACEOUS TERTIARY, P136; HERNGREEN GFW, 1986, REV PALAEOBOT PALYNO, V48, P1, DOI 10.1016/0034-6667(86)90055-2; Hultberg S.U., 1986, Journal of Micropalaeontology, V5, P37; Hultberg S.U., 1985, THESIS U STOCKHOLM S; JAIN KP, 1975, PALEOBOTANIST, V22, P1; JIANG MJ, 1986, MICROPALEONTOLOGY, V32, P232, DOI 10.2307/1485619; KJELLSTROM G, 1973, SVER GEOL UNDERS C, V688; KJELLSTROM G, 1981, GEOL FOREN STOCKH FO, V103, P272; LENTIN JK, 1985, 60 HYDR OC SERV CAN; MONTANARI A, 1983, GEOLOGY, V11, P668, DOI 10.1130/0091-7613(1983)11<668:SATCBA>2.0.CO;2; Morgenroth P., 1968, Geologisches Jahrbuch, V86, P533; Perch-Nielsen K., 1981, CAHIERS MICROPALEONT, V3, P7; Perch-Nielsen K., 1981, CAH MICROPALEONTOL, V3, P25; Perch-Nielsen K.J. McKenzie He., 1982, GEOLOGICAL SOCIETYOF, V190, P353; PERCHNIELSEN K, 1979, CRETACEOUS TERTIARY, V2, P238; Romein A.J.T., 1979, Utrecht Micropaleontological Bulletins, V22; ROMEIN AJT, 1982, INA NEWSL, V4, P63; SALAJ J, 1974, NOT SERV GEOL TUNIS, V41, P91; SALAJ J, 1980, PUBL I GEOL DIONYZ S; Schumacker-Lambry J., 1977, MACRO MICROFOSSILES, P45; SISSINGH W, 1977, GEOL MIJNBOUW, V56, P437; SMIT J, 1981, NATURE, V292, P47, DOI 10.1038/292047a0; SMIT J, 1980, NATURE, V285, P198, DOI 10.1038/285198a0; SMIT J, 1985, EARTH PLANET SC LETT, V74, P155, DOI 10.1016/0012-821X(85)90019-6; SMIT J., 1982, Geological implications of impacts of large asteroids and comets on the Earth, P329; STANLEY EDWARD A., 1965, BULL AMER PALEONTOL, V49, P179; STOVER LE, 1978, STANFORD U PUBL GEOL, V15; Verbeek J. W., 1977, UTRECHT MICROPALEONT, V16; Walliser O.H., 1986, LECTURE NOTES EARTH, V8, P381; Wilson GJ., 1974, THESIS U NOTTINGHAM; WILSON GJ, 1970, 2ND P PLANKT C ROM, P1259; Wonders A. A. H., 1980, UTRECHT MICROPALEONT, V24	51	41	42	0	5	ELSEVIER	AMSTERDAM	RADARWEG 29, 1043 NX AMSTERDAM, NETHERLANDS	0034-6667	1879-0615		REV PALAEOBOT PALYNO	Rev. Palaeobot. Palynology	AUG	1988	56	1-2					5	19		10.1016/0034-6667(88)90071-1	http://dx.doi.org/10.1016/0034-6667(88)90071-1			15	Plant Sciences; Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Paleontology	Q1249					2025-03-11	WOS:A1988Q124900002
J	MATSUOKA, K				MATSUOKA, K			CYST THECA RELATIONSHIPS IN THE DIPLOPSALID GROUP (PERIDINIALES, DINOPHYCEAE)	REVIEW OF PALAEOBOTANY AND PALYNOLOGY			English	Article								In the diplopsalid group of dinoflagellates, there are only a few species for which cyst-theca relationships have been demonstrated. Diplosalid cysts characteristically possess an archeopyle without a detached operculum, and this characteristic is confirmed by the present study of unialgal cyst cultures. The cyst-theca relationships of Diplopelta parva (Abe) comb. nov., Diplopsalis lebourae (Nie) Balech, Diplopsalis lenticula Bergh, Diplopsalopsis orbicularis (Paulsen) Meunier, Gotoius abei sp. nov., and Zygabikodinium lenticulatum (Paulsen) Loeblich et Loeblich indicate that these species have different cyst morphotypes, as well as differences in their motile thecae. Based on these observations, a new family, DIPLOPSALIDACEAE, a new species, Gotoius abei sp. nov. and a new combination, Diplopelta parva (Abe) comb. nov. [based upon Dissodium parvum], are proposed.			NAGASAKI UNIV, FAC LIB SCI, DEPT GEOL, 1-14 BUNKYO MACHI, NAGASAKI 852, JAPAN.							Abe T. H., 1936, Zoological Magazine Tokyo, V48, P747; Abe T. H., 1941, REC OCEAN OGR WORKS JAPAN, V12, P121; Abe T.H., 1981, SETO MARINE BIOL LAB, V6, P1, DOI DOI 10.5134/176462; ABE TOHRU HIDEMITI, 1927, SCI REPT TOHOKU IMP UNIV 4TH SER BIOL, V2, P383; [Anonymous], NOVA HEDWIGIA; [Anonymous], 1977, CONTRIBUTIONS STRATI; [Anonymous], 1985, SPOROPOLLENIN DINOFL; Balech E., 1967, Revista Mus argent Cienc nat Bernardino Rivadavia Inst nac Invest Cienc nat (Hidrologia), V2, P77; BALECH E., 1964, BOL INST BIOL MAR MAR DEL PLATA, V4, P1; BALECH E, 1971, REV MUS ARGENT CIENC, V2, P1; Balech E., 1979, PHYSIS, V38, P27; BERGH R. S., 1882, MORPHOL JB, V7, P12; Bourrelly P., 1968, Phykos, V7, P1; BUJAK JP, 1983, AM ASS STRATIGR PALY, V13; CARTY S, 1986, PHYCOLOGIA, V25, P197, DOI 10.2216/i0031-8884-25-2-197.1; DALE B, 1977, BRIT PHYCOL J, V12, P241, DOI 10.1080/00071617700650261; Dangeard P., 1927, Bul Inst Ocean Monaco, V507, P1; Dodge J.D., 1982, MARINE DINOFLAGELLAT, DOI DOI 10.37543/OCEANIDES.V25I1.79; DODGE JD, 1981, BOT J LINN SOC, V83, P15, DOI 10.1111/j.1095-8339.1981.tb00126.x; DODGE JD, 1985, 3RD INT C MOD FOSS D; EHRENBERGH CG, 1838, INFUSIONSTIERCHEN AL; EVITT W R, 1968, Stanford University Publications in the Geological Sciences, V12, P1; EVITT WR, 1977, 7624 GEOL SURV CAN P; EVITT WR, 1967, STANFORD U PUBL GEOL, V10, P355; FUKUYO Y, 1977, Bulletin of Plankton Society of Japan, V24, P11; HAECKEL E, 1894, ENTWURF EINES NATURL; HARLAND R, 1982, PALAEONTOLOGY, V25, P369; JORGENSEN E, 1912, SVEN HYDROGR BIOL KO, V4; LEBOUR M, 1922, J MAR BIOL ASSOC UK, V12, P817; Lebour M.V., 1925, DINOFLAGELLATES NO S; LEMMERMANN E, 1904, ARCH BOT, V2, P2; Lewis J., 1984, Journal of Micropalaeontology, V3, P25; LOEBLICH A R JR, 1970, Journal of Paleontology, V44, P536; LOEBLICH AR, 1970, 1969 P N AM PAL CO G, P867; Mangin L, 1911, CR HEBD ACAD SCI, V153, P644; MATSUOKA K, 1982, REV PALAEOBOT PALYNO, V38, P109, DOI 10.1016/0034-6667(82)90052-5; MATSUOKA K, 1985, T P PALAEONTOL SOC J, V140, P240; Matsuoka K., 1985, NATURAL SCI B, V25, P21; MATSUOKA K, 1982, FUNDAMENTAL STUDIES, P197; Meunier A, 1910, CAMPAGNE ARCTIQUE 19; Nie Dashu, 1943, SINENSIA, V14, P1; Norris G., 1978, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V155, P300; PAULSEN O, 1907, MEDD KOMM HAWUNDERS, V5; Pavillard J., 1913, GENRE DIPLOPSALIS BE, P1; SARJEANT WAS, 1982, CAN J BOT, V60, P922, DOI 10.1139/b82-119; SCHILLER J, 1937, KRYPTOGAMEN FLORA 3, V10, P481; SOURNIA A, 1984, PHYCOLOGIA, V23, P345, DOI 10.2216/i0031-8884-23-3-345.1; STEIN FR, 1983, ORGANISMUS INFUSIONS, V3; STOVER L E, 1978, Stanford University Publications in the Geological Sciences, V15, P1; TAYLOR FJR, 1980, BIOSYSTEMS, V13, P65, DOI 10.1016/0303-2647(80)90006-4; TAYLOR FJR, 1976, BIBL BOT, V132; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; WALL D, 1971, J PHYCOL, V7, P221, DOI 10.1111/j.1529-8817.1971.tb01507.x	53	60	63	1	3	ELSEVIER	AMSTERDAM	RADARWEG 29, 1043 NX AMSTERDAM, NETHERLANDS	0034-6667	1879-0615		REV PALAEOBOT PALYNO	Rev. Palaeobot. Palynology	AUG	1988	56	1-2					95	122		10.1016/0034-6667(88)90077-2	http://dx.doi.org/10.1016/0034-6667(88)90077-2			28	Plant Sciences; Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Paleontology	Q1249					2025-03-11	WOS:A1988Q124900008
J	SCHNEPF, E				SCHNEPF, E			CYTOCHALASIN-D INHIBITS COMPLETION OF CYTOKINESIS AND AFFECTS THECA FORMATION IN DINOFLAGELLATES	PROTOPLASMA			English	Article								In the presence of cytochalasin D, dinoflagellates undergo mitosis and the cells begin to divide, but the completion of cell division is inhibited. In Pausenella (dinospore formation), Gymnodinium and Prorocentrum, Siamese twins arise which remain connected at the epicones whereas the hypocones, containing the nuclei, are separated. In Scipsiella where the nucleus is centrally located, irregular binucleate cell bodies result. Cyst divisions which give rise to secondary or tertiary cysts in Paulsenella are not affected. In the athecates Paulsenella and Gymnodinium the morphogenesis of the separated cell portions is not or nearly not, respectively, disturbed by cytochalasin D. In the thecates Scripsiella and Prorocentrum morphogenesis is heavily affected. In Prorocentrum, wrinkled theca material is deposited instead of complete valvae. Doubling of the flagellar apparatus is not inhibited. It is concluded that the first phase of cytokinesis does not depend on actin. The daughter cells begin to separate by a mechanism which seems to be associated with the mitotic apparatus. Actin, however, is involved in the further constriction of the cleavage furrow in the second phase of cytokinesis and in the morphogenesis of the theca.	BIOL ANSTALT HELGOLAND, HELGOLAND, GERMANY	Helmholtz Association; Alfred Wegener Institute, Helmholtz Centre for Polar & Marine Research	UNIV HEIDELBERG, FAK BIOL, ZELLENLEHRE, NEUENHEIMER FELD 230, D-6900 HEIDELBERG 1, GERMANY.							ADAMS AEM, 1984, J CELL BIOL, V98, P934, DOI 10.1083/jcb.98.3.934; AUBIN JE, 1981, EXP CELL RES, V136, P63, DOI 10.1016/0014-4827(81)90038-0; DREBES G, 1982, HELGOLANDER MEERESUN, V35, P501, DOI 10.1007/BF01999138; DURR G, 1979, ARCH PROTISTENKD, V122, P55; DURR G, 1979, ARCH PROTISTENKD, V122, P88; FRITZ L, 1985, J PHYCOL, V21, P662, DOI 10.1111/j.0022-3646.1985.00662.x; GODDETTE DW, 1986, J BIOL CHEM, V261, P5974; Loeblich A.R. III, 1979, Journal of Plankton Research, V1, P113, DOI 10.1093/plankt/1.2.113; McLachlan J., 1973, Handbook of Phycological Methods, Culture Methods and Growth Measurements, P25; MENZEL D, 1986, PROTOPLASMA, V134, P30, DOI 10.1007/BF01276373; MORRILL LC, 1981, J PHYCOL, V17, P315, DOI 10.1111/j.0022-3646.1981.00315.x; MORRILL LC, 1984, J MAR BIOL ASSOC UK, V64, P939, DOI 10.1017/S0025315400047354; PICKETTHEAPS JD, 1975, PROTOPLASMA, V86, P205, DOI 10.1007/BF01275633; SCHNEPF E, 1985, PROTOPLASMA, V124, P188, DOI 10.1007/BF01290770; SORANNO T, 1982, EUR J CELL BIOL, V26, P234; TIPPIT DH, 1976, J CELL SCI, V21, P273; TRIEMER RE, 1982, J PHYCOL, V18, P399, DOI 10.1111/j.0022-3646.1982.00399.x; TUCKER JB, 1971, J CELL SCI, V8, P557; WESSELLS NK, 1971, SCIENCE, V171, P135, DOI 10.1126/science.171.3967.135; WETHERBEE R, 1975, J ULTRA MOL STRUCT R, V50, P65, DOI 10.1016/S0022-5320(75)90009-X; WETHERBEE R, 1975, J ULTRA MOL STRUCT R, V50, P77, DOI 10.1016/S0022-5320(75)90010-6; WETHERBEE R, 1975, J ULTRA MOL STRUCT R, V50, P58, DOI 10.1016/S0022-5320(75)90008-8	22	6	8	0	1	SPRINGER WIEN	Vienna	Prinz-Eugen-Strasse 8-10, A-1040 Vienna, AUSTRIA	0033-183X	1615-6102		PROTOPLASMA	Protoplasma		1988	143	1					22	28		10.1007/BF01282955	http://dx.doi.org/10.1007/BF01282955			7	Plant Sciences; Cell Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Cell Biology	M5690					2025-03-11	WOS:A1988M569000003
J	MCLEAN, N; HOCHBERG, FG; SHINN, GL				MCLEAN, N; HOCHBERG, FG; SHINN, GL			GIANT PROTISTAN PARASITES ON THE GILLS OF CEPHALOPODS (MOLLUSCA)	DISEASES OF AQUATIC ORGANISMS			English	Article								Large Prostista of unknown taxonomic affinities are described from 3 species of coleoid squids, and are reported from many other species of cephalopods. The white to yellow-orange, ovoid cyst-like parasites are partially embedded within small pockets on the surface of the gills, often in large numbers. Except for a holdfast region on one side of the large end, the surface of the parasite is elaborated into low triangular plates separated by grooves. The parasites are uninucleate; their cytoplasm bears lipid droplets and presumed paraglycogen granules. Trichocysts, present in a layer beneath the cytoplasmic surface, were found by transmission electron microscopy to be of the dinoflagellate type. Further studies are needed to clarify the taxonomic position of these protists.			SAN DIEGO STATE UNIV, DEPT BIOL, SAN DIEGO, CA 92182 USA.								0	4	4	0	4	INTER-RESEARCH	OLDENDORF LUHE	NORDBUNTE 23, D-21385 OLDENDORF LUHE, GERMANY	0177-5103	1616-1580		DIS AQUAT ORGAN	Dis. Aquat. Org.	DEC 14	1987	3	2					119	125		10.3354/dao003119	http://dx.doi.org/10.3354/dao003119			7	Fisheries; Veterinary Sciences	Science Citation Index Expanded (SCI-EXPANDED)	Fisheries; Veterinary Sciences	L3400		Bronze, Green Accepted			2025-03-11	WOS:A1987L340000007
J	HERBIN, JP; MASURE, E; ROUCACHE, J				HERBIN, JP; MASURE, E; ROUCACHE, J			CRETACEOUS FORMATIONS FROM THE LOWER CONTINENTAL RISE OFF CAPE-HATTERAS - ORGANIC GEOCHEMISTRY, DINOFLAGELLATE CYSTS, AND THE CENOMANIAN TURONIAN BOUNDARY EVENT AT SITE-603 (LEG-93) AND SITE-105 (LEG-11)	INITIAL REPORTS OF THE DEEP SEA DRILLING PROJECT			English	Article									UNIV PARIS 06, DEPT GEOL SEDIMENTAIRE, MICROPALEONTOL LAB, UNITE 319, F-75230 PARIS 05, FRANCE	Sorbonne Universite	INST FRANCAIS PETR, DIRECT RECH GEOL GEOCHIM, BP 311, F-92506 RUEIL MALMAISON, FRANCE.							[Anonymous], PALAEONTOLOGY; AZEMA C, 1981, REV PALAEOBOT PALYNO, V35, P237, DOI 10.1016/0034-6667(81)90111-1; BELOW R, 1982, Palaeontographica Abteilung B Palaeophytologie, V182, P1; BELOW R, 1981, Palaeontographica Abteilung B Palaeophytologie, V176, P1; Boltenhagen E, 1977, CAH PALEONTOL, P1; Bujak J.P., 1983, AM ASS STRATIGRAPHIE, V13, P1; BUJAK JP, 1978, CRETACEOUS PALYNOSTR, P297; Chenet P.Y., 1979, INITIAL REPORTS DEEP, V51-53, P1501; CHENET PY, 1979, INIT REPTS DSDP 2, V52, P1501; CHENET PY, 1979, INIT REPTS DSDP 2, V53, P1501; Davey R.J., 1973, REV ESP MICROPALEONT, V5, P173; DAVEY RJ, 1976, REV PALAEOBOT PALYNO, V22, P307, DOI 10.1016/0034-6667(76)90028-2; DAVEY RJ, 1969, B BRIT MUS NAT HIST, V7, P103; DEBOER PL, 1983, THESIS I AARDWETENSC; DEGRACIANSKY PC, 1982, REV I FR PETROL, V37, P275, DOI 10.2516/ogst:1982016; ESPITALIE J, 1985, REV I FR PETROL, V40, P563, DOI 10.2516/ogst:1985035; ESPITALIE J, 1985, REV I FR PETROL, V40, P755, DOI 10.2516/ogst:1985045; ESPITALIE J, 1977, REV I FR PETROL, V32, P23, DOI 10.2516/ogst:1977002; Espitalie J., 1984, Analytical pyrolysis - Techniques and applications, P276; Ewing J.I., 1972, Initial Reports on Deep Sea Drilling Project, V11, P951, DOI DOI 10.2973/DSDP.PROC.11.132.1972; Foucher J.-C., 1979, Palaeontographica Abteilung B Palaeophytologie, V169, P78; Foucher J.-C., 1982, B CTR RECHERCHES EXP, V6, P147; HABIB D, 1982, MICROPALEONTOLOGY, V28, P335, DOI 10.2307/1485449; HABIB D, 1983, INITIAL REP DEEP SEA, V76, P623; Habib D., 1972, Initial Rep Deep Sea Drilling Project, V11, P367; HABIB D, 1977, STRATIGRAPHIC MICROP, P341; Hedberg HD, 1937, BULL GEOL SOC AM, V48, P1971; HEDBERG HD, 1950, GEOL SOC AM BULL, V61, P1173, DOI 10.1130/0016-7606(1950)61[1173:GOTEVB]2.0.CO;2; HERBIN JP, 1983, INITIAL REP DEEP SEA, V76, P481; HERBIN JP, 1982, B SOC GEOL FR, V24, P497; HERBIN JP, IN PRESS GEOL SOC LO; HERBIN JP, IN PRESS B TECNICO P; HUC AY, 1978, INITIAL REPORTS DSDP, V42, P737; IKAN R, 1975, GEOCHIM COSMOCHIM AC, V39, P195, DOI 10.1016/0016-7037(75)90171-4; IKAN R, 1975, GEOCHIM COSMOCHIM AC, V39, P187, DOI 10.1016/0016-7037(75)90170-2; LANCELOT Y, 1972, INITIAL REPORTS DEEP, V11, P901; Lentin JK., 1981, Fossil dinoflagellates: index to genera and species, 1981; Manum S., 1964, Skrifter utgitt av det Norske Videnskapsakademi Mat Nat Kl NS, VNo. 17, P1; MASURE E, 1984, B SOC GEOL FR, V26, P93; Morgan R., 1978, INIT REPS DSDP, V40, P915; MULLER C, 1983, REV I FR PETROL, V38, P683, DOI 10.2516/ogst:1983042; MULLER C, 1984, REV I FR PETROL, V39, P3, DOI 10.2516/ogst:1984001; ROUCACHE J, 1979, REV I FR PETROL, V34, P191, DOI 10.2516/ogst:1979006; SEVER J, 1969, SCIENCE, V164, P1052, DOI 10.1126/science.164.3883.1052; Simoneit B. R. T., 1973, INITIAL REPORTS DEEP, VXXI, P909; THUROW J, IN PRESS GEOL SOC LO; TISSOT B, 1974, AAPG BULL, V58, P499; TISSOT B, 1981, 26TH OC ACT ACT INT, P97; Tissot B., 1979, DEEP DRILLING RESULT, V3, P362	49	6	6	0	0	US GOVERNMENT PRINTING OFFICE	WASHINGTON	SUPERINTENDENT DOCUMENTS,, WASHINGTON, DC 20402-9325 USA				INITIAL REP DEEP SEA		MAY	1987	93		2				1139	1162						24	Oceanography	Science Citation Index Expanded (SCI-EXPANDED)	Oceanography	H6572					2025-03-11	WOS:A1987H657200042
J	TOCHER, BA				TOCHER, BA			CAMPANIAN TO MAESTRICHTIAN DINOFLAGELLATE CYSTS FROM THE UNITED-STATES ATLANTIC MARGIN, DEEP-SEA DRILLING PROJECT SITE-612	INITIAL REPORTS OF THE DEEP SEA DRILLING PROJECT			English	Article											TOCHER, BA (通讯作者)，PLYMOUTH POLYTECH,DEPT GEOL SCI,DRAKE CIRCUS,PLYMOUTH PL4 8AA,DEVON,ENGLAND.							Alberti G., 1959, Mitteilungen aus dem Geologischen Staatsinstitut in Hamburg, V28, P93; Alberti G., 1961, Palaeontographica, V116, P1; BENSON GD, 1976, TULANE STUD GEOL PAL, V12, P169; BUJAK JP, 1978, B GEOL SURV CAN, V297; Clarke R. F. A., 1967, Verb K ned Akad Wet Amst, V24, P1; Cookson I. C., 1962, Micropaleontology, V8, P485, DOI 10.2307/1484681; COOKSON I C, 1968, Journal of the Royal Society of Western Australia, V51, P110; COOKSON I C, 1970, Proceedings of the Royal Society of Victoria, V83, P137; COOKSON I.C., 1974, PALAEONTOGRAPHICA, V148, P44; COOKSON IC, 1958, ROYAL SOC VICTORIA P, V70, P19; COOKSON ISABEL C., 1960, MICROPALEONTOLOGY, V6, P1, DOI 10.2307/1484313; Deflandre G., 1935, Bulletin Biologique de la France et de la Belgique, V69, P213; DEFLANDRE G., 1937, ANN PALEONTOL, V26, P51; Deflandre G., 1936, Annales de paleontologie, V25, P151; DOHER LI, 1980, 830 US GEOL SURV CIR; DRUGG W.S., 1967, PALAEONTOGRAPHICA B, V120, P1; HANSEN J M, 1977, Bulletin of the Geological Society of Denmark, V26, P1; HARLAND R, 1973, Palaeontology (Oxford), V16, P665; Kjellstrom, 1973, SVER GEOL UNDERS AFH, V688, P1; Lejeune-Carpentier M., 1938, ANN SOC GEOL BELG, V61, P163; LEJEUNECARPENTI.M, 1939, ANN SOC GEOL BELG, V62, P525; MAY F E, 1980, Palaeontographica Abteilung B Palaeophytologie, V172, P10; McIntyre D.J., 1975, Geoscience and Man, V11, P61, DOI DOI 10.1080/00721395.1975.9989756; NEVES R, 1963, NATURE, V198, P775, DOI 10.1038/198775a0; WHITNEY BL, 1984, AASP FIELD TRIP VOLU, P123; Williams G.L., 1975, GEOL SURV CAN BULL, V236, P1; WILLIAMS GL, 1975, PAP GEOL SURV CAN, V7430, P107; Wilson G.J., 1984, Newsletters on Stratigraphy, V13, P104; WILSON GJ, 1976, NEW ZEAL J GEOL GEOP, V19, P127, DOI 10.1080/00288306.1976.10423553; WILSON GJ, 1976, NEW ZEAL J GEOL GEOP, V19, P132, DOI 10.1080/00288306.1976.10423554; WILSON GJ, 1971, 2ND P PLANKT C ROM, P1259; WILSON GJ, 1974, THESIS NOTTINGHAM U	32	7	8	0	1	US GOVERNMENT PRINTING OFFICE	WASHINGTON	SUPT OF DOCUMENTS, WASHINGTON, DC 20402-9325				INITIAL REP DEEP SEA		APR	1987	95						419	429						11	Oceanography	Science Citation Index Expanded (SCI-EXPANDED)	Oceanography	H6570					2025-03-11	WOS:A1987H657000014
J	SAKO, Y; ISHIDA, Y; NISHIJIMA, T; HATA, Y				SAKO, Y; ISHIDA, Y; NISHIJIMA, T; HATA, Y			SEXUAL REPRODUCTION AND CYST FORMATION IN THE FRESH-WATER DINOFLAGELLATE PERIDINIUM-PENARDII	BULLETIN OF THE JAPANESE SOCIETY OF SCIENTIFIC FISHERIES			English	Article									KOCHI UNIV, FAC AGR, DEPT CULTURAL FISHERIES, AQUAT ENVIRONM SCI LAB, NANKOKU, KOCHI 783, JAPAN	Kochi University	KYOTO UNIV, DEPT FISHERIES, MICROBIOL LAB, KYOTO 606, JAPAN.							HATA Y, 1982, RES DATA NATL I ENV, V24, P15; ITOH T, 1979, B PLANKTON SOC JPN, V26, P113; Kadota H., 1984, MEM COLL AGR KYOTO U, V123, P27; PFIESTER LA, 1977, J PHYCOL, V13, P92, DOI 10.1111/j.0022-3646.1977.00092.x; PFIESTER LA, 1980, AM J BOT, V67, P955, DOI 10.2307/2442437; PFIESTER LA, 1979, PHYCOLOGIA, V18, P13, DOI 10.2216/i0031-8884-18-1-13.1; PFIESTER LA, 1976, J PHYCOL, V12, P234; PFIESTER LA, 1975, J PHYCOL, V11, P259, DOI 10.1111/j.1529-8817.1975.tb02776.x; PFIESTER LA, 1984, AM J BOT, V71, P1121, DOI 10.2307/2443388; POLLINGHER U, 1976, J PHYCOL, V12, P162, DOI 10.1111/j.1529-8817.1976.tb00494.x; SAKO Y, 1985, B JPN SOC SCI FISH, V51, P267; SAKO Y, 1984, B JPN SOC SCI FISH, V50, P743; Sako Y., 1986, Bulletin of Japanese Society of Microbial Ecology, V1, P19; TURPIN DH, 1978, J PHYCOL, V14, P235, DOI 10.1111/j.1529-8817.1978.tb02454.x; Von Stosch HA., 1973, Br Phycol J, V8, P105; WALKER LM, 1979, J PHYCOL, V15, P312; WATANABE MM, 1983, RES DATA NATL I ENV, V24, P111; YOSHIMATSU S, 1981, Bulletin of Plankton Society of Japan, V28, P131	18	20	20	0	0	JAPANESE SOC FISHERIES SCIENCE	TOKYO	C/O TOKYO UNIV FISHERIES, KONAN 4, MINATO, TOKYO, 108-8477, JAPAN	0021-5392			B JPN SOC SCI FISH		MAR	1987	53	3					473	478						6	Fisheries	Science Citation Index Expanded (SCI-EXPANDED)	Fisheries	G9595					2025-03-11	WOS:A1987G959500020
J	BINDER, BJ; ANDERSON, DM				BINDER, BJ; ANDERSON, DM			PHYSIOLOGICAL AND ENVIRONMENTAL-CONTROL OF GERMINATION IN SCRIPPSIELLA-TROCHOIDEA (DINOPHYCEAE) RESTING CYSTS	JOURNAL OF PHYCOLOGY			English	Article								The effects of aging, temperature, and growth medium on germination in culture-produced resting cysts of the marine dinoflagellate Scrippsiella trochoidea (Stein) Loeblich are examined. Cysts undergoing a mandatory period of dormancy lasting approximately 25 days, during which germination does not occur. The duration of this period is not affected by temperature. Once the dormancy period is completed, germination is regulated by external factors. Cysts germinate optimally in nutrient replete medium at temperatures greater than approximately 14.degree. C. At lower temperatures or in nutrient-depleted media germination rate is dramatically slowed, although the final germination frequency appears unchanged. The large Q10 of this temperature effect (ca. 11) suggests that the reduction in germination rate at lower temperatures is not merely the reflection of generally reduced metabolic rates, but rather the result of a temperature response specific to germination. At the highest temperatures tested (22-25.degree. C), germination rate remains maximal although vegetative growth is greatly reduced. A shift in temperature or nutrient conditions, per se, is not necessary for germination. The relatively short dormancy period combined with the absence of a requirement for a dramatic shift in environmental conditions could facilitate rapid cycling between resting and vegetative stages in natural S. trochoidea populations. At the same time, the dramatic reduction in germination rate at low temperatures would permit cysts of this species to serve as overwintering cells as well.	WOODS HOLE OCEANOG INST, DEPT BIOL, WOODS HOLE, MA 02543 USA									Anderson D.M., 1984, SEAFOOD TOXINS, V262, P125; ANDERSON DM, 1980, J PHYCOL, V16, P166; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; ANDERSON DM, 1985, J PHYCOL, V21, P200; ANDERSON DM, 1984, J PHYCOL, V20, P418, DOI 10.1111/j.0022-3646.1984.00418.x; [Anonymous], ALGAL PHYSL BIOCH; BINDER BJ, 1986, NATURE, V322, P659, DOI 10.1038/322659a0; BRAARUD T., 1958, NYTT MAG BOT, V6, P39; BRAND L E, 1981, Journal of Plankton Research, V3, P193, DOI 10.1093/plankt/3.2.193; CHAPMAN DV, 1981, BRIT PHYCOL J, V16, P183, DOI 10.1080/00071618100650191; Coleman A.W., 1983, P1; Dale B., 1983, P69; DURR G, 1979, ARCH PROTISTENKD, V122, P121; ENDO T, 1984, Bulletin of Plankton Society of Japan, V31, P23; GUILLARD RR, 1962, CAN J MICROBIOL, V8, P229, DOI 10.1139/m62-029; Guillard RRL., 1975, CULTURE MARINE INVER, P29, DOI [10.1007/978-1-4615-8714-93, DOI 10.1007/978-1-4615-8714-93, 10.1007/978-1-4615-8714-9_3]; Hoshaw R.W., 1973, HDB PHYCOLOGICAL MET, P53; Huber G., 1923, FLORA JENA, V116, P114; Kadota H., 1984, MEM COLL AGR KYOTO U, V123, P27; Nikolaeva MG., 1977, PHYSL BIOCH SEED DOR, P51; PFIESTER LA, 1977, J PHYCOL, V13, P92, DOI 10.1111/j.0022-3646.1977.00092.x; PFIESTER LA, 1976, J PHYCOL, V12, P234; PFIESTER LA, 1975, J PHYCOL, V11, P259, DOI 10.1111/j.1529-8817.1975.tb02776.x; PFIESTER LA, 1987, BIOL DINOFLAGELLATES, P661; PFIESTER LA, 1979, PHYCOLOGIA, V8, P13; PRICE CA, 1978, LIMNOL OCEANOGR, V23, P548, DOI 10.4319/lo.1978.23.3.0548; Von Stosch HA., 1973, Br Phycol J, V8, P105; WALL D, 1969, J PHYCOL, V5, P140, DOI 10.1111/j.1529-8817.1969.tb02595.x; WALL D, 1970, Phycologia, V9, P151, DOI 10.2216/i0031-8884-9-2-151.1; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; Wall D., 1971, Geoscience Man, V3, P1; WALL D., 1967, PHYCOLOGIA, V6, P83; Watanabe M., 1982, RES REP NAT I ENV ST, V30, P27	34	96	105	1	23	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0022-3646	1529-8817		J PHYCOL	J. Phycol.	MAR	1987	23	1					99	107						9	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	G5359					2025-03-11	WOS:A1987G535900011
J	ANDERSON, DM; TAYLOR, CD; ARMBRUST, EV				ANDERSON, DM; TAYLOR, CD; ARMBRUST, EV			THE EFFECTS OF DARKNESS AND ANAEROBIOSIS ON DINOFLAGELLATE CYST GERMINATION	LIMNOLOGY AND OCEANOGRAPHY			English	Article								The effects of light and anaerobiosis on germination of marine dinoflagellate resting cysts were examined. Germination of all species was completely inhibited during 7 weeks of anaerobic incubation, although the cysts remained viable. Light requirements were more variable. Germination rates in the light varied 20-fold between species; dark rates varied by a similar factor but were generally much lower. One species (Gonyaulax polyedra) required light to germinate, three germinated faster in the light than in the dark (Gonyaulax tamarensis, Scrippsiella sp., and Gonyaulax verior), and one germinated at comparable rates in the light and in the dark (Gonyaulax rugosum). Brief exposure to light at the beginning of the experiments made it impossible to say whether germination is possible in constant darkness. It is clear, however, that prolonged light exposure is a requirment only for G. polyedra, although it can significantly accelerate germination of the other species. Germination inhibition by darkness and anaerobiosis helps to explain the subsurface accumulation of dinoflagellate cysts in marine sediments and the persistence of benthic cyst populations at times when temperatures favor germination. These constraints are sufficiently common that many cysts will never germinate once they reach bottom sediments.			WOODS HOLE OCEANOG INST, DEPT BIOL, WOODS HOLE, MA 02543 USA.							Anderson D.M., 1985, P219; ANDERSON DM, 1980, J PHYCOL, V16, P166; ANDERSON DM, 1985, LIMNOL OCEANOGR, V30, P1000, DOI 10.4319/lo.1985.30.5.1000; ANDERSON DM, 1982, LIMNOL OCEANOGR, V27, P757, DOI 10.4319/lo.1982.27.4.0757; ANDERSON DM, 1983, MAR BIOL, V76, P179, DOI 10.1007/BF00392734; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; ANDERSON DM, 1984, J PHYCOL, V20, P418, DOI 10.1111/j.0022-3646.1984.00418.x; Bewley J D., 1982, Physiology and Biochemistry of Seeds; BINDER BJ, 1986, NATURE, V322, P659, DOI 10.1038/322659a0; BINDER BJ, 1986, THESIS MIT; BOON JJ, 1979, NATURE, V277, P125, DOI 10.1038/277125a0; CRAIB J. S., 1965, J CONS CONS PERMA INT EXPLOR MER, V30, P34; DALE B, 1977, SARSIA, V63, P29, DOI 10.1080/00364827.1977.10411318; Dale B., 1983, P69; ENDO T, 1984, Bulletin of Plankton Society of Japan, V31, P23; EVITT W.R., 1964, STANFORD U PUBLICATI, V10, P1; Evitt WR., 1970, GEOSCI MAN, V1, P29; FUKUYO Y, 1982, NAT JPN I ENV STUD R, V30, P27; GUILLARD RR, 1962, CAN J MICROBIOL, V8, P229, DOI 10.1139/m62-029; HEANEY SI, 1983, BRIT PHYCOL J, V18, P47, DOI 10.1080/00071618300650061; Huber G., 1922, Z BOTANIK, V14, P337; Huber G., 1923, FLORA JENA, V116, P114; HUNGATE RE, 1950, BACTERIOL REV, V14, P1; Hutchinson GE., 1957, TREATISE LIMNOLOGY; JORGENSEN BB, 1982, NATURE, V296, P643, DOI 10.1038/296643a0; KRUPA D, 1981, EKOL POL-POL J ECOL, V29, P545; Lewis J., 1985, P85; Steidinger K.A., 1975, P153; Sussman AS., 1966, SPORES THEIR DORMANC; TYLER MA, 1982, MAR ECOL PROG SER, V7, P163, DOI 10.3354/meps007163; VARY JC, 1965, SPORES, V3, P188; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; Wall D., 1973, Geoscience Man, V7, P95; WALL D, 1966, GRANA PALYNOL, V3, P243; WATRAS CJ, 1985, J PLANKTON RES, V7, P891, DOI 10.1093/plankt/7.6.891; WHITE AW, 1982, CAN J FISH AQUAT SCI, V39, P1185, DOI 10.1139/f82-156; Wolfe R S, 1971, Adv Microb Physiol, V6, P107, DOI 10.1016/S0065-2911(08)60068-5; YENTSCH CM, 1980, BIOSCIENCE, V30, P251, DOI 10.2307/1307880; 1976, APPL B ORION RES COR, V12	40	159	182	0	21	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0024-3590	1939-5590		LIMNOL OCEANOGR	Limnol. Oceanogr.	MAR	1987	32	2					340	351		10.4319/lo.1987.32.2.0340	http://dx.doi.org/10.4319/lo.1987.32.2.0340			12	Limnology; Oceanography	Science Citation Index Expanded (SCI-EXPANDED)	Marine & Freshwater Biology; Oceanography	H1882		Bronze			2025-03-11	WOS:A1987H188200006
J	REID, PC; BOALCH, GT				REID, PC; BOALCH, GT			A NEW METHOD FOR THE IDENTIFICATION OF DINOFLAGELLATE CYSTS	JOURNAL OF PLANKTON RESEARCH			English	Note									MARINE BIOL ASSOC LAB, PLYMOUTH PL1 2PB, DEVON, ENGLAND	Marine Biological Association United Kingdom	INST MARINE ENVIRONM RES, PROSPECT PL, PLYMOUTH PL1 3DH, DEVON, ENGLAND.							ANDERSON DM, 1983, MAR BIOL, V76, P179, DOI 10.1007/BF00392734; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; Bennett Stanley H., 1950, McClung's handbook of microscopical technique, chapter IX, V3rd, P591; Bibby B.T., 1972, British phycol J, V7, P85; CHAPMAN DV, 1982, J PHYCOL, V18, P121, DOI 10.1111/j.0022-3646.1982.00121.x; Dale B., 1983, P69; HEANEY SI, 1983, BRIT PHYCOL J, V18, P47, DOI 10.1080/00071618300650061; Kerr P.F., 1977, OPTICAL MINERALOGY, V4rt; MORRILL LC, 1981, J PHYCOL, V17, P315, DOI 10.1111/j.0022-3646.1981.00315.x; Reid P.C., 1974, Nova Hedwigia, V25, P579; REID PC, 1983, J PROTOZOOL, V30, P710, DOI 10.1111/j.1550-7408.1983.tb05348.x; Steidinger K.A., 1984, P201; SWIFT E, 1970, J PHYCOL, V6, P79, DOI 10.1111/j.0022-3646.1970.00079.x; TYLER MA, 1982, MAR ECOL PROG SER, V7, P163, DOI 10.3354/meps007163; Von Stosch HA., 1973, Br Phycol J, V8, P105; WALL D, 1968, Journal of Paleontology, V42, P1395; WHITE AW, 1982, CAN J FISH AQUAT SCI, V39, P1185, DOI 10.1139/f82-156	17	15	15	1	1	OXFORD UNIV PRESS	OXFORD	GREAT CLARENDON ST, OXFORD OX2 6DP, ENGLAND	0142-7873	1464-3774		J PLANKTON RES	J. Plankton Res.	JAN	1987	9	1					249	253		10.1093/plankt/9.1.249	http://dx.doi.org/10.1093/plankt/9.1.249			5	Marine & Freshwater Biology; Oceanography	Science Citation Index Expanded (SCI-EXPANDED)	Marine & Freshwater Biology; Oceanography	F6669					2025-03-11	WOS:A1987F666900017
J	SARJEANT, WAS; LACALLI, T; GAINES, G				SARJEANT, WAS; LACALLI, T; GAINES, G			THE CYSTS AND SKELETAL ELEMENTS OF DINOFLAGELLATES - SPECULATIONS ON THE ECOLOGICAL CAUSES FOR THEIR MORPHOLOGY AND DEVELOPMENT	MICROPALEONTOLOGY			English	Article									UNIV SASKATCHEWAN,DEPT BIOL,SASKATOON S7N 0W0,SASKATCHEWAN,CANADA; UNIV BRITISH COLUMBIA,DEPT OCEANOG,VANCOUVER V6T 1W5,BC,CANADA	University of Saskatchewan; University of British Columbia	SARJEANT, WAS (通讯作者)，UNIV SASKATCHEWAN,DEPT GEOL SCI,SASKATOON S7N 0W0,SASKATCHEWAN,CANADA.							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J	BALDWIN, RP				BALDWIN, RP			DINOFLAGELLATE RESTING CYSTS ISOLATED FROM SEDIMENTS IN MARLBOROUGH SOUNDS, NEW-ZEALAND	NEW ZEALAND JOURNAL OF MARINE AND FRESHWATER RESEARCH			English	Article								Seventeen species of dinoflagellate resting cysts have been recorded for the first time in New Zealand. Isolated from sediments at 93 locations in the Marlborough Sounds, these were Gonyaulax spinifera, G. grindleyi, G. polyedra, G. digitalis, Gonyaulax sp., Protoperidinium subinerme, P. pentagonum, P. conicum, P. oblongum, P. leonis, P. cf. punctulatum, P. cf. conicoides, Peridinium stellatum, Peridinium sp., Scrippsiella trochoidea, Polykrikos schwartzii, and Diplosalis sp. here possible their identities were confirmed by hatching experiments yielding live motile cells. Greatest cyst concentrations and species diversity were found in Kenepuru Sound and Tennyson Inlet. These areas may be more likely to harbour toxic species causing paralytic shellfish poisoning (PSP) or diarrhetic shellfish poisoning (DSP) if these were to appear in the future.			DSIR, DIV MARINE & FRESHWATER SCI, WELLINGTON, NEW ZEALAND.								0	37	40	0	1	TAYLOR & FRANCIS LTD	ABINGDON	2-4 PARK SQUARE, MILTON PARK, ABINGDON OR14 4RN, OXON, ENGLAND	0028-8330	1175-8805		NEW ZEAL J MAR FRESH	N. Z. J. Mar. Freshw. Res.		1987	21	4					543	553		10.1080/00288330.1987.9516258	http://dx.doi.org/10.1080/00288330.1987.9516258			11	Fisheries; Marine & Freshwater Biology; Oceanography	Science Citation Index Expanded (SCI-EXPANDED)	Fisheries; Marine & Freshwater Biology; Oceanography	N7888		Bronze			2025-03-11	WOS:A1987N788800001
J	TIMPANO, P; PFIESTER, LA				TIMPANO, P; PFIESTER, LA			OBSERVATIONS ON VAMPYRELLA-PENULA STYLODINIUM-SPHAERA AND THE ULTRASTRUCTURE OF THE REPRODUCTIVE CYST	AMERICAN JOURNAL OF BOTANY			English	Article								"Vampyrella-Stylodinium", an artificial name for a predaceous organism of uncertain taxonomic position, has at least three distinct phases in its life history: the amoeboid phase, both free-floating and attached; the feeding cyst or immobile phase; and flagellated gymnodinioid swarmers. The orange free-floating amoeba has unbranched, filose pseudopodia and several contractile vacuoles. When feeding on the filamentous green alga Oedogonium, the pseudopodia shorten and rearrange. After dissociation of part of the Oedogonium cell wall, the amoeba ingests the host protoplast. Then a stalked reproductive cyst may form. This cyst changes color from green to light orange as it matures. At the time of excystment, the cyst has a smooth outer wall, a spinose inner wall, and a well-delineated phagocytic vacuole. As this vacuole moves from its central position to the cyst''s periphery, the walls rupture and 2-4 amoebulae emerge. With TEM observations, the reproductive cyst is shown to be multinucleate. Each nucleus is eukaryotic in organization and possesses one nucleolus. Mitochondria have tubular cristae and no structures unique to the division Pyrrhophyta are observed. Although this stage of the life history does not have a dinokaryotic nucleus, the gymnodinioid swarmers that can emerge from the reproductive cyst, do. Like other parasites which have been assigned to the division of Pyrrhophyta, "Vampyrella-Stylodinium" does not conform well to the generalized concept of a dinoflagellate.	UNIV OKLAHOMA, DEPT BOT & MICROBIOL, NORMAN, OK 73019 USA									Baumeister W., 1943, Archiv fuer Protistenkunde Jena, V96, P344; BAUMEISTER WILLY, 1957, ARCH PROTISKENKUNDE, V102, P21; BRUGEROLLE G, 1979, PROTISTOLOGICA, V15, P183; CACHON J, 1977, CHROMOSOMA, V60, P237, DOI 10.1007/BF00329773; CACHON J, 1965, B I OCEANOGR MONACO, V359, P1; CANN JP, 1979, ARCH PROTISTENKD, V122, P226, DOI 10.1016/S0003-9365(79)80034-2; Cienkowski L, 1865, Archiv fr Mikroskopische Anatomie, V1, P203; Dodge J. D., 1973, FINE STRUCTURE ALGAL; DODGE JD, 1986, BIOL DINOFLAGELLATES; ERDTMAN G., 1960, SVENSK BOT TIDSKR, V54, P561; HORIGUCHI T, 1983, PHYCOLOGIA, V22, P23, DOI 10.2216/i0031-8884-22-1-23.1; HULSMANN N, 1982, PUBL WISS FILM 15 B; JOHANSEN DA, 1940, PLANT MICROTHECHIQUE; KLEBS G., 1912, Verh. Naturhist. - Med. Vereins Heidelberg, V11, P369; Leidy J., 1879, US Geological Survey of Territories, V12, P1; LLOYD F. E., 1929, ARCH PROTISTENK, V67, P219; LLOYD FRANCIS E., 1926, PAPERS MICHIGAN ACAD SCI, V7, P395; McCully ME, 1980, HDB PHYCOLOGICAL MET, P263; OBrien T.P., 1981, STUDY PLANT STRUCTUR; PAGE FC, 1967, T AM MICROSC SOC, V86, P405, DOI 10.2307/3224262; PASCHER A., 1927, ARCHIV JUR PROTISTENK, V58, P1; PASCHER A., 1944, Beih. Bot. Centralbl, V62A, P376; PEARLMUTTER NL, 1984, PROTOPLASMA, V122, P68, DOI 10.1007/BF01279438; POPOVSKY J, 1982, ARCH PROTISTENKD, V125, P115, DOI 10.1016/S0003-9365(82)80011-0; POPOVSKY J, 1987, DINOPHYCEAE, V6; SOYER MO, 1971, CHROMOSOMA, V33, P70, DOI 10.1007/BF00326385; SOYER MO, 1972, CHROMOSOMA, V39, P419, DOI 10.1007/BF00326176; SPECTOR D, 1985, DINOFLAGELLATES, P1; Starmach K., 1974, FLORA SLODKOWODNA PO, V4; SUREK B, 1980, ARCH PROTISTENKD, V123, P166, DOI 10.1016/S0003-9365(80)80003-0; THOMPSON RH, 1949, AM J BOT, V36, P301, DOI 10.2307/2437888; TIMPANO P, 1985, J PHYCOL, V21, P458; TIMPANO P, 1987, T AM MICROS SOC; ZINGMARK RG, 1970, AM J BOT, V57, P586, DOI 10.2307/2441057	34	6	6	1	2	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0002-9122	1537-2197		AM J BOT	Am. J. Bot.	SEP	1986	73	9					1341	1350		10.2307/2444068	http://dx.doi.org/10.2307/2444068			10	Plant Sciences	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences	D9689					2025-03-11	WOS:A1986D968900012
J	GARCON, VC; STOLZENBACH, KD; ANDERSON, DM				GARCON, VC; STOLZENBACH, KD; ANDERSON, DM			TIDAL FLUSHING OF AN ESTUARINE EMBAYMENT SUBJECT TO RECURRENT DINOFLAGELLATE BLOOMS	ESTUARIES			English	Article								A rhodamine dye tracer study was conducted over eight tidal cycles to investigate mixing and tidal exchange processes in Perch Pond, a Cape Cod [Massachusetts, USA] embayment subject to recurrent blooms of the toxic dinoflagellate, Gonyaulax tamarensis. Dye injected at the inlet to Perch Pond during flood tide became well-mixed within the pond in one day and was removed at an effective first order rate of 0.36 d-1, equivalent to a 70% utilization of the maximum possible tidal exchange. This relatively high flushing efficiency can be attributed to a density-driven circulation within the pond, consisting of a subsurface inflow of high salinity dense water on the flood tide followed by removal of lighter surface layers through the shallow inlet during ebb tide. The formation of a frontal convergence near the inlet on flood tide is consistent with the observed distribution of G. tamarensis cysts and shellfish toxicity. Is is also clear that phytoplankton like G. tamarensis, whose maximum growth rates approximate the rate of tidal flushing, can only bloom within the embayment by avoiding the outflowing surface waters. Mixing within the pond is probably less efficient and population losses greater during dry periods when the pond salinity is higher and the stratification weaker.	MIT, DEPT CIVIL ENGN, PARSONS LAB WATER RESOURCES & HYDRODYNAM, CAMBRIDGE, MA 02139 USA; WOODS HOLE OCEANOG INST, DEPT BIOL, WOODS HOLE, MA 02543 USA	Massachusetts Institute of Technology (MIT); Woods Hole Oceanographic Institution								AMOROCHO J, 1980, J GEOPHYS RES-OCEANS, V85, P433, DOI 10.1029/JC085iC01p00433; ANDERSON DM, 1982, LIMNOL OCEANOGR, V27, P757, DOI 10.4319/lo.1982.27.4.0757; ANDERSON DM, 1983, MAR BIOL, V76, P179, DOI 10.1007/BF00392734; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; ANDERSON DM, 1985, MAR ECOL PROG SER, V25, P39, DOI 10.3354/meps025039; ANDERSON DM, 1982, ESTUAR COAST SHELF S, V14, P447, DOI 10.1016/S0272-7714(82)80014-0; AUBREY DG, 1985, ESTUAR COAST SHELF S, V21, P185, DOI 10.1016/0272-7714(85)90096-4; BARLOW JP, 1956, J MAR RES, V15, P193; CRAWFORD RE, 1985, ESTUARIES, V8, P217, DOI 10.2307/1352202; CULLEN JJ, 1981, MAR BIOL, V62, P81, DOI 10.1007/BF00388169; DALE B, 1977, SARSIA, V63, P29, DOI 10.1080/00364827.1977.10411318; Hartwell A.D., 1975, P47; HEANEY S I, 1981, Journal of Plankton Research, V3, P331, DOI 10.1093/plankt/3.2.331; HEANEY SI, 1980, J ECOL, V68, P75, DOI 10.2307/2259245; HULBURT EM, 1956, BIOL BULL-US, V110, P157, DOI 10.2307/1538977; ISAJI T, 1985, ESTUARIES, V8, P203, DOI 10.2307/1352201; KAMYKOWSKI D, 1977, LIMNOL OCEANOGR, V22, P148, DOI 10.4319/lo.1977.22.1.0148; KETCHUM BH, 1951, J MAR RES, V10, P18; PRAKASH A, 1967, J FISH RES BOARD CAN, V24, P1589, DOI 10.1139/f67-131; Redfield A.C., 1980, TIDES WATERS NEW ENG; SCHREY SE, 1984, ESTUARIES, V7, P472, DOI 10.2307/1352050; SELIGER HH, 1970, LIMNOL OCEANOGR, V15, P234, DOI 10.4319/lo.1970.15.2.0234; Steidinger K.A., 1975, P153; THAYER PE, 1983, CAN J FISH AQUAT SCI, V40, P1308, DOI 10.1139/f83-149; TYLER MA, 1982, MAR ECOL PROG SER, V7, P163, DOI 10.3354/meps007163; TYLER MA, 1978, LIMNOL OCEANOGR, V23, P227, DOI 10.4319/lo.1978.23.2.0227; TYLER MA, 1981, LIMNOL OCEANOGR, V26, P310, DOI 10.4319/lo.1981.26.2.0310; Wall D., 1975, P249; WATRAS CJ, 1985, J PLANKTON RES, V7, P891, DOI 10.1093/plankt/7.6.891; WATRAS CJ, 1982, J EXP MAR BIOL ECOL, V62, P25, DOI 10.1016/0022-0981(82)90214-3	31	16	17	0	1	ESTUARINE RESEARCH FEDERATION	PORT REPUBLIC	2018 DAFFODIL, PO BOX 510, PORT REPUBLIC, MD 20676 USA	0160-8347			ESTUARIES	Estuaries	SEP	1986	9	3					179	187		10.2307/1352129	http://dx.doi.org/10.2307/1352129			9	Environmental Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Environmental Sciences & Ecology; Marine & Freshwater Biology	E7949					2025-03-11	WOS:A1986E794900003
J	BINDER, BJ; ANDERSON, DM				BINDER, BJ; ANDERSON, DM			GREEN LIGHT-MEDIATED PHOTOMORPHOGENESIS IN A DINOFLAGELLATE RESTING CYST	NATURE			English	Article											BINDER, BJ (通讯作者)，WOODS HOLE OCEANOG INST,DEPT BIOL,WOODS HOLE,MA 02543, USA.							ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, UNPUB LIMNOL OCEANOG; BINDER BJ, 1986, MIT WHOI869 WOODS HO; BRAUNE W, 1979, ARCH MICROBIOL, V122, P289, DOI 10.1007/BF00411293; CHAUVAT F, 1982, ARCH MICROBIOL, V133, P44, DOI 10.1007/BF00943768; Dale B., 1983, P69; DODGE JD, 1983, BRIT PHYCOL J, V18, P335, DOI 10.1080/00071618300650341; Dring M.J., 1983, Encyclopedia of plant physiology, New Series, Vol. 16 B, V16, P545; ENDO T, 1984, Bulletin of Plankton Society of Japan, V31, P23; FORWARD RB, 1970, PLANTA, V92, P248, DOI 10.1007/BF00388559; GUILLARD RR, 1962, CAN J MICROBIOL, V8, P229, DOI 10.1139/m62-029; Hall S., 1982, THESIS U ALASKA; HALLDAL PER, 1958, PHYSIOL PLANTARUM, V11, P118; HAND WG, 1967, BIOL BULL-US, V133, P150, DOI 10.2307/1539800; Hargraves P., 1983, SURVIVAL STRATEGIES, P49; HOLLIBAUGH JT, 1981, J PHYCOL, V17, P1; Huber G., 1923, FLORA JENA, V116, P114; KLEIN RM, 1979, PLANT PHYSIOL, V63, P114, DOI 10.1104/pp.63.1.114; KRUPA D, 1981, EKOL POL-POL J ECOL, V29, P545; LIPPS MJ, 1973, J PHYCOL, V9, P237; PFIESTER LA, BIOL DINOFLAGELLATES; REDDY PM, 1981, BIOCHEM PHYSIOL PFL, V176, P105; SHROPSHIRE W, 1983, ENCY PLANT PHYSL, V16; SHROPSHIRE W, 1983, ENCY PLANT PHYSL B, V16; TANADA T, 1983, PHYSIOL PLANTARUM, V58, P475, DOI 10.1111/j.1399-3054.1983.tb05730.x; YAMAMOTO Y, 1976, J GEN APPL MICROBIOL, V22, P311, DOI 10.2323/jgam.22.311	26	48	53	1	15	MACMILLAN MAGAZINES LTD	LONDON	PORTERS SOUTH, 4 CRINAN ST, LONDON, ENGLAND N1 9XW	0028-0836			NATURE	Nature	AUG 14	1986	322	6080					659	661		10.1038/322659a0	http://dx.doi.org/10.1038/322659a0			3	Multidisciplinary Sciences	Science Citation Index Expanded (SCI-EXPANDED)	Science & Technology - Other Topics	D6289					2025-03-11	WOS:A1986D628900063
J	JOHNSON, PT				JOHNSON, PT			PARASITES OF BENTHIC AMPHIPODS, DINOFLAGELLATES (DUBOSCQUODINIDA, SYNDINIDAE)	FISHERY BULLETIN			English	Article								During a 2 1/2-yr survey, 13 species of benthic amphipods collected from the continental shelf of the northern United States were found infected by dinoflagellates. Prevalences ranged from < 1% to 67%, depending on amphipod species, time, and place of collection. The parasites are assigned to the order Duboscquodinida, family Syndinidae, based on similar life histories and a similar kind of mitosis ("mitose syndinienne"). Two types of organisms were involved, both apparently more closely related to Hematodinium Chatton and Poisson than to other described syndinids. Morphology and development of the parasites and host-parasite interactions are discussed. A cytochemical method used to determine presence or absence of basic nuclear proteins was strongly positive for basic proteins in spores and prespores but negative in most other stages. A few spores in four infections possessed a distinct flagellum, but in the absence of living material, shape of spores and whether they were biflagellate could not be determined. With three possible exceptions in the group of 303 infections studied, the syndinids and fungi, only the fungi were being attacked by host hemocytes. High prevalences in certain of the amphipod species suggest that the syndinids might be population regulators in these species.	NOAA, NATL MARINE FISHERIES SERV, NW FISHERIES CTR, OXFORD, MD 21654 USA									ALFERT M, 1953, P NATL ACAD SCI USA, V39, P991, DOI 10.1073/pnas.39.10.991; Cachon J., 1964, Annales des Sciences Naturelles (12), V6, P1; Chatton E., 1920, Archives de Zoologie Experimentale Paris, V59; Chatton E, 1921, CR HEBD ACAD SCI, V173, P859; Chatton E, 1910, CR HEBD ACAD SCI, V151, P654; Chatton E., 1952, TRAITE ZOOL, P309; Chatton E.P.L., 1930, C.R. Seances Soc. Biol. Paris, V105, P553; DuPraw E.J., 1968, CELL MOL BIOL; HERZOG M, 1984, ORIGINS LIFE EVOL B, V13, P205, DOI 10.1007/BF00927172; HOLLANDE A, 1974, Protistologica, V10, P413; Jepps MW, 1937, Q J MICROSC SCI, V79, P589; JOHNSON PT, 1986, FISH B-NOAA, V84, P204; JOHNSON PT, 1985, FISH B-NOAA, V83, P497; LOEBLICH AR, 1976, J PROTOZOOL, V23, P13, DOI 10.1111/j.1550-7408.1976.tb05241.x; MACLEAN SA, 1978, J PARASITOL, V64, P158, DOI 10.2307/3279632; MANIER J-F, 1971, Protistologica, V7, P213; NEWMAN MW, 1975, J PARASITOL, V61, P554, DOI 10.2307/3279346; RIS H, 1974, J CELL BIOL, V60, P702, DOI 10.1083/jcb.60.3.702; RIZZO PJ, 1974, BIOCHIM BIOPHYS ACTA, V349, P402, DOI 10.1016/0005-2787(74)90126-9; SIEBERT AE, 1974, PROTOPLASMA, V81, P17, DOI 10.1007/BF02055771; STICKNEY AP, 1978, J INVERTEBR PATHOL, V32, P212, DOI 10.1016/0022-2011(78)90032-0; WU RS, 1982, CELL, V31, P367, DOI 10.1016/0092-8674(82)90130-1	22	34	39	0	0	NATL MARINE FISHERIES SERVICE SCIENTIFIC PUBL OFFICE	SEATTLE	7600 SAND POINT WAY NE BIN C15700, SEATTLE, WA 98115 USA	0090-0656	1937-4518		FISH B-NOAA	Fish. Bull.	JUL	1986	84	3					605	614						10	Fisheries	Science Citation Index Expanded (SCI-EXPANDED)	Fisheries	E2454					2025-03-11	WOS:A1986E245400010
J	MATSUOKA, K; FUKUYO, Y				MATSUOKA, K; FUKUYO, Y			CYST AND MOTILE MORPHOLOGY OF A COLONIAL DINOFLAGELLATE PHEOPOLYKRIKOS-HARTMANNII (ZIMMERMANN) COMB-NOV	JOURNAL OF PLANKTON RESEARCH			English	Article									UNIV TOKYO,DEPT FISHERIES,BUNKYO KU,TOKYO 113,JAPAN	University of Tokyo	MATSUOKA, K (通讯作者)，NAGASAKI UNIV,FAC LIBERAL ARTS,DEPT GEOL,1-14,BUNKYO MACHI,NAGASAKI 852,JAPAN.							ARENDS RG, 1980, QUATERNARY DEPOSITIO, P313; CAMPBELL PH, 1973, UNCSG7303 SEA GRANT, P407; CHATTON EDOUARD, 1933, BULL SOC ZOOL FRANCE, V58, P251; DODGE JD, 1983, MARINE DINOFLAGELLAT, P303; FUKYUO Y, 1982, FUNDAMENTAL STUDIES, P205; HARLAND R, 1981, Palynology, V5, P65; HULBURT EM, 1957, BIOL BULL-US, V112, P196, DOI 10.2307/1539198; IIZUKA S, 1979, MICROPHOTOGRAPHS IMP; LOEBLICH AR, 1980, TAXON, V29, P321, DOI 10.2307/1220299; MATSUOKA K, 1985, REV PALAEOBOT PALYNO, V44, P217, DOI 10.1016/0034-6667(85)90017-X; Matsuoka K., 1985, NATURAL SCI B, V25, P21; MATSUOKA K, 1982, FUNDAMENTAL STUDIES, P197; MOREYGAINES G, 1980, PHYCOLOGIA, V19, P230, DOI 10.2216/i0031-8884-19-3-230.1; REID PC, 1978, NEW PHYTOL, V80, P219, DOI 10.1111/j.1469-8137.1978.tb02284.x; SCHILLER J, 1983, KRYPTOGAMEN FLORA DE, V10, P433; Steidinger K.A., 1970, MEMOIRS HOURGLASS CR; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; ZIMMERMANN WALTER, 1930, ZEITSCHR BOT, V23, P419	18	35	36	0	4	OXFORD UNIV PRESS UNITED KINGDOM	OXFORD	WALTON ST JOURNALS DEPT, OXFORD, ENGLAND OX2 6DP	0142-7873			J PLANKTON RES	J. Plankton Res.	JUL	1986	8	4					811	818		10.1093/plankt/8.4.811	http://dx.doi.org/10.1093/plankt/8.4.811			8	Marine & Freshwater Biology; Oceanography	Science Citation Index Expanded (SCI-EXPANDED)	Marine & Freshwater Biology; Oceanography	D1565					2025-03-11	WOS:A1986D156500014
J	SANDGREN, CD; FLANAGIN, J				SANDGREN, CD; FLANAGIN, J			HETEROTHALLIC SEXUALITY AND DENSITY DEPENDENT ENCYSTMENT IN THE CHRYSOPHYCEAN ALGA SYNURA-PETERSENII KORSH	JOURNAL OF PHYCOLOGY			English	Article								Sexual reproduction of the common planktonic chrysophyte Synura petersenii is described from observations made on clonal isolates grown in defined culture. Sexual fusion was isogamous and heterothallic, with cells of normal appearance from compatible clones serving as hologametes. No special culture conditions were required to induce sexual behavior; actively growing cell populations appeared to be continually receptive to mating when mixed with a sufficient number of cells from a compatible clone. A single, bipolar mating group was documented containing five of the seven clones tested. Zygotic statospores were found to be binucleate and to contain 4 chloroplasts at maturity. Production rates of zygospores were low for even the most highly compatible clones, with batch culture yields ranging from 1-20% of final cell density under the culture conditions utilized. Six of the clones tested were also capable of very low frequency (0.001-0.01%) homothallic statospore production but the reproductive significance of these cysts remains enigmatic. The dynamics of sexual encystment suggest that the process proceeds during periods of active population growth and is density dependent. Based on the characteristics of cyst induction and encystment dynamics, it is concluded that chrysophycean flagellates may have a perennation strategy quite different from that that of the majority of planktonic diatoms, dinoflagellates, and green algae for which restingcyst production requires an exogenous trigger usually associated with physiological stress and periods of negative growth.	UNIV TEXAS, DEPT BIOL, ARLINGTON, TX 76019 USA	University of Texas System; University of Texas Arlington								ANDERSON DM, 1984, J PHYCOL, V20, P418, DOI 10.1111/j.0022-3646.1984.00418.x; BOURRELLY P, 1963, ANN NY ACAD SCI, V108, P421, DOI 10.1111/j.1749-6632.1963.tb13396.x; Bourrelly P., 1957, REV ALGOLOGIQUE MEMO, V1, P1; BRADLEY DE, 1966, J PROTOZOOL, V13, P143, DOI 10.1111/j.1550-7408.1966.tb01885.x; CAIN JR, 1976, J PHYCOL, V12, P383, DOI 10.1111/j.0022-3646.1976.00383.x; CRONBERG G, 1973, HYDROBIOLOGIA, V43, P29, DOI 10.1007/BF00014254; DAVIS CO, 1980, J PHYCOL, V16, P296; Doflein F., 1923, Archiv fuer Protistenkunde Jena, V46, P267; Drebes G., 1977, The Biology of Diatoms, P250; ELLIS RJ, 1968, AM J BOT, V55, P600, DOI 10.2307/2440615; FOTT B, 1964, PHYKOS, V3, P15; Fott B., 1959, NOVA HEDW, V1, P115; HANIC LA, 1979, STAIN TECHNOL, V54, P129, DOI 10.3109/10520297909112647; Hargraves P., 1983, SURVIVAL STRATEGIES, P49; HEANEY SI, 1983, BRIT PHYCOL J, V18, P47, DOI 10.1080/00071618300650061; KATES JR, 1964, J CELL COMP PHYSL, V63, P151; KIRK DL, 1986, SCIENCE, V231, P51, DOI 10.1126/science.3941891; KRISTIANSEN J., 1961, BOT TIDSSKR, V57, P306; KRISTIANSEN JORGEN, 1963, BOT TEDSSKR, V59, P244; LEHMAN JT, 1976, LIMNOL OCEANOGR, V21, P646, DOI 10.4319/lo.1976.21.5.0646; OKELLEY JC, 1983, J PHYCOL, V19, P57, DOI 10.1111/j.0022-3646.1983.00057.x; PFIESTER LA, 1979, PHYCOLOGIA, V18, P13, DOI 10.2216/i0031-8884-18-1-13.1; Sandgren C.D., 1983, P23; SANDGREN CD, 1981, J PHYCOL, V17, P199, DOI 10.1111/j.0022-3646.1981.00199.x; SANDGREN CD, 1980, PROTISTOLOGICA, V16, P289; SANDGREN CD, 1986, CHRYSOPHYTES ASPECTS; SANDGREN CD, 1978, THESIS U WASHINGTON; SHEATH RG, 1975, J PHYCOL, V11, P131, DOI 10.1111/j.1529-8817.1975.tb02760.x; Sokal RR., 1981, BIOMETRY; TURPIN DH, 1978, J PHYCOL, V14, P235, DOI 10.1111/j.1529-8817.1978.tb02454.x; Von Stosch HA., 1973, Br Phycol J, V8, P105; VONSTOSCH HA, 1967, ENCY PLANT PHYSL, V18, P637; WALKER LM, 1979, J PHYCOL, V15, P312; Wawrik F., 1972, Nova Hedwigia, V23, P353; WAWRIK F, 1981, ARCH PROTISTENKD, V124, P283, DOI 10.1016/S0003-9365(81)80021-8; WAWRIK F, 1970, Archiv fuer Protistenkunde, V112, P259; WAWRIK F, 1960, ARCH PROTISTENKD, V104, P542; WAWRIK F, 1980, NOVA HEDWIGIA, V33, P789	38	34	38	0	8	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0022-3646	1529-8817		J PHYCOL	J. Phycol.	JUN	1986	22	2					206	216		10.1111/j.1529-8817.1986.tb00014.x	http://dx.doi.org/10.1111/j.1529-8817.1986.tb00014.x			11	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	C9253					2025-03-11	WOS:A1986C925300014
J	LUBIAN, LM; ESTABLIER, R; YUFERA, M; FERNANDEZALES, R				LUBIAN, LM; ESTABLIER, R; YUFERA, M; FERNANDEZALES, R			STUDIES ON THE PHYTOPLANKTON IN SALT-MARSHES OF CADIZ (SW SPAIN) USED FOR EXTENSIVE FISH CULTURE	INVESTIGACION PESQUERA			Spanish	Article								Qualitative and quantitative (photosynthetic pigments) variations in the phytoplankton of 3 salt-marshes of the Cadiz area, used for fish culture, was analyzed. The dynamics of the phytoplankton population is closely related to the hydrology and management of these fish-ponds, which have a yearly cycle with 2 characteristic periods. The 1st one, with free-water renovation depending on tidal flow, and the 2nd with limited water-renovation when the pond-gates remain closed. In stagnant periods, generally during the summer months, the phytoplankton biomass increases, but due only to those species capable of growth at higher salinities. The diatom population is replaced with dinoflagellates, which are usually found in cyst form. Cluster analysis showed a closer relationship between the phytoplankton communities in the farthest salt-marshes. Pronounced qualitative variations unrelated with the recorded physicochemical factors were found. These results support the incidence of unknown variables in the presence of some species. The dominant organisms are the dinoflagellates (Prorocentrum scutellum, P. marinum and Peridinium subsalsum) and the Eustigmatophyceae Nannochloropsis sp.			INST INVEST PESQUERAS CADIZ, PUERTO PESQUERO SN, E-11006 CADIZ, SPAIN.		Yufera, Manuel/E-1309-2011; LUBIAN, LUIS/L-7241-2014						0	12	12	0	2	INST INVESTIGACIONES PESQUERAS	BARCELONA	PASEO NACIONAL S/N, 3 BARCELONA, SPAIN	0020-9953			INVEST PESQ		JUN	1985	49	2					175	218						44	Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Marine & Freshwater Biology	A2658					2025-03-11	WOS:A1985A265800004
J	MARANDA, L; ANDERSON, DM; SHIMIZU, Y				MARANDA, L; ANDERSON, DM; SHIMIZU, Y			COMPARISON OF TOXICITY BETWEEN POPULATIONS OF GONYAULAX-TAMARENSIS OF EASTERN NORTH-AMERICAN WATERS	ESTUARINE COASTAL AND SHELF SCIENCE			English	Article								Isolates of the dinoflagellate Gonyaulax tamarensis were established from benthic cysts or motile cells collected along the north-western Atlantic coast from the Bay of Fundy [Canada] to Long Island [USA]. All clones were grown under the same conditions and assayed in a blind test for toxin content and composition. Differences in toxin content (.mu.mouse unit per cell) spanning two orders of magnitude were found, with decreasing toxicity from north to south. Some isolates had undetectable toxin levels. The low toxicity of southern strains of G. tamarensis may explain the historical absence of paralytic shellfish poisoning (PSP) in areas where cysts and motile cells have been reported. The cause of the observed geographic pattern is unknown, but it does suggest that there may be an environmentally-determined southern limit to the regional PSP problem. Qualitative data on the toxin composition of some clones indicate that saxitoxin, neosaxitoxin and gonyautoxins-II, -III and -IV are generally present. A more quantitative approach (i.e. one which examines each isolate for all of the 12 Gonyaulax toxins) is needed to fully utilize the potential of toxin composition in discriminating between strains.	WOODS HOLE OCEANOG INST, DEPT BIOL, WOODS HOLE, MA 02543 USA; UNIV RHODE ISL, GRAD SCH OCEANOG, KINGSTON, RI 02881 USA; UNIV RHODE ISL, DEPT PHARMACOGNOSY & ENVIRONM HLTH SCI, KINGSTON, RI 02881 USA									ALAM MI, 1979, J PHYCOL, V15, P106, DOI 10.1111/j.0022-3646.1979.00106.x; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; ANDERSON DM, 1982, ESTUAR COAST SHELF S, V14, P447, DOI 10.1016/S0272-7714(82)80014-0; BRAND LE, 1981, EVOLUTION, V35, P1117, DOI 10.1111/j.1558-5646.1981.tb04981.x; CARPENTER EJ, 1970, ECOLOGY, V52, P183; DALE B, 1977, SARSIA, V63, P29, DOI 10.1080/00364827.1977.10411318; Fukuyo Y., 1979, P61; GALLAGHER JC, 1982, J PHYCOL, V18, P148, DOI 10.1111/j.1529-8817.1982.tb03169.x; GALLAGHER JC, 1980, J PHYCOL, V16, P464; GENENAH AA, 1981, J AGR FOOD CHEM, V29, P1289, DOI 10.1021/jf00108a047; GUILLARD RR, 1962, CAN J MICROBIOL, V8, P229, DOI 10.1139/m62-029; Hall S., 1982, THESIS U ALASKA; HASHIMOTO Y, 1976, B JPN SOC SCI FISH, V42, P671; HAYHOME BA, 1983, AM J BOT, V70, P1165, DOI 10.2307/2443286; HORWITZ W, 1980, OFFICIAL METHODS ANA, P298; HURST JW, 1979, TOXIC DINOFLAGELLATE, P231; Lewis C.M., 1979, P235; LOEBLICH LA, 1975, 1ST P INT C TOX DIN, P207; OSHIMA Y, 1982, B JPN SOC SCI FISH, V48, P1303; OSHIMA Y, 1982, B JPN SOC SCI FISH, V48, P851; PRAKASH A, 1967, J FISH RES BOARD CAN, V24, P1589, DOI 10.1139/f67-131; Prakash A, 1971, Bull Fish Res Bd Can, V177, P1; SCHMIDT RJ, 1979, J MAR BIOL ASSOC UK, V59, P479, DOI 10.1017/S0025315400042788; SCHMIDT RJ, 1978, J PHYCOL, V14, P5, DOI 10.1111/j.0022-3646.1978.00005.x; SCHREY SE, 1984, ESTUARIES, V7, P472, DOI 10.2307/1352050; Shimizu Y., 1979, P321; Shimizu Y., 1978, MARINE NATURAL PRODU, P1; SHIMIZU Y, 1984, FORTSCHRITTE CHEM OR, V46, P235; SIEBURTH JM, 1971, DEEP-SEA RES, V18, P1111, DOI 10.1016/0011-7471(71)90096-9; SINGH HT, 1982, B JPN SOC SCI FISH, V48, P1341; THAYER PE, 1983, CAN J FISH AQUAT SCI, V40, P1308, DOI 10.1139/f83-149; UNDERHILL PA, 1977, J PHYCOL, V13, P170, DOI 10.1111/j.0022-3646.1977.00170.x; WHITE AW, 1978, J FISH RES BOARD CAN, V35, P397, DOI 10.1139/f78-070; WHITE AW, 1978, J PHYCOL, V14, P475; WHITE AW, 1982, CAN J FISH AQUAT SCI, V39, P1185, DOI 10.1139/f82-156; YENTSCH CM, 1978, J PHYCOL, V14, P330, DOI 10.1111/j.1529-8817.1978.tb00307.x	37	75	82	0	3	ACADEMIC PRESS LTD- ELSEVIER SCIENCE LTD	LONDON	24-28 OVAL RD, LONDON NW1 7DX, ENGLAND	0272-7714	1096-0015		ESTUAR COAST SHELF S	Estuar. Coast. Shelf Sci.		1985	21	3					401	410		10.1016/0272-7714(85)90020-4	http://dx.doi.org/10.1016/0272-7714(85)90020-4			10	Marine & Freshwater Biology; Oceanography	Science Citation Index Expanded (SCI-EXPANDED)	Marine & Freshwater Biology; Oceanography	ASR42					2025-03-11	WOS:A1985ASR4200009
J	OWEN, KC; NORRIS, DR				OWEN, KC; NORRIS, DR			CYSTS AND LIFE-CYCLE CONSIDERATIONS OF THE THECATE DINOFLAGELLATE FRAGILIDIUM	JOURNAL OF COASTAL RESEARCH			English	Article									FLORIDA INST TECHNOL,DEPT OCEANOG & OCEAN ENGN,MELBOURNE,FL 32901	Florida Institute of Technology	OWEN, KC (通讯作者)，RECRA RES INC,4248 RIDGE LEA RD,AMHERST,NY 14226, USA.							ANDERSON DM, 1980, J PHYCOL, V16, P166; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; [Anonymous], 1974, FOSSIL LIVING DINOFL; BALECH E, 1959, BIOL BULL-US, V116, P195, DOI 10.2307/1539204; CORLISS JO, 1974, T AM MICROSC SOC, V93, P578, DOI 10.2307/3225158; DONNELLY PJ, 1980, THESIS FLORIDA I TEC, P22; OWEN K C, 1982, Florida Scientist, V45, P227; OWEN KC, 1979, THESIS FLORIDA I TEC, P17; STEIDINGER KA, 1975, 1ST P INT C TOX DIN, P153; STEIDINGER KA, 1967, FLORIDA BOARD CONSER, V52, P36; SWIFT E, 1972, PHYCOLOGIA, V11, P62; TURPIN DH, 1978, J PHYCOL, V14, P235, DOI 10.1111/j.1529-8817.1978.tb02454.x; Van Wagtendonk W.J., 1955, BIOCH PHYSL PROTOZOA, V2nd edition, P85; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; WALL D, 1966, REV PALAEOBOTANY PAL, V2, P249	15	12	13	0	2	COASTAL EDUCATION & RESEARCH FOUNDATION	LAWRENCE	810 EAST 10TH STREET, LAWRENCE, KS 66044	0749-0208			J COASTAL RES	J. Coast. Res.		1985	1	3					263	&						0	Environmental Sciences; Geography, Physical; Geosciences, Multidisciplinary	Science Citation Index Expanded (SCI-EXPANDED)	Environmental Sciences & Ecology; Physical Geography; Geology	AJZ06					2025-03-11	WOS:A1985AJZ0600006
J	ANDERSON, DM; LINDQUIST, NL				ANDERSON, DM; LINDQUIST, NL			TIME-COURSE MEASUREMENTS OF PHOSPHORUS DEPLETION AND CYST FORMATION IN THE DINOFLAGELLATE GONYAULAX-TAMARENSIS LEBOUR	JOURNAL OF EXPERIMENTAL MARINE BIOLOGY AND ECOLOGY			English	Article								Time-course measurements were made during the transition from asexual to sexual reproduction and cyst formation in P-limited batch cultures of the dinoflagellate G. tamarensis Lebour. The initial phase of growth was predominantly asexual, during which time the intracellular and extracellular P pools decreased steadily in the light and the dark. Cellular P dropped to a subsistence cell quota of 27 pg/cell as division ceased. This gradual decrease in cellular P in the presence of .mu. molar PO34- concentrations suggests that this species may encyst in natural waters in response to nutrient limitation at concentrations above analytical detection limits. As the cells approached plateau phase, asexual growth ceased and sexual reproduction occurred, marked by an initial decrease in average cell diameter; a subsequent increase in diameter through time as gametes fused, forming swimming zygotes (planozygotes); and a possible surge in division rate. Although the motile population appeared to reach a typical plateau or stationary growth phase, the population was changing in composition as planozygotes formed and cysts fell from suspension. Planozygote numbers increased gradually over a 4-day interval, followed 6 days later by a parallel increase in cyst numbers. Gamete formation and/or fusion did not occur in sudden, synchronized fashion, or alternatively that the duration of planozygote development varied as the batch cultures aged. Approximately 20% of all motile cells successfully completed encystment.	UNIV CALIF SAN DIEGO, SCRIPPS INST OCEANOG, LA JOLLA, CA 92093 USA	University of California System; University of California San Diego; Scripps Institution of Oceanography	WOODS HOLE OCEANOG INST, DEPT BIOL, WOODS HOLE, MA 02543 USA.							ANDERSON DM, 1980, J PHYCOL, V16, P166; ANDERSON DM, 1983, MAR BIOL, V76, P179, DOI 10.1007/BF00392734; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; ANDERSON DM, 1982, ESTUAR COAST SHELF S, V14, P447, DOI 10.1016/S0272-7714(82)80014-0; ANDERSON DM, 1984, J PHYCOL, V20, P418, DOI 10.1111/j.0022-3646.1984.00418.x; BEAM CA, 1974, NATURE, V250, P435, DOI 10.1038/250435a0; BIEBEL P, 1964, AM J BOT, V51, P697, DOI 10.2307/2440208; CAIN JR, 1976, J PHYCOL, V12, P383, DOI 10.1111/j.0022-3646.1976.00383.x; COATS DW, 1984, J PHYCOL, V20, P351, DOI 10.1111/j.0022-3646.1984.00351.x; CURRIE DJ, 1984, LIMNOL OCEANOGR, V29, P298, DOI 10.4319/lo.1984.29.2.0298; DALE B, 1977, SARSIA, V63, P29, DOI 10.1080/00364827.1977.10411318; Fogg G.E., 1965, Algal cultures and phytoplankton Ecology; GUILLARD RR, 1962, CAN J MICROBIOL, V8, P229, DOI 10.1139/m62-029; MENZEL DAVID W., 1965, LIMNOL OCEANOGR, V10, P280; MOREYGAINES G, 1980, PHYCOLOGIA, V19, P230, DOI 10.2216/i0031-8884-19-3-230.1; OKELLEY JC, 1983, J PHYCOL, V19, P57, DOI 10.1111/j.0022-3646.1983.00057.x; PFIESTER LA, 1977, J PHYCOL, V13, P92, DOI 10.1111/j.0022-3646.1977.00092.x; PFIESTER LA, 1976, J PHYCOL, V12, P234; PFIESTER LA, 1975, J PHYCOL, V11, P259, DOI 10.1111/j.1529-8817.1975.tb02776.x; PFIESTER LA, BIOL DINOFLAGELLATES; PRAKASH A, 1973, J FISH RES BOARD CAN, V30, P143, DOI 10.1139/f73-028; SAGER R, 1954, J GEN PHYSIOL, V37, P729, DOI 10.1085/jgp.37.6.729; Steidinger K.A., 1975, P153; Strickland J.D.H., 1972, B FISH RES BOARD CAN, V157, P310, DOI DOI 10.1002/IROH.19700550118; TRAINOR FR, 1958, AM J BOT, V45, P621, DOI 10.2307/2439236; TURPIN DH, 1978, J PHYCOL, V14, P235, DOI 10.1111/j.1529-8817.1978.tb02454.x; Von Stosch HA., 1973, Br Phycol J, V8, P105; WALKER LM, 1979, J PHYCOL, V15, P312; Wall D., 1975, P249; WALL D, 1970, Phycologia, V9, P151, DOI 10.2216/i0031-8884-9-2-151.1; Wall D., 1971, Geoscience Man, V3, P1; WATANABE MM, 1982, EUTROPHICATION RED T, P27; ZINGMARK RG, 1970, J PHYCOL, V6, P122, DOI 10.1111/j.0022-3646.1970.00122.x	34	110	117	1	9	ELSEVIER	AMSTERDAM	RADARWEG 29, 1043 NX AMSTERDAM, NETHERLANDS	0022-0981	1879-1697		J EXP MAR BIOL ECOL	J. Exp. Mar. Biol. Ecol.		1985	86	1					1	13		10.1016/0022-0981(85)90039-5	http://dx.doi.org/10.1016/0022-0981(85)90039-5			13	Ecology; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Environmental Sciences & Ecology; Marine & Freshwater Biology	AGB13					2025-03-11	WOS:A1985AGB1300001
J	TIMPANO, P; PFIESTER, LA				TIMPANO, P; PFIESTER, LA			COLONIZATION OF THE EPINEUSTON BY CYSTODINIUM-BATAVIENSE (DINOPHYCEAE) - BEHAVIOR OF THE ZOOSPORE	JOURNAL OF PHYCOLOGY			English	Article								C. bataviense Klebs is the 1st dinoflagellate observed to exhibit specialized zoospore behavior which result in colonization of the epineuston. The zoospore is strongly phototactic; changes shape rapidly upon release; possess at last 2 types of swimming behavior, including a stop mechanism and sheds it theca as the new cell wall asymmetrically elongates into the immobile vegetative stage. These features working in concert facilitate the entrance of Cystodinium into the epineuston. Detailed observations of zoospore morphology and analysis of its behavior are used as new characters to further delimit C. bataviense. Since vegetative morphology has proven unsatisfactory in circumscribing other Cystodinium spp., the study of variation in zoospore characters will help to clarify taxonomic units within the genus.	UNIV OKLAHOMA, DEPT BOT MICROBIOL, NORMAN, OK 73019 USA	University of Oklahoma System; University of Oklahoma - Norman								Baumeister W., 1963, Archiv fuer Protistenkunde, V106, P535; Baumeister W., 1938, Archiv fuer Protistenkunde Jena, V91, P462; BAUMEISTER W, 1957, ARCH PROTISTENKD, V102, P258; BAUMEISTER W, 1957, ARCH PROTISTENKD, V102, P240; BAUMEISTER WILLY, 1957, ARCH PROTISKENKUNDE, V102, P21; BAUMEISTER WILLY, 1957, ARCH PROTISTENKUNDE, V102, P1; CAREFOOT JR, 1968, J PHYCOL, V4, P129, DOI 10.1111/j.1529-8817.1968.tb04686.x; GEITLER LOTHAR, 1928, ARCH PROTIS TENK, V61, P1; GEITLER LOTHAR, 1928, ARCH PROTISTENK, V63, P67; GUILLARD RR, 1972, J PHYCOL, V8, P10, DOI 10.1111/j.1529-8817.1972.tb03995.x; HUBERPESTALOZZI G, 1968, BINNENGEWASSER 3, V16; Johansen DA., 1940, PLANT MICRO TECHNIQU; KLEBS G., 1912, Verh. Naturhist. - Med. Vereins Heidelberg, V11, P369; MAZIA D, 1975, J CELL BIOL, V66, P198, DOI 10.1083/jcb.66.1.198; McCully ME, 1980, HDB PHYCOLOGICAL MET, P263; OBrien T.P., 1981, STUDY PLANT STRUCTUR; PARKER BC, 1974, J PHYCOL, V10, P185; PASCHER A., 1928, ARCH PROTISTENK, V63, P241; PASCHER A., 1927, ARCHIV JUR PROTISTENK, V58, P1; Pearse AGE., 1968, HISTOCHEMISTRY THEOR, V1; PFIESTER LA, 1980, PHYCOLOGIA, V19, P178, DOI 10.2216/i0031-8884-19-3-178.1; Round, 1981, ECOLOGY ALGAE; STARMACH K, 1974, FLORA STODKOWODNA PO, V4; THOMPSON R H, 1984, Transactions of the Kansas Academy of Science, V87, P83, DOI 10.2307/3627841; THOMPSON RH, 1949, AM J BOT, V36, P301, DOI 10.2307/2437888	25	5	6	1	3	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0022-3646	1529-8817		J PHYCOL	J. Phycol.		1985	21	1					56	62						7	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	AEY52					2025-03-11	WOS:A1985AEY5200007
J	ANDERSON, DM; COATS, DW; TYLER, MA				ANDERSON, DM; COATS, DW; TYLER, MA			ENCYSTMENT OF THE DINOFLAGELLATE GYRODINIUM-UNCATENUM - TEMPERATURE AND NUTRIENT EFFECTS	JOURNAL OF PHYCOLOGY			English	Article								Sexual reproduction and encystment of the marine dinoflagellate G. uncatenum Hulburt were induced in N- and P-limited batch cultures. Sexuality did not occur under nutrient-replete conditions even when growth rate was reduced by non-optimal temperatures. Growth was optimal over a broader temperature range than encystment and virtually no cysts were produced at some low and high temperatures where growth occurred. Most cells initiated sexuality as intracellular pools of each limiting nutrient reached minimum or subsistence levels as much as 4 days after extracellular nutrients were exhausted. High N cell quotas during the P experiment indicate that sexuality was induced by a shortage of P and not by an indirect effect on N uptake. Total cyst yield corresponded to successful encystment of 9-13% of the motile populations, yet 60-85% of the plateau-phase motile cells were planozygotes (swimming zygotes formed from fusing gametes). Batch culture studies monitoring total cyst yield may thus seriously underestimate the extent of sexuality. More importantly, the number of cysts produced in a dinoflagellate population may be significantly reduced by environmental factors acting on the cells after sexual induction and infusion.	UNIV DELAWARE, COLL MARINE STUDIES, LEWES, DE 19958 USA; JOHNS HOPKINS UNIV, CHESAPEAKE BAY INST, SHADY SIDE, MD 20764 USA		WOODS HOLE OCEANOG INST, DEPT BIOL, WOODS HOLE, MA 02543 USA.							ANDERSON DM, 1985, J EXP MAR BIOL ECOL, V86, P1, DOI 10.1016/0022-0981(85)90039-5; ANDERSON DM, 1984, J PHYCOL, V20, P418, DOI 10.1111/j.0022-3646.1984.00418.x; COATS DW, 1984, J PHYCOL, V20, P351, DOI 10.1111/j.0022-3646.1984.00351.x; DARDEN WH, 1966, J PROTOZOOL, V13, P239, DOI 10.1111/j.1550-7408.1966.tb01901.x; GUILLARD RR, 1962, CAN J MICROBIOL, V8, P229, DOI 10.1139/m62-029; MENZEL DAVID W., 1965, LIMNOL OCEANOGR, V10, P280; PFIESTER LA, 1975, J PHYCOL, V11, P259, DOI 10.1111/j.1529-8817.1975.tb02776.x; PFIESTER LA, 1985, BIOL DINOFLAGELLATES; STARR RC, 1970, AM J BOT, V45, P621; Strickland J.D.H., 1972, B FISH RES BOARD CAN, V157, P310, DOI DOI 10.1002/IROH.19700550118; Tuffrau M., 1967, Protistologica, V3, P91; TYLER MA, 1982, MAR ECOL PROG SER, V7, P163, DOI 10.3354/meps007163; Von Stosch HA., 1973, Br Phycol J, V8, P105; WALKER LM, 1979, J PHYCOL, V15, P312; Watanabe M., 1982, RES REP NAT I ENV ST, V30, P27; WATRAS CJ, 1982, J EXP MAR BIOL ECOL, V62, P25, DOI 10.1016/0022-0981(82)90214-3	16	88	97	2	11	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0022-3646	1529-8817		J PHYCOL	J. Phycol.		1985	21	2					200	206						7	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	AKJ29					2025-03-11	WOS:A1985AKJ2900005
J	ANDERSON, DM; LIVELY, JJ; REARDON, EM; PRICE, CA				ANDERSON, DM; LIVELY, JJ; REARDON, EM; PRICE, CA			SINKING CHARACTERISTICS OF DINOFLAGELLATE CYSTS	LIMNOLOGY AND OCEANOGRAPHY			English	Article								This study reports the first direct measurements of the density and sinking rates of marine dinoflagellate cysts. Gyrodinium uncatenum, Gonyaulax tamarensis, and Scrippsiella trochoidea cysts had densities of 1.14, 1.24, and 1.32 g cm-3. No significant difference between cultured and natural cyst density was observed. Measured settling velocities ranged from 0.008 to 0.013 cm s-1 (6-11 m d-1). Settling rates calculated using the measured densities and reasonable assumptions about shape and orientation during descent were within 10-20% of measured sinking rates, confirming that cyst sinking can be described by a modification of Stokes'' law for nonspherical particles in a viscous medium. The three types of cysts examined are more dense and fall faster than most vegetative phytoplankton cells. Removal of an outer layer of short calcite spines from S. trochoidea cysts reduced both cell density and radius by 7% and the sinking rate by 37%. The faster settling velocity of the spiny cyst is not considered a general effect common to all ornamented cysts but presumably applies only to those with numerous short spines or processes. Morphological features can thus markedly affect the rate of cyst deposition, but the adaptive significance of surface ornamentation remains unknown.	WOODS HOLE OCEANOG INST, DEPT BIOL, WOODS HOLE, MA 02543 USA; RUTGERS STATE UNIV, WAKSMAN INST MICROBIOL, PISCATAWAY, NJ 08854 USA									ANDERSON DM, 1984, ACS SYM SER, V262, P125; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1984, J PHYCOL, V20, P418, DOI 10.1111/j.0022-3646.1984.00418.x; Bibby B.T., 1972, British phycol J, V7, P85; Chaloner W G, 1971, SPOROPOLLENIN, P273; CHAPMAN DV, 1982, J PHYCOL, V18, P121, DOI 10.1111/j.0022-3646.1982.00121.x; COATS DW, 1984, J PHYCOL, V20, P351, DOI 10.1111/j.0022-3646.1984.00351.x; CONWAY K, 1972, J PHYCOL, V8, P138, DOI 10.1111/j.0022-3646.1972.00138.x; DALE B, 1976, REV PALAEOBOT PALYNO, V22, P39, DOI 10.1016/0034-6667(76)90010-5; DALE B, 1978, Palynology, V2, P187; DALE B, 1982, SURVIVAL STRATEGIES, P69; DAVIES CN, 1947, T I CHEM ENG S, V25, P25; DURR G, 1979, ARCH PROTISTENKD, V122, P121; Eppley R.W., 1967, J EXP MAR BIOL ECOL, V1, P191; GUILLARD RR, 1962, CAN J MICROBIOL, V8, P229, DOI 10.1139/m62-029; KOMAR PD, 1980, J GEOL, V88, P327, DOI 10.1086/628510; McNOWN J. S., 1950, TRANS AMER GEOPHYS UNION, V31, P74; OLIVER RL, 1981, LIMNOL OCEANOGR, V26, P285, DOI 10.4319/lo.1981.26.2.0285; Orr C., 1966, Particulate Technology; PFIESTER LA, BIOL DINOFLAGELLATES; PRICE CA, 1978, LIMNOL OCEANOGR, V23, P548, DOI 10.4319/lo.1978.23.3.0548; RICKWOOD D, 1975, FEBS LETT, V50, P102, DOI 10.1016/0014-5793(75)80467-4; SARJEANT WA, PALYNOLOGY; Smayda T. J., 1970, Oceanogr. mar. Biol., V8, P353; SMAYDA THEODORE J., 1965, LIMNOL OCEANOGR, V10, P499; Sussman AS., 1966, SPORES THEIR DORMANC; TAGHON GL, 1984, LIMNOL OCEANOGR, V29, P64, DOI 10.4319/lo.1984.29.1.0064; TYLER MA, 1982, MAR ECOL PROG SER, V7, P163, DOI 10.3354/meps007163; WALL D, 1970, Phycologia, V9, P151, DOI 10.2216/i0031-8884-9-2-151.1; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; Wall D., 1971, Geoscience Man, V3, P1; WALSBY AE, 1977, BRIT PHYCOL J, V12, P215, DOI 10.1080/00071617700650231; Warth A D, 1978, Adv Microb Physiol, V17, P1, DOI 10.1016/S0065-2911(08)60056-9	33	108	116	0	13	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0024-3590	1939-5590		LIMNOL OCEANOGR	Limnol. Oceanogr.		1985	30	5					1000	1009		10.4319/lo.1985.30.5.1000	http://dx.doi.org/10.4319/lo.1985.30.5.1000			10	Limnology; Oceanography	Science Citation Index Expanded (SCI-EXPANDED)	Marine & Freshwater Biology; Oceanography	ASJ67					2025-03-11	WOS:A1985ASJ6700008
J	ANDERSON, DM; STOLZENBACH, KD				ANDERSON, DM; STOLZENBACH, KD			SELECTIVE RETENTION OF 2 DINOFLAGELLATES IN A WELL-MIXED ESTUARINE EMBAYMENT - THE IMPORTANCE OF DIEL VERTICAL MIGRATION AND SURFACE AVOIDANCE	MARINE ECOLOGY PROGRESS SERIES			English	Article								Diel vertical migration patterns of the dinoflagellates of Gonyauylax tamarensis and Heterocapsa triquetra were monitored in an estaurine embayment subject to localized blooms of both species. A concurrent study of tidal flushing using a dye tracer demonstrated an efficient, density-driven mixing process that exchanged water within the embayment at a rate of .apprx. 0.5 d-1. Loss rates of the whole pond populations of G. tamarensis and H. triquetra cells were smaller, ranging between 0.02 and 0.13 d-1. The cells were able to maintain a non-mixed distribution even under weakly stratified conditions. This selective retention of the 2 spp. relative to water exchange was due to the differential advection of surface and bottom waters through the inlet channel and the general avoidance of high irradiance surface layers by the dinoflagellates. Both species migrated to irradiances equivalent to 30% of summer sunlight when nutrients were presumably non-limiting, resulting in subsurface aggregations 1-2 m deep. Under nutrient-limited conditions, G. tamarensis migration was restricted to irradiance at or below 10-15% summer sunlight. Planozygotes (a life-cycle stage preceding cyst formation) migrated in a manner indistinguishable from the remainder of the nutrient-limited G. tamarensis population. The results help to explain the dominance of dinoflagellates in such embayments, the localization of their blooms, and the distribution of their resting cysts in the region.	MIT, DEPT CIVIL ENGN, CAMBRIDGE, MA 02139 USA	Massachusetts Institute of Technology (MIT)	WOODS HOLE OCEANOG INST, DEPT BIOL, WOODS HOLE, MA 02543 USA.							ANDERSON DM, 1982, LIMNOL OCEANOGR, V27, P757, DOI 10.4319/lo.1982.27.4.0757; ANDERSON DM, 1983, MAR BIOL, V76, P179, DOI 10.1007/BF00392734; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; ANDERSON DM, 1982, ESTUAR COAST SHELF S, V14, P447, DOI 10.1016/S0272-7714(82)80014-0; ANDERSON DM, 1984, J PHYCOL, V20, P418, DOI 10.1111/j.0022-3646.1984.00418.x; ANDERSON DM, 1985, J EXP MAR BIOL ECOL, V85, P1; BOOTH CR, 1976, LIMNOL OCEANOGR, V21, P326, DOI 10.4319/lo.1976.21.2.0326; BRAARUD T, 1951, NORSE VIDENSK AKA MN, V1, P1; CULLEN JJ, 1981, MAR BIOL, V62, P81, DOI 10.1007/BF00388169; Eppley R.W., 1975, P11; EPPLEY RW, 1968, J PHYCOL, V4, P333, DOI 10.1111/j.1529-8817.1968.tb04704.x; Forward Jr R.B., 1976, PHOTOCHEM PHOTOBIOL, V1, P157; GEORGE DG, 1978, J ECOL, V66, P133, DOI 10.2307/2259185; HAND WG, 1965, BIOL BULL-US, V128, P90, DOI 10.2307/1539392; HARRIS GP, 1979, FRESHWATER BIOL, V9, P413, DOI 10.1111/j.1365-2427.1979.tb01526.x; HEANEY S I, 1981, Journal of Plankton Research, V3, P331, DOI 10.1093/plankt/3.2.331; HEANEY SI, 1980, J ECOL, V68, P75, DOI 10.2307/2259245; HEANEY SI, 1976, FRESHWATER BIOL, V6, P531, DOI 10.1111/j.1365-2427.1976.tb01644.x; HEANEY SI, 1980, FRESHWATER BIOL, V10, P163, DOI 10.1111/j.1365-2427.1980.tb01190.x; HEANEY SI, 1974, FRESHWATER BIOL, V4, P103, DOI 10.1111/j.1365-2427.1974.tb00080.x; HOLMES RW, 1967, LIMNOL OCEANOGR, V12, P503, DOI 10.4319/lo.1967.12.3.0503; HULBURT EM, 1956, BIOL BULL-US, V110, P157, DOI 10.2307/1538977; KAMYKOWSKI D, 1977, LIMNOL OCEANOGR, V22, P148, DOI 10.4319/lo.1977.22.1.0148; MACISAAC JJ, 1978, LIMNOL OCEANOGR, V23, P1; MORRILL L C, 1981, Journal of Plankton Research, V3, P53, DOI 10.1093/plankt/3.1.53; SCHREY SE, 1984, ESTUARIES, V7, P472, DOI 10.2307/1352050; SELIGER HH, 1970, LIMNOL OCEANOGR, V15, P234, DOI 10.4319/lo.1970.15.2.0234; STRICKLAND JDH, 1972, B FISH RES BD CAN, V167; Taylor F.J.R., 1979, P47; TYLER MA, 1978, LIMNOL OCEANOGR, V23, P227, DOI 10.4319/lo.1978.23.2.0227; TYLER MA, 1981, LIMNOL OCEANOGR, V26, P310, DOI 10.4319/lo.1981.26.2.0310; WATRAS CJ, 1982, J EXP MAR BIOL ECOL, V62, P25, DOI 10.1016/0022-0981(82)90214-3; YENTSCH CM, 1984, ACS SYM SER, V262, P9	34	102	105	0	8	INTER-RESEARCH	OLDENDORF LUHE	NORDBUNTE 23, D-21385 OLDENDORF LUHE, GERMANY	0171-8630	1616-1599		MAR ECOL PROG SER	Mar. Ecol.-Prog. Ser.		1985	25	1					39	50		10.3354/meps025039	http://dx.doi.org/10.3354/meps025039			12	Ecology; Marine & Freshwater Biology; Oceanography	Science Citation Index Expanded (SCI-EXPANDED)	Environmental Sciences & Ecology; Marine & Freshwater Biology; Oceanography	ANY33		Bronze			2025-03-11	WOS:A1985ANY3300005
J	RIDING, JB; SARJEANT, WAS				RIDING, JB; SARJEANT, WAS			THE ROLE OF DINOFLAGELLATE CYSTS IN THE BIOSTRATIGRAPHICAL SUBDIVISION OF THE JURASSIC SYSTEM	NEWSLETTERS ON STRATIGRAPHY			English	Article									BRITISH GEOL SURVEY,NOTTINGHAM NG12 5GG,ENGLAND; UNIV SASKATCHEWAN,SASKATOON C7N 0W0,SASKATCHEWAN,CANADA	UK Research & Innovation (UKRI); Natural Environment Research Council (NERC); NERC British Geological Survey; University of Saskatchewan								[Anonymous], 1974, FOSSIL LIVING DINOFL; Arkell W.J., 1956, Monograph of the Palaeontographical Society; ARKELL WJ, 1946, B GEOL SOC AM, V57, P1; Beju D., 1971, ANN I GEOLOGICI PUBL, V54, P276; BJAERKE T, 1980, Palynology, V4, P57; BRADFORD M R, 1984, Palaeontographica Abteilung B Palaeophytologie, V192, P16; COPE JCW, 1980, 15 GEOL SOC LOND SPE; COPE JCW, 1980, 14 GEOL SOC LOND SPE; Davey RJ., 1979, AM ASS STRATIGRAPHIC, V5B, P49; DAVIES EH, 1983, B GEOL SURV CAN, V359; DEFLANDRE G, 1941, MEM ACAD SCI I FR, V65; Deflandre G., 1938, TRAVAUX STATION ZOOL, V13, P147; DORHOFER G., 1980, EVOLUTION ARCHEOPYLE; EHRENBERG C.G., 1843, VERHANDLUNGEN PREUSS, P100; EHRENBERG CG, 1954, MIKROGEOLOGIE ERDEN; Eisenack A., 1936, Zeitschrift fuer Geschiebeforschung, V12, P72; EISENACK A, 1935, Z GESCHIEBEFORSCH, V11, P167; EISENACK ALFRED, 1936, ANN PROTISTOLOGIE, V5, P59; ERKMEN U, 1980, GEOBIOS, P45; Fisher M.J., 1980, P 4 INT PAL C LUCHN, V2, P313; GITMEZ GU, 1972, B BR MUS NAT HIS G, V21, P171; Harland W.B., 1982, GEOLOGIC TIME SCALE; JOHNSON C D, 1973, Bulletin of Canadian Petroleum Geology, V21, P178; Klement K. W., 1960, Palaeontographica, VA114, P1; LENTIN JK, 1981, B1R8112 BEDF I OC RE; MERCIER J, 1938, C R SOMM SOC GEOL FR, V17, P334; MERCIER J, 1938, COMPT REND SOC GEOL, P114; Morgenroth P., 1970, Neues Jb. Geol. Palaont. Abh., V136, P345; NORRIS G., 1975, AM ASS STRAT PALY CO, V4, P29; ODIN GS, 1982, EPISODES, P3; RIDING JB, P YORKS GEOL SOC LEE, V45; RILEY L A, 1982, Palynology, V6, P193; Riley L.A., 1972, GEOPHYTOLOGY, V2, P1; Sarjeant W. A. S., 1965, Revue de Micropaleontologie, V8, P175; Sarjeant W.A.S., 1980, Acta Palaeontologica Polonica, V25, P279; Sarjeant W. A. S., 1962, Micropaleontology, V8, P255, DOI 10.2307/1484746; Sarjeant W.A.S., 1982, Journal of Micropalaeontology, V1, P85; SARJEANT W. A. S., 1961, PALAEONTOLOGY, V4, P90; Sarjeant WAS, 1960, P YORKS GEOL SOC, V32, P389; SARJEANT WAS, 1978, PALYNOLOGY, V2, P209; SARJEANT WAS, 1968, REV PALAEOBOT PALYNO, V5, P327; SARJEANT WAS, 1964, 1962 C JUR LUX, P441; SARJEANT WAS, 1972, DINOFLAGELLATE CYSTS, V195, P1; SARJEANT WAS, 1975, AM ASS STRATIGRAPHIC, V4, P51; SARJEANT WAS, 1976, GEOBIOS, P5; SARJEANT WAS, 1979, AM ASS STRATIGR PA B, V5, P133; Sarjeant WAS., 1962, PALAEONTOLOGY, V5, P478; Thusu B., 1978, DISTRIBUTION BIOSTRA, P61; TORRENS HS, 1980, 14 GEOL SOC LOND SPE, P16; VANHINTE JE, 1976, AAPG BULL, V60, P489; WESTERMANN G, 1984, EPISODES, V7, P26, DOI 10.18814/epiiugs/1984/v7i2/006; Wille W., 1982, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V164, P74; Wille W., 1979, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V158, P221; Williams G.L., 1977, Oceanic Micropalaeontology, V2, P1231; WISEMAN JF, 1980, 4 INT PAL C LUCKN, V2, P330; WOOLLAM R, 1983, 832 I GEOL SCI REP; 1983, B AM ASS PETROL GEOL, V67, P841; 1967, P GEOL SOC LOND, V1638, P75	58	11	11	0	0	GEBRUDER BORNTRAEGER	STUTTGART	JOHANNESSTR 3A, D-70176 STUTTGART, GERMANY	0078-0421			NEWSL STRATIGR	Newsl. Stratigr.		1985	14	2					96	&						0	Geology	Science Citation Index Expanded (SCI-EXPANDED)	Geology	AMK75					2025-03-11	WOS:A1985AMK7500003
J	EVITT, WR; GOCHT, H; NETZEL, H				EVITT, WR; GOCHT, H; NETZEL, H			GONYAULAX CYSTS FROM LAKE ZURICH SEDIMENTS	REVIEW OF PALAEOBOTANY AND PALYNOLOGY			English	Article								Dinoflagellate cysts were recovered from a core of sediments from Lake Zurich that were deposited during the first decades of this century. The distribution of ridges and pustulate ornament, as well as the position and form of the archeopyle, support reconstruction of a Gonyaulax-type paratabulation. The characters of the cyst covering indicate relationship to the living freshwater species Gonyaulax apiculata (Penard) Entz.	UNIV TUBINGEN, INST & MUSEUM GEOL & PALAONTOL, D-7400 TUBINGEN 1, GERMANY; UNIV TUBINGEN, INST BIOL 3, D-7400 TUBINGEN 1, GERMANY	Eberhard Karls University of Tubingen; Eberhard Karls University of Tubingen	STANFORD UNIV, DEPT GEOL, STANFORD, CA 94305 USA.							BOURRELLY P, 1980, Cryptogamie Algologie, V1, P161; ENTZ G, 1904, BEITRAGE KENNTNIS PL, P1; Evitt W.R., 1985, pi; GOCHT H, 1979, NEUES JB GEOLOGIE PA, P305; HICKEL B, UNPUB MORPHOLOGY ECO; Huber G., 1923, FLORA JENA, V116, P114; Huber-Pestalozzi G., 1968, PHYTOPLANKTON SUSSWA; JARNEFELT H, 1959, VIERTELJAHR NATURFOR, V104, P403; Kofoid Charles Atwood, 1909, Archiv fuer Protistenkunde Jena, V16; MARTIN PAUL, 1961, SCHWEIZ ZEIT HYDROL, V23, P462, DOI 10.1007/BF02505449; Penard E., 1891, Bull. Trav. Soc. Bot. Geneve, V6, P1; TAYLOR FJR, 1980, BIOSYSTEMS, V13, P65, DOI 10.1016/0303-2647(80)90006-4; Thomas E. A., 1964, Vierteljahrsschrift der Naturforschenden Gesellschaft in Zurich, V109, P103; WOLOSZYNSKA J, 1916, B INT ACAD SCI CRA B, V14, P260	14	17	17	0	5	ELSEVIER	AMSTERDAM	RADARWEG 29, 1043 NX AMSTERDAM, NETHERLANDS	0034-6667	1879-0615		REV PALAEOBOT PALYNO	Rev. Palaeobot. Palynology		1985	45	1-2					35	46		10.1016/0034-6667(85)90064-8	http://dx.doi.org/10.1016/0034-6667(85)90064-8			12	Plant Sciences; Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Paleontology	ASR60					2025-03-11	WOS:A1985ASR6000004
J	SARJEANT, WAS				SARJEANT, WAS			THE GERMAN APTIAN DINOFLAGELLATE CYSTS OF EISENACK (1958) - A RESTUDY	REVIEW OF PALAEOBOTANY AND PALYNOLOGY			English	Article								A re-examination of the type material of Late Aptian dinoflagellate cyst taxa described by Eisenack (1958) has resulted in a variety of taxonomic revisions. Tenua hystrix (Eisenack) is shown to be a senior synonym of Cerbia tabulata (Davey and Verdier); accordingly, the latter species is abandoned and the generic name Tenua reinstated, with a revised diagnosis corresponding to that of Cerbia Below. The diagnosis of Apteodinium is emended and retention of the genus Archeotectatum provisionally recommended. Two new species are recognized, Apteodinium thelium (formerly part of A. granulatum Eisenack) and Leptodinium gitmezae, the latter for Late Jurassic forms assigned originally to Leptodinium (now Cibroperidinium) aceras. Five new combinations are proposed, each with revised diagnoses: Acanthaulax? tenuiceras (Eisenack), Cribroperidinium aceras (Eisenack), Florentinia? neptuni (Eisenack), Parvocavatus? scutellus (Eisenack) and Rhynchodiniopsis microceras (Eisenack). Revised diagnoses are presented for the genus Pterodinium and seven other species: Achomosphaera hirundo (Eisenack), Apteodinium granulatum Eisenack, Cribroperidinium orthoceras (Eisenack), Dingodinium europaeum Eisenack, Kleithriasphaeridium eoinodes (Eisenack), Pterodinium aliferum Eisenack and Tenua hystrix Eisenack. Following these revisions, four other morphotypes are distinguished as also present in the assemblage: Apteodinium cf. conjunctum Eisenack and Cookson, Diphasiosphaera stolidota Duxbury, Occisucysta echinata Duxbury and Spiniferites cf. heterostylis (Heisecke). In addition, a form described by Eisenack as Pterospermopsis cf. danica W. Wetzel is shown to be a Caligodinium and compared with C. aceras (Manum and Cookson). An extensive bibliographical survey is presented for each taxon discussed. Whilst known ranges of the nineteen taxa distinguished herein accord well enough with the Late Aptian date assigned by Eisenack, it is stressed that several of those taxa are known so far only from his assemblages.			UNIV SASKATCHEWAN, DEPT GEOL SCI, GEN PURPOSE BLDG, ROOM 1082, SASKATOON S7N 0W0, SASKATCHEWAN, CANADA.							Alberti G., 1961, Palaeontographica, V116, P1; [Anonymous], PALAEONTOLOGY; [Anonymous], [No title captured]; [Anonymous], 1970, CAHIERS MICROPALEONT; [Anonymous], INITIAL REPORTS DEEP; [Anonymous], [No title captured]; ANTONESCU E, 1980, DS I GEOL GEOFIZ, V65, P5; ARTZNER D, 1979, R ONT MUS LIFE SCI M; Ashraf A.R., 1979, Palaeontographica Abteilung B Palaeophytologie, V169, P122; BALTES N, 1965, PETROL GAZE, V16, P3; BALTES N., 1963, PETROL SI GAZE, V14, P581; BALTES N, 1969, PET GAZE, V20, P332; BALTES N, 1966, REV PALAEOBOT PALYNO, V2, P183; Barss M.S., 1979, Geol. Surv. 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W., 1960, Palaeontographica, VA114, P1; LENTIN JK, 1981, BIR8112 BEDF I OC RE; LENTIN JK, 1973, 73 GEOL SURV CAN PAP; LENTIN JK, 1977, BIR778 BEDF I OC REP; Mantell G.A, 1850, A Pictorial Atlas of Fossil Remains Consisting of Coloured Illustrations Selected from Parkinson's "Organic Remains of a Former World", and Artis's "Antediluvian Phytology; Manum S., 1964, Skrifter utgitt av det Norske Videnskapsakademi Mat Nat Kl NS, VNo. 17, P1; MEHROTRA NC, 1984, MICROPALEONTOLOGY, V30, P292, DOI 10.2307/1485691; MICHAEL E, 1964, MITT GEOL I TECH HOC, V2, P22; MILLIOUD M E, 1967, Review of Palaeobotany and Palynology, V5, P155, DOI 10.1016/0034-6667(67)90219-9; Millioud M.E., 1969, Proceedings int Conf Plankt Microfoss, V2, P420; MILLIOUD ME, 1967, B VER SCHWEIZ PET GE, V33, P67; MORGAN R, 1980, MEM GEOL SURV NSW PA, V18; Morgan R., 1978, INIT REPS DSDP, V40, P915; NeaLE J.W., 1962, GEOL MAG, V99, P439; Norris G., 1978, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V156, P1; NORRIS G, 1965, NZ GEOL SURV PALEONT, V40; PIASECKI S, 1979, Bulletin of the Geological Society of Denmark, V28, P31; Playford G., 1975, Neues Jb Geol Paleont Abh, V149, P333; Pocock S.A.J., 1972, Palaeontographica Abteilung B Palaeophytologie, V137, P85; POCOCK SAJ, 1980, 4 INT PAL C LUCKN P, V2, P377; Reneville P. 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S, 1968, R MICROPALEONTOL, V10, P221; Sarjeant W.A.S., 1978, GRANA, V17, P47; Sarjeant WA., 1974, BIRBAL SAHNI I PALAE, V3, P9; SARJEANT WAS, 1966, B BRIT MUS NAT HIS S, V3, P107; SARJEANT WAS, 1982, AM ASS STRATIGR PALY, V9; SARJEANT WAS, 1966, B BRIT MUSEUM NAT S, V3, P199; SARJEANT WILLIAM ANTONY S., 1966, GRANA PALYNOL, V6, P503; SINGH C, 1971, RES COUNC ALBERTA B, V28; SRIVASTAVA NC, 1969, J SEN MEMORIAL VOLUM, P101; STOVER L E, 1978, Stanford University Publications in the Geological Sciences, V15, P1; TAKAHASHI K, 1980, B FAC LIB ARTS NAGAS, V20, P7; Takahashi K., 1981, T P PALAEONTOLOGICAL, V122, P105; VAVRDOVA M, 1964, SBOR GEOL VED R P, V4, P91; Verdier J.-P., 1975, Revue Micropaleont, V17, P191; von Benedek P.N., 1981, Nova Hedwigia, V35, P313; Vozzhennikova T.F., 1967, Extinct Peridinieae from the Jurassic, Cretaceous, and Paleogene Beds of the USSR; VOZZHENNIKOVA TF, 1971, NATIONAL LENDING LIB, P1; Wetzel O., 1933, Palaeontographica Stuttgart, V77, P141; WETZEL O., 1933, PALAEONTOGRAPHICA A, V78, P1; WETZEL W., 1952, GEOLOGISCHES JB HAMM, V66, P391; WILLIAMS G.L., 1978, INITIAL REPORTT FHE, P783; Williams G.L., 1975, GEOL SURV CAN BULL, V236, P1; WILLIAMS GL, 1974, GEOL SURV CAN PAP, V7450, P1; WILLIAMS GL, 1975, GEOLOGICAL SURVEY CA, V7430, P107; WILLIAMS GL, 1980, INITIAL REPORTS DEEP, V50, P467; WISEMAN JF, 1974, INIT REPTS DSDP, V27, P915; YU J, 1980, B CHIN ACAD GEOL S I, P93; YUN H-S, 1981, Palaeontographica Abteilung B Palaeophytologie, V177, P1	133	21	24	0	0	ELSEVIER	AMSTERDAM	RADARWEG 29, 1043 NX AMSTERDAM, NETHERLANDS	0034-6667	1879-0615		REV PALAEOBOT PALYNO	Rev. Palaeobot. Palynology		1985	45	1-2					47	106		10.1016/0034-6667(85)90065-X	http://dx.doi.org/10.1016/0034-6667(85)90065-X			60	Plant Sciences; Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Paleontology	ASR60					2025-03-11	WOS:A1985ASR6000005
J	WILLE, W; GOCHT, H				WILLE, W; GOCHT, H			SOLITARY AND CHAIN FORMING DINOFLAGELLATE CYSTS FROM THE JURASSIC OF SW GERMANY	REVIEW OF PALAEOBOTANY AND PALYNOLOGY			German	Article								Chain-forming dinoflagellate cysts have been found in marine Middle Jurassic sediments of SW Germany and described as DINAURELIA pyrgos gen. nov., sp. nov. They may be closely related to Mancodinium and Dapcodinium. Speculations on the formation of the cyst chain ("cystocone") and the autecology of Dinaurelia are presented. Solitary cysts called ROSSWANGIA simplex gen. nov., sp. nov. show a very similar general morphology.			UNIV TUBINGEN, INST GEOL PALAONTOL, SIGWARTSTR 10, D-7400 TUBINGEN 1, GERMANY.							ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ARTZNER D, 1979, R ONT MUS LIFE SCI M; Balech E., 1977, REV MUSEO ARGENTINO, V5, P115; Buck E., 1966, Jahresheft der Geologischen Landesamt in Baden-Wuerttemberg, V8, P23; Chatton E., 1952, TRAITE ZOOL, P309; DAVIES E. H., 1983, GEOL SURV CAN B, V359, P1; DIETL G, 1983, Jahreshefte der Gesellschaft fuer Naturkunde in Wuerttemberg, V138, P75; DIETL G, 1978, STUTTGARTER BEITRA B, V40, P1; DIETL G, 1981, STUTTGARTER BEITRAGE, V81, P1; Dietl G., 1984, JAHRESBERICHTE MITTE, V66, P307, DOI [10.1127/jmogv/66/1984/307, DOI 10.1127/JMOGV/66/1984/307]; DORHOFER G, 1980, R ONT MUS LIFE SCI M; EATON G L, 1980, Palaeontology (Oxford), V23, P667; Evitt W.R., 1967, Stanford University Publications, Geological Sciences, V10, P1; EVITT WR, 1961, J PALEONTOL, V35, P996; Fenton J.P.G., 1980, Palaeontology (Oxford), V23, P151; FRANZ M, 1982, THESIS U HEIDELBERG; HARLAND R, 1981, Palynology, V5, P65; Klement K. W., 1964, Bulletin Scripps Institution of Oceanography, V8, P347; Kofoid C.A., 1911, U CALIF PUBL ZOOL, V8, P287; LINDEMANN E., 1928, NAT RLICHEN PFLANZEN, P3; Morgenroth P., 1970, Neues Jb. Geol. Palaont. Abh., V136, P345; Norris G., 1978, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V156, P1; Norris G., 1978, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V155, P300; PETERS N, 1940, TIERWELT NORDUND OST, V1, P13; Sarjeant WA., 1974, BIRBAL SAHNI I PALAE, V3, P9; SCHOLZ H, 1966, THESIS U TUBINGEN; WALKER LM, 1979, J PHYCOL, V15, P312; WOOLLAM R, 1983, I GEOL SCI REP, V83, P1	28	2	2	0	0	ELSEVIER	AMSTERDAM	RADARWEG 29, 1043 NX AMSTERDAM, NETHERLANDS	0034-6667	1879-0615		REV PALAEOBOT PALYNO	Rev. Palaeobot. Palynology		1985	45	1-2					121	147		10.1016/0034-6667(85)90067-3	http://dx.doi.org/10.1016/0034-6667(85)90067-3			27	Plant Sciences; Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Paleontology	ASR60					2025-03-11	WOS:A1985ASR6000007
J	RIDING, JB; PENN, IE; WOOLLAM, R				RIDING, JB; PENN, IE; WOOLLAM, R			DINOFLAGELLATE CYSTS FROM THE TYPE AREA OF THE BATHONIAN STAGE (MIDDLE JURASSIC, SOUTHWEST ENGLAND)	REVIEW OF PALAEOBOTANY AND PALYNOLOGY			English	Article								The Bathonian sequence of the type area, around Bath, southwest England, yields diverse and well-preserved organic-walled microplankton floras dominated by ctenidodinioid dinoflagellate cysts, principally Ctenidodinium combazii Dupin 1968, and Dichadogonyaulax sellwoodii Sarjeant 1975 together with lesser numbers of Korystocysta spp. The stratigraphical distribution of dinoflagellate cysts within the Bathonian indicates few biostratigraphical events likely to be of correlative value. Comparison with other areas suggests that the geographical distribution of the dominant species reflects the supposed salinity levels of Bathonian surface waters, C. combazii being less tolerant of reduced salinity than D. sellwoodii or Korystocysta spp.	BP RES CTR, Sunbury On Thames TW16 7LN, MIDDX, ENGLAND	BP	BRITISH GEOL SURVEY, NOTTINGHAM NG12 5GG, ENGLAND.							[Anonymous], 1980, Special Papers; BEJU D, 1983, J PALEONTOL, V57, P106; CONWAY BH, 1978, REV PALAEOBOT PALYNO, V26, P337, DOI 10.1016/0034-6667(78)90041-6; Davis J.E., 1981, Journal of the University of Sheffield Geological Society, V7, P333; DODEKOVA L, 1975, BULG ACAD SCI PALAEO, V2, P17; DUPIN F, 1968, ARCH ORIG CENT D 1 8, V450, P1; FENSOME RA, 1979, GRONLANDS GEOLOGISKE, V132, P1; Fenton J.P.G., 1980, Palaeontology (Oxford), V23, P151; FENTON JPG, 1981, REV PALAEOBOT PALYNO, V31, P249; FENTON JPG, 1978, PALINOLOGIA NUMERO E, V1, P233; Gocht H., 1970, PALAEONTOGRAPHICA B, V129, P125; GOCHT H, 1984, NEUES JB GEOL PAL, P341; HERNGREEN GFW, 1978, PALINOLOGIA NUM EXTR, V1, P283; LENTIN JK, 1981, BIR8112 BEDF I OC RE, P1; PENN IE, 1976, I GEOL SCI LONDON RE, V766, P1; PENN IE, UNPUB CORRELATION BA; PENN IE, 1979, I GEOL SCI LONDON RE, V7822, P1; Riding J.B., 1982, Journal of Micropalaeontology, V1, P13; SARJEANT W A S, 1974, Grana, V14, P49; SARJEANT W A S, 1976, Geobios (Villeurbanne), V9, P5, DOI 10.1016/S0016-6995(76)80017-4; SARJEANT WAS, 1975, SCOTT J GEOL, V11, P143; SARJEANT WAS, 1972, KOMM VIDENSK UNDERS, V195, P1; TAUGOURDEAULANT.J, 1984, DOCUMENTS BRGM, V8111, P59; VALENSI LIONEL, 1953, MEM SOC GEOL FRANCE, V68, P1; WALL D, 1977, MAR MICROPALEONTOL, V2, P121, DOI 10.1016/0377-8398(77)90008-1; WOOLLAM R, 1983, Palynology, V7, P183; WOOLLAM R, 1983, I GEOL SCI LONDON RE, V832, P1	27	43	45	0	3	ELSEVIER	AMSTERDAM	RADARWEG 29, 1043 NX AMSTERDAM, NETHERLANDS	0034-6667	1879-0615		REV PALAEOBOT PALYNO	Rev. Palaeobot. Palynology		1985	45	1-2					149	+		10.1016/0034-6667(85)90068-5	http://dx.doi.org/10.1016/0034-6667(85)90068-5			1	Plant Sciences; Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Paleontology	ASR60					2025-03-11	WOS:A1985ASR6000008
J	MATSUOKA, K				MATSUOKA, K			ARCHEOPYLE STRUCTURE IN MODERN GYMNODINIALEAN DINOFLAGELLATE CYSTS	REVIEW OF PALAEOBOTANY AND PALYNOLOGY			English	Article								Cysts of 5 spp. of gymnodinialean dinoflagellates [Gyrodinium instriatum, Cocholodinium sp., Polykrikos kofoidii, P. hartmannii, and P. schwartzi] are described. The aperture of excystment is morphologically different from the archeopyle as typically developed in some peridinialean dinoflagellates. Two major types were observed in these cysts, and they are described and named. The "chasmic archeopyle" shows a linear to slightly curved rupture. The "tremic archeopyle" marks a circular to nearly circular hole. The geographical distribution of these cysts around the Japanese Islands is shown.			NAGASAKI UNIV, FAC LIBERAL ARTS, DEPT GEOL, NAGASAKI 852, JAPAN.							[Anonymous], 1977, CONTRIBUTIONS STRATI; ARENDS RG, 1980, QUATERNARY DEPOSITIO, P313; Chatton E., 1914, ARCH ZOOLOGIE EXPT, V54, P157; DALE B, 1977, BRIT PHYCOL J, V12, P241, DOI 10.1080/00071617700650261; Dale B., 1983, P69; DODGE JD, 1983, MARINE DINOFLAGELLAT; Evitt W. R., 1961, Micropaleontology, V7, P385, DOI 10.2307/1484378; Evitt W.R., 1967, Stanford University Publications, Geological Sciences, V10, P1; EVITT WR, 1963, P NATL ACAD SCI USA, V49, P158, DOI 10.1073/pnas.49.2.158; Evitt WR., 1969, Aspects of palynology, P439; EVITT WR, 1968, STANFORD U PUBL GEOL, V2, P1; FREUDENTHAL HD, 1963, J PROTOZOOL, V10, P182, DOI 10.1111/j.1550-7408.1963.tb01659.x; FUKUYO Y, 1982, FUNDAMENTAL STUDIES, P205; HARLAND R, 1981, Palynology, V5, P65; Harland R., 1977, Palaeontographica Abteilung B Palaeophytologie, V164, P87; Hensen V., 1887, BER KOMM WISS UNTERS, V5, P1; LENTIN JK, 1976, BIR7516 BEDF I OC RE, P1; LISTER T.R., 1970, PALAEONTOLOGICAL SOC, V124, P1; Loeblich A. R. Jr., 1969, Revista Espanola de Micropaleontologia, V1, P45; MATSUOKA K, 1982, FUNDAMENTAL STUDIES, P197; MOREYGAINES G, 1980, PHYCOLOGIA, V19, P230, DOI 10.2216/i0031-8884-19-3-230.1; REID PC, 1978, NEW PHYTOL, V80, P219, DOI 10.1111/j.1469-8137.1978.tb02284.x; Tappan H., 1980, P1; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690	24	45	47	0	2	ELSEVIER	AMSTERDAM	RADARWEG 29, 1043 NX AMSTERDAM, NETHERLANDS	0034-6667	1879-0615		REV PALAEOBOT PALYNO	Rev. Palaeobot. Palynology		1985	44	3-4					217	231		10.1016/0034-6667(85)90017-X	http://dx.doi.org/10.1016/0034-6667(85)90017-X			15	Plant Sciences; Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Paleontology	ALJ06					2025-03-11	WOS:A1985ALJ0600005
J	HARA, S; TANOUE, E				HARA, S; TANOUE, E			PROTIST ALONG 150-DEGREES-E IN THE SOUTHERN-OCEAN - ITS COMPOSITION, STOCK AND DISTRIBUTION	TRANSACTIONS OF THE TOKYO UNIVERSITY OF FISHERIES-TOKYO SUISAN DAIGAKU TOKUBETSU KENKYU HOKOKU			English	Article								Surface seawater samples were collected along 150.degree. E in the Australian sector of the Southern Ocean during Feb. 8-16, 1984. Protists in the samples were analyzed by light and EM to elucidate the quantitative and qualitative characteristics of their distribution. The predominant group of protists were dinoflagellates throughout the areas examined. The subdominant group was diatoms in the Antarctic water and coccolithophorids in the subtropical water. Transitional change between the subdominant 2 groups was observed in the Subantarctic region. Two major peaks were observed in the horizontal distribution of the total cell volume: the one located in the northern part of the Antarctic Ocean was dominated by diatoms, and the other located in the northern Subantarctic area was dominated by dinoflagellates. The significance of fronts as biological boundaries was investigated. Subantarctic Front (SAF) was the major southern boundary for the species of dinoflagellates and coccolithophorids in their southward distribution. Antarctic Polar Front (APF) and/or Subtropical Convergence (STC) were the major boundaries for the northward distributions of diatoms, coccolithophorids and siliceous, cysts. In dinoflagellates SAF as well as STC were the major northern boundaries of their northward distribution. Amoebae and colorless dinoflagellates were the common and the main components of the heterotrophic protists. The ratio of the colorless cell volume to the total cell volume varied from 0%-25% (7% In average) throughout areas surveyed.			KOBE UNIV, GRAD SCH SCI & TECHNOL, NADA KU, KOBE 657, JAPAN.							BALECH E, 1968, ANTARCTIC MAP FOLIO, P8; BOOTH B C, 1981, Biological Oceanography, V1, P57; BOOTH BC, 1980, MAR BIOL, V58, P205, DOI 10.1007/BF00391877; BUCK KR, 1983, DEEP-SEA RES, V30, P1261, DOI 10.1016/0198-0149(83)90084-5; Fukase S, 1962, ANTARCT REC, V15, P53; HASLE GR, 1969, HVALRADETS SKRIFTER, V52, P6; HASLE GR, 1968, ANTARCTIC MAP FOLIO, P6; HENDEY NI, 1964, MINISTRY AGRICULTU 4, P1; IORIYA T, 1982, Transactions of the Tokyo University of Fisheries, P129; MAEDA M, 1985, T TOKYO UNIV FISH, P23; MATSUURA N, 1985, T TOKYO UNIV FISH, P9; MITCHELL JG, 1982, NATURE, V296, P437, DOI 10.1038/296437a0; NISHIDA S, 1979, 3 OS MUS NAT HIST MI; PALNCKE J, 1977, ADAPTATION ANTARCTIC, P51; SILVER MW, 1980, MAR BIOL, V58, P211, DOI 10.1007/BF00391878; TAKAHASHI E, 1984, PHYCOLOGIA, V23, P103, DOI 10.2216/i0031-8884-23-1-103.1; Tanoue E., 1984, MEM NAT I POLAR RES, V32, P1	17	3	3	0	1	TOKYO UNIV FISHERIES LIBRARY	TOKYO	KONAN 4-5-7 MINATO-KU, TOKYO, 108, JAPAN	0388-0966			T TOKYO UNIV FISH			1985		6					99	115						17	Fisheries	Science Citation Index Expanded (SCI-EXPANDED)	Fisheries	ATL49					2025-03-11	WOS:A1985ATL4900009
J	ANDERSON, DM				ANDERSON, DM			SHELLFISH TOXICITY AND DORMANT CYSTS IN TOXIC DINOFLAGELLATE BLOOMS	ACS SYMPOSIUM SERIES			English	Review											WOODS HOLE OCEANOG INST, DEPT BIOL, WOODS HOLE, MA 02543 USA.							ALAM MI, 1979, J PHYCOL, V15, P106, DOI 10.1111/j.0022-3646.1979.00106.x; ANDERSON D, UNPUB; ANDERSON DM, 1980, J PHYCOL, V16, P166; ANDERSON DM, 1982, LIMNOL OCEANOGR, V27, P757, DOI 10.4319/lo.1982.27.4.0757; ANDERSON DM, 1983, MAR BIOL, V76, P179, DOI 10.1007/BF00392734; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; ANDERSON DM, 1982, ESTUAR COAST SHELF S, V14, P447, DOI 10.1016/S0272-7714(82)80014-0; ANDERSON DM, UNPUB SEXUALITY CYST, V2; BEAM CA, 1980, BIOCH PHYSL PROTOZOA, V2, P171; BICKNELL WJ, 1975, TOXIC DINOFLAGELLATE, P447; BOURNE N, 1965, J FISH RES BOARD CAN, V22, P1137, DOI 10.1139/f65-102; BRAND LE, 1981, MAR BIOL, V62, P103, DOI 10.1007/BF00388171; CLEVE PT, 1900, SVENSKA VETENSKAPSAK, P32; DALE B, 1978, SCIENCE, V201, P1223, DOI 10.1126/science.201.4362.1223; DALE B, 1977, SARSIA, V63, P29, DOI 10.1080/00364827.1977.10411318; Dale B., 1983, P69; Dale B., 1979, P443; GALLAGHER JC, 1982, J PHYCOL, V18, P148, DOI 10.1111/j.1529-8817.1982.tb03169.x; Hall S., 1982, PhD diss; Hartwell A.D., 1975, P47; HENSEN V, 1887, 1882 1886 KOMM WISS; JAMIESON GS, 1983, CAN J FISH AQUAT SCI, V40, P313, DOI 10.1139/f83-046; JAMIESON GS, 1979, 0915 CAN FISH MAR SE; LEWIS CM, 1979, TOXIC DINOFLAGELLATE, P47; MARANDA L, UNPUB; MEDCOF JC, 1947, B FISH RES BD CAN, V7, P490; OSHIMA Y, 1982, B JPN SOC SCI FISH, V48, P1303; PFIESTER LA, BIOL DINOFLAGELLATES; PRAKASH A, 1967, J FISH RES BOARD CAN, V24, P1589, DOI 10.1139/f67-131; ROBINSON WE, 1981, FISH B-NOAA, V79, P449; SAUNDERS S, 1982, PARALYTIC SHELLFISH; Schmidt R.J., 1979, P83; SCHMITTER R, 1979, TOXIC DINOFLAGELLATE, P47; Shimizu Y., 1979, P321; SPENCER DW, 1970, MAR GEOL, V9, P117, DOI 10.1016/0025-3227(70)90064-2; Steidinger K.A., 1975, P153; Taylor F.J.R., 1979, P47; THAYER PE, 1983, CAN J FISH AQUAT SCI, V40, P1308, DOI 10.1139/f83-149; TURPIN DH, 1978, J PHYCOL; Von Stosch HA., 1973, Br Phycol J, V8, P105; WALKER LM, 1982, T AM MICROSC SOC, V101, P287, DOI 10.2307/3225818; Wall D., 1975, P249; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; Wall D., 1971, Geoscience Man, V3, P1; WATRAS CJ, 1982, J EXP MAR BIOL ECOL, V62, P25, DOI 10.1016/0022-0981(82)90214-3; WHITE AW, 1982, CAN J FISH AQUAT SCI, V39, P1185, DOI 10.1139/f82-156; Yentsch C.M., 1975, P163; YENTSCH CS, 1973, SAVANNAH RIVER PROJE, P508; YOSHIMATSU S, 1981, Bulletin of Plankton Society of Japan, V28, P131	50	24	28	0	3	AMER CHEMICAL SOC	WASHINGTON	1155 16TH ST, NW, WASHINGTON, DC 20036 USA	0097-6156	1947-5918		ACS SYM SER	ACS Symp. Ser.		1984	262						125	138						14	Chemistry, Multidisciplinary	Science Citation Index Expanded (SCI-EXPANDED)	Chemistry	AWV27					2025-03-11	WOS:A1984AWV2700011
J	LEWIS, JM; DODGE, JD; TETT, PB				LEWIS, JM; DODGE, JD; TETT, PB			DINOFLAGELLATE CYSTS FROM A SCOTTISH SEA LOCH AND THEIR GERMINATION IN THE LABORATORY	BRITISH PHYCOLOGICAL JOURNAL			English	Meeting Abstract									UNIV LONDON ROYAL HOLLOWAY COLL,EGHAM TW20 0EX,SURREY,ENGLAND; SCOTTISH MARINE BIOL ASSOC,OBAN PA34 4AD,ARGYLL,SCOTLAND	University of London; Royal Holloway University London									0	0	0	0	0	ACADEMIC PRESS LTD	LONDON	24-28 OVAL RD, LONDON, ENGLAND NW1 7DX	0007-1617			BRIT PHYCOL J			1984	19	2					196	196						1	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	ST832					2025-03-11	WOS:A1984ST83200035
J	SAKO, Y; ISHIDA, Y; KADOTA, H; HATA, Y				SAKO, Y; ISHIDA, Y; KADOTA, H; HATA, Y			SEXUAL REPRODUCTION AND CYST FORMATION IN THE FRESH-WATER DINOFLAGELLATE PERIDINIUM-CUNNINGTONII	BULLETIN OF THE JAPANESE SOCIETY OF SCIENTIFIC FISHERIES			English	Article									KOCHI UNIV,FAC AGR,DEPT CULTURAL FISHERIES,AQUAT ENVIRONM SCI LAB,KOCHI 783,JAPAN	Kochi University	SAKO, Y (通讯作者)，KYOTO UNIV,FAC AGR,DEPT FISHERIES,MICROBIOL LAB,KYOTO 606,JAPAN.							ANDERSON DM, 1980, J PHYCOL, V16, P166; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; ITOH T, 1979, B PLANKTON SOC JPN, V26, P113; PFIESTER LA, 1977, J PHYCOL, V13, P92, DOI 10.1111/j.0022-3646.1977.00092.x; PFIESTER LA, 1980, AM J BOT, V67, P955, DOI 10.2307/2442437; PFIESTER LA, 1979, PHYCOLOGIA, V18, P13, DOI 10.2216/i0031-8884-18-1-13.1; PFIESTER LA, 1976, J PHYCOL, V12, P234; PFIESTER LA, 1975, J PHYCOL, V11, P259, DOI 10.1111/j.1529-8817.1975.tb02776.x; PRAKASH A, 1967, J FISH RES BOARD CAN, V24, P1589, DOI 10.1139/f67-131; SANDGREN CD, 1981, J PHYCOL, V17, P199, DOI 10.1111/j.0022-3646.1981.00199.x; Steidinger K.A., 1975, P153; TURPIN DH, 1978, J PHYCOL, V14, P235, DOI 10.1111/j.1529-8817.1978.tb02454.x; Von Stosch HA., 1973, Br Phycol J, V8, P105; WALKER LM, 1979, J PHYCOL, V15, P312	14	26	27	0	2	JAPAN SOC SCI FISHERIES TOKYO UNIV FISHERIES	TOKYO	5-7 KONAN-4 MINATO-KU, TOKYO 108, JAPAN	0021-5392			B JPN SOC SCI FISH			1984	50	5					743	750						8	Fisheries	Science Citation Index Expanded (SCI-EXPANDED)	Fisheries	SZ561					2025-03-11	WOS:A1984SZ56100002
J	BELOW, R				BELOW, R			APTIAN TO CENOMANIAN DINOFLAGELLATE CYSTS FROM THE MAZAGAN PLATEAU, NORTHWEST AFRICA (SITE-545 AND SITE-547, DEEP-SEA DRILLING PROJECT LEG-79)	INITIAL REPORTS OF THE DEEP SEA DRILLING PROJECT			English	Article											BELOW, R (通讯作者)，UNIV BONN, INST PALAONTOL, D-5300 BONN, FED REP GER.							Alberti G., 1961, Palaeontographica, V116, P1; [Anonymous], PALAEONTOLOGY; BELOW R, 1982, Palaeontographica Abteilung B Palaeophytologie, V182, P1; BELOW R, 1981, Palaeontographica Abteilung B Palaeophytologie, V176, P1; BELOW R, 1982, Revista Espanola de Micropaleontologia, V14, P23; BRIDEAUX W., 1971, PALAEONTOGRAPHICA B, V135, P53; BRIDEAUX W. W., 1975, GEOLOGICAL SURVEY CA, V252, P1; CLARKE R F A, 1968, Taxon, V17, P181, DOI 10.2307/1216512; CLARKE RFA, 1967, K NEDERL AKAD WETE N, V24, P1; Cookson I. C., 1962, Micropaleontology, V8, P485, DOI 10.2307/1484681; Cookson I. C., 1958, Proceedings of the Royal Society of Victoria N S, V70, P19; COOKSON I.C., 1974, PALAEONTOGRAPHICA, V148, P44; Cookson I.E., 1960, PALAEONTOLOGY, V2, P243; Davey JJ., 1966, B BR MUS NAT HIS G, P157; DAVEY R J, 1974, Palaeontology (Oxford), V17, P623; Davey R.J., 1979, Initial Reports of the Deep Sea Drilling Project, V48, P547; Davey R.J., 1974, S STRATIGRAPHIC PALY, V3, P41; Davey R.J., 1966, STUDIES MESOZOIC CAI, P28; Davey R.J., 1978, INIT REPS DSDP, V40, P883, DOI [10.2973/dsdp.proc.40.125.1978, DOI 10.2973/DSDP.PROC.40.125.1978]; Davey R.J., 1973, REV ESP MICROPALEONT, V5, P173; Davey R.J., 1966, STUDIES MESOZOIC CAI, P53; DAVEY RJ, 1976, REV PALAEOBOT PALYNO, V22, P307, DOI 10.1016/0034-6667(76)90028-2; DAVEY RJ, 1969, BRIT MUSEUM NATURAL, V3, P4; DAVEY RJ, 1971, NEDERLANDSE AKAD WET, V26, P1; DAVEY RJ, 1969, B BRIT MUS NAT HIST, V17, P1; Deflandre G., 1939, Bulletin de la Societe Francaise de Microscopie, V8, P95; Deflandre G., 1935, Bulletin Biologique de la France et de la Belgique, V69, P213; DEFLANDRE G., 1937, ANN PALEONTOL, V26, P51; Deflandre G., 1936, Annales de paleontologie, V25, P151; DEFLANDRE GEORGES, 1955, AUSTRALIAN JOUR MARINE AND FRESHWATER RES, V6, P242; DORHOFER G, 1980, R ONT MUS LIFE SCI M; DOWNIE C, 1965, GEOL SOC AM MEM, V94; Drugg W.S., 1978, Palaeontographica Abteilung B Palaeophytologie, V168, P61; Duxbury S., 1980, Palaeontographica Abteilung B Palaeophytologie, V173, P107; DUXBURY S, 1979, Micropaleontology (New York), V25, P198, DOI 10.2307/1485266; Duxbury S., 1977, Palaeontographica Abteilung B Palaeophytologie, V160, P17; EHRENBERG CG, 1838, ABH AKAD WISS BERL P, P109; Eisenack A., 1958, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V106, P383; Eisenack A., 1960, P R SOC VIC, V72, P1; EISENACK A, 1971, KATALOG FOSSILEN DIN, V2; EVITT WR, 1963, P NATL ACAD SCI USA, V49, P158, DOI 10.1073/pnas.49.2.158; GERLACH H, 1961, NEUES JAHRB GEOL PAL, V112, P143; GITMEZ G.U., 1970, B BRIT MUS NAT HIST, V18, P231; Gocht H., 1957, Palaeontologische Zeitschrift, V31, P163; GOCHT H., 1959, PAL ONTOLOGISCHE Z, V33, P50; Habib D., 1972, Initial Rep Deep Sea Drilling Project, V11, P367; HABIB D., 1976, MICROPALEONTOLOGY, V21, P373; HASENBOEHLER B, Z REV MICROPALEONTOL; Jain K.P., 1973, PALAEOBOTANIST, V20, P22; Jain KP., 1977, PALEOBOTANIST, V24, P170; Klement K. W., 1960, Palaeontographica, VA114, P1; LENTIN JK, 1981, BIR8112 BEDF I OC RE; LENTIN JK, 1976, BIR7516 BED I OC REP; LENTIN JK, 1973, 7342 GEOL SURV CAN P; LOEBLICH AR, 1966, STUD TROP OCEANOGR M, V3; MAIER D., 1959, NEUES JB F R GEOLOGI, V107, P278; Mantell G.A, 1850, A Pictorial Atlas of Fossil Remains Consisting of Coloured Illustrations Selected from Parkinson's "Organic Remains of a Former World", and Artis's "Antediluvian Phytology; Manum S., 1964, Skrifter utgitt av det Norske Videnskapsakademi Mat Nat Kl NS, VNo. 17, P1; MILLIOUD ME, 1967, 1ST P INT C PLANKT M, V2, P420; NeaLE J.W., 1962, GEOL MAG, V99, P439; NORVICK M. S., 1976, AUSTR BUREAU MINERAL, V151, P21; Pocock S., 1962, PALAEONTOGRAPHICA, V111, P1; SARJEANT W A S, 1970, Grana, V10, P74; SARJEANT WAS, 1966, B BRIT MUS NAT HIS S, V3, P107; SARJEANT WAS, 1969, B BR MUS NAT HIST S, V3, P7; SARJEANT WAS, 1966, B BRIT MUSEUM NAT S, V3, P199; Singh C., 1964, Alberta Research Council Bulletin, V15, P1; STOVER L E, 1978, Stanford University Publications in the Geological Sciences, V15, P1; VALENSI LIONEL, 1955, BULL SOC GEOL FRANCE, V5, P35; Wetzel O., 1933, PALAEONTOGRAPHICA, V77, P141; WHITE H.H., 1842, MICROSCOPICAL J LOND, V11, P35; Williams G.L., 1975, GEOL SURV CAN PAP, V2, P107, DOI DOI 10.4095/102513; WILLIAMS G.L., 1978, INITIAL REPORTT FHE, P783; YUN H-S, 1981, Palaeontographica Abteilung B Palaeophytologie, V177, P1	74	45	48	0	1	US GOVERNMENT PRINTING OFFICE	WASHINGTON	SUPERINTENDENT DOCUMENTS,, WASHINGTON, DC 20402-9325 USA				INITIAL REP DEEP SEA			1984	79	NOV					621	649						29	Oceanography	Science Citation Index Expanded (SCI-EXPANDED)	Oceanography	TW063					2025-03-11	WOS:A1984TW06300024
J	COATS, DW; TYLER, MA; ANDERSON, DM				COATS, DW; TYLER, MA; ANDERSON, DM			SEXUAL PROCESSES IN THE LIFE-CYCLE OF GYRODINIUM-UNCATENUM (DINOPHYCEAE) - A MORPHOGENETIC OVERVIEW	JOURNAL OF PHYCOLOGY			English	Review								Sexual processes in the life cycle of the dinoflagellate G. uncatenum Hulburt were investigated in isolated field populations. Morphological and morphogenetic aspects of gamete production, planozygote formation, encystment, excystment, and planomeiocyte division are described from observations of living specimens, Protargol silver impregnated material and scanning electron microscope preparations. The sexual cycle was initiated by gamete formation which involved 2 asexual divisions of the vegetative organism. Gametes were fully differentiated following the 2nd division and immediately capable of forming pairs. Either isogamous or anisogamous pairs were formed by the mid-ventral union of gametes. Gametes invariably joined with flagellar bases in close juxtaposition. Complete fusion of gametes required .apprx. 1 h, involved plasmogamy followed by karyogamy and resulted in a quadriflagellated planozygote. Planozygotes encysted in 24-48 h to yield a hypnozygote capable of overwintering in estuarine sediments. Hypnozygotes collected from sediment in late winter readily excysted upon exposure to temperatures above 15.degree. C. A single quadriflagellated planomeiocyte emerged from the cyst and under culture conditions divided 1-2 days later. The 4 flagella were not were not evenly distributed at the 1st division and both bi- and tri-flagellated daughter cells were formed.	UNIV DELAWARE, COLL MARINE SCI, LEWES, DE 19958 USA; WOODS HOLE OCEANOG INST, DEPT BIOL, WOODS HOLE, MA 02543 USA		JOHNS HOPKINS UNIV, CHESAPEAKE BAY INST, SHADY SIDE, MD 20764 USA.			Coats, D Wayne/0000-0002-0636-189X				ANDERSON DM, 1980, J PHYCOL, V16, P166; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; Bibby B.T., 1972, British phycol J, V7, P85; Borgert A., 1910, Archiv fuer Protistenkunde Jena, V20; Cao Vien M., 1968, CR ACADSCI D, V267, P701; CHAPMAN DV, 1982, J PHYCOL, V18, P121, DOI 10.1111/j.0022-3646.1982.00121.x; CHAPMAN DV, 1981, BRIT PHYCOL J, V16, P183, DOI 10.1080/00071618100650191; COATS DW, 1982, MAR BIOL, V67, P71, DOI 10.1007/BF00397096; Dodge J. D., 1963, Archiv fuer Protistenkunde, V106, P442; Galigher A.E., 1971, Essentials of practical microtechnique, V1st; GUILLARD RR, 1962, CAN J MICROBIOL, V8, P229, DOI 10.1139/m62-029; HULBURT EM, 1957, BIOL BULL-US, V112, P196, DOI 10.2307/1539198; Parducz B., 1967, International Review of Cytology, V21, P91, DOI 10.1016/S0074-7696(08)60812-8; PFIESTER LA, 1977, J PHYCOL, V13, P92, DOI 10.1111/j.0022-3646.1977.00092.x; PFIESTER LA, 1976, J PHYCOL, V12, P234; PFIESTER LA, 1975, J PHYCOL, V11, P259, DOI 10.1111/j.1529-8817.1975.tb02776.x; PFIESTER LA, 1984, BIOL DINOFLAGELLATES; Skoczylas O., 1958, Archiv fuer Protistenkunde, V103, P193; SPECTOR DL, 1981, AM J BOT, V68, P34, DOI 10.2307/2442989; Stosch H.A., 1964, Helgolander Wissenschaftliche Meeresuntersuchungen, V10, P140; Tuffrau M., 1967, Protistologica, V3, P91; TURPIN DH, 1978, J PHYCOL, V14, P235, DOI 10.1111/j.1529-8817.1978.tb02454.x; TYLER MA, 1982, MAR ECOL PROG SER, V7, P163, DOI 10.3354/meps007163; VIEN C, 1967, CR ACAD SCI D NAT, V264, P1006; von Stosch H.A., 1972, MEM SOC BOT FR, V1972, P201; von Stosch H.A., 1965, NATURWISSENSCHAFTEN, V52, P112; Von Stosch HA., 1973, Br Phycol J, V8, P105; WALKER LM, 1979, J PHYCOL, V15, P312; WALKER LM, 1982, T AM MICROSC SOC, V101, P287, DOI 10.2307/3225818; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; Watanabe M., 1982, RES REP NAT I ENV ST, V30, P27; ZINGMARK RG, 1970, J PHYCOL, V6, P122, DOI 10.1111/j.0022-3646.1970.00122.x	33	53	54	0	0	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0022-3646	1529-8817		J PHYCOL	J. Phycol.		1984	20	3					351	361		10.1111/j.0022-3646.1984.00351.x	http://dx.doi.org/10.1111/j.0022-3646.1984.00351.x			11	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	TM742					2025-03-11	WOS:A1984TM74200003
J	ANDERSON, DM; KULIS, DM; BINDER, BJ				ANDERSON, DM; KULIS, DM; BINDER, BJ			SEXUALITY AND CYST FORMATION IN THE DINOFLAGELLATE GONYAULAX-TAMARENSIS - CYST YIELD IN BATCH CULTURES	JOURNAL OF PHYCOLOGY			English	Article								Encystment of the toxic dinoflagellate G. tamarensis Lebour (var. excavata) was monitored in batch cultures exposed to a variety of nutritional and environmental treatments. Limitation by N (as ammonium or nitrate) or P (as phosphate) resulted in cyst formation. When the initial concentration of limiting nutrient was varied, total cyst yield (ml-1) was directly proportional to the cell yield at all but the highest nutrient concentrations (where encystment was minimal). Encystment efficiency was relatively constant (0.1-0.2 cysts/cell) over a 5-fold range of cell densities, indicating that 20-40% of the vegetative populations successfully encysted. Cyst formation was negligible in nutrient-replete medium, even with a significant reduction in growth rate due to non-optimal light, temperature, or to high batch culture cell densities. Low light levels decreased cyst yield once encystment was initiated by nutrient limitation, but this was probably linked to smaller motile cell yield and not to a specific inhibition of encystment. In contrast, encystment was more sensitive to temperature than was growth rate: optimal cyst production occurred over a relatively narrow temperature range and no cysts were formed at some temperatures that permitted growth. Cyst yield could also be reduced by chemical contaminants introduced during culture medium preparation. There is no evidence for a density-dependent induction mechanism, nor is there a link between sexuality and reduced growth rate in nutrient-replete medium.			WOODS HOLE OCEANOG INST, DEPT BIOL, WOODS HOLE, MA 02543 USA.							ANDERSON DM, 1980, J PHYCOL, V16, P166; ANDERSON DM, 1983, MAR BIOL, V76, P179, DOI 10.1007/BF00392734; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; [Anonymous], DEV BIOL; Beam C. A., 1980, BIOCH PHYSL PROTOZOA, V3, P171; BEAM CA, 1974, NATURE, V250, P435, DOI 10.1038/250435a0; BRAARUD T, 1945, AVH NOR VITENSKAPELI, V3, P1; BRAND L E, 1981, Journal of Plankton Research, V3, P193, DOI 10.1093/plankt/3.2.193; CAIN JR, 1976, J PHYCOL, V12, P383, DOI 10.1111/j.0022-3646.1976.00383.x; Coleman A.W., 1962, PHYSL BIOCH ALGAE, P711; DALE B, 1977, BRIT PHYCOL J, V12, P241, DOI 10.1080/00071617700650261; DALE B, 1977, SARSIA, V63, P29, DOI 10.1080/00364827.1977.10411318; DARDEN WH, 1966, J PROTOZOOL, V13, P239, DOI 10.1111/j.1550-7408.1966.tb01901.x; ELLIS RJ, 1968, AM J BOT, V55, P600, DOI 10.2307/2440615; Guillard R. R. L., 1973, CULTURE MARINE INVER, P29; GUILLARD RR, 1962, CAN J MICROBIOL, V8, P229, DOI 10.1139/m62-029; MOREYGAINES G, 1980, PHYCOLOGIA, V19, P230, DOI 10.2216/i0031-8884-19-3-230.1; NECAS J, 1982, BIOL PLANTARUM, V24, P311, DOI 10.1007/BF02879471; OKELLEY JC, 1983, J PHYCOL, V19, P57, DOI 10.1111/j.0022-3646.1983.00057.x; PFIESTER LA, 1977, J PHYCOL, V13, P92, DOI 10.1111/j.0022-3646.1977.00092.x; PFIESTER LA, 1976, J PHYCOL, V12, P234; PFIESTER LA, 1975, J PHYCOL, V11, P259, DOI 10.1111/j.1529-8817.1975.tb02776.x; PFIESTER LA, BIOL DINOFLAGELLATES; PRAKASH A, 1967, J FISH RES BOARD CAN, V24, P1589, DOI 10.1139/f67-131; TRAINOR FR, 1958, AM J BOT, V45, P621, DOI 10.2307/2439236; TURPIN DH, 1978, J PHYCOL, V14, P235, DOI 10.1111/j.1529-8817.1978.tb02454.x; Von Stosch HA., 1973, Br Phycol J, V8, P105; VON STOSCH HANS A., 1964, HELGOLANDER WISSENSCHAFTLICHE MEERESUNTERSUCH, V11, P209; WALKER LM, 1979, J PHYCOL, V15, P312; WALL D, 1970, Phycologia, V9, P151, DOI 10.2216/i0031-8884-9-2-151.1; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; Watanabe M., 1982, RES REP NAT I ENV ST, V30, P27; WATRAS CJ, 1982, J EXP MAR BIOL ECOL, V62, P25, DOI 10.1016/0022-0981(82)90214-3; Yentsch C.M., 1975, P163; ZINGMARK RG, 1970, J PHYCOL, V6, P122, DOI 10.1111/j.0022-3646.1970.00122.x	35	185	195	0	15	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0022-3646	1529-8817		J PHYCOL	J. Phycol.		1984	20	3					418	425		10.1111/j.0022-3646.1984.00418.x	http://dx.doi.org/10.1111/j.0022-3646.1984.00418.x			8	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	TM742					2025-03-11	WOS:A1984TM74200012
J	MEHROTRA, NC; SARJEANT, WAS				MEHROTRA, NC; SARJEANT, WAS			ARCHEOPYLE TYPE IN THE DINOFLAGELLATE CYST GENUS IMBATODINIUM - SOME NEW OBSERVATIONS	MICROPALEONTOLOGY			English	Article								A taxonomic analysis of Imbatodinium with reference to morphologically similar genera was made. The mechanism of excystment is more complex than previously supposed, as a compound archeopyle is developed by the loss of 3 or 4 opercular pieces. A revised diagnosis for the genus incorporates this new information. One new species, I. fractum, is described and 2 new combinations, I. pomum (Davey) [Batioladinium] and I. radiculatum (Davey), are proposed. [This dinoflagellate cyst complex is from an assemblage from the Lower Cretaceous, South India.].	OIL & NAT GAS COMMISS, KD MALAVIYA INST PETR EXPLORAT, DEHRA DUN 248195, UTTAR PRADESH, INDIA; UNIV SASKATCHEWAN, DEPT GEOL SCI, SASKATOON S7N 0W0, SASKATCHEWAN, CANADA	University of Saskatchewan								Alberti G., 1961, Palaeontographica, V116, P1; BRIDEAUX WW, 1975, CAN J BOT, V53, P1239, DOI 10.1139/b75-148; COOKSON IC, 1958, ROY SOC VICTORIA P, V70, P1; Davey R.J., 1982, GEOL SURV DENMARK, V6, P1; DORHOFER G, 1980, R ONT MUS LIFE SCI M, P1; EISENACK A, 1960, ROYAL SOC VICTORIA P, V72, P1; Evitt W. R., 1961, Micropaleontology, V7, P385, DOI 10.2307/1484378; Evitt W.R., 1967, Stanford University Publications, Geological Sciences, V10, P1; Gocht H., 1957, Palaeontologische Zeitschrift, V31, P163; LENTIN JK, 1976, BIR7516 BEDF I OC RE; LENTIN JK, 1981, BIR8112 BEDF I OC RE, P1; Norris G., 1978, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V156, P1; Norris G., 1978, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V155, P300; SARJEANT WAS, 1982, CAN J BOT, V60, P922, DOI 10.1139/b82-119; STOVER L E, 1978, Stanford University Publications in the Geological Sciences, V15, P1; Vozzhennikova T. F., 1967, Inst Geologii Geofizika Moskva, P1; Wiggins V.D., 1975, Geoscience Man, V11, P95	17	2	4	1	1	MICRO PRESS	FLUSHING	6530 KISSENA BLVD, FLUSHING, NY 11367 USA	0026-2803	1937-2795		MICROPALEONTOLOGY	Micropaleontology		1984	30	2					213	222		10.2307/1485718	http://dx.doi.org/10.2307/1485718			10	Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Paleontology	SZ400					2025-03-11	WOS:A1984SZ40000005
J	MEHROTRA, NC; SARJEANT, WAS				MEHROTRA, NC; SARJEANT, WAS			DINGODINIUM, A DINOFLAGELLATE CYST GENUS EXHIBITING VARIATION IN ARCHEOPYLE CHARACTER	MICROPALEONTOLOGY			English	Article								The style of archeopyle in the dinoflagellate cyst genus Dingodinium is reveiwed on the basis of new observations of D. cerviculum. The peripyle in this species is formed by dorsal separation of the apex; the endopyle involves not only the loss of intercalary paraplates but also in the opening or loss of a precingular paraplate. Revised diagnoses for this species and for the genus incorporate these new details of archeopyle and paratabulation. These emendations may necessitate some revision of current approaches in dinoflagellate cyst taxonomy. The species ? D. albertii is rejected as a subjective junior synonym of D. cerviculum.	OIL & NAT GAS COMMISS, KD MALAVIYA INST PETR EXPLORAT, DEHRA DUN 248195, UTTAR PRADESH, INDIA; UNIV SASKATCHEWAN, DEPT GEOL SCI, SASKATOON S7N 0W0, SASKATCHEWAN, CANADA	University of Saskatchewan								Alberti G., 1961, Palaeontographica, V116, P1; Antonescu E., 1980, Anuarul Institutului de Geologie si Geofizica, V56, P97; BRIDEAUX W., 1971, PALAEONTOGRAPHICA B, V135, P53; BRIDEAUX W. W., 1975, GEOLOGICAL SURVEY CA, V252, P1; BURGER D, 1982, Palynology, V6, P161; BURGER D, 1973, BUR MINER RESOURCES, V150, P27; BURGER D., 1980, BUREAU MINERAL RESOU, V189, P1; BURGER D, 1968, UNPUB STRATIGRAPHY P; COOKSON I C, 1982, Palaeontographica Abteilung B Palaeophytologie, V184, P23; COOKSON IC, 1958, ROYAL SOC VICTORIA P, V70, P19; DAVEY R J, 1974, Palaeontology (Oxford), V17, P623; Davey R.J., 1978, INIT REPS DSDP, V40, P883, DOI [10.2973/dsdp.proc.40.125.1978, DOI 10.2973/DSDP.PROC.40.125.1978]; Davey R.J., 1979, American Association of Stratigraphic Palynologists Contributions Series, V5B, P48; DAVEY RJ, 1974, BIRBAL SAHNI I PALAE, V3, P41; DODEKOVA L, 1975, Paleontologiya Stratigrafiya i Litologiya, V2, P17; Duxbury S., 1980, Palaeontographica Abteilung B Palaeophytologie, V173, P107; Duxbury S., 1977, Palaeontographica Abteilung B Palaeophytologie, V160, P17; Eisenack A., 1958, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V106, P383; EVANS PR, 1967, UNPUB CRETACEOUS BEL; EVANS PR, 1966, UNPUB CONTRIBUTION P; EVANS PR, 1963, PUBLS PETROL SEARCH, V23, P19; EVITT WR, 1967, STANFORD U PUBL GEOL, V10; Fisher M.J., 1980, P 4 INT PAL C LUCHN, V2, P313; GITMEZ G.U., 1970, B BRIT MUS NAT HIST, V18, P231; Habib D., 1972, Initial Rep Deep Sea Drilling Project, V11, P367; HABIB D, 1975, Micropaleontology (New York), V21, P373, DOI 10.2307/1485290; HARRIS WK, 1976, INITIAL REPORTS DEEP, V36, P761; HASKELL TR, 1969, AUSTR ROY SOC QUEENS, V81, P57; Herngreen G.F.W., 1978, Palinologia, P273; JANSONIUS J, 1981, IPRCERMG8103 ESS RES; KEMP E. M., 1976, BUR MIN RESOUR GEOL, V160, P23; LENTIN JK, 1976, B1R7516 BEDF I OC RE; LENTIN JK, 1981, BIR8112 BEDF I OC RE, P1; Millioud M.E., 1969, Proceedings int Conf Plankt Microfoss, V2, P420; Norris G., 1978, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V156, P1; Norris G., 1978, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V155, P300; Pocock S.A.J., 1972, Palaeontographica Abteilung B Palaeophytologie, V137, P85; SARJEANT WAS, 1966, B BRIT MUSEUM NAT S, V3, P199; SINGH C, 1971, RES COUNCIL ALBERTA, V28, P301; STOVER L E, 1978, Stanford University Publications in the Geological Sciences, V15, P1; TZECHEN S, 1978, PALEOGENE DINOFLAGEL, P1; WILLIAMS GL, 1975, 7430 GEOL SURV CAN, P107	42	7	9	0	1	MICRO PRESS	FLUSHING	6530 KISSENA BLVD, FLUSHING, NY 11367 USA	0026-2803	1937-2795		MICROPALEONTOLOGY	Micropaleontology		1984	30	3					292	305		10.2307/1485691	http://dx.doi.org/10.2307/1485691			14	Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Paleontology	TL044					2025-03-11	WOS:A1984TL04400005
J	SELVIN, RC; LEWIS, CM; YENTSCH, CM; HURST, JW				SELVIN, RC; LEWIS, CM; YENTSCH, CM; HURST, JW			SEASONAL PERSISTENCE OF RESTING CYST TOXICITY IN THE DINOFLAGELLATE GONYAULAX-TAMARENSIS VAR EXCAVATA	TOXICON			English	Note									DEPT MARINE RESOURCES, W BOOTHBAY HARBOR, ME 04575 USA		BIGELOW LAB OCEAN SCI, W BOOTHBAY HARBOR, ME 04575 USA.							ANDERSON DM, 1982, LIMNOL OCEANOGR, V27, P757, DOI 10.4319/lo.1982.27.4.0757; DALE B, 1978, SCIENCE, V201, P1223, DOI 10.1126/science.201.4362.1223; PRAKASH A, 1963, J FISH RES BOARD CAN, V20, P983, DOI 10.1139/f63-067; 1975, OFFICIAL METHODS ANA, P319	4	5	5	1	1	PERGAMON-ELSEVIER SCIENCE LTD	OXFORD	THE BOULEVARD, LANGFORD LANE, KIDLINGTON, OXFORD OX5 1GB, ENGLAND	0041-0101			TOXICON	Toxicon		1984	22	5					817	820		10.1016/0041-0101(84)90166-1	http://dx.doi.org/10.1016/0041-0101(84)90166-1			4	Pharmacology & Pharmacy; Toxicology	Science Citation Index Expanded (SCI-EXPANDED)	Pharmacology & Pharmacy; Toxicology	TU504	6523510				2025-03-11	WOS:A1984TU50400015
J	HEANEY, SI; CHAPMAN, DV; MORISON, HR				HEANEY, SI; CHAPMAN, DV; MORISON, HR			THE ROLE OF THE CYST STAGE IN THE SEASONAL GROWTH OF THE DINOFLAGELLATE CERATIUM-HIRUNDINELLA WITHIN A SMALL PRODUCTIVE LAKE	BRITISH PHYCOLOGICAL JOURNAL			English	Article								Large populations of the dinoflagellate C. hirundinella occur regularly in a small productive lake and their decline during Sept. and Oct. is normally associated with mass encystment. Evidence for the major role of benthic cysts in providing the inoculum for subsequent growth is given from morphological and quantitative studies over 2 contrasting years of cyst production, 1980 and 1981. For both years there were 2 distinct phases of population increase in the plankton. Low winter densities were followed by rapid rates of increase during Feb. and March at the same time as empty cysts appeared in the sediment. These changes occurred when water temperatures rose from .apprx. 3.degree.-5.degree. C. After near-stationary periods in April and May 1980 and April to June 1981 there followed phases of exponential growth, but at appreciably slower rates of population increase than during recruitment from excystment. That excystment was the major contributor to the rapid vernal increase of planktonic cells is supported by the observation in the plankton to high percentages of preceratium (recently excysted) cells and young vegetative cells with carbohydrate in their posterior halves. Moreover, a calculation of growth rate in situ, from the phasing of cell division when water temperatures were .apprx. 8.degree. C, indicated that vegetative growth was very slow relative to the earlier observed rate of increase. Growth rates in culture at temperatures below 10.degree. C were also very slow. Instead of the usual encystment in 1980 there was an early mass mortality of cells. This failure to form cysts did not prevent recruitment from benthic cysts in 1981 due to the large reservoir of viable cysts in the sediment from earlier years.	UNIV LONDON ROYAL HOLLOWAY COLL, DEPT BOT, EGHAM TW20 0EX, SURREY, ENGLAND	University of London; Royal Holloway University London	FRESHWATER BIOL ASSOC, AMBLESIDE LA22 0LP, CUMBRIA, ENGLAND.							ANDERSON DM, 1980, J PHYCOL, V16, P166; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; [Anonymous], HYDROBIOL J; BOOTH CR, 1976, LIMNOLOGY OCEANOGRAP, V13, P574; BRUNO SF, 1977, J PROTOZOOL, V24, P548, DOI 10.1111/j.1550-7408.1977.tb01012.x; CANTER HM, 1968, P LINN SOC LONDON, V192, P197; CHAPMAN DV, 1982, J PHYCOL, V18, P121, DOI 10.1111/j.0022-3646.1982.00121.x; CHAPMAN DV, 1981, BRIT PHYCOL J, V16, P183, DOI 10.1080/00071618100650191; CHAPMAN DV, 1981, THESIS U LONDON; Chu SP, 1942, J ECOL, V30, P284, DOI 10.2307/2256574; DOTTNE-LINDGREN A, 1975, Internationale Revue der Gesamten Hydrobiologie, V60, P115, DOI 10.1002/iroh.19750600105; ENTZ G, 1925, ARCH PROTISTENKD, V51, P131; ENTZ GEZA, 1927, ARCH PROTISTENK, V58, P344; FALLON RD, 1981, FRESHWATER BIOL, V11, P217, DOI 10.1111/j.1365-2427.1981.tb01255.x; FREMPONG E, 1982, INT REV GES HYDROBIO, V67, P323; Fritsch FE, 1931, J ECOL, V19, P233, DOI 10.2307/2255819; GEORGE DG, 1978, J ECOL, V66, P133, DOI 10.2307/2259185; HAUGE H. V., 1958, NYTT MAG BOT, V6, P97; Heaney S. I., 1980, REP FRESHWAT BIOL AS, V48, P27; HEANEY SI, 1980, J ECOL, V68, P75, DOI 10.2307/2259245; HEANEY SI, 1976, FRESHWATER BIOL, V6, P531, DOI 10.1111/j.1365-2427.1976.tb01644.x; HEANEY SI, 1980, FRESHWATER BIOL, V10, P163, DOI 10.1111/j.1365-2427.1980.tb01190.x; HELLER MD, 1977, FRESHWATER BIOL, V7, P527, DOI 10.1111/j.1365-2427.1977.tb01704.x; Huber G., 1923, FLORA JENA, V116, P114; HUBERPESTALOZZI G, 1950, BINNENGEWASSER 3, V16; JEWSON DH, 1981, LIMNOL OCEANOGR, V26, P1045, DOI 10.4319/lo.1981.26.6.1045; LIVINGSTONE D, 1979, THESIS U LEICESTER; LUND J. W. G., 1958, HYDROBIOLOGIA, V11, P143, DOI 10.1007/BF00007865; Lund J. W. G., 1972, TAXONOMY BIOL BLUE G, P305; LUND JWG, 1949, J ECOL, V37, P389, DOI 10.2307/2256614; LUND JWG, 1955, J ECOL, V43, P90, DOI 10.2307/2257123; LUND JWG, 1954, J ECOL, V42, P151, DOI 10.2307/2256984; MACKERETH FJH, 1964, J SCI INSTRUM, V41, P38, DOI 10.1088/0950-7671/41/1/311; Mortimer CH, 1942, J ECOL, V30, P147, DOI 10.2307/2256691; Mortimer CH, 1941, J ECOL, V29, P280, DOI 10.2307/2256395; MORTIMER CH, 1971, LIMNOL OCEANOGR, V16, P387, DOI 10.4319/lo.1971.16.2.0387; PEARSALL WH, 1929, P LEEDS PHIL SOC, V1, P432; PRESTON T, 1980, NATURE, V288, P365, DOI 10.1038/288365a0; REYNOLDS CS, 1981, PHILOS T R SOC B, V293, P419, DOI 10.1098/rstb.1981.0081; REYNOLDS CS, 1978, BRIT PHYCOL J, V13, P329, DOI 10.1080/00071617800650391; REYNOLDS CS, 1976, J ECOL, V64, P529, DOI 10.2307/2258772; SKUJA H., 1948, Schweden. - Symb. Bot. Upsal, V9, P1, DOI DOI 10.1016/J.HAL.2015.12.001; SPODNIEWSKA I, 1979, EKOL POL-POL J ECOL, V27, P481; Stosch H.A., 1964, Helgolander Wissenschaftliche Meeresuntersuchungen, V10, P140; TALLING J.F., 1971, MITTEL INT VERIENIGU, V19, P214; TAMAS G, 1974, Annales Instituti Biologici (Tihany) Hungaricae Academiae Scientiarum, V41, P323; von Stosch H.A., 1972, MEM SOC BOT FR, V1972, P201; WEILER CS, 1979, J EXP MAR BIOL ECOL, V39, P1, DOI 10.1016/0022-0981(79)90002-9; WEILER CS, 1979, J PHYCOL, V15, P384; WEILER CS, 1976, J EXP MAR BIOL ECOL, V25, P239, DOI 10.1016/0022-0981(76)90126-X; WEILER CS, 1980, LIMNOL OCEANOGR, V25, P610, DOI 10.4319/lo.1980.25.4.0610	52	66	73	0	5	ACADEMIC PRESS LTD- ELSEVIER SCIENCE LTD	LONDON	24-28 OVAL RD, LONDON NW1 7DX, ENGLAND	0007-1617			BRIT PHYCOL J			1983	18	1					47	59		10.1080/00071618300650061	http://dx.doi.org/10.1080/00071618300650061			13	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	QH639		Bronze			2025-03-11	WOS:A1983QH63900006
J	JOHN, AWG; REID, PC				JOHN, AWG; REID, PC			POSSIBLE RESTING CYSTS OF DISSODINIUM-PSEUDOLUNULA SWIFT EX ELBRACHTER ET DREBES IN THE NORTHEAST ATLANTIC AND THE NORTH-SEA	BRITISH PHYCOLOGICAL JOURNAL			English	Article								Possible resting cysts of D. pseudolunula, a dinoflagellate parasitic on copepod eggs, were observed regularly in samples taken by the Continuous Plankton Recorder. They are widely distributed in the plankton of the eastern North Atlantic and North Sea, with a peak in numbers in Aug. and Sept.			NERC, INST MARINE ENVIRONM RES, PLYMOUTH PL1 3DH, DEVON, ENGLAND.							COLEBROOK JM, 1978, OCEANOL ACTA, V1, P9; Dodge J. D., 1981, PROVISIONAL ATLAS MA; DREBES G, 1976, BOT MAR, V19, P75, DOI 10.1515/botm.1976.19.2.75; DREBES G, 1981, BRIT PHYCOL J, V16, P207, DOI 10.1080/00071618100650211; DREBES G, 1978, BRIT PHYCOL J, V13, P319, DOI 10.1080/00071617800650381; DREBES G, 1969, HELGOLAND WISS MEER, V19, P58, DOI 10.1007/BF01625859; ELBRACHTER M, 1978, HELGOLAND WISS MEER, V31, P347, DOI 10.1007/BF02189487; GLOVER R. S., 1967, SYMP ZOOL SOC LONDON, V19, P189; KASAHARA S, 1979, MAR BIOL, V55, P63, DOI 10.1007/BF00391718; Krause M., 1980, METEOR FORSCH ERGE A, V22, P133; LEGER G, 1973, Bulletin de l'Institut Oceanographique (Monaco), V71, P1; MARGALEF RAMON, 1957, INVEST PESQ, V7, P3; Reid P.C., 1972, THESIS U SHEFFIELD; ZILLIOUX FJ, 1972, 5TH EUR MAR BIOL S, P217; 1973, B MAR ECOL, V7, P1	15	9	11	0	0	ACADEMIC PRESS LTD- ELSEVIER SCIENCE LTD	LONDON	24-28 OVAL RD, LONDON NW1 7DX, ENGLAND	0007-1617			BRIT PHYCOL J			1983	18	1					61	67		10.1080/00071618300650071	http://dx.doi.org/10.1080/00071618300650071			7	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	QH639					2025-03-11	WOS:A1983QH63900007
J	REID, PC; JOHN, AWG				REID, PC; JOHN, AWG			DINOFLAGELLATE CYSTS IN CONTINUOUS PLANKTON RECORDS	BRITISH PHYCOLOGICAL JOURNAL			English	Meeting Abstract									INST MARINE ENVIRONM RES,PLYMOUTH PL1 3DH,DEVON,ENGLAND										0	0	0	0	0	ACADEMIC PRESS LTD	LONDON	24-28 OVAL RD, LONDON, ENGLAND NW1 7DX	0007-1617			BRIT PHYCOL J			1983	18	2					209	209						1	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	QW037					2025-03-11	WOS:A1983QW03700044
J	BALCH, WM; REID, PC; SURREYGENT, SC				BALCH, WM; REID, PC; SURREYGENT, SC			SPATIAL AND TEMPORAL VARIABILITY OF DINOFLAGELLATE CYST ABUNDANCE IN A TIDAL ESTUARY	CANADIAN JOURNAL OF FISHERIES AND AQUATIC SCIENCES			English	Article									INST MARINE ENVIRONM RES,PLYMOUTH PL1 3DH,DEVON,ENGLAND		BALCH, WM (通讯作者)，UNIV CALIF SAN DIEGO,SCRIPPS INST OCEANOG,INST MARINE RESOURCES,LA JOLLA,CA 92093, USA.							Anderson D.M., 1979, P145; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1982, ESTUAR COAST SHELF S, V14, P447, DOI 10.1016/S0272-7714(82)80014-0; [Anonymous], NOVA HEDWIGIA; CRAIB J. S., 1965, J CONS CONS PERMA INT EXPLOR MER, V30, P34; DALE B, 1976, REV PALAEOBOT PALYNO, V22, P39, DOI 10.1016/0034-6667(76)90010-5; Dale B., 1979, P443; EVITT W. R., 1964, GEOL SCI, V10, P1; GARDNER WD, 1980, J MAR RES, V38, P41; HARGRAVE BT, 1979, LIMNOL OCEANOGR, V24, P1124, DOI 10.4319/lo.1979.24.6.1124; Holme N. A., 1971, IBP HDB, V16; LEBOUR MV, 1925, J MAR BIOL ASS UK; Lewis C.M., 1979, P235; MOMMAERTS JP, 1969, J MAR BIOL ASSOC UK, V49, P749, DOI 10.1017/S0025315400037267; Reid P.C., 1974, Nova Hedwigia, V25, P579; REID PC, 1972, J MAR BIOL ASSOC UK, V52, P939, DOI 10.1017/S0025315400040674; REID PC, 1977, ZENOZOIC PALYNOLOGY, V1, P147; Steidinger K.A., 1975, P153; TYLER MA, 1981, MAR ECOL PROG SER, V7, P163; Wall D., 1965, Grana Palynologica, V6, P297; WALL D, 1977, MAR MICROPALEONTOL, V2, P121, DOI 10.1016/0377-8398(77)90008-1	21	17	17	0	1	NATL RESEARCH COUNCIL CANADA	OTTAWA	RESEARCH JOURNALS, MONTREAL RD, OTTAWA ON K1A 0R6, CANADA	0706-652X			CAN J FISH AQUAT SCI	Can. J. Fish. Aquat. Sci.		1983	40			1			244	261		10.1139/f83-287	http://dx.doi.org/10.1139/f83-287			18	Fisheries; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Fisheries; Marine & Freshwater Biology	PZ883					2025-03-11	WOS:A1983PZ88300024
J	BEJU, D				BEJU, D			BURTONIA-POLYGONALIS, A NEW DINOFLAGELLATE FROM THE BATHONIAN OF SOUTHERN ENGLAND	JOURNAL OF PALEONTOLOGY			English	Article								A new dinoflagellate cyst, BURTONIA polygonalis n. gen., n. sp., from the Lower Bathonian Zigzagiceras zigzag zone of Dorset, England, is systematically described and illustrated.	AMOCO PROD CO, CTR RES, POB 591, TULSA, OK 74102 USA									[Anonymous], 1978, ANALYSES PREPLEISTOC; ATONESCU E, 1974, REV MICROPALEONTOL, V17, P61; BJAERKE T, 1980, Palynology, V4, P57; CHATWIN CP, 1960, BRIT REGIONAL GEOLOG; COPE JCW, 1980, 15 GEOL SOC SPEC REP; DODEKOVA L, 1975, BULG ACAD SCI PALAEO, V2, P17; DORHOFER G., 1980, EVOLUTION ARCHEOPYLE; Drugg W.S., 1978, Palaeontographica Abteilung B Palaeophytologie, V168, P61; EVITT WILLIAM R., 1961, MICROPALEONTOLOGY, V7, P305, DOI 10.2307/1484365; EVITT WR, 1977, GEOLOGICAL SURVEY CA, V7624, P1; Fensome R.A., 1981, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V161, P47; Fenton J.P.G., 1980, Palaeontology (Oxford), V23, P151; FENTON JPG, 1978, PALINOLOGIA NUMERO E, V1, P233; Gocht H., 1970, PALAEONTOGRAPHICA B, V129, P125; GOCHT H, 1975, NEUES JB GEOLOGIE PA, P343; SARJEANT WAS, 1976, NEUES JB GEOLOGIE PA, V3, P163; SARJEANT WAS, 1978, LOUISIANA STATE U SC, V781; TORRENS HS, 1969, INFERIOR OOLITE FULL, P21	18	3	3	0	0	CAMBRIDGE UNIV PRESS	CAMBRIDGE	EDINBURGH BLDG, SHAFTESBURY RD, CB2 8RU CAMBRIDGE, ENGLAND	0022-3360	1937-2337		J PALEONTOL	J. Paleontol.		1983	57	1					106	111						6	Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Paleontology	QD030					2025-03-11	WOS:A1983QD03000008
J	ANDERSON, DM; CHISHOLM, SW; WATRAS, CJ				ANDERSON, DM; CHISHOLM, SW; WATRAS, CJ			IMPORTANCE OF LIFE-CYCLE EVENTS IN THE POPULATION-DYNAMICS OF GONYAULAX-TAMARENSIS	MARINE BIOLOGY			English	Article								Life cycle changes that allow populations of the toxic dinoflagellate G. tamarensis Lebour to inhabit the benthos and the plankton alternately are important factors regulating the initiation and decline of blooms in restricted embayments. The dynamics of these estuarine populations were monitored during bloom and non-bloom years. Each year, germination of benthic cysts inoculated the overlying waters during the vernal warming period, but a large residual population remained in the sediments throughout the blooms. The resulting planktonic population began growth under suboptimal temperature conditions. The populations developed from this inoculum through asexual reproduction until sexuality (and cyst formation) were induced. Encystment was not linked to any obvious environmental cue and occurred under apparently optimal conditions. An increase in the number of non-mitotic swimming cells (planozygotes, the precursors to dormant cysts) accompanied the rapid decline of the planktonic population. Thus encystment, in combination with hypothesized losses due to advection and grazing, contributed substantially to the decline of the vegetative cell population. The encystment/excystment cycle temporally restricts the occurrence of the vegetative population and may not be optimized for rapid or sustained vegetative growth and bloom formation in shallow embayments. The factors that distinguish bloom from non-bloom years thus appear to be operating on the growth of the planktonic population.	MIT, RALPH M PARSONS LAB, CAMBRIDGE, MA 02139 USA	Massachusetts Institute of Technology (MIT)	WOODS HOLE OCEANOG INST, DEPT BIOL, WOODS HOLE, MA 02543 USA.			Chisholm, Sallie/0000-0003-1480-2445				ANDERSON DM, 1980, J PHYCOL, V16, P166; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; ANDERSON DM, 1982, SHELF SCI, V14, P447; BEAM CA, 1974, NATURE, V250, P435, DOI 10.1038/250435a0; BEAM CA, 1977, J PROTOZOOL, V24, P532, DOI 10.1111/j.1550-7408.1977.tb01007.x; BRAND L E, 1981, Journal of Plankton Research, V3, P193, DOI 10.1093/plankt/3.2.193; DALE B, 1977, SARSIA, V63, P29, DOI 10.1080/00364827.1977.10411318; Dale B., 1979, P443; Edler L, 1979, BALTIC MARINE BIOL, P13; Hollenberg GJ, 1936, AM J BOT, V23, P1, DOI 10.2307/2436382; Hoyt WD, 1927, AM J BOT, V14, P592, DOI 10.2307/2446299; Huber G., 1922, Z BOTANIK, V14, P337; Huber G., 1923, FLORA JENA, V116, P114; KETCHUM BH, 1951, J MAR RES, V10, P18; Loeblich A.R. III, 1979, P41; MOREYGAINES G, 1980, PHYCOLOGIA, V19, P230, DOI 10.2216/i0031-8884-19-3-230.1; PFIESTER LA, 1977, J PHYCOL, V13, P92, DOI 10.1111/j.0022-3646.1977.00092.x; PFIESTER LA, 1976, J PHYCOL, V12, P234; PFIESTER LA, 1975, J PHYCOL, V11, P259, DOI 10.1111/j.1529-8817.1975.tb02776.x; PFIESTER LA, BIOL DINOFLAGELLATES; PRAKASH A, 1975, ENVIRON LETT, V9, P121, DOI 10.1080/00139307509435841; RUBIN CG, 1981, THESIS MASSACHUSETTS; SMITH GM, 1947, AM J BOT, V34, P80, DOI 10.2307/2437232; SOLORZANO L, 1969, LIMNOL OCEANOGR, V14, P799, DOI 10.4319/lo.1969.14.5.0799; Steidinger K.A., 1975, P153; STOECKER D, 1981, BIOL BULL-US, V160, P136, DOI 10.2307/1540907; Stosch H.A., 1964, Helgolander Wissenschaftliche Meeresuntersuchungen, V10, P140; Strickland J.D.H., 1972, B FISH RES BOARD CAN, V157, P310, DOI DOI 10.1002/IROH.19700550118; Tahara M., 1909, Bot. Mag. Tokyo, V23, P151; Taylor F.J.R., 1979, P47; TURNER JT, UNPUB ZOOPLANKTON GR; TURPIN DH, 1978, J PHYCOL, V14, P235, DOI 10.1111/j.1529-8817.1978.tb02454.x; Von Stosch HA., 1973, Br Phycol J, V8, P105; WALKER LM, 1979, J PHYCOL, V15, P312; WALL D, 1970, Phycologia, V9, P151, DOI 10.2216/i0031-8884-9-2-151.1; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; Watanabe M.M., 1982, 30 NAT JAP I ENV STU, P43; WATRAS CJ, 1982, J EXP MAR BIOL ECOL, V62, P25, DOI 10.1016/0022-0981(82)90214-3; ZINGMARK RG, 1970, J PHYCOL, V6, P122, DOI 10.1111/j.0022-3646.1970.00122.x	40	178	190	1	12	SPRINGER HEIDELBERG	HEIDELBERG	TIERGARTENSTRASSE 17, D-69121 HEIDELBERG, GERMANY	0025-3162	1432-1793		MAR BIOL	Mar. Biol.		1983	76	2					179	189		10.1007/BF00392734	http://dx.doi.org/10.1007/BF00392734			11	Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Marine & Freshwater Biology	RR388					2025-03-11	WOS:A1983RR38800008
J	HARLAND, R				HARLAND, R			DISTRIBUTION MAPS OF RECENT DINOFLAGELLATE CYSTS IN BOTTOM SEDIMENTS FROM THE NORTH-ATLANTIC OCEAN AND ADJACENT SEAS	PALAEONTOLOGY			English	Article								Distribution maps were drawn for 42 extant species of dinoflagellate cysts recovered from bottom sediments in the North Atlantic Ocean and adjacent seas. Data were compiled from published and unpublished work for 142 sample stations. The maps clearly show the influence of the North Atlantic circulation pattern, and areas of convergence, on the patterns of dinoflagellate cyst distribution. Areas of concentrations of cyst species are noted and discussed, as are the differing distribution patterns of several cysts that have at some time been referable to a single thecate species. The differences of distribution between neritic and oceanic cyst assemblages is clearly demarcated. A tentative broad ecological classification of cyst types is attempted. Impagidinium aculeatum (Wall) and I. sphaericum (Wall) [both Leptodinium] are proposed as new combinations.	INST GEOL SCI, LEEDS LS15 8TQ, ENGLAND	UK Research & Innovation (UKRI); Natural Environment Research Council (NERC); NERC British Geological Survey								ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; [Anonymous], 1977, CONTRIBUTIONS STRATI; [Anonymous], P YORKSHIRE GEOL SOC; BINNS PE, 1974, NATURE, V248, P751, DOI 10.1038/248751a0; BRADFORD MR, 1975, CAN J BOT, V53, P3064, DOI 10.1139/b75-335; Bujak J., 1980, PALAEONTOLOGICAL ASS, V24, P1; DALE B, 1976, REV PALAEOBOT PALYNO, V22, P39, DOI 10.1016/0034-6667(76)90010-5; DALE B, 1977, BRIT PHYCOL J, V12, P241, DOI 10.1080/00071617700650261; DALE B, 1978, Palynology, V2, P187; DODGE JD, 1977, MAR BIOL, V40, P327, DOI 10.1007/BF00395725; DODGE JD, 1974, BOT MAR, V17, P113, DOI 10.1515/botm.1974.17.2.113; DODGE JD, 1977, BOT MAR, V20, P307, DOI 10.1515/botm.1977.20.5.307; DOWNIE C, 1969, Grana Palynologica, V9, P124; du Chene R.J., 1977, Revista Espanola de Micropaleontologia, V9, P97; GRAHAM HW, 1944, PUBLS CARNEGIE I WAS, V565, P1; GREGORY D, 1978, REP I GEOL SCI, V77, P41; GREGORY D, 1978, SCOTT J GEOL, V14, P147; HARLAND R, 1981, Palynology, V5, P65; HARLAND R, 1982, PALAEONTOLOGY, V25, P369; HARLAND R, 1978, BOREAS, V7, P91; Harland R., 1968, Grana Palynologica, V8, P536; HARLAND R, 1982, Palynology, V6, P9; HARLAND R, 1980, Grana, V19, P211; Harland R., 1977, Palaeontographica Abteilung B Palaeophytologie, V164, P87; HARLAND R, 1973, REP I GEOL SCI, V73, P36; HARLAND R., 1978, B GEOLOGICAL SURVEY, V64, P41; HARLAND R, 1974, REP I GEOL SCI, V73, P37; Holligan P.M., 1979, P249; HOLLIGAN PM, 1981, PHILOS T R SOC A, V302, P547, DOI 10.1098/rsta.1981.0182; HOLLIGAN PM, 1980, J MAR BIOL ASSOC UK, V60, P851, DOI 10.1017/S0025315400041941; HUGHES MJ, 1977, REP I GEOL SCI, V77, P36; Morzadec-Kerfourn M. T., 1977, Revue Micropaleont, V20, P157; MORZADEC-KERFOURN M.T., 1979, MER PELAGIENNE ETUDE, VVI, P221; MUDIE P, 1981, AM ASS STRAT PALYNOL, P36; PANTIN HM, 1978, B GEOLOGICAL SURVEY, V64, P1; Reid P.C., 1974, Nova Hedwigia, V25, P579; REID PC, 1978, NEW PHYTOL, V80, P219, DOI 10.1111/j.1469-8137.1978.tb02284.x; REID PC, 1972, J MAR BIOL ASSOC UK, V52, P939, DOI 10.1017/S0025315400040674; REID PC, 1975, NEW PHYTOL, V75, P589, DOI 10.1111/j.1469-8137.1975.tb01425.x; REID PC, 1978, NOVA HEDWIGIA, V29, P429; REID PC, 1972, THESIS U SHEFFIELD, P1; Rossignol M., 1964, Revue de Micropaleontologie, V7, P83; STEIDINGER K.A., 1967, FLA BD CONSERV MAR L, V1, P1; STOVER L E, 1978, Stanford University Publications in the Geological Sciences, V15, P1; TURON JL, 1980, MEM MUS NAT HIST NAT, V27, P269; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; WALL D, 1968, NEW PHYTOL, V67, P315, DOI 10.1111/j.1469-8137.1968.tb06387.x; WALL D, 1977, MAR MICROPALEONTOL, V2, P121, DOI 10.1016/0377-8398(77)90008-1; WALL D., 1967, PALAEONTOLOGY, V10, P95; WILLIAMS D.B., 1971, MICROPALAEONTOLOGY O; Williams DB., 1965, THESIS, P1	51	313	332	0	6	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0031-0239	1475-4983		PALAEONTOLOGY	Paleontology		1983	26	MAY					321	387						67	Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Paleontology	QW893					2025-03-11	WOS:A1983QW89300006
J	POPOVSKY, J				POPOVSKY, J			ANOTHER CASE OF PHAGOTROPHY BY GYMNODINIUM-HELVETICUM PENARD F-ACHROUM SKUJA	ARCHIV FUR PROTISTENKUNDE			English	Article								Several new details in the behavior of G. helveticum f. achroum Skuja during phagotrophic feeding were described. Diatom cells entered the Gymnodinium by means of a lobopode extruding from the sulcus. During phagotrophic feeding, a cone shaped nucleus is closely attached to the food vacuole in the epicone. Evidently, this Gymnodinium exhibits probably selective phagotrophy. The systematic position of the dinoflagellates is discussed. In the case of Katodinium spirodinioides Christen a motionless stage with numerous rhizopodia was present. Pumping of diatom cell contents with the help of rhizopodia was noticed. A possible relationship between K. spirodinioides Christen and present Cystodinedria cells is discussed.			CZECHOSLOVAK ACAD SCI, INST LANDSCAPE ECOL, HYDROBIOL LAB, PRAGUE, CZECH REPUBLIC.							IRISH AE, 1979, BRIT PHYCOL J, V14, P11, DOI 10.1080/00071617900650021; Matvienko A.M., 1954, OPREDELITEL PRESNOVO, V3; PFIESTER LA, 1979, NATURE, V279, P421, DOI 10.1038/279421a0; SCHUSSNIG B, 1960, HDB PROTOPHYTENKUNDE, V2; SIMONSEN R, 1979, Bacillaria, V2, P9; SKUJA H, 1948, SYMB BOT UPPSAL, V9; Starmach K., 1974, FLORA SLODKOWODNA PO, V4	7	13	13	0	4	GUSTAV FISCHER VERLAG	JENA	VILLENGANG 2, D-07745 JENA, GERMANY	0003-9365			ARCH PROTISTENKD	Arch. Protistenkd.		1982	125	1-4					73	78		10.1016/S0003-9365(82)80006-7	http://dx.doi.org/10.1016/S0003-9365(82)80006-7			6	Microbiology	Science Citation Index Expanded (SCI-EXPANDED)	Microbiology	NH846					2025-03-11	WOS:A1982NH84600005
J	POPOVSKY, J; PFIESTER, LA				POPOVSKY, J; PFIESTER, LA			THE LIFE-HISTORIES OF STYLODINIUM-SPHAERA PASCHER AND CYSTODINEDRIA-INERMIS (GEITLER) PASCHER (DINOPHYCEAE), 2 FRESH-WATER FACULTATIVE PREDATOR-AUTOTROPHS	ARCHIV FUR PROTISTENKUNDE			English	Article								Observation are given on the life cycles of 2 freshwater facultative predator.sbd.autotrophs. Two sessile dinoflagellates, S. sphaera and C. inermis have amoeboid and heliozoid stages which are predatory on other algae. Some stages are identical to named protozoan species from genera Vampyrella, Amoeba, Dinamoeba, Actinophrys, Raphidiocystis, Trichophyra.	UNIV OKLAHOMA, DEPT BOT & MICROBIOL, NORMAN, OK 73019 USA	University of Oklahoma System; University of Oklahoma - Norman	CZECHOSLOVAK ACAD SCI, INST LANDSCAPE ECOL, PRAGUE, CZECH REPUBLIC.							BAUMEISTER W, 1943, ARCH PROTISTENKD, V97, P344; BAUMEISTER WILLY, 1957, ARCH PROTISKENKUNDE, V102, P21; Bourrelly P., 1970, ALGUES EAU DOUCE, VIII; GEITLER L, 1944, WIENER BOT Z, V93, P226; GEITLER L., 1943, Beih. Bot. Centralbl, V62A, P160; HIERONYMUS G, 1905, HEDWIGIA, V44, P137; KLEBS G., 1912, Verh. Naturhist. - Med. Vereins Heidelberg, V11, P369; Kudo R.R., 1971, Protozoology; PASCHER A., 1928, ARCH PROTISTENK, V63, P241; PASCHER A., 1927, ARCHIV JUR PROTISTENK, V58, P1; PASCHER A., 1944, Beih. Bot. Centralbl, V62A, P376; PFIESTER LA, 1977, J PHYCOL, V13, P92, DOI 10.1111/j.0022-3646.1977.00092.x; PFIESTER LA, 1979, PHYCOLOGIA, V18, P13, DOI 10.2216/i0031-8884-18-1-13.1; PFIESTER LA, 1976, J PHYCOL, V12, P234; PFIESTER LA, 1975, J PHYCOL, V11, P259, DOI 10.1111/j.1529-8817.1975.tb02776.x; PFIESTER LA, 1979, NATURE, V279, P421, DOI 10.1038/279421a0; Popovsky J., 1967, SBOR PRAC TANAP, V10, P269; POPOVSKY J, 1961, PRESLIA, V33, P291; SCHUSSNIG B, 1954, GRUNDRISS PROTOPHYCO; SCHUSSNIG B, 1960, HDB PROTOPHYTENKUNDE, V2; Starmach K., 1974, FLORA SLODKOWODNA PO, V4; Von Stosch HA., 1973, Br Phycol J, V8, P105	22	17	17	1	3	GUSTAV FISCHER VERLAG	JENA	VILLENGANG 2, D-07745 JENA, GERMANY	0003-9365			ARCH PROTISTENKD	Arch. Protistenkd.		1982	125	1-4					115	127		10.1016/S0003-9365(82)80011-0	http://dx.doi.org/10.1016/S0003-9365(82)80011-0			13	Microbiology	Science Citation Index Expanded (SCI-EXPANDED)	Microbiology	NH846					2025-03-11	WOS:A1982NH84600010
J	SARJEANT, WAS				SARJEANT, WAS			DINOFLAGELLATE CYST TERMINOLOGY - A DISCUSSION AND PROPOSALS	CANADIAN JOURNAL OF BOTANY-REVUE CANADIENNE DE BOTANIQUE			English	Article											SARJEANT, WAS (通讯作者)，UNIV SASKATCHEWAN,DEPT GEOL SCI,SASKATOON S7N 0W0,SASKATCHEWAN,CANADA.							[Anonymous], 1974, FOSSIL LIVING DINOFL; Deflandre G., 1936, Flagelles Ann Paleont Paris, V25, P151; Deflandre G., 1938, TRAVAUX STATION ZOOL, V13, P147; Dodekova L., 1974, Izvestiya geol Inst sofia (Ser Paleont), V23, P25; DORHOFER G, 1980, EVOLUTION ARCHAEOPYL; DOWNIE C, 1966, B BR MUS NAT HIST S, V3, P10; DURR G, 1974, CELL TISSUE RES, V150, P21; EATON G L, 1980, Palaeontology (Oxford), V23, P667; Evitt W. R., 1961, Micropaleontology, V7, P385, DOI 10.2307/1484378; EVITT WR, 1963, P NATL ACAD SCI USA, V49, P158, DOI 10.1073/pnas.49.2.158; Evitt WR., 1969, Aspects of palynology, P439; EVITT WR, 1977, GEOL SURV PAP GEOL S, V7642, P1; EVITT WR, 1967, STANFORD U PUBL GEOL, V10; GEDDIE W, 1962, CHAMBERS 20TH CENTUR; GITMEZ GU, 1972, B BR MUS NAT HIS G, V21, P171; Gocht H., 1979, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V157, P344; GOCHT H, 1976, NEUES JB GEOL PALAEO, V153, P380; GOCHT H, 1974, ARCH PROTISTENKD, V116, P43; GOCHT H, 1976, NEUES JB GEOL PALAEO, V153, P360; HARLAND R, 1975, Palaeontology (Oxford), V18, P847; Klement K. W., 1960, Palaeontographica, VA114, P1; KOFOID C.A., 1911, U CALIFORNIA PUBLICA, V8, P187; Kofoid Charles Atwood, 1907, Zoologischer Anzeiger Leipzig, V32; Kofoid Charles Atwood, 1909, Archiv fuer Protistenkunde Jena, V16; LENTIN JK, 1976, B1R7516 BEDF I OC RE; LISTER T R, 1970, Palaeontographical Society Monographs (London), V124, P1; LOEBLICH AR, 1970, 1969 P N AM PAL CO G, P867; Morbey J., 1975, Palaeontographica B, V152, P1; MUIR MD, 1978, REV PALAEOBOT PALYNO, V25, P193, DOI 10.1016/0034-6667(78)90027-1; Norris G., 1978, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V156, P1; NORRIS G, 1978, NEUES JB GEOL PALAEO, V156, P300; Pocock S.A.J., 1972, Palaeontographica Abteilung B Palaeophytologie, V137, P85; Riegel W., 1982, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V162, P286; Sarjeant W.A.S., 1972, Meddelelser om Gronland, V195, P1; Sarjeant W. A. S., 1962, Micropaleontology, V8, P255, DOI 10.2307/1484746; SARJEANT W A S, 1976, Geobios (Villeurbanne), V9, P5, DOI 10.1016/S0016-6995(76)80017-4; Sarjeant W.A.S., 1978, GRANA, V17, P47; SARJEANT WAS, 1969, HDB PALYNOLOGY MORPH, P165; SARJEANT WAS, 1966, B BRIT MUSEUM NAT S, V3, P199; STOVER L E, 1977, Micropaleontology (New York), V23, P330, DOI 10.2307/1485219; STOVER LE, 1978, STANFORD U PUBL GEOL, V15; TAYLOR FJR, 1980, BIOSYSTEMS, V13, P65, DOI 10.1016/0303-2647(80)90006-4; von Benedek P.N., 1982, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V162, P265; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; Wall D., 1971, Geoscience Man, V3, P1; Wall D., 1975, Micropalaeontology, V21, P14, DOI 10.2307/1485153; WIGGINS V D, 1973, Micropaleontology (New York), V19, P1, DOI 10.2307/1484961; WILLIAMS GL, 1978, ED AM ASS STRATIGR A, V2; WILLIAMS GL, 1973, AM ASS STRATIGR PALY, V2	49	16	18	0	1	NATL RESEARCH COUNCIL CANADA	OTTAWA	RESEARCH JOURNALS, MONTREAL RD, OTTAWA ON K1A 0R6, CANADA	0008-4026			CAN J BOT	Can. J. Bot.-Rev. Can. Bot.		1982	60	6					922	945		10.1139/b82-119	http://dx.doi.org/10.1139/b82-119			24	Plant Sciences	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences	NZ505					2025-03-11	WOS:A1982NZ50500023
J	WHITE, AW; LEWIS, CM				WHITE, AW; LEWIS, CM			RESTING CYSTS OF THE TOXIC, RED TIDE DINOFLAGELLATE GONYAULAX-EXCAVATA IN BAY OF FUNDY SEDIMENTS	CANADIAN JOURNAL OF FISHERIES AND AQUATIC SCIENCES			English	Article								During the winter of 1980-1981 sediment samples were collected from 115 stations throughout the southern Bay of Fundy to determine the distribution and abundance of G. excavata resting cysts. An improved, semiquantitative method of cyst enumeration was developed for this purpose. Resting cysts of G. excavata were widely dispersed in the Bay, occurring both offshore and inshore, including the intertidal zone. The great majority of cysts occurred in a large, extremely rich deposit located offshore in the southwestern Bay of Fundy in a zone of fine brown mud at depths of 80-160 m. The location of this deposit was consistent with hydrographic and sedimentary processes in the Bay. Cyst concentrations ranged from 2000-8000 cyst .cntdot. cm-3 wet sediment at many stations in the .apprx.2000-km2 deposit. Mouse bioassay tests of cyst extracts (prepared by sonication or boiling) indicated that the cysts were toxic, containing 2-5 .RTM. 105 .mu.g saxitoxin (STX) equivalent per cyst, the same range as for G. excavata motile cells in culture. The wintertime acquistion of G. excavata toxins by offshore and inshore molluscan shellfish is caused by ingestion of cysts. Apparently the offshore seed bed serves as the primary source of the motile cells which initiate the annual G. excavata bloom in the Bay of Fundy.			FISHERIES & OCEANS CANADA, BIOL STN, ST ANDREWS E0G 2X0, NB, CANADA.							ALAM MI, 1979, J PHYCOL, V15, P106, DOI 10.1111/j.0022-3646.1979.00106.x; ANDERSON DM, 1980, J PHYCOL, V16, P166; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; BOURNE N, 1965, J FISH RES BOARD CAN, V22, P1137, DOI 10.1139/f65-102; Bumpus D.F., 1965, Serial Atlas of the Marine Environment; Caddy J., 1979, Rapp. el Proces-Verbaux des Reun. Conscil Int. pour 1'Exploration la Mer, V15, P97; DALE B, 1978, SCIENCE, V201, P1223, DOI 10.1126/science.201.4362.1223; DALE B, 1977, SARSIA, V63, P29, DOI 10.1080/00364827.1977.10411318; DALE B, 1979, DEV MARINE BIOL, V1, P443; FADER GB, 1977, 7617 GEOL SURV CAN P; GODIN G, 1968, MS REP SER, V8; HSU CP, 1979, J FISH RES BOARD CAN, V36, P32, DOI 10.1139/f79-004; HUNTER B, 1976, J MAR BIOL ASSOC UK, V56, P951, DOI 10.1017/S0025315400020993; HURST JW, 1981, CAN J FISH AQUAT SCI, V38, P152, DOI 10.1139/f81-020; LAUZIER LM, 1967, J FISH RES BOARD CAN, V24, P1845, DOI 10.1139/f67-154; LEWIS CM, 1979, TOXIC DINOFLAGELLATE, V1, P235; PRAKASH A, 1967, J FISH RES BOARD CAN, V24, P1589, DOI 10.1139/f67-131; PRAKASH A, 1963, J FISH RES BOARD CAN, V20, P983, DOI 10.1139/f63-067; PRAKASH A, 1971, B FISH RES BOARD CAN, V171; REID PC, 1980, MAR POLLUT BULL, V11, P47, DOI 10.1016/0025-326X(80)90352-5; SCHMIDT RJ, 1979, J MAR BIOL ASSOC UK, V59, P479, DOI 10.1017/S0025315400042788; STEIDINGER KA, 1975, 1ST P INT C TOX DIN, P153; TYLER MA, 1982, MAR ECOL PROG SER; WALL D, 1975, 1ST P INT C TOX DIN, P249; WHITE AW, 1978, J FISH RES BOARD CAN, V35, P397, DOI 10.1139/f78-070; WHITE AW, 1981, MAR BIOL, V65, P255, DOI 10.1007/BF00397119; WHITE AW, 1977, J FISH RES BOARD CAN, V34, P2421, DOI 10.1139/f77-328; WHITE AW, 1981, LIMNOL OCEANOGR, V26, P103, DOI 10.4319/lo.1981.26.1.0103; WHITE AW, 1980, CAN J FISH AQUAT SCI, V37, P2262, DOI 10.1139/f80-271; WHITE AW, 1980, INT COUNC EXPLOR SEA, V50; WHITE AW, 1982, 1064 CAN TECH REP FI; WHITE AW, 1979, DEV MARINE BIOL, V1, P381; YENTSCH CM, 1979, DEV MARINE BIOL, V1, P127; 1975, OFFICIAL METHODS ANA, P319	35	62	71	0	6	CANADIAN SCIENCE PUBLISHING	OTTAWA	65 AURIGA DR, SUITE 203, OTTAWA, ON K2E 7W6, CANADA	0706-652X	1205-7533		CAN J FISH AQUAT SCI	Can. J. Fish. Aquat. Sci.		1982	39	8					1185	1194		10.1139/f82-156	http://dx.doi.org/10.1139/f82-156			10	Fisheries; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Fisheries; Marine & Freshwater Biology	PG820					2025-03-11	WOS:A1982PG82000012
J	ANDERSON, DM; KULIS, DM; ORPHANOS, JA; CEURVELS, AR				ANDERSON, DM; KULIS, DM; ORPHANOS, JA; CEURVELS, AR			DISTRIBUTION OF THE TOXIC DINOFLAGELLATE GONYAULAX-TAMARENSIS IN THE SOUTHERN NEW-ENGLAND REGION	ESTUARINE COASTAL AND SHELF SCIENCE			English	Article								Based on the presence or absence of cysts in sediment samples from selected estuarine and coastal locations in southern New England and Long Island, a population distribution is described for the toxic dinoflagellate G. tamarensis Lebour. This distribution is influenced by hydrography and shoreline configuration, which accumulations predominantly offshore in the Cape Ann and Massachusetts Bay regions, and within estuarine embayments on Cape Cod. Three locations in Connecticut and 6 on Long Island also accumulated cysts, despite a history free from paralytic shellfish poisoning (PSP). It would appear that a massive coastal red tide in 1972 introduced G. tamarensis into numerous embayments in previously unaffected areas. However, discovery of cysts of this organism in 11 locations with no history of PSP supports an alternative hypothesis that isolated populations of G. tamarensis existed in the region prior to 1972. Whether these newly discovered populations represent a continuation of a southward dispersal of the toxic organism cannot be resolved at this time. These data suggest different mechanisms for the initiation and development of G. tamarensis populations responsible for PSP in the study area. While cysts on Cape Cod are found in close proximity to the toxic shellfish, other areas are apparently exposed to motile populations of this species originating further afield. Extreme localization of cysts on Cape Cod has remained essentially unchanged over a 3-yr period, despite recurrent outbreaks. The patchy distribution of cysts and motile cells in the southern New England region may reflect physical and chemical constraints or may simply be a manifestation of relatively recent colonization.	WOODS HOLE OCEANOG INST, DEPT BIOL, WOODS HOLE, MA 02543 USA; MASSACHUSETTS DEPT ENVIRONM QUAL ENGN, LAKEVILLE, MA 02346 USA; MASSACHUSETTS DIV MARINE FISHERIES, SALEM, MA 01970 USA									ALAM MI, 1979, J PHYCOL, V15, P106, DOI 10.1111/j.0022-3646.1979.00106.x; ANDERSON DM, 1978, LIMNOL OCEANOGR, V23, P283, DOI 10.4319/lo.1978.23.2.0283; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; Bigelow H.B., 1927, FISH B-NOAA, V40, P511; BOTHNER MH, 1981, J SEDIMENT PETROL, V51, P281; Bumpus D.F., 1973, PROG OCEANOGR, V6, P111, DOI DOI 10.1016/0079-6611(73)90006-2; BUMPUS DF, 1971, J BOSTON SOC CIV ENG, V58, P255; BUMPUS DF, 1949, 496 WOODS HOL OC I R; DALE B, 1976, REV PALAEOBOT PALYNO, V22, P39, DOI 10.1016/0034-6667(76)90010-5; DALE B, 1977, SARSIA, V63, P29, DOI 10.1080/00364827.1977.10411318; GANONG WF, 1889, B NATURAL HIST SOC N, V8; GRAHAM JJ, 1970, INT COMM NW ATLANTIC, V7, P19; GRAN HH, 1935, J BIOL BOARD CAN, V1, P1; GRAN HH, 1933, BIOL BULL, V74, P159; Hartwell A.D., 1975, P47; HURST JW, 1975, TOXIC DINOFLAGELLATE, P525; Lewis C.M., 1979, P235; LILLICK LOIS C., 1937, BIOL BULL, V73, P488, DOI 10.2307/1537608; Mulligan H.F., 1975, P23; OHARA CJ, 1980, BEDFORM MORPHOLOGY N; PRAKASH A, 1967, J FISH RES BOARD CAN, V24, P1589, DOI 10.1139/f67-131; RHOADS DC, 1970, J MAR RES, V28, P150; Riley G.A., 1956, Physical Oceanography, V15, P15; SCHLEE JD, 1973, BOTTOM SEDIMENTS CON; Seliger H.H., 1979, P239; Steidinger K.A., 1975, P153; TUCHOLKE BE, 1972, MAP SHOWING ECHO SOU; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; Yentsch C.M., 1975, P163	30	55	61	0	4	ACADEMIC PRESS LTD- ELSEVIER SCIENCE LTD	LONDON	24-28 OVAL RD, LONDON NW1 7DX, ENGLAND	0272-7714	1096-0015		ESTUAR COAST SHELF S	Estuar. Coast. Shelf Sci.		1982	14	4					447	458		10.1016/S0272-7714(82)80014-0	http://dx.doi.org/10.1016/S0272-7714(82)80014-0			12	Marine & Freshwater Biology; Oceanography	Science Citation Index Expanded (SCI-EXPANDED)	Marine & Freshwater Biology; Oceanography	NM604					2025-03-11	WOS:A1982NM60400007
J	CHAPMAN, DV; DODGE, JD; HEANEY, SI				CHAPMAN, DV; DODGE, JD; HEANEY, SI			CYST FORMATION IN THE FRESH-WATER DINOFLAGELLATE CERATIUM-HIRUNDINELLA (DINOPHYCEAE)	JOURNAL OF PHYCOLOGY			English	Article								Cyst formation in C. hirundinella (O. F. Muell.) Bergh was studied by light and microscopy and EM, using material from several lakes and reserviors and also laboratory cultures. Cells preparing to encyst build up large quantities of starch and lipid and at the same time reduce their other cell components. The cyst is released from the theca as a naked cell bounded by a double membrane. The most commonly found cyst deposits a layer of electron-dense granules containing Si on the outer membrane and lays down a cellulose-like material between the 2 membranes. Cysts without the electron-dense granules are commonly formed in cultures but rarely found in lakes. These cysts appear less resistant to decay and do not show the reorganization of cell contents for dormancy. Apparently, C. hirundinella has a resting cyst, forming part of the life cycle, and a temporary cyst stage.	FRESHWATER BIOL ASSOC, CUMBRIA LA22 0LP, ENGLAND; UNIV LONDON ROYAL HOLLOWAY COLL, DEPT BOT, EGHAM TW20 0EX, SURREY, ENGLAND	Freshwater Biological Association (FBA); University of London; Royal Holloway University London								ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; [Anonymous], 1968, PALAEONTOGRAPHICA B; Bibby B.T., 1972, British phycol J, V7, P85; Canter H.M., 1968, Proceedings of the Linnean Society of London, V179, P197, DOI [DOI 10.1111/J.1095-8312.1968.TB00977.X, 10.1111/j.1095-8312.1968. tb009 77.x]; CHAPMAN DV, 1981, BRIT PHYCOL J, V16, P183, DOI 10.1080/00071618100650191; DALE B, 1977, SARSIA, V63, P29, DOI 10.1080/00364827.1977.10411318; Dale B., 1979, P443; DODGE JD, 1970, J PHYCOL, V6, P137, DOI 10.1111/j.1529-8817.1970.tb02372.x; DURR G, 1979, ARCH PROTISTENKD, V122, P121; Entz G., 1931, Archiv fuer Protistenkunde, V74, P310; ENTZ G, 1925, ARCH PROTISTENKD, V51, P131; EREN J, 1969, J PROTOZOOL, VS 16, P35; EVITT WR, 1968, STANFORD U PUBL GEOL, V12, P2; Georg H., 1858, Mem Inst Natn Genev, DOI 10.5962/bhl.title.29753; GEORGE DG, 1978, J ECOL, V66, P133, DOI 10.2307/2259185; HARRIS GP, 1979, FRESHWATER BIOL, V9, P413, DOI 10.1111/j.1365-2427.1979.tb01526.x; Heaney S. I., 1980, REP FRESHWAT BIOL AS, V48, P27; HEANEY SI, 1980, FRESHWATER BIOL, V10, P163, DOI 10.1111/j.1365-2427.1980.tb01190.x; Huber G., 1922, Z BOTANIK, V14, P337; LACK TJ, 1974, FRESHWATER BIOL, V4, P399, DOI 10.1111/j.1365-2427.1974.tb00105.x; LOEBLICH AR, 1969, P N AM PALEONTOLOGIC, P867; Patalas K., 1954, Ekologia Polska, V2, P231; PEARSALL WH, 1929, P LEEDS PHIL SOC, V1, P432; PFIESTER LA, 1977, J PHYCOL, V13, P92, DOI 10.1111/j.0022-3646.1977.00092.x; PFIESTER LA, 1979, PHYCOLOGIA, V18, P13, DOI 10.2216/i0031-8884-18-1-13.1; PFIESTER LA, 1976, J PHYCOL, V12, P234; PFIESTER LA, 1975, J PHYCOL, V11, P259, DOI 10.1111/j.1529-8817.1975.tb02776.x; RAHAT M, 1968, ISRAEL J BOT, V17, P200; REYNOLDS ES, 1963, J CELL BIOL, V17, P208, DOI 10.1083/jcb.17.1.208; SPURR AR, 1969, J ULTRA MOL STRUCT R, V26, P31, DOI 10.1016/S0022-5320(69)90033-1; TURPIN DH, 1978, J PHYCOL, V14, P235, DOI 10.1111/j.1529-8817.1978.tb02454.x; Von Stosch HA., 1973, Br Phycol J, V8, P105; WALKER LM, 1979, J PHYCOL, V15, P312; Wall D., 1975, P249; WALL D, 1968, Journal of Paleontology, V42, P1395; WALL D, 1967, Review of Palaeobotany and Palynology, V2, P349, DOI 10.1016/0034-6667(67)90165-0; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; Wall D., 1975, Micropalaeontology, V21, P14, DOI 10.2307/1485153; Wesenberg-Lund C., 1908, PLANKTON INVESTIGATI	40	54	55	1	8	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0022-3646	1529-8817		J PHYCOL	J. Phycol.		1982	18	1					121	129		10.1111/j.0022-3646.1982.00121.x	http://dx.doi.org/10.1111/j.0022-3646.1982.00121.x			9	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	NH927					2025-03-11	WOS:A1982NH92700015
J	ANDERSON, DM; AUBREY, DG; TYLER, MA; COATS, DW				ANDERSON, DM; AUBREY, DG; TYLER, MA; COATS, DW			VERTICAL AND HORIZONTAL DISTRIBUTIONS OF DINOFLAGELLATE CYSTS IN SEDIMENTS	LIMNOLOGY AND OCEANOGRAPHY			English	Note									WOODS HOLE OCEANOG INST, DEPT GEOL & GEOPHYS, WOODS HOLE, MA 02543 USA; JOHNS HOPKINS UNIV, CHESAPEAKE BAY INST, BALTIMORE, MD 21218 USA	Woods Hole Oceanographic Institution; Johns Hopkins University	WOODS HOLE OCEANOG INST, DEPT BIOL, WOODS HOLE, MA 02543 USA.			Coats, D Wayne/0000-0002-0636-189X				ALLER RC, 1980, STUDIES LONG ISLAND, V22, P237; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; ANDERSON DM, 1982, ESTUARINE COASTAL SH, V14; BALCH WM, CAN J FISH AQUAT SCI; BAXTER MS, 1981, ENVIRON SCI TECHNOL, V15, P843, DOI 10.1021/es00089a014; DALE B, 1976, REV PALAEOBOT PALYNO, V22, P39, DOI 10.1016/0034-6667(76)90010-5; DALE B, 1978, SCIENCE, V201, P1223, DOI 10.1126/science.201.4362.1223; Dale B., 1979, P443; DAVEY RJ, 1971, 2ND P PLANKT C ROM, P331; Evitt WR., 1970, GEOSCI MAN, V1, P29; HENRICI ARTHUR T., 1938, TRANS WISCONSIN ACAD SCI ARTS AND LETT, V31, P323; Lewis C.M., 1979, P235; Onbe T., 1974, J. Fac. Fish. Anim. Husb., V13, P83, DOI DOI 10.15027/41211; Reid P.C., 1974, Nova Hedwigia, V25, P579; REID PC, 1972, J MAR BIOL ASSOC UK, V52, P939, DOI 10.1017/S0025315400040674; Rhoads D.C., 1974, Oceanography mar Biol, V12, P263; RHOADS DC, 1970, J MAR RES, V28, P150; Steidinger K.A., 1975, P153; TUREKIAN KK, 1978, OCEANUS, V21, P34; Wall D., 1975, P249; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; WALL D, 1977, MAR MICROPALEONTOL, V2, P121, DOI 10.1016/0377-8398(77)90008-1; WILLIAMS D.B., 1971, MICROPALAEONTOLOGY O	24	73	88	2	9	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0024-3590	1939-5590		LIMNOL OCEANOGR	Limnol. Oceanogr.		1982	27	4					757	765		10.4319/lo.1982.27.4.0757	http://dx.doi.org/10.4319/lo.1982.27.4.0757			9	Limnology; Oceanography	Science Citation Index Expanded (SCI-EXPANDED)	Marine & Freshwater Biology; Oceanography	NY083		Bronze			2025-03-11	WOS:A1982NY08300018
J	TYLER, MA; COATS, DW; ANDERSON, DM				TYLER, MA; COATS, DW; ANDERSON, DM			ENCYSTMENT IN A DYNAMIC ENVIRONMENT - DEPOSITION OF DINOFLAGELLATE CYSTS BY A FRONTAL CONVERGENCE	MARINE ECOLOGY PROGRESS SERIES			English	Article								The dinoflagellate Gyrodinium uncatenum forms massive summer red tides in Chesapeake Bay (USA) and tributary estuaries. These blooms are delimited in the downstream direction by estuarine fronts may serve to concentrate and recirculate the population. Toward the end of the bloom cycle, G. uncatenum sexual stages accumulate in the frontal convergence and are transported downward along the frontal interface. These stages are retained below the pycnocline in net upstream flowing bottom waters and settle out into the sediments along the subsurface transport pathway. Examination of sediments indicates that major deposits of cysts of G. uncatenum are bounded in an upstream direction by a benthic front (where the pycnocline intersects the bottom). Above this area, motile cells and sexual stages are absent from the water column and cysts are absent from the sediment. Streamflow-induced variations in the location of the estuarine front in 1979 and in 1980 result in deposition of cysts in different regions, predictable from examination of the location of the convergence. It is proposed that the convergence zone of the estuarine front and the associated pycnocline serve to transfer encysting dinoflagellate forms from surface waters to their ultimate seedbed locations.	JOHNS HOPKINS UNIV, CHESAPEAKE BAY INST, BALTIMORE, MD 21218 USA; WOODS HOLE OCEANOG INST, WOODS HOLE, MA 02543 USA	Johns Hopkins University; Woods Hole Oceanographic Institution	UNIV DELAWARE, COLL MARINE STUDIES, LEWES, DE 19958 USA.							Anderson D.M., 1979, P145; ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1982, ESTUAR COAST SHELF S; ANDERSON DM, 1982, UNPUB LIMNOL OCEANOG; Blasco D., 1975, P113; ELLIOTT A J, 1976, Chesapeake Science, V17, P141, DOI 10.2307/1351191; ELLIOTT AJ, 1978, ESTUAR COAST MAR SCI, V6, P285, DOI 10.1016/0302-3524(78)90017-8; Garvine R W., 1977, Estuaries, Geofphisics and the Environment, P30; GUILLARD RRL, 1962, GRAN CAN J MICROBIOL, V8, P229; HAMMOND D, RATES EXCHANGE SEDIM; Hartwell A.D., 1975, P47; Holligan P.M., 1979, P249; Huber G., 1922, Z BOTANIK, V14, P337; Huber G., 1923, FLORA JENA, V116, P114; LASKER R, 1975, FISH B-NOAA, V73, P453; Lewis C.M., 1979, P235; LOFTUS M E, 1972, Chesapeake Science, V13, P282, DOI 10.2307/1351112; Mulligan H.F., 1975, P23; OWENS OVH, 1977, CHESAPEAKE SCI, V18, P325; PFIESTER LA, 1977, J PHYCOL, V13, P92, DOI 10.1111/j.0022-3646.1977.00092.x; PFIESTER LA, 1980, T AM MICROSC SOC, V99, P213, DOI 10.2307/3225709; PFIESTER LA, 1976, J PHYCOL, V12, P234; PFIESTER LA, 1975, J PHYCOL, V11, P259, DOI 10.1111/j.1529-8817.1975.tb02776.x; PINGREE RD, 1978, DEEP-SEA RES, V25, P1011, DOI 10.1016/0146-6291(78)90584-2; PRITCHARD DW, 1952, J MAR RES, V11, P106; SELIGER H H, 1974, Chesapeake Science, V15, P185, DOI 10.1007/BF02688900; Seliger H.H., 1979, P239; Seliger H.H., 1975, P181; SPOON DM, 1977, J PROTOZOOL, V24, P471, DOI 10.1111/j.1550-7408.1977.tb04779.x; Steidinger K.A., 1975, P153; STEIDINGER KA, J PHYCOL; STOMMEL H, 1949, J MAR RES, V8, P25; TYLER MA, 1978, LIMNOL OCEANOGR, V23, P227, DOI 10.4319/lo.1978.23.2.0227; TYLER MA, 1981, LIMNOL OCEANOGR, V26, P310, DOI 10.4319/lo.1981.26.2.0310; TYLER MA, UNPUB GAMETE PRODUCT; VIEN DMC, 1967, CR ACAD SCI D NAT, V264, P1006; Von Stosch HA., 1973, Br Phycol J, V8, P105; Wall D., 1975, P249; Wall D., 1971, Geoscience Man, V3, P1; Yentsch C.M., 1979, P127; 1980, USGS MDDE791 WAT DAT	41	79	86	0	3	INTER-RESEARCH	OLDENDORF LUHE	NORDBUNTE 23, D-21385 OLDENDORF LUHE, GERMANY	0171-8630	1616-1599		MAR ECOL PROG SER	Mar. Ecol.-Prog. Ser.		1982	7	2					163	178		10.3354/meps007163	http://dx.doi.org/10.3354/meps007163			16	Ecology; Marine & Freshwater Biology; Oceanography	Science Citation Index Expanded (SCI-EXPANDED)	Environmental Sciences & Ecology; Marine & Freshwater Biology; Oceanography	NB844		Bronze			2025-03-11	WOS:A1982NB84400006
J	MOREYGAINES, G				MOREYGAINES, G			GYMNODINIUM-CATENATUM GRAHAM (DINOPHYCEAE) - MORPHOLOGY AND AFFINITIES WITH ARMORED FORMS	PHYCOLOGIA			English	Article								Samples of the unarmored dinoflagellate G. catenatum Graham, collected from the plankton during an outbreak of paralytic shellfish-poisoning, were examined with light microscopy and EM. No thecal plates were seen. Instead, a pellicular layer surrounded the cells. Cell size and shape, nucleus shape and position, cingulum arrangement, the pellicular layer, chain formation, apical markings, toxicity and possibly cyst morphology indicate close affinities with members of the thecate genus Protogonyaulax Taylor.			SO ILLINOIS UNIV, DEPT BOT, CARBONDALE, IL 62901 USA.							ADACHI R, 1979, B JPN SOC SCI FISH, V45, P67; BALECH E, 1959, BIOL BULL-US, V116, P195, DOI 10.2307/1539204; BALECH E., 1964, BOL INST BIOL MAR MAR DEL PLATA, V4, P1; Balech E., 1977, NEOTROPICA, V23, P49; Balech E., 1971, SERV HIDROGR NAVAL A, V654, P1; BALECH E, 1967, REV MUS ARGENT C NAT, V2, P1; Biecheler B., 1952, Bull. Biol. Fr. Belg., V36, P1; Chatton E, 1934, CR SOC BIOL, V115, P1036; Chatton E., 1952, TRAITE ZOOL, P309; DODGE JD, 1970, J PHYCOL, V6, P137, DOI 10.1111/j.1529-8817.1970.tb02372.x; DODGE JD, 1969, NEW PHYTOL, V68, P613, DOI 10.1111/j.1469-8137.1969.tb06465.x; DRAGESCO J, 1965, CR HEBD ACAD SCI, V260, P2073; FAUST MA, 1974, J PHYCOL, V10, P315, DOI 10.1111/j.0022-3646.1974.00315.x; Graham Herbert W, 1943, TRANS AMER MICROSC SOC, V62, P259, DOI 10.2307/3223028; HOWELL JOHN F., 1953, TRANS AMER MICROSC SOC, V72, P153, DOI 10.2307/3223513; LEE RE, 1977, J MAR BIOL ASSOC UK, V57, P303, DOI 10.1017/S0025315400021779; Loeblich A.R. III, 1979, P41; LOEBLICH AR, 1979, J MAR BIOL ASSOC UK, V59, P195, DOI 10.1017/S0025315400046270; LOEBLICH AR, 1969, P N AM PALEONTOLOGIC, P867; MEE L, 1980, GULF CALIFORNIA ORIG; MEUNIER V, 1977, PHYCOLOGIA, V16, P359, DOI 10.2216/i0031-8884-16-4-359.1; POSTEK MT, 1976, J PHYCOL, V12, P88, DOI 10.1111/j.1529-8817.1976.tb02832.x; Schmidt R.J., 1979, P83; STEIDINGER K A, 1971, Phycologia, V10, P183, DOI 10.2216/i0031-8884-10-2-183.1; STEIDINGER K.A., 1967, FLA BD CONSERV MAR L, V1, P1; STEIDINGER KA, 1978, J PHYCOL, V14, P72, DOI 10.1111/j.1529-8817.1978.tb00634.x; SWIFT E, 1972, Phycologia, V11, P57, DOI 10.2216/i0031-8884-11-1-57.1; Taylor F.J.R., 1979, P71; Taylor F.J.R., 1979, P47; TAYLOR F J R, 1972, Phycologia, V11, P47, DOI 10.2216/i0031-8884-11-1-47.1; Taylor F.J.R., 1976, BIBLIOTHECA BOT, V132, P1; TAYLOR FJR, 1975, ENVIRON LETT, V9, P103, DOI 10.1080/00139307509435840; Vollenweider R.A., 1969, IBP HDB, V12; VONSTOSCH HA, 1969, HELGOLAND WISS MEER, V19, P569; WALL D, 1971, J PHYCOL, V7, P221, DOI 10.1111/j.1529-8817.1971.tb01507.x; WETHERBEE R, 1975, J ULTRA MOL STRUCT R, V50, P65, DOI 10.1016/S0022-5320(75)90009-X; WETHERBEE R, 1975, J ULTRA MOL STRUCT R, V50, P77, DOI 10.1016/S0022-5320(75)90010-6; WETHERBEE R, 1975, J ULTRA MOL STRUCT R, V50, P58, DOI 10.1016/S0022-5320(75)90008-8; Whedon W. F., 1936, University of California Publications in Zoology, V41, P25; Woloszynska J., 1939, Bull Mus Hist nat Belg, V15, P1	40	38	41	0	5	TAYLOR & FRANCIS LTD	ABINGDON	2-4 PARK SQUARE, MILTON PARK, ABINGDON OR14 4RN, OXON, ENGLAND	0031-8884	2330-2968		PHYCOLOGIA	Phycologia		1982	21	2					154	163		10.2216/i0031-8884-21-2-154.1	http://dx.doi.org/10.2216/i0031-8884-21-2-154.1			10	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	NS729					2025-03-11	WOS:A1982NS72900007
J	HOLLANDE, A; CORBEL, JC				HOLLANDE, A; CORBEL, JC			ULTRASTRUCTURE, LIFE-CYCLE AND SYSTEMATIC POSITION OF CARYOTOMA-BERNARDI, HOLL AND ENJ (DINOFLAGELLATE, OODINIDAE) AN ENDOCAPSULAR PARASITE OF THALASSICOLA (RADIOLARIA)	PROTISTOLOGICA			French	Article								The study of the life-cycle and the ultrastructure of C. bernardi indicates this parasite is a dinoflagellate related to the Oodinida. The cycle is simple: penetration of a gymnodinian spore into the endocapsular endoplasm of the radiolaria; growth of the spore (osmotrophy) which, after a long trophic period, changes itself into a large-size trophozoite with a synergid nucleus substituting itself to its host; fragmentation of the trophozoite into zoospores which are liberated in sea water after the lysis of the Thalassicolla capsular envelope. During sporogenesis the resolution of the synergid nucleus with a homogeneous structure into secondary nuclei with fibrillar chromosomes assumes the same characteristics as in Noctiluca, Blastodinium or Oodinium. A special reference is made to the peculiar modalities (apparition of an axial canal) assumed, in the sporocytes, by the division of chromosomes into their constitutive chromatids. The ultrastructural modifications taking place during the segmentation of the trophozoite into sporocysts and afterwards into spores are exposed. The action of the parasite on its host reveals itself at the first developing stages by the loss of melanic pigments which generally line the capsular envelope of Thalassicolla.			LAB CYTOPHYSIOL PROTOZOAIRES, 105 BLVD RASPAIL, PARIS, FRANCE.							CACHON J, 1974, CR ACAD SCI D NAT, V278, P1735; HOLLANDE A, 1974, Protistologica, V10, P413; HOLLANDE ANDRE, 1953, ANN SCI NAT ZOOL 11ESER, V15, P99; SOYER M-O, 1978, Vie et Milieu Serie AB Biologie Marine et Oceanographie, V28-29, P461; SOYER MO, 1974, J MICROSC-PARIS, V19, P137; SOYER MO, 1967, CR ACAD SCI D NAT, V265, P1206; SOYER MO, 1972, CHROMOSOMA, V39, P412	7	7	7	0	2	EDITIONS C N R S	PARIS	20/22 RUE ST. AMAND, 75015 PARIS, FRANCE	0033-1821			PROTISTOLOGICA			1982	18	1					123	133						11	Microbiology	Science Citation Index Expanded (SCI-EXPANDED)	Microbiology	NX097					2025-03-11	WOS:A1982NX09700009
J	WALKER, LM				WALKER, LM			EVIDENCE FOR A SEXUAL CYCLE IN THE FLORIDA RED TIDE DINOFLAGELLATE, PTYCHODISCUS-BREVIS (=GYMNODINIUM-BREVE)	TRANSACTIONS OF THE AMERICAN MICROSCOPICAL SOCIETY			English	Article								Sexual stages (gametes, planozygotes) were observed in non-clonal strains of P. brevis stock cultures. Sexual states were induced repeatedly in nonclonal isolates and crosses of 6 different isolates using N-deficient NH-15 medium, blue or green light, and/or lowered temperatures. Sexual stages were observed in field populations during Florida [USA] red tides. So far, hypnozygotic cysts have not been confirmed in laboratory cultures or field populations, although possible cysts have been observed during cold temperature experiments, initial experiments with multiple crosses and during continuous 24-h sampling during a red tide cruise in Jan. 1980.	FLORIDA DEPT NAT RESOURCES, MARINE RES LAB, 100 8TH AVE SE, ST PETERSBURG, FL 33701 USA									DURANT JP, 1968, J PHYCOL, V4, P356, DOI 10.1111/j.1529-8817.1968.tb04708.x; FREEBERG LR, 1978, 2ND INT C TOX DIN BL; GATES JEAN A., 1960, LIMNOL AND OCEANOGR, V5, P171; Haddad K.D., 1979, P269; LOPER CL, 1980, T AM MICROSC SOC, V99, P343, DOI 10.2307/3226012; LUNING K, 1975, MAR BIOL, V29, P195, DOI 10.1007/BF00391846; PATEL R J, 1971, Phykos, V10, P40; PFIESTER LA, 1977, J PHYCOL, V13, P92, DOI 10.1111/j.0022-3646.1977.00092.x; PFIESTER LA, 1979, PHYCOLOGIA, V18, P13, DOI 10.2216/i0031-8884-18-1-13.1; PFIESTER LA, 1976, J PHYCOL, V12, P234; PFIESTER LA, 1975, J PHYCOL, V11, P259, DOI 10.1111/j.1529-8817.1975.tb02776.x; Steidinger K.A., 1975, P153; STEIDINGER KA, 1981, BIOSCIENCE, V31, P814, DOI 10.2307/1308678; STEIDINGER KA, 1975, ENVIRON LETT, V9, P129, DOI 10.1080/00139307509435842; STEIDINGER KA, 1972, ENVIRON LETT, V3, P271, DOI 10.1080/00139307209435473; STEIDINGER KA, 1978, J PHYCOL, V14, P72, DOI 10.1111/j.1529-8817.1978.tb00634.x; VESK M, 1977, J PHYCOL, V13, P280, DOI 10.1111/j.1529-8817.1977.tb00597.x; Von Stosch HA., 1973, Br Phycol J, V8, P105; WALKER LM, 1979, J PHYCOL, V15, P312; WALLEN DG, 1971, MAR BIOL, V10, P34, DOI 10.1007/BF02026764; WILSON WB, 1967, CONTRIB MAR SCI, V12, P120; YENTSCH CM, 1980, BIOSCIENCE, V30, P251, DOI 10.2307/1307880	22	34	37	0	3	AMER MICROSCOPICAL SOC	LAWRENCE	810 EAST 10TH ST, LAWRENCE, KS 66044-8897 USA	0003-0023			T AM MICROSC SOC			1982	101	3					287	293		10.2307/3225818	http://dx.doi.org/10.2307/3225818			7	Microscopy	Science Citation Index Expanded (SCI-EXPANDED)	Microscopy	PC967					2025-03-11	WOS:A1982PC96700007
J	PINCEMIN, JM; GAYOL, P; SALVANO, P				PINCEMIN, JM; GAYOL, P; SALVANO, P			OBSERVATIONS ON THE THECATE STAGE OF THE DINOFLAGELLATE PYROCYSTIS CF FUSIFORMIS (CLONES NOB2 AND 111) - VARIATIONS IN MORPHOLOGY AND TABULATION	ARCHIV FUR PROTISTENKUNDE			English	Article								P. ef. fusiformis clones NOB2/111 (Pincemin and Gayol 1978) has the following tabulation: P, 4'', Oa, 7-8'''', 6c, 7'''''', 1p, 1'''''''', but other possible interpretations are discussed. The apical closing platelets, whether they are porulated or not, are distinctive. The platelet, when it bears a pore, imparts a print on the antapical plate 1'''''''' of the anteriormost individual of a chain. Seven or 8 precingular plates are observed of which 2 are small. The postcingular plates 1'''''' and 7'''''' are narrow and well separated from the deep sulcus. Numerous variations were observed in the shape of the plates particularly involving the sensitive plates 4'''' or 5'''' and 4''''''. The plate formula of the P. fusiformis of Kofoid and Michener (Taylor 1972) is similar to this one. Some discrepancies are noted. The different size of the cyst does not affirm that the 2 organisms are the same species. The flagellate tabulation is also similar to that of P. acuta (Swift and Wall 1972) but is far from that of the P. fusiformis of Meunier and Swift (1977). The tabulation of P. ef. fusiformis clones NOB2/111 is of a gonyaulacoid type, more precisely near the genus Protogonyaulax (Taylor 1979) or the genus Gessnerium, after its reinterpretation by Loeblich III A. R and Ioeblich L. A. (1979).			FAC SCI NICE, PROTISTOL MARINE LAB, F-06034 NICE, FRANCE.							BALECH E, 1959, BIOL BULL-US, V116, P195, DOI 10.2307/1539204; BALECH E, 1962, CIENC ZOOL, V7, P3; Balech E., 1967, HIDROBIOLOGIA, V2, P77; Gaardner K. R., 1954, Report Sars North Atlantic Deep Sea Expedition, V2, P1; Halim Y., 1960, Vie et Milieu, V11, P102; Hattori, 1968, CULTURES COLLECTIONS, P63; KARSTEN G., 1907, Wissenschaftliche Ergebnisse der Deutschen Tiefsee-Expedition auf dem Dampfer Valdivia 18981899, V2, P221; LOEBLICH AR, 1979, DEV MAR BIOL, V1, P41; MEUNIER V, 1977, PHYCOLOGIA, V16, P359, DOI 10.2216/i0031-8884-16-4-359.1; MURRAY J, 1876, P ROY SOC LONDON, V24, P471; MURRAY J, 1885, REP SCI RESULTS CHAL, V1, P935; PINCEMIN J M, 1979, Journal of Protozoology, V26, p67A; PINCEMIN JM, 1978, ARCH PROTISTENKD, V120, P401, DOI 10.1016/S0003-9365(78)80031-1; PINCEMIN JM, 1978, APR PENR C MOD FOSS; STEIDINGER K A, 1971, Phycologia, V10, P183, DOI 10.2216/i0031-8884-10-2-183.1; STEIDINGER K.A., 1967, FLA BD CONSERV MAR L, V1, P1; SWIFT E, 1971, J PHYCOL, V7, P89, DOI 10.1111/j.1529-8817.1971.tb01486.x; SWIFT E, 1972, Phycologia, V11, P57, DOI 10.2216/i0031-8884-11-1-57.1; TAYLOR F J R, 1972, Phycologia, V11, P47, DOI 10.2216/i0031-8884-11-1-47.1; Taylor F.J.R., 1976, BIBLIOTHECA BOT, V132, P1; TAYLOR FJR, 1975, ENVIRON LETT, V9, P103, DOI 10.1080/00139307509435840; TAYLOR FJR, 1971, PHYCOLOGIA, V10, P143; TAYLOR FJR, 1979, DEV MAR BIOL, V1, P41; VONSTOSCH HA, 1969, HELGOLAND WISS MEER, V19, P569	24	5	5	0	1	GUSTAV FISCHER VERLAG	JENA	VILLENGANG 2, D-07745 JENA, GERMANY	0003-9365			ARCH PROTISTENKD	Arch. Protistenkd.		1981	124	3					271	282		10.1016/S0003-9365(81)80020-6	http://dx.doi.org/10.1016/S0003-9365(81)80020-6			12	Microbiology	Science Citation Index Expanded (SCI-EXPANDED)	Microbiology	MA296					2025-03-11	WOS:A1981MA29600007
J	DEANE, EM; OBRIEN, RW				DEANE, EM; OBRIEN, RW			UPTAKE OF SULFATE, TAURINE, CYSTEINE AND METHIONINE BY SYMBIOTIC AND FREE-LIVING DINOFLAGELLATES	ARCHIVES OF MICROBIOLOGY			English	Article								Sulfate uptake by Amphidinium carterae, A. klebsii and Gymnodinium microadriaticum grown on artificial seawater medium with sulfate, cysteine, methionine or taurine as sulfur source occurred via an active transport system which conformed to Michaelis-Menten type saturation kinetics. Values for Km ranged from 0.18-2.13 mM and Vmax ranged from 0.2-24.2 nmol .cntdot. 105 cells-1 .cntdot. h-1. Km for symbiotic G. microadriaticum was 0.48 mM and Vmax was 0.2 nmol .cntdot. 105 cells-1 .cntdot. h-1. Sulfate uptake was slightly inhibited by chromate and selenate but not by tungstate, molybdate, sulfite or thiosulphate. Cysteine and methionine (0.1 mM), but not taurine, inhibited sulfate uptake by symbiotic G. microadriaticum but not by the 2 spp. of Amphidinium. Uptake was inhibited 45-97% under light and dark conditions by carbonylcyanide 3-chlorophenylhydrazone (CCCP); under dark conditions sulfate uptake was 40-60% of that observed under light conditions and was little affected by 3-(3,4-dichlorophenyl) 1,1-dimethylurea (DCMU). The uptake of taurine, cysteine and methionine by A. carterae, A. klebsii, cultured and symbiotic G. microadriaticum conformed to Michaelis-Menten type saturation kinetics. Km values of taurine uptake ranged from 1.9-10 mM; for cysteine uptake from 0.6-3.2 mM and methionine from 0.001-0.021 mM. Cysteine induced a taurine uptake system with a Km of 0.3-0.7 mM. Cysteine and methionine uptake by all organisms was largely unaffected by darkness or by DCMU in light or darkness. CCCP significantly inhibited uptake of these amino acids. Energy for cysteine and methionine uptake was supplied mainly by respiration. Taurine uptake by A. carterae was independent of light but was inhibited by CCCP, uptake by A. klebsii and symbiotic G. microadriaticum was partially dependent on photosynthetic energy. Taurine uptake by cultured G. microadraiticum was more dependent on photosynthetic energy and was more sensitive to CCCP. Cysteine inhibited uptake of methionine and taurine by cultured and symbiotic G. microadriaticum to a greater extent than in the Amphidinium species. Methionine did not greatly affect taurine uptake but did inhibit cysteine uptake. Taurine did not affect the uptake of cysteine or methionine.	UNIV SYDNEY, DEPT BIOCHEM, SYDNEY, NSW 2006, AUSTRALIA	University of Sydney								CHRISTENSEN HN, 1975, BIOL TRANSPORT; COUGHLAN S, 1977, J EXP BOT, V28, P1207, DOI 10.1093/jxb/28.5.1207; DEANE EM, 1980, COMP BIOCHEM PHYS A, V66, P339, DOI 10.1016/0300-9629(80)90173-5; DEANE EM, 1975, ARCH MICROBIOL, V105, P295, DOI 10.1007/BF00447149; DEANE EM, 1978, BRIT PHYCOL J, V13, P189, DOI 10.1080/00071617800650241; FANKBONE.PV, 1971, BIOL BULL-US, V141, P222, DOI 10.2307/1540113; GUTKNECHT J, 1968, Oceanography and Marine Biology an Annual Review, V6, P163; HEYTLER PG, 1963, BIOCHEMISTRY-US, V2, P357, DOI 10.1021/bi00902a031; Izawa S., 1972, Meth. Enzym, V24, P355; JEANJEAN R, 1977, ARCH MICROBIOL, V114, P19, DOI 10.1007/BF00429625; MCLACHLAN J, 1964, CAN J MICROBIOL, V10, P769, DOI 10.1139/m64-098; SEGEL IH, 1961, J BACTERIOL, V81, P91, DOI 10.1128/JB.81.1.91-98.1961; SHRIFT A, 1954, AM J BOT, V41, P223, DOI 10.2307/2438977; Sutton L.E., 1958, TABLES INTERATOMIC D; TAYLOR DL, 1971, J MAR BIOL ASSOC UK, V51, P301, DOI 10.1017/S0025315400031799; TRENCH RK, 1979, ANNU REV PLANT PHYS, V30, P485, DOI 10.1146/annurev.pp.30.060179.002413; VALLEE M, 1968, BIOCHIM BIOPHYS ACTA, V150, P599, DOI 10.1016/0005-2736(68)90049-7; VANDERMEULEN JH, 1972, MAR BIOL, V16, P185	18	26	27	0	6	SPRINGER	NEW YORK	ONE NEW YORK PLAZA, SUITE 4600, NEW YORK, NY, UNITED STATES	0302-8933	1432-072X		ARCH MICROBIOL	Arch. Microbiol.		1981	128	3					311	319		10.1007/BF00422537	http://dx.doi.org/10.1007/BF00422537			9	Microbiology	Science Citation Index Expanded (SCI-EXPANDED)	Microbiology	LB032					2025-03-11	WOS:A1981LB03200011
J	HEANEY, SI; CHAPMAN, DV; MORISON, HR				HEANEY, SI; CHAPMAN, DV; MORISON, HR			THE IMPORTANCE OF THE CYST STAGE IN THE SEASONAL GROWTH OF THE DINOFLAGELLATE CERATIUM-HIRUNDINELLA IN A SMALL PRODUCTIVE LAKE	BRITISH PHYCOLOGICAL JOURNAL			English	Meeting Abstract									FRESHWATER BIOL ASSOC,AMBLESIDE LA22 0LP,CUMBRIA,ENGLAND; UNIV LONDON ROYAL HOLLOWAY COLL,EGHAM TW20 0EX,SURREY,ENGLAND	Freshwater Biological Association (FBA); University of London; Royal Holloway University London									0	3	3	0	3	ACADEMIC PRESS LTD	LONDON	24-28 OVAL RD, LONDON, ENGLAND NW1 7DX	0007-1617			BRIT PHYCOL J			1981	16	2					136	136						1	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	LT985					2025-03-11	WOS:A1981LT98500013
J	REID, PC; BALCH, WM; SUREYGENT, SC; JOHN, AWG				REID, PC; BALCH, WM; SUREYGENT, SC; JOHN, AWG			RESUSPENSION OF DINOFLAGELLATE CYSTS DURING 1980 FROM BOTTOM MUDS IN PLYMOUTH SOUND	BRITISH PHYCOLOGICAL JOURNAL			English	Meeting Abstract									INST MARINE ENVIRONM RES,PLYMOUTH PL1 3DH,DEVONSHIRE,ENGLAND; UNIV CALIF SAN DIEGO,SCRIPPS INST OCEANOG,LA JOLLA,CA 92093	University of California System; University of California San Diego; Scripps Institution of Oceanography									0	3	3	0	0	ACADEMIC PRESS LTD	LONDON	24-28 OVAL RD, LONDON, ENGLAND NW1 7DX	0007-1617			BRIT PHYCOL J			1981	16	2					140	140						1	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	LT985					2025-03-11	WOS:A1981LT98500026
J	SPERO, HJ; MOREE, MD				SPERO, HJ; MOREE, MD			PHAGOTROPHIC FEEDING AND ITS IMPORTANCE TO THE LIFE-CYCLE OF THE HOLOZOIC DINOFLAGELLATE, GYMNODINIUM-FUNGIFORME	JOURNAL OF PHYCOLOGY			English	Article								The holozoic dinoflagellate, G. fungiforme Anissimova, was observed in asexually and sexually reproducing cultures. Asexual reproduction is characterized by zoosporangium formation and subsequent new cell release. Sexuality is gametic and planozygotes and hypnozygotes are present. The life cycle is highly dependent on feeding and in food-depleted cultures the swimming cells rapidly disappear. These are replaced with resistant long-term resting cysts. Despite its small size (8.5-19 .mu.m), G. fungiforme can feed on prey as large as the cilitated protozoan, Condylostoma magnum Spiegel (600-1000 .mu.m in length), or small injured metazoans, and was cultured phagotrophically with the chlorophyte, Dunaliella salina Teodoresco as a food source. Eleven additional species of algae [Tetraselmis chuii, Skeletonema costatum, S. tropicum, Thalassiosira alleni, T. decipiens, T. pseudonana, T. subtilis, T. tropicum, Erythrolobus sp., Porphyridium cruentum and Rhodosorus marinus], were not suitable as food sources. Feeding is characterized by the formation of dynamic aggregations of hundreds of dinoflagellates that attach to the surface of a prey organism by a peduncle. G. fungiforme ingests the cytoplasm or body fluids of its prey and a feeding aggregation can ingest a C. magnum in 20-30 min.	TEXAS A&M UNIV, DEPT OCEANOG, COLLEGE STN, TX 77843 USA; BELLAIRS RES INST, ST JAMES, BARBADOS	Texas A&M University System; Texas A&M University College Station			Spero, Howard/LMM-9947-2024	Spero, Howard/0000-0001-5465-8607				ANISSIMOVA N. V., 1926, [RUSS HYDRO BIOL ZEITSCHR], V5, P188; [Anonymous], 2002, SYSTEMATIC BIOL; BARKER H. ALBERT, 1935, ARCH MIKROBIOL, V6, P157, DOI 10.1007/BF00407285; Bergh R. 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R, 1975, Microbial Ecol, V1, P246; HAUSER DCR, 1975, SCIENCE, V190, P285, DOI 10.1126/science.1080881; HAUSER DCR, 1978, NATURE, V273, P230, DOI 10.1038/273230a0; HOFENEDER HEINRICH, 1930, ARCH PROTISTENK, V71, P1; IRISH AE, 1979, BRIT PHYCOL J, V14, P11, DOI 10.1080/00071617900650021; KENT S, 1881, MANUAL INFUSORIA, V1; Kofoid C. A., 1921, Memoirs of the University of California, V5, P1; KUBAI DF, 1969, J CELL BIOL, V40, P508, DOI 10.1083/jcb.40.2.508; LEE RE, 1977, J MAR BIOL ASSOC UK, V57, P303, DOI 10.1017/S0025315400021779; LEVANDOWSKY M, 1975, J BACTERIOL, V124, P1037, DOI 10.1128/JB.124.2.1037-1038.1975; NORRIS DR, 1969, LIMNOL OCEANOGR, V14, P448, DOI 10.4319/lo.1969.14.3.0448; PFIESTER LA, 1976, J PHYCOL, V12, P234; PFIESTER LA, 1975, J PHYCOL, V11, P259, DOI 10.1111/j.1529-8817.1975.tb02776.x; Pouchet G., 1885, J ANAT PHYSL, V21, P28; Pouchet G, 1883, J ANATOM PHYSL NORM, V19, P399; PRASAD R. R., 1958, PROC INDIAN ACAD SCI SECT B, V47, P331; PRASAD R. RAGHU, 1953, PROC INDIAN ACAD SCI SECT B, V38, P40; Sato T., 1967, J ELECTRON MICROSC, V16, P133; SCHILLING A.J., 1891, Ber. Deutsch. Bot. Ges, V9, P199; Schmarda L.K., 1854, DENKSCH K AKAD WISS, VVII, P1; SMAYDA TJ, 1969, J PHYCOL, V5, P150, DOI 10.1111/j.1529-8817.1969.tb02596.x; SPERO HJ, 1979, 42ND M AM SOC LIMN O; SPERO HJ, 1979, THESIS TEXAS AM U CO; SPURR AR, 1969, J ULTRA MOL STRUCT R, V26, P31, DOI 10.1016/S0022-5320(69)90033-1; Steidinger K.A., 1970, Memoirs Hourglass Cruises, V2, P1; Steidinger K A, 1973, CRC Crit Rev Microbiol, V3, P49, DOI 10.3109/10408417309108745; STEIDINGER KA, 1967, FLA BD CONSERV MAR L, V52; Stein F, 1883, Die Naturgeschichte der Arthrodelen Flagellaten Einleitung und Erklarung der Abbildungen; Utermu┬hl H., 1958, MITT INT VER LIMNOL, V9, P1, DOI DOI 10.1080/05384680.1958.11904091; Von Stosch HA., 1973, Br Phycol J, V8, P105; VONSTOSCH HA, 1969, P INT SEAWEED S, V6, P389; VONSTOSCH HA, 1972, SOC BOT FR MEMOIRES, P201	51	72	79	0	4	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0022-3646	1529-8817		J PHYCOL	J. Phycol.		1981	17	1					43	51		10.1111/j.1529-8817.1981.tb00817.x	http://dx.doi.org/10.1111/j.1529-8817.1981.tb00817.x			9	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	LW411					2025-03-11	WOS:A1981LW41100006
J	MORRILL, LC; LOEBLICH, AR				MORRILL, LC; LOEBLICH, AR			THE DINOFLAGELLATE PELLICULAR WALL LAYER AND ITS OCCURRENCE IN THE DIVISION PYRRHOPHYTA	JOURNAL OF PHYCOLOGY			English	Article								Dinoflagellates (45 spp.) were surveyed for the presence of a pellicular layer in the amphiesma or cell covering. Such a layer was present in 15 of the 20 genera studied. Half the pellicles tested were resistant to acetolysis and may contain a sporopollenin-like material similar to that of some dinoflagellate cyst walls. Most organisms which formed pellicles were capable of reinforcing this layer with cellulose. Pellicles of Heterocapsa niei (Loeblich) Morrill et Loeblich and Scrippsiella trochoidea (Stein) Loeblich were studied by EM. Evidence is presented indicating that dividing cells of S. trochoidea form new walls while still enclosed in the parental pellicular layer.	UNIV HOUSTON, PROGRAM MARINE SCI, GALVESTON, TX 77550 USA									ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ATKINSON AW, 1972, PLANTA, V7, P1; DALE B, 1976, REV PALAEOBOT PALYNO, V22, P39, DOI 10.1016/0034-6667(76)90010-5; DODGE JD, 1970, J PHYCOL, V6, P137, DOI 10.1111/j.1529-8817.1970.tb02372.x; DURR G, 1979, ARCH PROTISTENKD, V122, P88; EVITT WR, 1964, STANFORD U PUBL   GS, V10, P3; Gray J., 1965, Handbook of paleontological techniques, P530; GUILLARD RR, 1962, CAN J MICROBIOL, V8, P229, DOI 10.1139/m62-029; HERMAN EM, 1975, J ULTRA MOL STRUCT R, V50, P347, DOI 10.1016/S0022-5320(75)80065-7; Jensen W.A., 1962, BOT HISTOCHEMISTRY P; KALLEY JP, 1975, CAN J BOT, V53, P483, DOI 10.1139/b75-059; KUBAI DF, 1969, J CELL BIOL, V40, P508, DOI 10.1083/jcb.40.2.508; LEE RF, 1971, PHYTOCHEMISTRY, V10, P593, DOI 10.1016/S0031-9422(00)94703-4; Loeblich A.R., 1970, North Am. Paleont. Conv. Symp. Pt. G, P867; LOEBLICH AR, 1979, J MAR BIOL ASSOC UK, V59, P195, DOI 10.1017/S0025315400046270; LOEBLICH AR, 1975, J PHYCOL, V11, P80, DOI 10.1111/j.1529-8817.1975.tb02752.x; LOEBLICH AR, 1979, 37TH ANN P EL MICR S, P184; MEUNIER V, 1977, PHYCOLOGIA, V16, P359, DOI 10.2216/i0031-8884-16-4-359.1; MORRILL L C, 1981, Journal of Plankton Research, V3, P53, DOI 10.1093/plankt/3.1.53; Norris G., 1978, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V156, P1; REYNOLDS ES, 1963, J CELL BIOL, V17, P208, DOI 10.1083/jcb.17.1.208; SCHMIDT RJ, 1978, J PHYCOL, V14, P5, DOI 10.1111/j.0022-3646.1978.00005.x; SOUTHWORTH D, 1973, J HISTOCHEM CYTOCHEM, V21, P73, DOI 10.1177/21.1.73; SOUTHWORTH D, 1974, AM J BOT, V61, P36, DOI 10.2307/2441242; SPURR AR, 1969, J ULTRA MOL STRUCT R, V26, P31, DOI 10.1016/S0022-5320(69)90033-1; STAEHELIN LA, 1975, J PHYCOL, V11, P163, DOI 10.1111/j.0022-3646.1975.00163.x; SWEENEY BM, 1976, J CELL BIOL, V68, P451, DOI 10.1083/jcb.68.3.451; SWIFT E, 1970, J PHYCOL, V6, P79, DOI 10.1111/j.0022-3646.1970.00079.x; SWIFT E, 1972, Phycologia, V11, P57, DOI 10.2216/i0031-8884-11-1-57.1; TUTTLE R C, 1975, Phycologia, V14, P1, DOI 10.2216/i0031-8884-14-1-1.1; VONSTOSCH HA, 1969, HELGOLAND WISS MEER, V19, P558; VONSTOSCH HA, 1972, SOC BOT FR MEMOIRES, P201; WALKER LM, 1979, J PHYCOL, V15, P312; WALL D, 1977, MAR MICROPALEONTOL, V2, P121, DOI 10.1016/0377-8398(77)90008-1; Wall D., 1971, Geoscience Man, V3, P1; Wall D., 1975, Micropalaeontology, V21, P14, DOI 10.2307/1485153; WETHERBEE R, 1975, J ULTRA MOL STRUCT R, V50, P58, DOI 10.1016/S0022-5320(75)90008-8; YENTSCH CM, 1980, BIOSCIENCE, V30, P251, DOI 10.2307/1307880	38	55	58	1	4	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0022-3646	1529-8817		J PHYCOL	J. Phycol.		1981	17	4					315	323		10.1111/j.0022-3646.1981.00315.x	http://dx.doi.org/10.1111/j.0022-3646.1981.00315.x			9	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	MT331					2025-03-11	WOS:A1981MT33100005
J	REID, PC; JOHN, AWG				REID, PC; JOHN, AWG			A POSSIBLE RELATIONSHIP BETWEEN CHITINOZOA AND TINTINNIDS	REVIEW OF PALAEOBOTANY AND PALYNOLOGY			English	Article								The biological affinity of the extinct microfossil order Chitinozoa has been the source of much discussion in the 50 yr since they were first discovered. Within this period these flask-shaped, organic-walled organisms have been variously attributed to rhizopods, flagellates, tintinnids, chrysomonads, metazoan eggs, dinoflagellates and fungi. Most of these suggested relationships were made before it was recognized that chitinozoans were encapsulated and must therefore be resting cysts or eggs and not active individuals. There are no living organisms which combine all the characteristics of the Chitonozoa. Of all the possibilities, a grouping of flask-shaped cysts found in present-day marine plankton and sediment comes closest to characterizing the morphology of Chitinozoa. This grouping of flask-shaped cysts includes forms found within tintinnid loricae. Another modern cyst type Pacillina arctica, believed to be a ciliate cyst, comes close to replicating the morphology of the chitinozoan genus Hoegisphaera. The structure of tintinnid, other flask-shaped cysts and P. arctica are discussed in relation to chitinozoan morphology, drawing attention to similarities and differences. The occurrence and distribution of these cyst forms in present-day plankton is described and interpreted.			INST MARINE ENVIRONM RES, NERC, PROSPECT PL, PLYMOUTH PL1 3DH, DEVONSHIRE, ENGLAND.							[Anonymous], EXPEDITION GESELLSCH; BOCKELIE TG, 1978, NORSK GEOL TIDSSKR, V58, P301; Cleve P.T., 1894, KONGLI SVENSKA VETEN, V26, P1, DOI DOI 10.5962/BHL.TITLE.54740; CLEVE PT, 1903, B RESULT COURS PER D, P296; COLEBROOK J M, 1975, Bulletins of Marine Ecology, V8, P123; Cramer F.H., 1974, PALAEONTOGR ABT B, V148, P1; Deflandre G., 1945, Annales de Paleontologie, V31, P41; Eisenack A, 1930, NATURWISSENSCHAFTEN, V18, P880, DOI 10.1007/BF01488901; EISENACK A, 1978, NEUES JB GEOL PAL, P590; EISENACK ALFRED, 1931, PALAEONT ZEITSCHR, V13, P74; GAJEWSKAJA N., 1933, ZOOLOGICA, VBd. 32, P1; GLOVER R. S., 1967, SYMP ZOOL SOC LONDON, V19, P189; Jansonius J., 1970, P N AM PAL CONV G, P789; Jenkins W.A.M., 1970, GEOSCI MAN, V1, P1; Kozlowski R., 1963, Acta Palaeontologica Polonica, V8, P425; Laufeld S., 1974, Fossils Strata, VNo. 5, P1; LEGAULT JA, 1973, CAN J EARTH SCI, V10, P793, DOI 10.1139/e73-072; LOCQUIN MV, 1977, 2ND INT C MYC TAMP; LOEBLICH AR, 1968, J PROTOZOOL, V15, P185, DOI 10.1111/j.1550-7408.1968.tb02108.x; Lohmann H, 1910, NORDISCHES PLANKTON, V1, P1; PARANJAPE MA, 1980, J EXP MAR BIOL ECOL, V48, P23, DOI 10.1016/0022-0981(80)90004-0; PINGREE RD, 1978, DEEP-SEA RES, V25, P1011, DOI 10.1016/0146-6291(78)90584-2; REID PC, 1978, J MAR BIOL ASSOC UK, V58, P551, DOI 10.1017/S0025315400041205; REID PC, 1975, NEW PHYTOL, V75, P589, DOI 10.1111/j.1469-8137.1975.tb01425.x; REID PC, 1981, REV PALAEOBOT PALYNO, V34, P263, DOI 10.1016/0034-6667(81)90044-0; TURNER JT, 1979, BIOSCIENCE, V29, P670, DOI 10.2307/1307591; URBAN J B, 1970, Journal of Paleontology, V44, P69; Visscher H., 1970, GEOLOGICAL SURVEY IR, V1, P61; 1973, B MAR ECOL, V7, P1	29	23	24	0	0	ELSEVIER	AMSTERDAM	RADARWEG 29, 1043 NX AMSTERDAM, NETHERLANDS	0034-6667	1879-0615		REV PALAEOBOT PALYNO	Rev. Palaeobot. Palynology		1981	34	2					251	262		10.1016/0034-6667(81)90043-9	http://dx.doi.org/10.1016/0034-6667(81)90043-9			12	Plant Sciences; Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Paleontology	MQ841					2025-03-11	WOS:A1981MQ84100011
J	WOLFARD, A; VANERVE, AW				WOLFARD, A; VANERVE, AW			CRUSSOLIA-DEFLANDREI NOV GEN ET NOV-SP, A DINOFLAGELLATE CYST FROM THE JURASSIC (CALLOVIAN-LOWER OXFORDIAN) OF MONTAGNE CRUSSOL, RHONE VALLEY, FRANCE	REVIEW OF PALAEOBOTANY AND PALYNOLOGY			English	Article								The presence paper provides the formal description of CRUSSOLIA deflandrei gen. et sp. nov., a new dinoflagellate cyst from the Jurassic (Callovian-Lower Oxfordian) of Montagne Crussol, Rhone Valley, France. The Family Pareodiniaceae Gocht, 1957 is emended to facilitate inclusion of forms with a type 51 archeopyle and 2 wall layers.	FREE UNIV BERLIN, INST PALAEONTOL, D-1000 BERLIN 33, FED REP GER	Free University of Berlin	STATE UNIV UTRECHT, PALAEOBOT & PALYNOL LAB, UTRECHT, NETHERLANDS.							Alberti G., 1961, Palaeontographica, V116, P1; Antonescu E., 1974, Revue Micropaleont, V17, P61; BUJAK J P, 1976, Micropaleontology (New York), V22, P44, DOI 10.2307/1485320; Cookson I. C., 1962, Micropaleontology, V8, P485, DOI 10.2307/1484681; Cookson I.E., 1960, PALAEONTOLOGY, V2, P243; COOKSON ISABEL C., 1960, MICROPALEONTOLOGY, V6, P1, DOI 10.2307/1484313; COSTA L I, 1976, Palaeontology (Oxford), V19, P591; Deflandre G., 1947, Bulletin de l'Inst Oceanogr Monaco No, V921, P1; DODEKOVA L, 1975, Paleontologiya Stratigrafiya i Litologiya, V2, P17; Dorhofer G, 1980, LIFE SCI MISCELLANEO; DRUGG W.S., 1967, PALAEONTOGRAPHICA B, V120, P1; DRUGG WS, 1970, 1969 P S N AM PAL G, P809; Eisenack A., 1938, Schriften der Physikalisch-Okonomischen Gesellschaft zu Konigsberg, V70, P181; GITMEZ GU, 1972, B BR MUS NAT HIS G, V21, P171; Gocht H., 1957, Palaeontologische Zeitschrift, V31, P163; GOCHT H, 1955, N JB GEOL PALAONT MH, P84; Jain K.P., 1973, PALAEOBOTANIST, V20, P22; Lentin J.K., 1977, Palynology, V1, P167; LENTIN JK, 1976, BIR7516 BEDF I OC RE, P1; LENTIN JK, 1977, NIR778 CAN GEOL SURV, P1; MANUM S., 1960, NYTT MAG BOT, V8, P17; Riegel W., 1974, Revista Esp Micropaleont, V6, P347; Sarjeant W.A.S., 1976, Geoscience Man, V15, P1; SARJEANT W. A. S., 1961, PALAEONTOLOGY, V4, P90; SARJEANT WAS, 1978, LSU SCH GEOSCI MISC, V781; SARJEANT WAS, 1966, B BRIT MUSEUM NAT S, V3, P199; STOVER L E, 1978, Stanford University Publications in the Geological Sciences, V15, P1; VOZZHENIKOVA TF, 1963, FUNDAMENTALS PALEONT, V14, P179; VOZZHENNIKOVA TF, 1967, SIB OTD I GEOL GEOFI; Wiggins V.D., 1975, Geoscience Man, V11, P95	30	4	4	0	0	ELSEVIER	AMSTERDAM	RADARWEG 29, 1043 NX AMSTERDAM, NETHERLANDS	0034-6667	1879-0615		REV PALAEOBOT PALYNO	Rev. Palaeobot. Palynology		1981	34	3-4					321	329		10.1016/0034-6667(81)90048-8	http://dx.doi.org/10.1016/0034-6667(81)90048-8			9	Plant Sciences; Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Paleontology	MR503					2025-03-11	WOS:A1981MR50300003
J	FENTON, JPG				FENTON, JPG			TAXONOMIC REVISION OF SELECTED DINOFLAGELLATE CYSTS FROM THE LATE BAJOCIAN (MIDDLE JURASSIC) OF NORTHWEST GERMANY	REVIEW OF PALAEOBOTANY AND PALYNOLOGY			English	Article								Re-examination of material [dinoflagellate cyst assemblages] described by W. Wetzel (1967) [from the Bathonian-early Callovian strata of Eastern England, UK] allows a revision to be made of certain taxa. Lithodinia arktikos is proposed as a new species. Lithodinia superornata (W. Wetzel 1967) [Gonyaulax superornata] and Cribroperidinium crispum (W. Wetzel 1967) [G. crispa] are proposed as new combinations, and the latter species is emended. Meiourogonyaulax Sarjeant 1966 is retained as a junior synonym of Lithodinia Eisenack 1935 emend. Gocht 1975.			ROBERTSON RES INT LTD, LLANDUDNO, WALES.							Balme B.E., 1957, COMMONW SCI IND RES, V25, P1; CONWAY BH, 1978, REV PALAEOBOT PALYNO, V26, P337, DOI 10.1016/0034-6667(78)90041-6; Cookson I.C., 1947, BANZ ANTARCTIC RES E, V2, P127; DEFLANDRE G, 1947, 918 I OC MON B, P1; Deflandre G., 1938, STATION ZOOLOGIQUE W, V13, P147; EISENACK A, 1957, NEUES JB MIN GEOL PA, V15, P239; EISENACK A, 1963, NEUES JB GEOLOGIE PA, P98; Fenton J.P.G., 1980, Palaeontology (Oxford), V23, P151; Fenton J.P.G., 1978, Palinologia, P233; Gocht H., 1975, Neues Jb Geol Paleont Abh, V148, P12; Gocht H., 1970, PALAEONTOGRAPHICA B, V129, P125; HERNGREEN G F W, 1974, Geologie en Mijnbouw, V53, P343; LENTIN JK, 1977, BIR778 BEDF I OC REP; Norris G., 1978, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V156, P1; Pocock S.A.J., 1972, Palaeontographica Abteilung B Palaeophytologie, V137, P85; SARJEANT WAS, 1966, B BRIT MUS NAT HIS S, V3, P107; SARJEANT WAS, 1975, GRANA, V14, P49; SARJEANT WAS, 1972, KOMM VIDENSK UNDERS, V195, P1; SARJEANT WAS, 1969, B BR MUS NAT HIST S, V3, P7; STOVER LE, 1978, 15 STANF U GEOL SCI; STOVER LEWIS E., 1966, J PALEONTOL, V40, P41; WALL DAVID, 1965, MICRO PALEONTOLOGY, V11, P151, DOI 10.2307/1484516; WETZEL W, 1967, Z DTSCH GEOL GES, V116, P867	23	8	8	0	0	ELSEVIER	AMSTERDAM	RADARWEG 29, 1043 NX AMSTERDAM, NETHERLANDS	0034-6667	1879-0615		REV PALAEOBOT PALYNO	Rev. Palaeobot. Palynology		1981	31	3-4					249	260						12	Plant Sciences; Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Paleontology	LF037					2025-03-11	WOS:A1981LF03700002
J	KAT, M				KAT, M			PRELIMINARY NOTE ON DINOFLAGELLATE CYSTS IN THE OOSTERSCHELDE (THE NETHERLANDS) IN RELATION TO SHELLFISH POISONING	AQUACULTURE			English	Note											NETHERLANDS INST FISHERY INVEST, HARINGKADE 1, IJMUIDEN, NETHERLANDS.							AYRES PA, 1978, 40 FISH RES TECHN RE; DALE B, 1976, REV PALAEOBOT PALYNO, V22, P39, DOI 10.1016/0034-6667(76)90010-5; DALE B, 1978, SCIENCE, V201, P1223, DOI 10.1126/science.201.4362.1223; DODGE JD, 1977, MAR BIOL, V40, P327, DOI 10.1007/BF00395725; Kat M., 1979, DEV MARINE BIOL, V1, P215; KAT M, 1977, ICESCM1977L2 PLANKT; LEWIS CM, 1979, DEV MARINE BIOL, V1, P235; REID PC, 1978, NEW PHYTOL, V80, P219, DOI 10.1111/j.1469-8137.1978.tb02284.x; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690	9	0	0	0	2	ELSEVIER SCIENCE BV	AMSTERDAM	PO BOX 211, 1000 AE AMSTERDAM, NETHERLANDS	0044-8486	1873-5622		AQUACULTURE	Aquaculture		1980	21	1					97	100		10.1016/0044-8486(80)90130-1	http://dx.doi.org/10.1016/0044-8486(80)90130-1			4	Fisheries; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Fisheries; Marine & Freshwater Biology	KH552					2025-03-11	WOS:A1980KH55200008
J	YENTSCH, CM; LEWIS, CM; YENTSCH, CS				YENTSCH, CM; LEWIS, CM; YENTSCH, CS			BIOLOGICAL RESTING IN THE DINOFLAGELLATE GONYAULAX-EXCAVATA	BIOSCIENCE			English	Article											BIGELOW LAB OCEAN SCI, MCKOWN POINT, W BOOTHBAY HARBOR, ME 04575 USA.							DALE B, 1978, SCIENCE, V201, P1223, DOI 10.1126/science.201.4362.1223; DALE B, 1977, SARSIA, V63, P29, DOI 10.1080/00364827.1977.10411318; Dale B., 1979, P443; Evitt W. R., 1961, Micropaleontology, V7, P385, DOI 10.2307/1484378; EVITT W. R., 1964, GEOL SCI, V10, P1; FOGEL M, 1971, ARCH BIOCHEM BIOPHYS, V142, P310, DOI 10.1016/0003-9861(71)90289-X; HABAS EJ, 1975, 1ST P INT C TOX DIN, P499; Lewis C.M., 1979, P235; MOREL FMM, 1979, J PHYCOL, V15, P135, DOI 10.1111/j.0022-3646.1979.00135.x; Schmitter R.E., 1979, P123; Steidinger K.A., 1979, P435; TURPIN DH, 1978, J PHYCOL, V14, P235, DOI 10.1111/j.1529-8817.1978.tb02454.x; WALL D, 1966, NATURE, V211, P1025, DOI 10.1038/2111025a0; Wall D., 1965, Grana Palynologica, V6, P297; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; WALL D., 1967, PHYCOLOGIA, V6, P83; YENTSCH CM, 1980, MUSSEL CULTURE N AM; YENTSCH CM, INT J CHRONOBIOL; 1975, OFFICAL METHODS ANAL, V28, P319	19	26	26	0	0	OXFORD UNIV PRESS	OXFORD	GREAT CLARENDON ST, OXFORD OX2 6DP, ENGLAND	0006-3568	1525-3244		BIOSCIENCE	Bioscience		1980	30	4					251	254		10.2307/1307880	http://dx.doi.org/10.2307/1307880			4	Biology	Science Citation Index Expanded (SCI-EXPANDED)	Life Sciences & Biomedicine - Other Topics	JM693					2025-03-11	WOS:A1980JM69300010
J	HEANEY, SI; TALLING, JF				HEANEY, SI; TALLING, JF			DYNAMIC ASPECTS OF DINOFLAGELLATE DISTRIBUTION PATTERNS IN A SMALL PRODUCTIVE LAKE	JOURNAL OF ECOLOGY			English	Article								Vertical and temporal distribution patterns of the dinoflagellate Ceratium hirundinella O.F. Muller, in relation to controlling factors, were studied for a small English [UK] lake (Esthwaite Water). General and grosser features of distribution were established from regular sampling at one station; examples are given from 1966-1967 and 1975-1977. Finer resolution and analysis were possible from more intensive study of selected episodes over the whole lake in 1976 and 1977. The seasonal cycle of the euphotic population comprised a phase of near-exponential increase (May-July), a stationary phase of high numbers (July-Sept.), and a very rapid decline, often accompanied by cyst-formation (late Sept.-Oct.). The motile cells avoided the anoxic hypolimnion and, at times, the strongly illuminated surface layer. Depth-maxima often formed at the boundaries of these regions. Under conditions of low wind stress during the rapid (exponential) growth phase, vertical distribution may be mainly controlled by the underwater light climate and thermocline (pycnocline). Maximum density of Ceratium occurred at 3-4 m depth, at which depth about 10% of the surface-penetrating irradiance wa measured. Surface-avoidance by cells was often found, but not appreciable vertical migration. During the stationary phase of the population cycle there was a change of behavior, and Ceratium aggregated near the surface during daytime. Conditions of light wind stress along the long axis of the lake (about 3 m s-1) may cause laminar horizontal flow of the surface layers, which induced upwelling of subsurface maxima of Ceratium at the windward end of the lake, or downwind transport of the alga when concentrated in the surface waters. Moderate to strong wind conditions (> 4 m/s) caused sufficient turbulent mixing to eliminate vertical stratification of Ceratium within the epilimnion. Photo-inhibition of cellular fluorescence by Ceratium occurred in the upper layers during the day. Cells collected below the euphotic zone quickly (< 2 min) showed large decreases in fluorescence when exposed to strong sunlight.			FRESHWATER BIOL ASSOC, AMBLESIDE LA22 0LP, CUMBRIA, ENGLAND.							BALDI E, 1941, ARCH HYDROBIOL, V38, P299; BERMAN T., 1971, Mitt. Int. Ver. Theor. Angew. Limnol, V19, P266; BIGGS W W, 1971, Ecology (Washington D C), V52, P125, DOI 10.2307/1934743; BLASCO D, 1978, MAR BIOL, V46, P41, DOI 10.1007/BF00393819; EPPLEY RW, 1968, J PHYCOL, V4, P333, DOI 10.1111/j.1529-8817.1968.tb04704.x; GEORGE DG, 1978, J ECOL, V66, P133, DOI 10.2307/2259185; GOEDHEER JC, 1972, ANN REV PLANT PHYSIO, V23, P87, DOI 10.1146/annurev.pp.23.060172.000511; HAND WG, 1965, BIOL BULL-US, V128, P90, DOI 10.2307/1539392; HARRIS GP, 1979, FRESHWATER BIOL, V9, P413, DOI 10.1111/j.1365-2427.1979.tb01526.x; HASLE GR, 1950, OIKOS, V2, P162, DOI 10.2307/3564790; HASLE GRETHE RYTTER, 1954, NYTT MAG BOT, V2, P139; HEANEY SI, 1976, FRESHWATER BIOL, V6, P531, DOI 10.1111/j.1365-2427.1976.tb01644.x; HEANEY SI, 1978, FRESHWATER BIOL, V8, P115, DOI 10.1111/j.1365-2427.1978.tb01434.x; HEANEY SI, 1974, FRESHWATER BIOL, V4, P103, DOI 10.1111/j.1365-2427.1974.tb00080.x; HELLER MD, 1977, THESIS U LANCASTER; Hutchinson GE., 1957, TREATISE LIMNOLOGY; KAMYKOWSKI D, 1977, LIMNOL OCEANOGR, V22, P148, DOI 10.4319/lo.1977.22.1.0148; KIEFER DA, 1973, MAR BIOL, V23, P39, DOI 10.1007/BF00394110; LUND J. W. G., 1958, HYDROBIOLOGIA, V11, P143, DOI 10.1007/BF00007865; Lund J. W. G., 1972, TAXONOMY BIOL BLUE G, P305; LUND JWG, 1949, J ECOL, V37, P389, DOI 10.2307/2256614; LUND JWG, 1963, PHILOS T R SOC B, V246, P255, DOI 10.1098/rstb.1963.0006; MACKERETH FJH, 1964, J SCI INSTRUM, V41, P38, DOI 10.1088/0950-7671/41/1/311; MOHANTY P, 1973, BIOCHIM BIOPHYS ACTA, V305, P95, DOI 10.1016/0005-2728(73)90235-1; Mortimer CH, 1942, J ECOL, V30, P147, DOI 10.2307/2256691; Mortimer CH, 1941, J ECOL, V29, P280, DOI 10.2307/2256395; MURATA N, 1970, BIOCHIM BIOPHYS ACTA, V205, P379, DOI 10.1016/0005-2728(70)90104-0; NULTSCH W, 1977, ARCH MICROBIOL, V112, P179, DOI 10.1007/BF00429333; Papageorgiou G., 1975, BIOENERG PHOTOSYNTH, V15, P319; PREZELIN BB, 1976, PLANTA, V128, P130; SAUBERER F, 1958, WETTER LEBEN, V10, P67; SIBLEY TH, 1974, J PHYCOL, V10, P475, DOI 10.1111/j.1529-8817.1974.tb02743.x; SMITH IR, 1975, 29 FRESHW BIOL ASS S; Tailing J.F., 1974, A Manual on Methods for Measuring Primary Productivity in Aquatic Environments, P22; TALLING J.F., 1971, MITTEL INT VERIENIGU, V19, P214; TYLER MA, 1978, LIMNOL OCEANOGR, V23, P227, DOI 10.4319/lo.1978.23.2.0227	36	93	100	1	11	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0022-0477	1365-2745		J ECOL	J. Ecol.		1980	68	1					75	94		10.2307/2259245	http://dx.doi.org/10.2307/2259245			20	Plant Sciences; Ecology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Environmental Sciences & Ecology	JK962					2025-03-11	WOS:A1980JK96200006
J	ANDERSON, DM				ANDERSON, DM			EFFECTS OF TEMPERATURE CONDITIONING ON DEVELOPMENT AND GERMINATION OF GONYAULAX-TAMARENSIS (DINOPHYCEAE) HYPNOZYGOTES	JOURNAL OF PHYCOLOGY			English	Article								Plankton samples from a dense bloom of the toxic red tide dinoflagellate G. tamarensis Lebour were incubated in the laboratory to study the formation and development of thick-walled, overwintering cysts. Samples contained very few cysts, and fusing cells were seen only twice. However, thousands of elongate cysts were formed from large posteriorly biflagellated cells (presumed to be planozygotes) that comprised approximately 50% of the initial motile population. Development of these new cysts (hypnozygotes) was studied under different storage conditions. Each hypnozygote lost pigmentation and formed a thick cell wall during the first several days of storage, producing a starch-filled cell with a yellow accumulation body. Starch reserves decreased rapidly during storage at warm (22.degree. C) temperatures and more slowly at 5.degree. C (with no apparent effect from light, dark or added nutrients). Excretion of mucilaginous material was also observed. Periodic germination experiments showed that 22.degree. C temperatures led to rapid development of the hypnozygote, with germination possible 1 mo. after formation, while 5.degree. C storage retarded development, with the 1st revivals after nearly 4 mo. Excystment was initiated only after an applied stimulus-either a temperature increase or decrease depending on the previous storage temperature. Cysts formed during the late spring in temperate waters are thus capable of excystment several months later as fall temperatures decrease; those formed in the fall take longer to mature, but are viable after 6 mo. of overwintering. Alternating spring and fall blooms seeded by germinating populations of dormant cysts are thus possible, a finding consistent with recent field observations.			WOODS HOLE OCEANOG INST, WOODS HOLE, MA 02543 USA.							ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; ANDERSON DM, 1979, ESTUAR COAST MAR SCI, V8, P279, DOI 10.1016/0302-3524(79)90098-7; DALE B, 1978, SCIENCE, V201, P1223, DOI 10.1126/science.201.4362.1223; DALE B, 1977, SARSIA, V63, P29, DOI 10.1080/00364827.1977.10411318; GUILLARD RR, 1962, CAN J MICROBIOL, V8, P229, DOI 10.1139/m62-029; Huber G., 1922, Z BOTANIK, V14, P337; Huber G., 1923, FLORA JENA, V116, P114; PFIESTER LA, 1977, J PHYCOL, V13, P92, DOI 10.1111/j.0022-3646.1977.00092.x; PFIESTER LA, 1976, J PHYCOL, V12, P234; PFIESTER LA, 1975, J PHYCOL, V11, P259, DOI 10.1111/j.1529-8817.1975.tb02776.x; PRAKASH A, 1967, J FISH RES BOARD CAN, V24, P1589, DOI 10.1139/f67-131; Steidinger K.A., 1975, P153; TURPIN DH, 1978, J PHYCOL, V14, P235, DOI 10.1111/j.1529-8817.1978.tb02454.x; Von Stosch HA., 1973, Br Phycol J, V8, P105; VONSTOSC, 1965, NATURWISSENSCHAFTEN, V52, P112; Wall D., 1975, P249; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690	17	174	191	1	12	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0022-3646	1529-8817		J PHYCOL	J. Phycol.		1980	16	2					166	172						7	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	JX762					2025-03-11	WOS:A1980JX76200003
J	ETTL, H; MOESTRUP, O				ETTL, H; MOESTRUP, O			ON AN INTRACELLULAR PARASITE IN CRYPTOMONAS (CRYPTOPHYCEAE) .1.	PLANT SYSTEMATICS AND EVOLUTION			German	Article								An intracellular parasite occurs in C. rostratiformis and less numerously in C. erosa and C. phaseolus. The parasite is described. It grows in the dorsal side of the host near the nucleus from which it is optically indistinguishable in young stages. When mature the parasite fills 1/3-1/2 the volume of the Cryptomonas cell. It is a colorless blister, which pushes back the plastid of the host. Reproduction occurs by separation of the protoplast into 100 or more Bodo like swarmers which may represent the infectious phase. During a decline of the Cryptomonas population, the parasite transforms into thick-walled spindle-shaped cysts. Like the swarmers these cysts are released by rupture of the cryptomonad cells. The fate of the cysts is not known. The Cryptomonas population is destroyed by the infection in a few days. The parasite was known for a long time, but considered incorrectly as part of the Cryptomonas, or as a result of phagotrophic uptake of the Cryptomonas. The parasite is compared with a similar parasite in Mallomonas and with certain parasitic dinoflagellates. The similarity with the latter is superficial as it possesses a eukaryotic nucleus. The parasite shows some similarity with the genus Paradinium (Mycetozoa) as well as with certain Sporozoa.	UNIV COPENHAGEN, INST SPOREPLANTER, DK-1353 COPENHAGEN, DENMARK					Moestrup, Ojvind/0000-0003-0965-8645				[Anonymous], 1960, TRAITE BOTANIQUE SYS; Bold H.C., 1978, INTRO ALGAE; Cachon J., 1964, Annales des Sciences Naturelles (12), V6, P1; Cachon J., 1968, Protistologica, V4, P303; Chatton E., 1920, Archives de Zoologie Experimentale Paris, V59; CHATTON E, 1973, ANN SCI NAT ZOOL, V12, P27; Chatton E., 1952, TRAITE ZOOL, P309; DOFLEIN F, 1953, LEHRBUCH PROTOZOENKU; GRELL KG, 1968, PROTOZOOLOGIE; HARRIS K, 1953, J LINN SOC LOND BOT, V60, P88; HUBERPESTALOZZI G, 1968, PHYTOPLANKTON SUSSWA, V2; NYGAARD GUNNAR, 1949, K DANSKE VIDENSKAB SELSKAB BIOL SKRIFT, V7, P1; SKUJA H, 1956, NOVA ACTA SOC SCI UP, V18, P1; Starmach K., 1974, FLORA SLODKOWODNA PO, V4; STEIN F, 1878, ORGANISMUS INFUSIO 1; WAWRIK F, 1970, Archiv fuer Protistenkunde, V112, P312; WAWRIK F, 1977, ARCH PROTISTENKD, V119, P407	17	5	5	0	1	SPRINGER WIEN	Vienna	Prinz-Eugen-Strasse 8-10, A-1040 Vienna, AUSTRIA	0378-2697	1615-6110		PLANT SYST EVOL	Plant Syst. Evol.		1980	135	3-4					211	226		10.1007/BF00983187	http://dx.doi.org/10.1007/BF00983187			16	Plant Sciences; Evolutionary Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Evolutionary Biology	KK211					2025-03-11	WOS:A1980KK21100006
J	CACHON, J; CACHON, M; SALVANO, P				CACHON, J; CACHON, M; SALVANO, P			NUCLEAR DIVISION OF OXYRRHIS-MARINA - EXAMPLE OF THE ROLE PLAYED BY THE NUCLEAR-ENVELOPE IN CHROMOSOME SEGREGATION	ARCHIV FUR PROTISTENKUNDE			English	Article								O. marina is a marine microorganism which has no clear position among the Dinoflagellates also though its mitosis was considered by Grasse (1952) as typical of the group. EM observations show singular mitosis. The nucleus is deeply furrowed, as is usual in Dinoflagellates, but no microtubules are observed. The chromosomes are rod-shaped and made of longitudinal fibrils. They are attached by 1 end of the nuclear envelope, and at these levels no kinetochore is seen. The separation of the daughter chromosomes and their distribution in 2 sets occur by an elongation of the nuclear envelope. There is a progressive and continuous DNA synthesis during the resting stage and an equal distribution of DNA between the 2 telophase daughter nuclei.			FAC SCI NICE, PROTISTOL MARINE LAB, F-06230 Villefranche Sur Mer, FRANCE.							[Anonymous], [No title captured]; CACHON J, 1977, CHROMOSOMA, V60, P237, DOI 10.1007/BF00329773; CACHON J, 1978, MAI GROUP PROT LANG; DODGE J D, 1974, Protistologica, V10, P239; FORER A, 1974, CELL CYCLE CONTROLE; GABE PR, 1968, TECHNIQUES HISTOLOGI; GRASSE PP, 1952, TRAITE ZOOL, V1, P107; Hall R. P., 1925, University of California Publications in Zoology, V26, P281; HOLLANDE A, 1972, ANN BIOL, V9, P428; KEYSSELITZ G, 1908, ARCH PROTISTENKD, V2, P334; KUBAI DF, 1969, J CELL BIOL, V40, P508, DOI 10.1083/jcb.40.2.508; KUBAI DF, 1973, J CELL SCI, V13, P511; LEIBOWITZ PJ, 1975, INT REV CYTOL, V41, P1, DOI 10.1016/S0074-7696(08)60964-X; LOEBLICH AR, 1977, STADLER S, V8, P111; NISSENBAUM G, 1953, SCIENCE, V118, P31, DOI 10.1126/science.118.3053.31-a; PATAU K, 1952, CHROMOSOMA, V5, P341; SOYER M-O, 1973, Journal de Microscopie (Paris), V18, P267; SOYER MO, 1969, J MICROSC-PARIS, V8, P709; SOYER MO, 1977, CR ACAD SCI D NAT, V285, P693; SOYER MO, 1969, J MICROSC-PARIS, V8, P569; SOYER MO, 1973, J MICROSCOPIE      S, V17	21	12	12	0	1	GUSTAV FISCHER VERLAG	JENA	VILLENGANG 2, D-07745 JENA, GERMANY	0003-9365			ARCH PROTISTENKD	Arch. Protistenkd.		1979	122	1-2					43	54		10.1016/S0003-9365(79)80019-6	http://dx.doi.org/10.1016/S0003-9365(79)80019-6			12	Microbiology	Science Citation Index Expanded (SCI-EXPANDED)	Microbiology	HP261					2025-03-11	WOS:A1979HP26100004
J	DURR, G				DURR, G			ELECTRON-MICROSCOPE STUDIES ON THE THECA OF DINOFLAGELLATES .3. CYST OF PERIDINIUM-CINCTUM	ARCHIV FUR PROTISTENKUNDE			German	Article									UNIV TUBINGEN,INST BIOL 3,D-7400 TUBINGEN 1,FED REP GER	Eberhard Karls University of Tubingen								BALECH E, 1967, COMUNIC MUS ARG CS N, V1, P5; DURR G, 1974, CELL TISSUE RES, V150, P21; DURR G, 1979, ARCH PROTISTENKD, V122, P88; EHRENBERG CG, 1836, BERICHT VERHANDL KON, P114; Evitt W.R., 1968, University Series of Geological Science, P1; FRITSCH FE, 1935, STRUCTURE REPRODUCTI; Gocht H., 1976, Neues Jb Geol Paleont Abh, V152, P380; GRAHAM HW, 1951, MANUAL PHYCOLOGY, P105; PFJESTER LA, 1975, J PHYCOL, V11, P259; POLLINGHER U, 1976, J PHYCOL, V12, P162, DOI 10.1111/j.1529-8817.1976.tb00494.x; Prescott G.W., 1954, How to know the fresh water algae, P1; SMITH GM, 1938, ALGAE FUNGI, V1; VON STOSCH H. A., 1967, HDB PFL PHYSL, VXVIII, P626; Von Stosch HA., 1973, Br Phycol J, V8, P105; WALE D, 1966, NATURE, V211, P1025; WALL D, 1969, J PHYCOL, V5, P140, DOI 10.1111/j.1529-8817.1969.tb02595.x; WALL D, 1970, Phycologia, V9, P151, DOI 10.2216/i0031-8884-9-2-151.1; Wall D., 1965, Grana Palynologica, V6, P297; WALL D, 1971, J PHYCOL, V7, P221, DOI 10.1111/j.1529-8817.1971.tb01507.x; WALL D, 1970, Micropaleontology (New York), V16, P47, DOI 10.2307/1484846; Wall D., 1971, Geoscience Man, V3, P1; WALL D, 1968, MICROPALEONTOLOGY, V12, P265; WALL D, 1970, P N AM PALEONTOLOG G, P844	23	16	17	0	1	GUSTAV FISCHER VERLAG	JENA	VILLENGANG 2, D-07745 JENA, GERMANY	0003-9365			ARCH PROTISTENKD	Arch. Protistenkd.		1979	122	1-2					121	139						19	Microbiology	Science Citation Index Expanded (SCI-EXPANDED)	Microbiology	HP261					2025-03-11	WOS:A1979HP26100007
J	IRISH, AE				IRISH, AE			GYMNODINIUM-HELVETICUM PENARD F-ACHROUM SKUJA A CASE OF PHAGOTROPHY	BRITISH PHYCOLOGICAL JOURNAL			English	Article								G. helveticum f. achroum in Blelham Tarn [England] was occasionally noted to exhibit phagotrophy. Various algae were observed inside Gymnodinium cells. The seedling of an experimental enclosure with dead Lycopodium spores resulted in some of the Gymnodinium cells containing a spore. This dinoflagellate apparently exhibits non-selective and non-predatory phagotrophy.			FRESHWATER BIOL ASSOC, AMBLESIDE LA22 0LP, CUMBRIA, ENGLAND.							[Anonymous], BIOL STUDIES ENGLISH; BARKER H. ALBERT, 1935, ARCH MIKROBIOL, V6, P157, DOI 10.1007/BF00407285; Biecheler B., 1952, Bull. Biol. Fr. Belg., V36, P1; DROOP MR, 1953, NATURE, V172, P250, DOI 10.1038/172250b0; HOFENEDER HEINRICH, 1930, ARCH PROTISTENK, V71, P1; Kofoid C. A., 1921, Memoirs of the University of California, V5, P1; LEFEVRE M, 1932, THESIS FS U PARIS; LUND J. W. G., 1958, HYDROBIOLOGIA, V11, P143, DOI 10.1007/BF00007865; Mortimer CH, 1942, J ECOL, V30, P147, DOI 10.2307/2256691; NAUWERCK ARNOLD, 1963, SYMBOLAE BOT UPSALIENSIS, V17, P1; NORRIS DR, 1969, LIMNOL OCEANOGR, V14, P448, DOI 10.4319/lo.1969.14.3.0448; Penard E., 1891, Bull. Trav. Soc. Bot. Geneve, V6, P1; Schwoerbel J., 1970, METHODS HYDROBIOLOGY	13	11	12	1	2	ACADEMIC PRESS LTD- ELSEVIER SCIENCE LTD	LONDON	24-28 OVAL RD, LONDON NW1 7DX, ENGLAND	0007-1617			BRIT PHYCOL J			1979	14	1					11	15		10.1080/00071617900650021	http://dx.doi.org/10.1080/00071617900650021			5	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	GM182					2025-03-11	WOS:A1979GM18200002
J	WALKER, LM; STEIDINGER, KA				WALKER, LM; STEIDINGER, KA			SEXUAL REPRODUCTION IN THE TOXIC DINOFLAGELLATE GONYAULAX-MONILATA	JOURNAL OF PHYCOLOGY			English	Article								The sexual cycle of G. monilata Howell was observed in stationary cultures and in N-deficient medium. The armored, isogamous gametes fuse in a characteristic manner with cingula at oblique angles. Nuclear fusion lags slightly behind cytoplasmic fusion. The zygote enlarges for several days. The dark, double-flagellated planozygote encysts within 1-3 wk. Early hypnozygotes are round to ovoid and contain lipid and one or two large, golden-yellow globules. As the hypnozygote matures, the globules become smaller and the cytoplasm darkens and pulls from the wall. All cysts examined contained only 1 nucleus. A very dark, uninucleate post-hypnozygotic cell escapes through an archeopyle and within 24 h divides into daughter cells which divide in 24-48 h forming a small chain. The production of thick walled zygotes in culture implies that such resting stages in marine sediments could serve as a source stock for blooms. This species causes toxic red tides, and the existence of benthic seed beds consisting of hypnozygotes is now plausible.			FLORIDA DEPT NAT RESOURCES, MARINE RES LAB, 100 8TH AVE SE, ST PETERSBURG, FL 33701 USA.							ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; GATES JEAN A., 1960, LIMNOL AND OCEANOGR, V5, P171; HALIM Y, 1967, Internationale Revue der Gesamten Hydrobiologie, V52, P701, DOI 10.1002/iroh.19670520504; HALIM Y, 1969, Internationale Revue der Gesamten Hydrobiologie, V54, P619, DOI 10.1002/iroh.19690540410; LOEBLICH AR, 1970, N AM PALEONTOLOGICAL, pG867; PFIESTER LA, 1977, J PHYCOL, V13, P92, DOI 10.1111/j.0022-3646.1977.00092.x; PFIESTER LA, 1976, J PHYCOL, V12, P234; PFIESTER LA, 1975, J PHYCOL, V11, P259, DOI 10.1111/j.1529-8817.1975.tb02776.x; Ray S., 1967, ANIMAL TOXINS, P75; Steidinger K.A., 1975, P153; TAYLOR F.J.R., 1976, DINOFLAGELLATES INT; TURPIN DH, 1978, J PHYCOL, V14, P235, DOI 10.1111/j.1529-8817.1978.tb02454.x; Wall D., 1975, P249; WALL D, 1969, J PHYCOL, V5, P140, DOI 10.1111/j.1529-8817.1969.tb02595.x; Wardle W.J., 1975, P257; WILLIAMS J, 1972, FLA DEP NAT RESOUR M, V1	16	70	78	0	1	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0022-3646	1529-8817		J PHYCOL	J. Phycol.		1979	15	3					312	315						4	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	HL468					2025-03-11	WOS:A1979HL46800014
J	BRUGEROLLE, G; MIGNOT, JP				BRUGEROLLE, G; MIGNOT, JP			OBSERVATIONS ON THE CYCLE, ULTRASTRUCTURE AND SYSTEMATIC POSITION OF SPIROMONAS-PERFORANS (BODO-PERFORANS HOLLANDE 1938), A PARASITIC FLAGELLATE OF CHILOMONAS-PARAMECIUM - ITS RELATIONS WITH DINOFLAGELLATA AND SPOROZOA	PROTISTOLOGICA			French	Article								A part of the life cycle and cell ultrastructure of the parasitic flagellate previously named B. perforans by Hollande (1938) is observed. The parasite is attached by its rostrum at the base of the flagella of C. paramecium, it penetrates the host cell, engulfs the host cytoplasm in some minutes, then encysts, digests the food and divides in the cyst to produce 4 cells. This behavior is strikingly similar to the flagellate S. angusta Alexieff (1929), so it was transferred to Spiromonas as S. perforans comb. nov. The fine structure study shows that the cell is enveloped in a pellicle composed of 3 membranes with micropores and underlying microtubules as in Sporozoa and some Dinoflagellida. The cell still contains trichocysts like those of dinoflagellates, polysaccharide grains free in the cytoplasm, Golgi bodies and a contractile vacuole just behind the pair of flagella. A rostrum at the cell apex is applied to the membrane of the base of the Chilomonas flagella. It contains microfilaments, microtubules and dense organelles like micronemes oriented to the canaliculi on the apex. The division and the complete life cycle of the parasite was not observed. This flagellate is obviously not a bodonid, but rather related to parasitic dinoflagellates despite a classic organization of the chromatin; the similarities to the Sprotozoa are enigmatic and no conclusions were reached with regard to phylogeny or convergence. The mode of penetration and the rapidity of host cytoplasm engulfment is an interesting problem. Diagnosis for the genus Spiromonas and for the new family SPIROMONADIDAE are given.			UNIV CLERMONT FERRAND 2, ZOOL & PROTISTOL LAB, CNRS, LAB 138, F-63170 AUBIERE, FRANCE.							Alexeieff A., 1929, Archives de Zoologie Experimentale et Generale Paris, V68, P609; Brooker B. E., 1971, Bull Br Mus nat Hist (Zool), V22, P89; BRUGEROLLE G, 1978, 5TH INT C PROT NEW Y; BRUGEROLLE G, 1979, PROTISTOLOGICA, V15; CACHON J, 1971, Archiv fuer Protistenkunde, V113, P293; Chatton E, 1936, CR HEBD ACAD SCI, V203, P573; Chatton E., 1934, CR Acad Sci Paris, V199, P252; Dodge J. D., 1973, FINE STRUCTURE ALGAL; DUBREMETZ JF, 1978, 4TH INT C PAR WARSZ, P81; HOLLANDE A, 1974, Protistologica, V10, P413; Hollande A., 1952, P669; Hollande A., 1938, Archives de Zoologie Experimentale Paris, V79, P75; Hollande A., 1942, Archives de Zoologie Experimentale et Generale Paris, V83, P1; LOM J, 1973, Protistologica, V9, P293; MACDONALD CM, 1977, PROTISTOLOGICA, V8, P441; PORCHET-HENNERE E, 1971, Annee Biologique, V10, P77; THIERY JP, 1974, J MICROSC-PARIS, V21, P225; VICKERMAN K, 1976, BIOL KINETOPLASTIDA, V1, P1; Vivier E., 1978, 4th International Congress of Parasitology, 19-26 August, 1978, Warsaw. Short communications, Section B., P82; Von Stosch HA., 1973, Br Phycol J, V8, P105	20	53	55	0	0	EDITIONS C N R S	PARIS	20/22 RUE ST. AMAND, 75015 PARIS, FRANCE	0033-1821			PROTISTOLOGICA			1979	15	2					183	196						14	Microbiology	Science Citation Index Expanded (SCI-EXPANDED)	Microbiology	HR297					2025-03-11	WOS:A1979HR29700006
J	ARTZNER, DG; DORHOFER, G				ARTZNER, DG; DORHOFER, G			TAXONOMIC NOTE - LEJEUNECYSTA NOM-NOV-PRO-LEJEUNIA GERLACH 1961 EMEND LENTIN AND WILLIAMS 1976 - DINOFLAGELLATE CYST GENUS	CANADIAN JOURNAL OF BOTANY-REVUE CANADIENNE DE BOTANIQUE			English	Note								The name LEJEUNECYSTA is proposed for the dinoflagellate cyst genus Lejeunia Gerlach 1961 emend. Lentin and Williams 1976, a later homonym of the modern liverwort genus Lejeunea Libert 1820. Species of the genus are transferred accordingly. [The new combinations, all transferred from Lejeunia to Lejeunecysta include L. hyalina (Gerlach), L. applanata (Bradford), L. diversiforma (Bradford), L. d. muscatense (Bradford), L. fallax (Morgenroth), L. magnifica (Stanley), L. paratenella (Benedek) and L. psilodora (Benedek). Also proposed were Lejeunecysta, pentagonalis (Deflandrea pentagonalis Corradini and L. tricuspis (Peridinium tricuspis O. Wetzel).].			UNIV TORONTO, DEPT GEOL, TORONTO M5S 1A1, ONTARIO, CANADA.							GROLLE R, 1976, Feddes Repertorium, V87, P171; GROLLE R, 1973, Taxon, V22, P689, DOI 10.2307/1218655; HAMPE, 1837, LINNAEA, V11, P92; LENTIN JK, 1977, BIR778 BEDF I OC REP, pR1; Libert M.-A., 1820, Annales generales des sciences physiques, V6, P372; STAFLEU FA, 1969, 11TH INT BOT C SEATT	6	30	33	0	0	CANADIAN SCIENCE PUBLISHING	OTTAWA	65 AURIGA DR, SUITE 203, OTTAWA, ON K2E 7W6, CANADA	0008-4026			CAN J BOT	Can. J. Bot.-Rev. Can. Bot.		1978	56	11					1381	1382		10.1139/b78-158	http://dx.doi.org/10.1139/b78-158			2	Plant Sciences	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences	FE121					2025-03-11	WOS:A1978FE12100011
J	ANDERSON, DM; WALL, D				ANDERSON, DM; WALL, D			POTENTIAL IMPORTANCE OF BENTHIC CYSTS OF GONYAULAX-TAMARENSIS AND G GONYAULAX-EXCAVATA IN INITIATING TOXIC DINOFLAGELLATE BLOOMS	JOURNAL OF PHYCOLOGY			English	Article								Thick-walled, nonmotile cysts (termed hypnocysts) of 2 dinoflagellates were isolated from estuarine sediments in Cape Cod, Massachusetts [USA], and germinated to produce their respective motile, thecate stages. Hypnocysts from Orleans district were identified as G. excavata (Braarud) Balech sensu Loeblich et Loeblich. Visually identical hypnocysts from Falmouth district were provisionally identified as G. tamarensis Lebour. Both species were toxic. A geographic survey in Sept. detected hypnocysts in only the sediments of locations where toxic blooms developed the preceding and following spring. Laboratory incubation (16.degree. C) of hypnocysts from sediment samples stored in the dark (5.degree. C) for 6 mo. initiated excystment by the temperature increase, with no appreciable effect from light regime, nutrient, or chelator concentrations. Motility of excysted gemlings was optimum in highly chelated medium and in the presence of light. Hypnocysts of both taxa are important in seeding recurrent annual blooms, synchronizing early bloom development with vernal warming of seawater and increasing the geographic range of the species. Many red tides in New England and eastern Canadian waters are probably initiated through the displacement of motile estuarine populations into nearshore areas by tidal advection and surface runoff, although the potential existence and importance of offshore cyst reservoirs cannot be discounted. Evidence is presented that hypnocysts are probably sexual zygotes whereas the thin-walled cysts readily formed in laboratory cultures (pellicle cysts) are asexual. Pellicle cysts are of limited durability, do not overwinter in nature and therefore do not play a significant role in initiating toxic blooms.	MIT, DEPT CIVIL ENGN, CAMBRIDGE, MA 02139 USA; WOODS HOLE OCEANOG INST, WOODS HOLE, MA 02543 USA	Massachusetts Institute of Technology (MIT); Woods Hole Oceanographic Institution								ANDERSON DM, 1978, LIMNOL OCEANOGR, V23, P283, DOI 10.4319/lo.1978.23.2.0283; Brooks J., 1971, Sporopollenin, P351, DOI [10.1016/B978-0-12-135750-4.50018-3, DOI 10.1016/B978-0-12-135750-4.50018-3]; DALE B, 1977, SARSIA, V63, P29, DOI 10.1080/00364827.1977.10411318; EMERY KO, 1969, COASTAL POND; ENTZ GEZA, 1926, ARCH PROTISTENK, V56, P397; Evitt W.R., 1967, STANFORD U PUBIS GEO, V10, P1; GRAY J., 1965, HDB PALEONTOLOGICAL, P471; GUILLARD RR, 1962, CAN J MICROBIOL, V8, P229, DOI 10.1139/m62-029; Hartwell A.D., 1975, P47; Huber G., 1922, Z BOTANIK, V14, P337; Huber G., 1923, FLORA JENA, V116, P114; LOEBLICH AR, 1970, N AM PALEONTOLOGICAL, P867; Loeblich L.A., 1975, P207; MOREL FMM, 1975, 16 MASS I TECHN DEP; Mulligan H.F., 1975, P23; PRAKASH A, 1967, J FISH RES BOARD CAN, V24, P1589, DOI 10.1139/f67-131; PRAKASH A, 1975, ENVIRON LETT, V9, P121, DOI 10.1080/00139307509435841; Ryther J.H., 1955, The Luminescence of Biological Systems, P387; Steidinger K.A., 1975, P153; STEIDINGER K A, 1971, Phycologia, V10, P183, DOI 10.2216/i0031-8884-10-2-183.1; STOSCH H A, 1969, Helgolaender Wissenschaftliche Meeresuntersuchungen, V19, P569, DOI 10.1007/BF01608816; Stosch H.A. von., 1973, British phycol J, V8, P105; STOSCH HAV, 1965, NATURWISSENSCHAFTEN, V52, P112; TAYLOR FJR, 1975, ENVIRON LETT, V9, P103, DOI 10.1080/00139307509435840; Wall D., 1975, P249; WALL D, 1969, J PHYCOL, V5, P140, DOI 10.1111/j.1529-8817.1969.tb02595.x; WALL D, 1968, Journal of Paleontology, V42, P1395; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690	28	326	356	3	23	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0022-3646	1529-8817		J PHYCOL	J. Phycol.		1978	14	2					224	234		10.1111/j.1529-8817.1978.tb02452.x	http://dx.doi.org/10.1111/j.1529-8817.1978.tb02452.x			11	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	FH958					2025-03-11	WOS:A1978FH95800017
J	TURPIN, DH; DOBELL, PER; TAYLOR, FJR				TURPIN, DH; DOBELL, PER; TAYLOR, FJR			SEXUALITY AND CYST FORMATION IN PACIFIC STRAINS OF TOXIC DINOFLAGELLATE GONYAULAX-TAMARENSIS	JOURNAL OF PHYCOLOGY			English	Note								Sexuality was established for a culture of G. tamarensis Lebour (strain NEPCC-71). The addition of a thick inoculum to a N-deprived medium results in the occurrence of anisogamous sexual fusion within the 1st 3 days in the new culture. Planozygotes, large lumpy cells recognizable by their 4 flagella, may persist up to 2 wk before forming a smooth-walled, oval hypnozygote. The latter resembles cysts released asexually by ecdysis but has a slightly thicker wall. Viable cysts resembling hypnozygotes (zygotic cysts), but with reduced photosynthetic pigmentation, have been isolated from natural marine sediments in Hidden Basin, British Columbia [Canada], and a culture (strain NEPCC-254) was initiated from excysted individuals. Zygotic cysts of NEPCC-71 remained encysted in the light at 17.degree. C for 8 wk before excysting. The presence of a ventral pore with toxicity in the latter strain indicates that the taxonomy of G. tamarensis-like organisms is still in a state of flux and the criteria for recognition of G. excavata (Braarud) Balech as a separate species are not satisfactory as presently formulated.	UNIV BRITISH COLUMBIA, INST OCEANOG, VANCOUVER V6T 1W5, BC, CANADA; UNIV BRITISH COLUMBIA, DEPT BOT, VANCOUVER V6T 1W5, BC, CANADA	University of British Columbia; University of British Columbia			Turpin, David/E-1850-2012					ANDERSON DM, 1978, J PHYCOL, V14, P224, DOI 10.1111/j.1529-8817.1978.tb02452.x; BALECH E, 1971, ARMADA ARGENTINA SER; GUILLARD RR, 1962, CAN J MICROBIOL, V8, P229, DOI 10.1139/m62-029; Loeblich L.A., 1975, P207; OTT FR, 1966, MARINE BIOL LAB CONT, V72, P1; PFIESTER LA, 1977, J PHYCOL, V13, P92, DOI 10.1111/j.0022-3646.1977.00092.x; PFIESTER LA, 1976, J PHYCOL, V12, P234; PFIESTER LA, 1975, J PHYCOL, V11, P259, DOI 10.1111/j.1529-8817.1975.tb02776.x; PRAKASH A, 1963, J FISH RES BOARD CAN, V20, P983, DOI 10.1139/f63-067; SILVA E, 1962, NOTAS ESTUD INST BIOL MARITIMA, V26, P1; Stosch H.A. von., 1973, British phycol J, V8, P105; TAYLOR FJR, 1975, ENVIRON LETT, V9, P103, DOI 10.1080/00139307509435840	12	101	105	0	4	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0022-3646	1529-8817		J PHYCOL	J. Phycol.		1978	14	2					235	238		10.1111/j.1529-8817.1978.tb02454.x	http://dx.doi.org/10.1111/j.1529-8817.1978.tb02454.x			4	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	FH958					2025-03-11	WOS:A1978FH95800019
J	YENTSCH, CM; DALE, B; HURST, JW				YENTSCH, CM; DALE, B; HURST, JW			COEXISTENCE OF TOXIC AND NONTOXIC DINOFLAGELLATES RESEMBLING GONYAULAX-TAMARENSIS IN NEW-ENGLAND COASTAL WATERS (NW ATLANTIC)	JOURNAL OF PHYCOLOGY			English	Article								Two forms resembling G. tamarensis Lebour, coexist in Maine [USA] coast plankton; 1 is toxic, the other is nontoxic. At times, red patches of dinoflagellates were identified as G. tamarensis, yet only presumed to be toxic. Toxic forms were found in June, July 1975 and 1976. The nontoxic form was found in a more estaurine area, e.g., mid-July 1975, early July 1976. These 2 forms are not easily distinguished by conventional microscopic observations, nor by pigment analysis. Preliminary observations suggest that the nontoxic form is smaller than G. excavata (Braarud) Balech and lacks the excavated ventral region. Characteristic G. excavata resting cysts were found in sediments from the shellfish toxic area off Newagen and Monhegan (Maine) and were not found in sediments from areas where the nontoxic form bloomed. There appear to be a minimum of 2 G. tamarensis-like organisms. Full systematic treatment of these must await further information.	BIGELOW LAB OCEAN SCI, W BOOTHBAY HARBOR, ME 04575 USA; UNIV OSLO, INST MARINE BIOL & LIMNOL, OSLO, NORWAY									Braarud T., 1945, Avhandlinger utgitt av det Norske Videnskaps-Akademi i Oslo, V11, P1; DALE B, 1977, SARSIA, V63, P29, DOI 10.1080/00364827.1977.10411318; GRAN HH, 1935, J BIOL BD CAN, V1, P280; LOEBLICH LA, 1975, 1ST P INT C TOX DIN, P207; PRAKASH A, 1963, J FISH RES BOARD CAN, V20, P983, DOI 10.1139/f63-067; Sommer H, 1937, ARCH PATHOL, V24, P560; TAYLOR FJR, 1975, ENVIRON LETT, V9, P103, DOI 10.1080/00139307509435840; YENTSCH CS, 1963, DEEP-SEA RES, V10, P221, DOI 10.1016/0011-7471(63)90358-9; YENTSCH CS, 1970, PREDICTION MEASUREME, P489	9	31	34	0	0	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0022-3646	1529-8817		J PHYCOL	J. Phycol.		1978	14	3					330	332		10.1111/j.1529-8817.1978.tb00307.x	http://dx.doi.org/10.1111/j.1529-8817.1978.tb00307.x			3	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	FS790					2025-03-11	WOS:A1978FS79000016
J	REID, PC				REID, PC			DINOFLAGELLATE CYSTS IN PLANKTON	NEW PHYTOLOGIST			English	Article								The geographical and seasonal occurrences of dinoflagellate cysts at a depth of 10 m in the North Atlantic and North Sea are described from samples taken by the Continuous Plankton Recorder [CPR] between June 1973 and Dec. 1975. A special study was made of the large cyst of Polykrikos schwartzii Butschli in the autumn of 1973 when CPR samples were supplemented by vertical sampling in the upper 500 m with a Longhurst-Hardy Plankton Recorder at Ocean Weather Station. Only 10 isolated records of cysts were made in the western Atlantic. All others occurred to the east of 30.degree. West in both oceanic and neritic waters and especially in the shallow waters of the North Sea. Cysts were found in the spring plankton but were most abundant in the autumn. They were recorded down to 500 m but occur most frequently in the top 30 m of the water column. Large aggregations of cysts in bottom sediments probably reflect concentration over many years since they cannot be explained by the low numbers found in the plankton. Generally, the distribution of cysts in the plankton is reflected in bottom sediments but concentrations in sediments may be outside the centers of production, implying movement by currents or sediment transport.			INST MARINE ENVIRONM RES, PLYMOUTH, ENGLAND.							[Anonymous], PLANKTON; Apstein C., 1906, WISSENSCHAFTLICHE ME, V9, P1; Braarud T., 1953, RAPP PV REUN CONS PE, V133, P1, DOI DOI 10.14430/ARCTIC3544; Cleve P. T, 1899, KONGLIGA SVENSKA VET, V32, P1; DALE B, 1976, REV PALAEOBOT PALYNO, V22, P39, DOI 10.1016/0034-6667(76)90010-5; EISENACK A, 1963, NEUES JB GEOL PAL, V118, P98; Gaardner K. R., 1954, Report Sars North Atlantic Deep Sea Expedition, V2, P1; GLOVER R. S., 1967, SYMP ZOOL SOC LONDON, V19, P189; GRAN WW, 1915, B PLANKT, P5; HARDY A. C., 1939, HULL BULL MARINE ECOL, V1, P1; HARLAND R, 1973, SUPERFICIAL DEPOSITS, P1; HARLAND R, 1974, GEOLOGY SEA HEBRIDES, P1; Hensen V., 1887, BER KOMM WISS UNTERS, V5, P1; LOEBLICH LA, 1975, 1ST P INT C TOX DIN, P207; LOHMANN H, 1904, ERGEBNISSE PLANKTON, V4, P1; LOHMANN H., 1910, NORD PLANKTON ZOOLOG, V2, P1; LONGHURST AR, 1976, DEEP-SEA RES, V23, P1067, DOI 10.1016/0011-7471(76)90883-4; LOUIS A, 1974, STUDIA ALGOLOGICA LO, P1; MULLIGAN HF, 1973, J FISH RES BOARD CAN, V30, P1363, DOI 10.1139/f73-218; Nordli E., 1951, Nyt Magazin for Naturvidenskaberne, V88, P207; OSTENFELD C.H., 1903, BOT FAEROES PART 2 C, P558; OSTENFELD CH, 1906, 33 CIRC CONS PERM IN, P1; OSTENFELD CH, 1916, 70 CIRC CONS PERM IN, P1; PAULSEN O, 1918, MEDD KOMIS HAVUNDE P, V1, P1; PAULSEN O., 1908, NORDISCHES PLANKTON, VXVIII, P1; Reid P.C., 1974, Nova Hedwigia, V25, P579; Reid P.C., 1972, THESIS U SHEFFIELD; REID PC, 1972, J MAR BIOL ASSOC UK, V52, P939, DOI 10.1017/S0025315400040674; REID PC, 1975, NEW PHYTOL, V75, P589, DOI 10.1111/j.1469-8137.1975.tb01425.x; ROBINSON GA, 1968, NATURE, V220, P22, DOI 10.1038/220022a0; WALL D, 1966, NATURE, V211, P1025, DOI 10.1038/2111025a0; Wall D., 1965, Grana Palynologica, V6, P297; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; Wall D., 1975, Micropalaeontology, V21, P14, DOI 10.2307/1485153	34	44	45	0	3	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0028-646X	1469-8137		NEW PHYTOL	New Phytol.		1978	80	1					219	+		10.1111/j.1469-8137.1978.tb02284.x	http://dx.doi.org/10.1111/j.1469-8137.1978.tb02284.x			0	Plant Sciences	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences	EM464		Bronze			2025-03-11	WOS:A1978EM46400026
J	WILSON, GJ				WILSON, GJ			KAIWARADINIUM, A NEW DINOFLAGELLATE GENUS FROM LATE JURASSIC OF NORTH CANTERBURY, NEW-ZEALAND	NEW ZEALAND JOURNAL OF GEOLOGY AND GEOPHYSICS			English	Article								KAIWARADINIUM buccinatum gen. et sp. nov., a distinctive chorate dinoflagellate cyst belonging to the Hystrichosphaeridiaceae, is described from Torlesse rocks of Puaroan age (Early Tithonian) in the Kaiwara Valley.	DSIR, NEW ZEALAND GEOL SURVEY, LOWER HUTT, NEW ZEALAND				Wilson, Graeme/R-1037-2019					SARJEANT WAS, 1974, S STRAT PAL B SAHN I, P9; SPEDEN IG, 1975, 69 NZ GEOL SURV REP	2	1	1	0	0	TAYLOR & FRANCIS LTD	ABINGDON	2-4 PARK SQUARE, MILTON PARK, ABINGDON OR14 4RN, OXON, ENGLAND	0028-8306	1175-8791		NEW ZEAL J GEOL GEOP	N. Z. J. Geol. Geophys.		1978	21	1					81	84		10.1080/00288306.1978.10420724	http://dx.doi.org/10.1080/00288306.1978.10420724			4	Geology; Geosciences, Multidisciplinary	Science Citation Index Expanded (SCI-EXPANDED)	Geology	FK914					2025-03-11	WOS:A1978FK91400007
J	REID, PC				REID, PC			PERIDINIACEAN AND GLENODINIACEAN-DINOFLAGELLATE CYSTS FROM THE BRITISH-ISLES	NOVA HEDWIGIA			English	Article											REID, PC (通讯作者)，INST MARINE ENVIRONM RES,67 CITADEL RD,PLYMOUTH PL1 3DH,ENGLAND.								0	57	59	0	3	GEBRUDER BORNTRAEGER	STUTTGART	JOHANNESSTR 3A, D-70176 STUTTGART, GERMANY	0029-5035			NOVA HEDWIGIA	Nova Hedwigia		1978	29	3-4					429	463						35	Plant Sciences	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences	HH138					2025-03-11	WOS:A1978HH13800002
J	DALE, B; YENTSCH, CM; HURST, JW				DALE, B; YENTSCH, CM; HURST, JW			TOXICITY IN RESTING CYSTS OF RED-TIDE DINOFLAGELLATE GONYAULAX-EXCAVATA FROM DEEPER WATER COASTAL SEDIMENTS	SCIENCE			English	Article								For the 1st time, G. excavata cysts were shown to be toxic. Bottom sediments from a water depth of 90 m off the Maine [USA] coast were extremely rich in cysts, which were approximately 10 .times. more toxic than the corresponding motile stages. Cysts are probably ingested by shellfish, thereby causing shellfish toxicity in deeper waters offshore and contributing to shellfish toxicity in shallower coastal waters. A new approach to the problem of paralytic shellfish poisoning is needed, one that takes into account benthic cysts and sedimentary factors affecting their distribution. The possible dangers of spreading poisoning through human activities must be considered.	BIGELOW LAB OCEAN SCI, W BOOTHBAY HARBOR, ME 04575 USA; MAINE DEPT MARINE RESOURCES, W BOOTHBAY HARBOR, ME 04575 USA	Bigelow Laboratory for Ocean Sciences	UNIV OSLO, DEPT MARINE BIOL & LIMNOL, OSLO, NORWAY.							BOURNE N, 1965, J FISH RES BOARD CAN, V22, P1137, DOI 10.1139/f65-102; DALE B, 1976, REV PALAEOBOT PALYNO, V22, P39, DOI 10.1016/0034-6667(76)90010-5; DALE B, 1977, SARSIA, V63, P29, DOI 10.1080/00364827.1977.10411318; GILFILLAN ES, UNPUBLISHED; LOCICERO VR, 1975, 1ST P INT C TOX DIN; PRAKASH A, 1971, 177 FISH RES BOARD C; PRAKASH A, 1975, 1ST P INT C TOX DIN; STEIDINGER KA, 1975, ENVIRON LETT, V9, P129, DOI 10.1080/00139307509435842; WALL D., 1967, PHYCOLOGIA, V6, P83	9	71	84	0	8	AMER ASSOC ADVANCEMENT SCIENCE	WASHINGTON	1200 NEW YORK AVE, NW, WASHINGTON, DC 20005 USA	0036-8075	1095-9203		SCIENCE	Science		1978	201	4362					1223	1224		10.1126/science.201.4362.1223	http://dx.doi.org/10.1126/science.201.4362.1223			2	Multidisciplinary Sciences	Science Citation Index Expanded (SCI-EXPANDED)	Science & Technology - Other Topics	FP768	17801389				2025-03-11	WOS:A1978FP76800015
J	KURELEC, B; RIJAVEC, M; BRITVIC, S; MULLER, WEG; ZAHN, RK				KURELEC, B; RIJAVEC, M; BRITVIC, S; MULLER, WEG; ZAHN, RK			PHYTOPLANKTON - PRESENCE OF GAMMA-GLUTAMYL CYCLE ENZYMES	COMPARATIVE BIOCHEMISTRY AND PHYSIOLOGY B-BIOCHEMISTRY & MOLECULAR BIOLOGY			English	Article								The presence of the .gamma.-glutamyl cycle enzymes in natural (Adriatic) phytoplankton populations (mostly diatoms and dinoflagellates) was investigated. Crude homogenates or purified preparations from phytoplankton homogenates revealed the activities of the .gamma.-glutamyl transpeptidase, .gamma.-glutamyl cyclotransferase, oxoprolinase, and in an over-all reaction .gamma.-glutamyl cysteine synthetase and glutathione synthetase. Amino acid transport in the phytoplankton may function via the .gamma.-glutamyl cycle. .gamma.-Glutamyl transpeptidase, the enzyme occupying a central part in the concept of amino acid transport, was absent in zooplankton (a single crustacean species).	RUDJER BOSKOVIC INST, CTR MARINE RES, MARINE MOLEC BIOL LAB, YU-41001 Zagreb, YUGOSLAVIA	Rudjer Boskovic Institute								COHN VH, 1966, ANAL BIOCHEM, V14, P434, DOI 10.1016/0003-2697(66)90286-7; COLINVAUX PA, 1973, INTRO ECOLOGY, P189; DUGDALE RC, 1967, LIMNOL OCEANOGR, V12, P196, DOI 10.4319/lo.1967.12.2.0196; FOGG GE, 1975, CHEM OCEANOGR, P386; GUIDOTTI G, 1976, TRENDS BIOCHEM SCI, V1, P11, DOI 10.1016/0968-0004(76)90256-5; LOWRY OH, 1951, J BIOL CHEM, V193, P265; MEISTER A, 1973, SCIENCE, V180, P33, DOI 10.1126/science.180.4081.33; MEISTER A, 1975, METABOLISM SULFUR CO, V7, P101; Mooz E.D., 1971, METHODS ENZYMOLOGY B, V17, P483; NORTH BB, 1975, LIMNOL OCEANOGR, V20, P20, DOI 10.4319/lo.1975.20.1.0020; NORTH BB, 1972, J PHYCOL, V8, P64, DOI 10.1111/j.1529-8817.1972.tb04003.x; NORTH BB, 1971, BIOL BULL, V140, P242, DOI 10.2307/1540072; ORLOWSKI M, 1969, BIOCHEMISTRY-US, V8, P1048, DOI 10.1021/bi00831a036; ORLOWSKI M, 1970, P NATL ACAD SCI USA, V67, P1248, DOI 10.1073/pnas.67.3.1248; ORLOWSKI M, 1970, METHODS ENZYMOL    A, V17, P883; PARDEE AB, 1968, SCIENCE, V162, P632, DOI 10.1126/science.162.3854.632; Putter A. F. R, 1909, ERNAHRUNG WASSERTIER; REVELANTE N, 1975, THESIS U ZAGREB; SCHELL DM, 1974, LIMNOL OCEANOGR, V19, P260, DOI 10.4319/lo.1974.19.2.0260; Stephens G.C., 1972, P155; STEPHENS GC, 1963, COMP BIOCHEM PHYSIOL, V10, P191, DOI 10.1016/0010-406X(63)90033-1; STEPHENS GC, 1968, AM ZOOL, V8, P95; TATE SS, 1974, J BIOL CHEM, V249, P7593; VANDERWERF P, 1971, P NATL ACAD SCI USA, V68, P2982; WHEELER PA, 1974, LIMNOL OCEANOGR, V19, P249, DOI 10.4319/lo.1974.19.2.0249	25	0	0	0	1	ELSEVIER SCIENCE INC	NEW YORK	STE 800, 230 PARK AVE, NEW YORK, NY 10169 USA	1096-4959	1879-1107		COMP BIOCHEM PHYS B	Comp. Biochem. Physiol. B-Biochem. Mol. Biol.		1977	56	4					415	419		10.1016/0305-0491(77)90241-3	http://dx.doi.org/10.1016/0305-0491(77)90241-3			5	Biochemistry & Molecular Biology; Zoology	Science Citation Index Expanded (SCI-EXPANDED)	Biochemistry & Molecular Biology; Zoology	DB575					2025-03-11	WOS:A1977DB57500013
J	BEAM, CA; HIMES, M; HIMELFARB, J; LINK, C; SHAW, K				BEAM, CA; HIMES, M; HIMELFARB, J; LINK, C; SHAW, K			GENETIC EVIDENCE OF UNUSUAL MEIOSIS IN DINOFLAGELLATE CRYPTHECODINIUM-COHNII	GENETICS			English	Article								Genetic analysis of the homothallic dinoflagellate, C. cohnii, using 16 nonallelic motility mutants, revealed virtual absence of 2nd division segregation and independent assortment of all genes except for 3 cases of cross specific, "false" linkage and 1 possible case of linkage with a high percentage of crossing over. The probability that at least 2 of the 16 genes studied are on 1 of the approximately 50 (minimal) chromosomes is extremely high and, since recombination is observed between all pairs of markers, it is highly probable that some results from crossing over. This likelihood plus the observed absence of 2nd division segregation and the significant number of 2 celled zygotic cysts support the view that the meiosis of C. cohnii is a 1-division process.	CUNY, BROOKLYN COLL, DEPT BIOL, BROOKLYN, NY 11210 USA									ALLEN JR, 1975, CELL, V6, P161, DOI 10.1016/0092-8674(75)90006-9; BEAM C, IN PRESS; BEAM CA, 1974, NATURE, V250, P435, DOI 10.1038/250435a0; CLEVELAND LR, 1950, J MORPHOL, V86, P215, DOI 10.1002/jmor.1050860111; GOLD K, 1966, J PROTOZOOL, V13, P255, DOI 10.1111/j.1550-7408.1966.tb01902.x; GOWANS C, 1976, GENETICS ALGAE, V12, P145; GRASSE P, 1965, CR HEBD ACAD SCI, V260, P6975; HIMES M, 1975, P NATL ACAD SCI USA, V72, P4546, DOI 10.1073/pnas.72.11.4546; KUBAI DF, 1969, J CELL BIOL, V40, P508, DOI 10.1083/jcb.40.2.508; PROVASOLI L, 1962, ARCH MIKROBIOL, V42, P196, DOI 10.1007/BF00408175; RIZZO PJ, 1974, BIOCHIM BIOPHYS ACTA, V349, P415, DOI 10.1016/0005-2787(74)90127-0; ROBERTS TM, 1974, NATURE, V248, P446, DOI 10.1038/248446a0; ROMAN H, 1955, GENETICS, V40, P546; TATUM EL, 1946, COLD SPRING HARB SYM, V11, P278; WRIGHT DA, 1968, J EXP ZOOL, V167, P197, DOI 10.1002/jez.1401670208; YAMAZAKI T, 1975, J BACTERIOL, V125, P461	16	16	16	0	1	GENETICS SOCIETY AMERICA	BETHESDA	9650 ROCKVILLE AVE, BETHESDA, MD 20814 USA	0016-6731	1943-2631		GENETICS	Genetics		1977	87	1					19	32						14	Genetics & Heredity	Science Citation Index Expanded (SCI-EXPANDED)	Genetics & Heredity	EB619	17248757				2025-03-11	WOS:A1977EB61900002
J	LEFFINGWELL, HA; MORGAN, RP				LEFFINGWELL, HA; MORGAN, RP			RESTUDY AND COMPARISON OF DINOFLAGELLATE CYST GENUS CARPODINIUM TO THAT OF PRIONODINIUM-N-GEN	JOURNAL OF PALEONTOLOGY			English	Article								PRIONODINIUM alaskense gen. et sp. nov. and P. alveolatum sp. nov., from the upper Neocomian (Hauterivian-Barremian) of southern Alaska [USA], have a reflected tabulation of 4'', 6'''', 6c, 5-6'''''', 1 p, (1 ps), 1''''''''. Although both species have a similar tabulation and resemble those assigned to Carpodinium, a restudy of the holotype, C. granulatum Cookson et Eisenack, 1962, indicates the latter differs by the inflated crests and by a less completely defined reflected tabulation. The descriptions of Carpodinium and C. granulatum are emended.	UNION OIL RES CTR, BREA, CA 92621 USA; GEOL SURVEY SYDNEY, SYDNEY, NEW S WALES, AUSTRALIA									[Anonymous], PALAEONTOLOGY; Burger D., 1973, Bureau of Mineral Resources, Geology and Geophysics Australia, V140, P27; Cookson I. C., 1962, Micropaleontology, V8, P485, DOI 10.2307/1484681; Davey R.J., 1971, VERHANDEL KONINKL NE, V26, P1; DAVEY RJ, 1974, 3 BIRB SAHN I PAL SP, P41; DAVEY RJ, 1966, B BRIT MUS NAT HI S3, P28; Dettmann M.E., 1969, Stratigraphy and palaeontology: essays in honour of Dorothy Hill, P174; EVANS PR, 1966, 1966198 BUR MIN RES; Habib D., 1972, Initial Rep Deep Sea Drilling Project, V11, P367; JONES DL, 1966, US GEOL SURV PROF PA, V550, pD53; WIGGINS V D, 1969, Micropaleontology (New York), V15, P145, DOI 10.2307/1484918	11	2	2	0	0	CAMBRIDGE UNIV PRESS	CAMBRIDGE	EDINBURGH BLDG, SHAFTESBURY RD, CB2 8RU CAMBRIDGE, ENGLAND	0022-3360	1937-2337		J PALEONTOL	J. Paleontol.		1977	51	2					288	302						15	Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Paleontology	DA892					2025-03-11	WOS:A1977DA89200008
J	KIMOR, B; GOLANDSKY, B				KIMOR, B; GOLANDSKY, B			MICROPLANKTON OF GULF OF ELAT - ASPECTS OF SEASONAL AND BATHYMETRIC DISTRIBUTION	MARINE BIOLOGY			English	Article								The components of 4 major groups of microplankton were identified and their numerical abundance determined in net samples collected at depth intervals down to 600 m at a permanent station off the H. Steinitz Marine Biological Laboratory, Elat, Israel. The samples analyzed were collected once a fortnight over a period of 1 yr beginning in June 1974. The groups studied were the Cyanophyta, Bacillariophyta and Pyrrhophyta of the phytoplankton and the Tintinnina of the microzooplankton. The pattern of vertical distribution of the phytoplankton as a whole showed a general decrease in cell numbers with increasing depth. The blue-green algae, consisting mainly of Trichodesmium sp. trichomes, were confined primarily to the upper 100 m. The diatoms were unevenly distributed, with 1 sp., a minute centric diatom, Thalassiosira subtilis, associated with a massive bloom during March 1975 between 300 and 400 m. The peridinians, the group with the largest number of species, included forms which were evenly distributed throughout the whole water column and forms limited either to the upper or deeper water strata in accordance with their light intensity preferences. The mass occurrence of newly-emerged dinoflagellate cysts of Pyrophacus horologicum, a weakly-armored dinoflagellate, in the 200-300 m depth interval during April 1975, suggests that reproductive processes in dinoflagellates may also be light-controlled. The tintinnids, like the phytoplankton groups, were most abundant in the upper 100 m with a gradual decrease in numbers of individuals, though not in species, in the deeper water strata. The overall yearly pattern of microplankton distribution indicated 3 peaks: late fall and early summer peaks consisting primarily of blue-green algae and 1 in early spring consisting of several species of diatoms and peridinians and of species of tintinnids which thrive in the same niches as the phytoplankton. Both phytoplankton and tintinnid production was lowest during the summer months.	ISRAEL OCEANOGRAPHIC & LIMNOLO RES LTD, HAIFA LABS, HAIFA, ISRAEL									DUGDALE RC, 1964, LIMNOL OCEANOGR, V9, P507, DOI 10.4319/lo.1964.9.4.0507; DUGDALE RC, 1961, DEEP-SEA RES, V7, P297, DOI 10.1016/0146-6313(61)90051-X; DURAIRATNAM M, 1964, INF B PLANKTOL JAPAN, V11, P1; Fogg G.E., 1973, BLUE GREEN ALGAE; GOLANDSKY B, 1976, THESIS HEBREW U; HADIN H, 1975, ZOON, V3, P125; HASLE GR, 1959, DEEP-SEA RES, V6, P38, DOI 10.1016/0146-6313(59)90055-3; HULBURT EM, 1966, J MAR RES, V24, P67; JORGENSEN E., 1924, BIOL, V2, P1; KIMOR B, 1971, 1970 P JT OC ASS TOK, P442; KLINKER J, 1975, ELAT, V4, P46; KLINKER J, IN PRESS; Komarovsky B., 1962, Bulletin Sea Fisheries Research Station Israel, VNo. 30, P48; Komarovsky B., 1959, Bulletin Sea Fisheries Research Station Israel, VNo. 21, P1; OREN OH, 1962, B SEA FISH RES STN, V30, P1; Posta A., 1963, Cahiers de Biologie Marine, V4, P201; RAMPI L, 1950, 974 I OC MON B, P1; REISS Z, 1974, ISR J EARTH SCI, V23, P69; SERRUYA C, 1971, MITT INT VER THEOR, V19, P277; SOURNIA A, 1969, MAR BIOL, V3, P287, DOI 10.1007/BF00698859; STEEDMAN RH, 1976, MONOGR OCEANOGRL MET, V4, P103; Wood E J F, 1964, Nova Hedwigia, V8, P453; 1968, MONOGR OCEANOGRL MET, V2, P153	23	69	69	0	1	SPRINGER HEIDELBERG	HEIDELBERG	TIERGARTENSTRASSE 17, D-69121 HEIDELBERG, GERMANY	0025-3162	1432-1793		MAR BIOL	Mar. Biol.		1977	42	1					55	67		10.1007/BF00392014	http://dx.doi.org/10.1007/BF00392014			13	Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Marine & Freshwater Biology	DP203					2025-03-11	WOS:A1977DP20300007
J	WALL, D; DALE, B; LOHMANN, GP; SMITH, WK				WALL, D; DALE, B; LOHMANN, GP; SMITH, WK			ENVIRONMENTAL AND CLIMATIC DISTRIBUTION OF DINOFLAGELLATE CYSTS IN MODERN MARINE-SEDIMENTS FROM REGIONS IN NORTH AND SOUTH-ATLANTIC OCEANS AND ADJACENT SEAS	MARINE MICROPALEONTOLOGY			English	Article							BENGUELA CURRENT REGION; COASTAL WATERS; TEMPERATURE; DIVERSITY; SALINITY; PLANKTON; BRITAIN; PHYTOPLANKTON; ABUNDANCE; FEBRUARY		WOODS HOLE OCEANOG INST, WOODS HOLE, MA 02543 USA	Woods Hole Oceanographic Institution								ANDERSON WW, 1957, 210 US FISH WILDL SE; ANDERSON WW, 1957, 234 US FISH WILDL SE; ANDERSON WW, 1956, 198 US FISH WILDL SE; ANDERSON WW, 1956, 178 US FISH WILDL SE; [Anonymous], 1954, VERHANDELINGEN KONIN; [Anonymous], COASTAL ECOLOGICAL S; BANG ND, 1971, DEEP-SEA RES, V18, P209, DOI 10.1016/0011-7471(71)90110-0; BARY BM, 1963, J FISH RES BOARD CAN, V20, P1031, DOI 10.1139/f63-070; BARY BM, 1963, J FISH RES BOARD CAN, V20, P789, DOI 10.1139/f63-052; BARY BM, 1963, J FISH RES BOARD CAN, V20, P1519, DOI 10.1139/f63-104; BARY BM, 1964, J FISH RES BOARD CAN, V21, P183, DOI 10.1139/f64-014; Bigelow H.B., 1935, Pap. 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E., 1933, BULL BINGLIAM OCEANOGR COLL, V4, P1; PARSONS TR, 1973, BIOLOGICAL OCEANOGRA; PEASE TE, 1969, GSLTR697 NEW YOR U S; Pianka E.R., 1974, EVOL ECOL; PICKET TE, 1969, US SE GEOL, V11, P53; PIELOU E C, 1969, P286; Pritchard D.W., 1967, Estuaries, P3; Reid P.C., 1974, Nova Hedwigia, V25, P579; REID PC, 1972, J MAR BIOL ASSOC UK, V52, P939, DOI 10.1017/S0025315400040674; REID PC, 1975, NEW PHYTOL, V75, P589, DOI 10.1111/j.1469-8137.1975.tb01425.x; REYSSAC J., 1970, B IFAN A, P869; Robinson M.K., 1973, ATLAS MONTHLY MEAN S; ROELOFS E. W., 1953, BULL MARINE SCI GULF AND CARIBBEAN, V3, P181; ROGERS J, 1971, B S AFR NAT COM OCEA, V1, P1; Rossignol M., 1964, Revue de Micropaleontologie, V7, P83; ROUND F. E., 1967, J EXP MAR BIOL ECOL, V1, P76, DOI 10.1016/0022-0981(67)90008-1; SANDERS HL, 1968, AM NAT, V102, P243, DOI 10.1086/282541; SCHILLER J, 1937, OSTERREICH SCHWEIZ, V10, P1; SCHLEE J, 1973, 529L US GEOL SURV PR, P1; SELIGER HH, 1970, LIMNOL OCEANOGR, V15, P234, DOI 10.4319/lo.1970.15.2.0234; SELIGER HH, 1971, LIMNOL OCEANOGR, V16, P608, DOI 10.4319/lo.1971.16.4.0608; Shannon LV, 1966, INVESTL REP DIV FISH, V58, P1; SLOBODKIN LB, 1969, BROOKHAVEN SYM BIOL, P82; SMAYDA TJ, 1973, 2 U RHOD ISL MAR PUB; Smith CL, 1940, J MAR RES, V3, P147; SMITH RL, 1971, INVEST PESQ, V35, P9; SMITH W, 1977, BIOMETRICS, V33, P283, DOI 10.2307/2529778; STANDER GH, 1964, INVEST REP MAR RES L, V12, P1; Valentine J.W., 1973, EVOLUTIONARY PALEOEC; Wall D., 1965, Grana Palynologica, V6, P297; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; WALL D, 1968, NEW PHYTOL, V67, P315, DOI 10.1111/j.1469-8137.1968.tb06387.x; WALL D, 1970, Micropaleontology (New York), V16, P47, DOI 10.2307/1484846; WALL D, 1975, AM ASSOC STRATIGR PA, V4, P37; WALL D, 1970, 1969 P N AM PAL CO G, P844; Wall D., 1974, AAPG Memoir. Chemistry and Biology, P364; WALL D., 1967, PALAEONTOLOGY, V10, P95; WALSH JJ, 1971, INVEST PESQ, V35, P25; WILLIAMS D.B., 1971, MICROPALAEONTOLOGY O; WILLIAMS W.T., 1971, Annual Review of Ecological Systems, V2, P303; WILSON GJ, 1973, NEW ZEAL J GEOL GEOP, V16, P345, DOI 10.1080/00288306.1973.10431363; Wyrtki K., 1966, Oceanogr. Mar. Biol. Annu. Rev, V4, P33; ZAGWIJN W H, 1974, Boreas (Oslo), V3, P75; ZENKEVICH LA, 1949, 13 CR C INT ZOOL, P522; 1960, 311 US DEP COMM COAS; 1944, 225 US HYDR OFF PUBL; 1967, 700 US NAV OC OFF PU	124	518	548	0	11	ELSEVIER	AMSTERDAM	RADARWEG 29, 1043 NX AMSTERDAM, NETHERLANDS	0377-8398	1872-6186		MAR MICROPALEONTOL	Mar. Micropaleontol.		1977	2	2					121	200		10.1016/0377-8398(77)90008-1	http://dx.doi.org/10.1016/0377-8398(77)90008-1			80	Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Paleontology	DT788					2025-03-11	WOS:A1977DT78800002
J	WILLIAMS, GL; BUJAK, JP				WILLIAMS, GL; BUJAK, JP			DISTRIBUTION PATTERNS OF SOME NORTH-ATLANTIC CENOZOIC DINOFLAGELLATE CYSTS	MARINE MICROPALEONTOLOGY			English	Article									GEOL SURVEY CANADA, CTR ATLANTIC GEOSCI, DARTMOUTH, NS, CANADA	Natural Resources Canada; Lands & Minerals Sector - Natural Resources Canada; Geological Survey of Canada								[Anonymous], ANTARCT ECOL; Davey R.J., 1970, B BR MUS NAT HIS G, V18, P333; DAVEY RJ, 1975, MAR GEOL, V18, P213, DOI 10.1016/0025-3227(75)90097-3; DAVEY RJ, 1971, 2ND P PLANKT C ROM, P331; Downie C., 1971, Geoscience Man, V3, P29; EATON GL, 1971, 2ND P PLANKT C ROM, P355; Evitt W.R., 1967, STANFORD U PUBIS GEO, V10, P1; GRADSTEIN FM, 1975, OCEAN SCI REV, P15; GRAHAM HW, 1942, 542 CARN I WASH PUBL, P1; GRAHAM HW, 1944, 562 CARN I WASH PUBL, P1; Klumpp B., 1953, Palaeontographica A, V103, P377; KOFOID C.A., 1906, U CALIFORNIA PUBLICA, V2, P341; LENTIN JK, 1976, OCT JOINT M AM ASS S; NIELSEN ES, 1934, DANA REP           4, V1; PETERS N, 1932, WISS ERGEBN DTSCH AT, V11, P1; Reid P.C., 1974, Nova Hedwigia, V25, P579; REID PC, 1975, NEW PHYTOL, V75, P589, DOI 10.1111/j.1469-8137.1975.tb01425.x; ROSSIGNOL MARTINE, 1962, POLLEN SPORES, V4, P121; Scull B. J., 1966, Transactions of the Gulf Coast Association of Geological Societies, V16, P81; WALL D, 1969, J PHYCOL, V5, P140, DOI 10.1111/j.1529-8817.1969.tb02595.x; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; WALL D, 1970, Micropaleontology (New York), V16, P47, DOI 10.2307/1484846; Weissell J.K., 1972, Antarctic Oceanology II, the Australian New Zealand sector, American Geophysical Union Antarctic Research Series, V19, P165; WILLIAMS D.B., 1971, MICROPALAEONTOLOGY O; Williams G.L., 1975, GEOL SURV CAN PAP, V2, P107, DOI DOI 10.4095/102513; WILLIAMS GL, 1977, OCEANIC MICROPALAEON	26	23	29	0	2	ELSEVIER SCIENCE BV	AMSTERDAM	PO BOX 211, 1000 AE AMSTERDAM, NETHERLANDS	0377-8398	1872-6186		MAR MICROPALEONTOL	Mar. Micropaleontol.		1977	2	3					223	233		10.1016/0377-8398(77)90012-3	http://dx.doi.org/10.1016/0377-8398(77)90012-3			11	Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Paleontology	DV948					2025-03-11	WOS:A1977DV94800002
J	GREUET, C				GREUET, C			STRUCTURAL AND ULTRASTRUCTURAL EVOLUTION OF OCELLOID OF ERYTHROPSIDINIUM-PAVILLARDI-KOFOID-AND-SWEZY (DINOFLAGELLATE WARNOWIIDAE, LINDEMANN) DURING DIVISION AND PALINTOMIC DIVISIONS	PROTISTOLOGICA			French	Article								The division of the ocelloid takes place before the division of the protist. The 2 constitutive parts of the ocelloid, the hyalosome and the melanosome, have an independent evolution; while this evolution is on, they are always conspicuous. The different flattened layers of the crystalline lens of the hyalosome give progressively way to 2 equal sets of hyaline globules, each of them also giving 2 new sets. They finally produce a new crystalline lens by flattening their different parts and coapting each of them. This new crystalline lens is completed by addition of different cornean layers. The melanosome then migrates towards the division site. Its shape is no more regular and many digitations are formed. This dedifferentiated organelle, limited by 2 membranes, containing pigmented globules and vesicles which could correspond to thylakoides, could then be considered as a plaste. The plastidial nature cannot be recognized during the resting stage. This organelle divides exactly as a protophyte plaste. While being reorganized, the thylakoides are coupled and the common wall being formed by the 2 previous membranes shows the characteristic ondulation described before. After the division the melanosome retracts its digitations while the pigmented globules go deeply in the retina and in the pigmented ring encircling the hyalosome. Once the hyalosome and the melanosome are put together, an ocella camera is formed. Then the new organelle is completely constituted. When the palintomic divisions appear, it is in relation with sudden vanishing of the ocella. At the end of the evolution, the melanosome still shows that same structure as the protoplastes; the crystalline lens is no more conspicuous. Its disappearance and return indicate that it could have an endoplasmic origin.	FAC SCI & TECH NICE, BIOL ANIM & CYTOL LAB, ZOOL STN, VILLEFRANCHE SUR MER, FRANCE									DODGE J D, 1969, British Phycological Journal, V4, P199; Dodge J. D., 1973, FINE STRUCTURE ALGAL; DODGE JD, 1969, J CELL SCI, V5, P479; EAKIN RM, 1972, HDB SENSORY PHYSIOLO, V7, P1; EAKIN RM, 1963, GENERAL PHYSIOLOGY C; Fauré-Fremiet, 1913, CR HEBD ACAD SCI, V157, P1019; Faure-Fremiet E., 1914, Archiv fuer Protistenkunde Jena, V35; FRANCIS D, 1967, J EXP BIOL, V47, P495; Greuet C., 1968, Protistologica, V4, P209; Greuet C., 1968, Protistologica, V4, P419; GREUET C, 1965, CR HEBD ACAD SCI, V261, P1904; GREUET C, 1970, 7 P INT C EM GREN, P385; GREUET C, 1969, PROTISTOLOGICA, V5, P431; GREUET C, 1969, THESIS; HERTWIG R, 1884, MORPH JAHR, V10, P204; KOFOID CA, 1921, MEMOIRE U CALIFORNIA, V5; LEADBEATER B., 1966, BRIT PHYCOL BULL, V3, P1; LEEDALE GF, 1965, ARCH MIKROBIOL, V50, P68, DOI 10.1007/BF00439788; LINDEMAN E, 1928, NATURLICHEN PFLANZEN; LOEBLICH AR, 1960, STUD TROP OCEANOGR, V3, P1; MORNIN L, 1967, J MICROBIOL, V6, P750; Pouchet G., 1885, J LANATOMIE PHYSIOL, V21, P525; POUCHET G, 1886, CR SEANC SOC BIOL, V3, P223; Pouchet G., 1885, J ANAT PHYSL, V21, P28; POUCHET G, 1886, CR HEBD ACAD SCI, V103, P801; POUCHET G, 1887, CR HEBD ACAD SCI, V23, P87; SCHILLER J, 1935, RABENHORST KRYPTOGAM; SILVA PAUL C., 1960, TAXON, V9, P18, DOI 10.2307/1217351; VOGT C, 1885, ZOOL ANZ, V8, P153	29	12	12	1	6	EDITIONS C N R S	PARIS	20/22 RUE ST. AMAND, 75015 PARIS, FRANCE	0033-1821			PROTISTOLOGICA			1977	13	1					127	143						17	Microbiology	Science Citation Index Expanded (SCI-EXPANDED)	Microbiology	DM737					2025-03-11	WOS:A1977DM73700012
J	DALE, B				DALE, B			CYSTS OF TOXIC RED-TIDE DINOFLAGELLATE GONYAULAX-EXCAVATA (BRAARUD) BALECH FROM OSLOFJORDEN, NORWAY	SARSIA			English	Article								G. excavata was cultured from resting cysts isolated from bottom sediments in Oslofjorden, the type locality. Resting cysts were elongate-ovoid with thick smooth walls surrounded by gelatinous material incorporating detritus; contents typically included starch grains, oil globules and a conspicuous red-pigmented body. A resting period seems to be mandatory, and cysts are suggested to act as seed beds for some toxic blooms [shell fish poisoning]. Other non-motile cells (temporary cysts) were formed in cultures, cooled from 15.degree. C to less than 5.degree. C. These had thinner walls and lacked gelatinous cover and typical cell contents of resting cysts. They quickly reestablished motile cells when returned to 15.degree. C. Cultured motile cells were toxic to mice, bioluminescent and consistently lacking ventral pores, in accordance with recent suggestions that these are specific criteria. Resting cyst morphology suggests a possible systematic relationship between G. excavata and Pyrophacus horologium.	UNIV OSLO, INST MARINBIOL & LIMOL, AVD MARIN BOT, OSLO, NORWAY	University of Oslo								BALECH E, 1959, BIOL BULL-US, V116, P195, DOI 10.2307/1539204; Braarud T, 1945, AVH NORSKE VIDENSK A, V11, P1; BRAARUD  T, 1950, NATUREN, P33; DALE B, 1976, REV PALAEOBOT PALYNO, V22, P39, DOI 10.1016/0034-6667(76)90010-5; Eppley R.W., 1967, J EXP MAR BIOL ECOL, V1, P191; GRAN HH, 1935, J BIOL BD CAN, V1, P280; LOEBLICH LA, 1975, 1ST P INT C TOX DIN, P207; PRAKASH A, 1967, J FISH RES BOARD CAN, V24, P1589, DOI 10.1139/f67-131; SAKSHAUG E, 1971, K NORSKE VIDENSK SEL, V15, P1; Sommer H, 1937, ARCH PATHOL, V24, P537; STEIDINGER K A, 1971, Phycologia, V10, P183, DOI 10.2216/i0031-8884-10-2-183.1; STEIDINGER KA, 1975, ENVIRON LETT, V9, P129, DOI 10.1080/00139307509435842; STEIDINGER KA, 1975, 1ST P INT C TOX DIN, P153; TAYLOR FJR, 1975, ENVIRON LETT, V9, P103, DOI 10.1080/00139307509435840; VONSTOSCH HA, 1969, HELGOLAND WISS MEER, V19, P569; WALL D, 1969, J PHYCOL, V5, P140, DOI 10.1111/j.1529-8817.1969.tb02595.x; WALL D, 1971, J PHYCOL, V7, P221, DOI 10.1111/j.1529-8817.1971.tb01507.x; WALL D, 1975, 1ST P INT C TOX DIN, P249; WALL D, 1975, P FORUM DINOFLAGELLA, P37; WALL D., 1967, PHYCOLOGIA, V6, P83; Woloszynska J., 1939, Bull Mus Hist nat Belg, V15, P1	21	91	95	0	6	TAYLOR & FRANCIS AS	OSLO	KARL JOHANS GATE 5, NO-0154 OSLO, NORWAY	0036-4827			SARSIA	Sarsia		1977	63	1					29	34		10.1080/00364827.1977.10411318	http://dx.doi.org/10.1080/00364827.1977.10411318			6	Ecology; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Environmental Sciences & Ecology; Marine & Freshwater Biology	DX546					2025-03-11	WOS:A1977DX54600005
J	TAPPAN, H; LOEBLICH, AR				TAPPAN, H; LOEBLICH, AR			PERIDINIALEAN CYST AFFINITY, RATHER THAN GYMNODINIALEAN MOTILE STAGE, OF LATE CRETACEOUS DINOFLAGELLATE DINOGYMNIUM	TRANSACTIONS OF THE AMERICAN MICROSCOPICAL SOCIETY			English	Article								Morphological comparison of fossil Dinogymnium to motile cells and cysts of living representatives of the orders Gymnodiniales and Peridiniales suggests an affinity with the modern family Lophodiniaceae (Peridiniales). The thick, acid-resistant, highly punctate to perforated wall resembles the exospore layer of the resting zygote cyst of Woloszynskia and probably of Lophodinium. The meridional ridges of some Dinogymnium, interrupted only by the median cingulum, are similar to features of Lophodinium. The archeopyle of Dinogymnium develops at the time of excystment. The rarely present flagellar pores result from the late retention of the flagella by the planozygote, prior to completion of the thick cellulosic endospore layer of the wall of the later hypnozygote stage. Within the perforated exospore, this thicker endospore layer protects the pre-meiotic zygote, although the cellulosic composition precludes its preservation. Other than the endoskeletal Actiniscaceae, all fossil dinoflagellates thus appear to represent cysts, and from analogy with modern species, probably all are hypnozygotes.	UNIV CALIF LOS ANGELES, DEPT GEOL, LOS ANGELES, CA 90024 USA; STANDARD OIL CALIF, CHEVRON OIL FIELD RES CO, LA HABRA, CA 90631 USA									Bibby B.T., 1972, British phycol J, V7, P85; Cookson I. C., 1965, Proceedings of the Royal Society of Victoria, V79, P139; Cookson I. C., 1958, Proceedings of the Royal Society of Victoria N S, V70, P19; DADAY EV, 1905, ZOOLOGICA STUTTGART, V18; Deflandre G., 1936, Annales de paleontologie, V25, P151; Dodge J. D., 1968, Protistologica, V4, P231; DODGE JD, 1969, NEW PHYTOL, V68, P613, DOI 10.1111/j.1469-8137.1969.tb06465.x; Eisenack A., 1954, Palaeontographica A, V105, P49; EVITT W R, 1967, Review of Palaeobotany and Palynology, V2, P355, DOI 10.1016/0034-6667(67)90166-2; Evitt W.R., 1967, STANFORD U PUBIS GEO, V10, P1; Gocht H., 1967, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V128, P195; Gocht H., 1970, PALAEONTOGRAPHICA B, V129, P125; KOFOID CA, 1921, 5 U CAL MEM; LEADBEATER B., 1966, BRIT PHYCOL BULL, V3, P1; LOEBLICH AR, 1970, 1969 P N AM PAL CO G, P867; MAY FE, 1976, SCIENCE, V193, P1128, DOI 10.1126/science.193.4258.1128; oSoRIo-TAFALL B. F., 1942, CIENCIA REV HISPANOA, V3, P114; PARKE M, 1976, J MAR BIOL ASSOC UK, V56, P527, DOI 10.1017/S002531540002066X; SCHILLER J, 1932, KRYPTOGAMEN FLORA DE, V10, P257; Stosch H.A. von., 1973, British phycol J, V8, P105; Thompson R.H., 1951, Lloydia, V13, P277; Thompson RH, 1947, CHESAPEAKE BIOL LAB, V67, P3; Woloszynska J., 1917, Bulletin International de lAcademie des Sciences de Cracovie, Classe des Sciences Mathematiques et Naturelles, serie B: Sciences Naturelles, V1917, P114	23	3	3	0	0	AMER MICROSCOPICAL SOC	LAWRENCE	810 EAST 10TH ST, LAWRENCE, KS 66044-8897 USA	0003-0023			T AM MICROSC SOC			1977	96	4					497	505		10.2307/3225668	http://dx.doi.org/10.2307/3225668			9	Microscopy	Science Citation Index Expanded (SCI-EXPANDED)	Microscopy	DZ283					2025-03-11	WOS:A1977DZ28300008
J	KAYSER, H				KAYSER, H			WASTEWATER ASSAY WITH CONTINUOUS ALGAL CULTURES - EFFECT OF MERCURIC ACETATE ON GROWTH OF SOME MARINE DINOFLAGELLATES	MARINE BIOLOGY			English	Article								The effect of mercuric acetate was studied in culture experiments with the dinoflagellates Scrippsiella faeroense (Paulsen) Balech et Soares, Prorocentrum micans Ehrenberg and Gymnodinium splendens Lebour. Impairment of growth rates, in vivo chlorophyll fluorescence, maximum cell densities and morphological changes served as criteria for assessing sublethal influences. Tests were made using the batch and continuous culture techniques. Addition of Hg at concentrations of 0.001 mg.1-1 and higher resulted in reduction of relative growth rates. In a few cases populations recovered from the initial decline and showed new growth. Cell counts corresponded very closely to in vivo chlorophyll fluorescence measurements. Morphological variations were observed in S. faeroense, which responded (even in sublethal concentrations) by bursting its thecae, releasing naked motile cells and forming vegetative resting stages. The problems of optimal algal-bioassay methods are discussed.	BIOL ANSTALT HELGOLAND, D-2282 LIST, FED REP GER	Helmholtz Association; Alfred Wegener Institute, Helmholtz Centre for Polar & Marine Research								Balech E., 1966, NEOTROPICA, V12, P103; BENBASSAT D, 1972, NATURE, V240, P43, DOI 10.1038/240043a0; BLASCO D, 1973, INVEST PESQ, V37, P533; Boltovskoy A., 1973, Revista Esp Micropaleont, V5, P81; BRAARUD T., 1958, NYTT MAG BOT, V6, P39; DAVIES AG, 1974, J MAR BIOL ASSOC UK, V54, P157, DOI 10.1017/S002531540002213X; Fisher NS, 1974, MICROB ECOL, V1, P39, DOI 10.1007/BF02512378; HANNAN PJ, 1972, BIOTECHNOL BIOENG, V14, P93, DOI 10.1002/bit.260140109; HANNAN PJ, 1973, NRL7628 REP, P1; HARRISS RC, 1970, SCIENCE, V170, P736, DOI 10.1126/science.170.3959.736; JENSEN A, 1974, J EXP MAR BIOL ECOL, V15, P145, DOI 10.1016/0022-0981(74)90040-9; KAYSER H, 1970, HELGOLAND WISS MEER, V20, P195, DOI 10.1007/BF01609899; KAYSER H, 1973, HELGOLAND WISS MEER, V25, P357, DOI 10.1007/BF01611204; KAYSER H, 1971, Thalassia Jugoslavica, V7, P139; KAYSER H, 1969, HELGOLAND WISS MEER, V19, P21, DOI 10.1007/BF01625857; KNAUER GA, 1972, LIMNOL OCEANOGR, V17, P868, DOI 10.4319/lo.1972.17.6.0868; MAGOS L, 1964, BRIT J IND MED, V21, P294; MATIDA Y, 1971, Bulletin of Freshwater Fisheries Research Laboratory (Tokyo), V21, P197; NUZZI R, 1972, NATURE, V237, P38, DOI 10.1038/237038a0; SOUSAESILVA E, 1962, NOTAS ESTUD I BIOL M, V26, P1; Stosch H.A. von., 1973, British phycol J, V8, P105	21	39	39	0	2	SPRINGER HEIDELBERG	HEIDELBERG	TIERGARTENSTRASSE 17, D-69121 HEIDELBERG, GERMANY	0025-3162	1432-1793		MAR BIOL	Mar. Biol.		1976	36	1					61	72		10.1007/BF00388429	http://dx.doi.org/10.1007/BF00388429			12	Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Marine & Freshwater Biology	BT324					2025-03-11	WOS:A1976BT32400009
J	WILSON, GJ				WILSON, GJ			LATE CRETACEOUS (SENONIAN) DINOFLAGELLATE CYSTS FROM KAHUITARA TUFF, CHATHAM ISLANDS	NEW ZEALAND JOURNAL OF GEOLOGY AND GEOPHYSICS			English	Note								A sparse, well-preserved assemblage, dominated by Deflandrea [including D. cf. acutula, D. cf. echinoidea, D. minor, D. serratula, D. cf. tripartita, D. cf. victoriensis, Exochosphaeridium sp., Horologinella apiculata, Oligosphaeridium complex, Spiniferites cingulatus, Chlamydophorella cf. discreta, Chlamydophorella cf. discreta, Chytroeisphaeridia sp., Cyclonephelium distinctum] indicates that the Kahuitara Tuff is Senonian. This is a significantly younger age than that determined previously from the associated macrofauna.	NEW ZEALAND GEOL SURVEY, LOWER HUTT, NEW ZEALAND				Wilson, Graeme/R-1037-2019					BOREHAM ANNE U. E., 1959, TRANS ROY SOC NEW ZEALAND, V86, P119; HAY RF, 1970, 83 NZ GEOL SURV B; MILDENHALL DC, 1976, NEW ZEAL J GEOL GEOP, V19, P121, DOI 10.1080/00288306.1976.10423552; SARJEANT W A S, 1967, Review of Palaeobotany and Palynology, V1, P323, DOI 10.1016/0034-6667(67)90132-7; WILSON GJ, 1972, NEW ZEAL J GEOL GEOP, V15, P184, DOI 10.1080/00288306.1972.10423961; Wilson GJ., 1974, THESIS U NOTTINGHAM; WILSON GJ, UNPUBLISHED REPORT; WILSON GRAEME J., 1967, N Z J BOT, V5, P223	8	13	13	0	0	TAYLOR & FRANCIS LTD	ABINGDON	2-4 PARK SQUARE, MILTON PARK, ABINGDON OR14 4RN, OXON, ENGLAND	0028-8306	1175-8791		NEW ZEAL J GEOL GEOP	N. Z. J. Geol. Geophys.		1976	19	1					127	130		10.1080/00288306.1976.10423553	http://dx.doi.org/10.1080/00288306.1976.10423553			4	Geology; Geosciences, Multidisciplinary	Science Citation Index Expanded (SCI-EXPANDED)	Geology	BS934					2025-03-11	WOS:A1976BS93400008
J	BRADFORD, MR				BRADFORD, MR			NEW DINOFLAGELLATE CYST GENERA FROM RECENT SEDIMENTS OF PERSIAN GULF	CANADIAN JOURNAL OF BOTANY-REVUE CANADIENNE DE BOTANIQUE			English	Article									UNIV SASKATCHEWAN,DEPT GEOL SCI,SASKATOON S7N 0W0,SASKATCHEWAN,CANADA	University of Saskatchewan								ABE TH, 1927, SCI REP TOHOKU U, V2, P1; BRADFORD MR, 1973, 9TH INQUA C NEW ZEAL, P40; Drugg W.S., 1967, Tulane Studies in Geology, V5, P181; Gran HH, 1900, REP NORWEG FISH INVE, V1, P1; HARADA K, 1974, THESIS U KYOTO, P1; HARLAND R, 1973, SUPERFICIAL DEPOSITS, P1; HUGHES CLARKE M. W., 1973, PERSIAN GULF, P33; LOEBLICH AR, 1970, 1969 P N AM PAL CO G, P867; MEUNIER A., 1919, MDMOIRES MUSEE DHIST, V8, P1; NIE D, 1939, KOHSUEH, V23, P584; Ostenfeld C.H., 1902, VIDENSKABELIGE MEDDE, V6, P141; Paulsen O., 1904, MEDD KOMM HAVUNDERS, V1, P1; Plate Ludwig, 1906, Archiv fuer Protistenkunde Jena, V7, P411; Purser B.H., 1973, PERSIAN GULF, P1; Reid P.C., 1974, Nova Hedwigia, V25, P579; REID PC, 1972, THESIS U SHEFFIELD, P1; ROSSIGNOL MARTINE, 1962, POLLEN SPORES, V4, P121; Sarjeant W.A.S., 1974, P1; SARJEANT WAS, 1974, 3 BIRB SAHN I PAL SP, P9; WALL D, 1969, J PHYCOL, V5, P140, DOI 10.1111/j.1529-8817.1969.tb02595.x; Wall D., 1965, Grana Palynologica, V6, P297; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; WALL D, 1971, J PHYCOL, V7, P221, DOI 10.1111/j.1529-8817.1971.tb01507.x; WALL D., 1967, PALAEONTOLOGY, V10, P95; WILLIAMS GL, 1973, AM ASSOC STRAT PALYN, P1	25	46	50	0	3	NATL RESEARCH COUNCIL CANADA	OTTAWA	RESEARCH JOURNALS, MONTREAL RD, OTTAWA ON K1A 0R6, CANADA	0008-4026			CAN J BOT	Can. J. Bot.-Rev. Can. Bot.		1975	53	24					3064	&		10.1139/b75-335	http://dx.doi.org/10.1139/b75-335			0	Plant Sciences	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences	BH372					2025-03-11	WOS:A1975BH37200018
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Palaeobot. Palynology		1975	20	4					217	315		10.1016/0034-6667(75)90013-5	http://dx.doi.org/10.1016/0034-6667(75)90013-5			99	Plant Sciences; Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Paleontology	AZ360					2025-03-11	WOS:A1975AZ36000001
J	REID, PC				REID, PC			DINOFLAGELLATE CYST DISTRIBUTION AROUND BRITISH-ISLES	JOURNAL OF THE MARINE BIOLOGICAL ASSOCIATION OF THE UNITED KINGDOM			English	Article																		[Anonymous], TIERWELT NORD UND OS; KOFOID C.A., 1911, U CALIFORNIA PUBLICA, V8, P187; LEBOUR MV, 1925, DINOFLAGELLATES NORT; MARGALEF RAMON, 1956, INVEST PESQ, V5, P113; NEVES R, 1968, NATURE, V198, P775; Nordli E., 1951, Nyt Magazin for Naturvidenskaberne, V88, P207; REINECKE PANDORA, 1967, J S AFR BOT, V33, P157; Rossignol M., 1961, Pollens et Spores, V3, P303; Wall D., 1965, Grana Palynologica, V6, P297; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; WILLIAMS D.B., 1971, MICROPALAEONTOLOGY O; Williams D.B., 1967, MAR GEOL, V5, P389; WILLIAMSON D. I., 1956, BULL MARINE ECOL, V4, P87	13	50	52	0	2	CAMBRIDGE UNIV PRESS	NEW YORK	40 WEST 20TH STREET, NEW YORK, NY 10011-4211	0025-3154			J MAR BIOL ASSOC UK	J. Mar. Biol. Assoc. U.K.		1972	52	2					939	&		10.1017/S0025315400040674	http://dx.doi.org/10.1017/S0025315400040674			0	Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Marine & Freshwater Biology	O1344					2025-03-11	WOS:A1972O134400013
J	NORRIS, G; MCANDREWS, JH				NORRIS, G; MCANDREWS, JH			DINOFLAGELLATE CYSTS FROM POST-GLACIAL LAKE MUDS, MINNESOTA (USA)	REVIEW OF PALAEOBOTANY AND PALYNOLOGY			English	Article																		[Anonymous], PALAEONTOLOGY; Chatton E., 1952, TRAITE ZOOL, P309; CHURCHILL DM, 1963, GRANA PALYNOL, V3, P29; COOKSON ISABEL C., 1960, MICROPALEONTOLOGY, V6, P1, DOI 10.2307/1484313; Cross A.T., 1966, MAR GEOL, V4, P467, DOI [10.1016/0025-3227(66)90012-0, DOI 10.1016/0025-3227(66)90012-0]; Davey RJ., 1966, B BR MUS NAT HIST S, V3, P1; DOWNIE C, 1964, GEOL SOC AM MEM, V94, P1; EDDY SAMUEL, 1930, TRANS AMER MICROSC SOC, V49, P277, DOI 10.2307/3222160; EISENACK A, 1965, GEOL FOREN STOCKHOLM, V87, P239; Evitt W. R., 1961, Micropaleontology, V7, P385, DOI 10.2307/1484378; Evitt W.R., 1968, STANFORD U PUBL   GS, V10, P1; Evitt W.R., 1967, STANFORD U PUBIS GEO, V10, P1; EVITT WR, 1964, STANFORD U PUBL   GS, V9, P1; FRIES MAGNUS, 1962, ECOLOGY, V43, P295, DOI 10.2307/1931985; FRITSCH FE, 1956, STRUCTURE REPRODUCTI; FUNKHOUSER JOHN W., 1959, MICROPALEONTOLOGY, V5, P369, DOI 10.2307/1484431; HUBER-PESTALOZZI G., 1950, BINNENGEWASSER, V16, P1; JEFFORDS RM, 1959, J PALEONTOL, V33, P344; Krutzsch W, 1962, HALLESCHES JB MITTEL, V4, P40; Manum S., 1964, Skrifter utgitt av det Norske Videnskapsakademi Mat Nat Kl NS, VNo. 17, P1; McAndrews J., 1966, TORREY BOT CLUB MEMO, V22, P1; McKee E. D., 1959, Bulletin of the American Association of Petroleum Geologists, V43, P501; MULLER JAN, 1959, MICROPALEONTOLOGY, V5, P1, DOI 10.2307/1484153; PRESCOTT GW, 1962, ALGAE WESTERN GREAT; Rossignol M., 1964, Revue de Micropaleontologie, V7, P83; ROSSIGNOL MARTINE, 1962, POLLEN SPORES, V4, P121; SCHILLER J, 1933, KRYPTOGAMENFLORA DEU, V1; SCHILLER J, KRYPTOGAMENFLORA DEU, V2; Tschudy R.H., 1961, 16th Annual Field Conference Guidebook, Symposium on Late Cretaceous Rocks, Wyoming and Adjacent Areas, P53; WALL D, 1967, Review of Palaeobotany and Palynology, V2, P349, DOI 10.1016/0034-6667(67)90165-0; Wall D., 1965, Grana Palynologica, V6, P297; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; WALL D., 1967, PALAEONTOLOGY, V10, P95; Williams D.B., 1967, MAR GEOL, V5, P389	34	23	25	0	1	ELSEVIER SCIENCE BV	AMSTERDAM	PO BOX 211, 1000 AE AMSTERDAM, NETHERLANDS	0034-6667	1879-0615		REV PALAEOBOT PALYNO	Rev. Palaeobot. Palynology		1970	10	2					131	+		10.1016/0034-6667(70)90016-3	http://dx.doi.org/10.1016/0034-6667(70)90016-3			1	Plant Sciences; Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Paleontology	H3554					2025-03-11	WOS:A1970H355400004
J	WALL, D; DALE, B				WALL, D; DALE, B			HYSTRICHOSPHAERID RESTING SPORE OF DINOFLAGELLATE PYRODINIUM BAHAMENSE, PLATE, 1906	JOURNAL OF PHYCOLOGY			English	Article																		BOHM ANTON, 1931, ARCH PROTISTENK, V74, P188; Cookson I.C., 1967, Proceeding of the Royal Society of Victoria, V80, P131; DAVEY RJ, 1966, B BRIT MUSEUM  S3 ED, P10; DAVEY RJ, 1966, B BRIT MUS NAT HI S3, P53; DEGENS ET, 1969, HOT BRINES RECENT ED; DOWNIE C, 1964, 94 GEOL SOC AM MEM; Downie C., 1966, B SUPPLEMENT BRIT MU, P10; Drugg W.S., 1967, Tulane Studies in Geology, V5, P181; ENGLER A, 1928, NATURLICHEN PFLAN ED, V2, P1; ENTZ GEZA, 1926, ARCH PROTISTENK, V56, P397; EVITT WR, 1968, STANFORD U PUBL U GS, V12; EVITT WR, 1964, STANFORD U PUBL U GS, V10; EVITT WR, 1967, STANFORD U PUBL U GS, V10; Huber G., 1922, Z BOTANIK, V14, P337; Huber G., 1923, FLORA JENA, V116, P114; LANG A, 1965, ENCYCLOPEDIA PL 2 ED, V15, P933; Lindemann E., 1929, Archiv fuer Protistenkunde Jena, V68, P1; Lindemann E., 1928, NATURLICHEN PFLANZEN, P1; Margalef R., 1957, Invest. Pesq, V6, P39; MARGALEF RAMON, 1961, INVEST PESQUERA, V18, P33; Plate Ludwig, 1906, Archiv fuer Protistenkunde Jena, V7, P411; Rossignol M., 1964, Revue de Micropaleontologie, V7, P83; ROSSIGNOL M, 1961, POLLEN SPORES, V4, P121; STARR RC, 1955, AM J BOT, V42, P577, DOI 10.2307/2485314; Sussman A., 1965, ENCYCL PLANT PHYSIOL, P931; Sussman AS., 1966, SPORES THEIR DORMANC; TAFALL O, 1942, ANLES ESC NAC CIENC, V2, P435; WALL D, 1968, Journal of Paleontology, V42, P1395; WALL D, 1968, Micropaleontology (New York), V14, P265, DOI 10.2307/1484690; WALL D., 1967, PALAEONTOLOGY, V10, P95; WALL D, 1969, HOT BRINES RECENT HE; WALL D., 1967, PHYCOLOGIA, V6, P83	32	65	71	1	7	PHYCOLOGICAL SOC AMER INC	LAWRENCE	810 EAST 10TH ST, LAWRENCE, KS 66044	0022-3646			J PHYCOL	J. Phycol.		1969	5	2					140	&		10.1111/j.1529-8817.1969.tb02595.x	http://dx.doi.org/10.1111/j.1529-8817.1969.tb02595.x			0	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	D5793	27096245				2025-03-11	WOS:A1969D579300011
J	SARJEANT, WA; ANDERSON, RY				SARJEANT, WA; ANDERSON, RY			A RE-EXAMINATION OF SOME DINOFLAGELLATE CYSTS FROM UPPERMOST LEWIS SHALE (LATE CRETACEOUS), NEW-MEXICO (USA)	REVIEW OF PALAEOBOTANY AND PALYNOLOGY			English	Article																		Alberti G., 1959, Mitteilungen aus dem Geologischen Staatsinstitut in Hamburg, V28, P93; ANDERSON RY, 1960, NEW MEXICO BUREAU MI, V6, P1; BALTZ EH, 1966, 524D US GEOL SURV PR; COBBAN WA, 1952, B GEOL SOC AM, V63, P1011; Cookson I. C., 1962, Micropaleontology, V8, P485, DOI 10.2307/1484681; COOKSON ISABEL C., 1960, MICROPALEONTOLOGY, V6, P1, DOI 10.2307/1484313; Davey R.J., 1966, STUDIES MESOZOIC CAI, P28; DEFLANDRE G, 1965, FICHIER MICRO PAL 14, V407; DRUGG W.S., 1967, PALAEONTOGRAPHICA B, V120, P1; EHRENBERG CG, 1838, ABH AKAD WISS BERL P, P109; Eisenack A., 1958, Neues Jahrbuch fuer Geologie und Palaeontologie Abhandlungen, V106, P383; Gocht H., 1960, NEUES JB GEOLOGIE PA, P511; MANTELL GA, 1954, MEDALS CREATION 1 LE; SARJEANT WAS, IN PRESS; SARJEANT WAS, 1967, GRANA PALYNOLOGICA, V7, P242; SARJEANT WILLIAM ANTONY S., 1966, GRANA PALYNOL, V6, P503; Sarmiento R., 1957, Bulletin of the American Association of Petroleum Geologists, V41, P1683; Valensi L, 1955, BULL SOC PREHIST FR, V52, P584, DOI 10.3406/bspf.1955.3263; Vozzhennikova T. F., 1960, Trudy Instituta Geologii i Geofiziki Sibirskoe Otdelenie Novosibirsk, V1, P7; Williams D.B., 1966, STUDIES MESOZOIC CAI, P215, DOI DOI 10.1080/0028825X.1967.10428735	20	1	1	0	1	ELSEVIER SCIENCE BV	AMSTERDAM	PO BOX 211, 1000 AE AMSTERDAM, NETHERLANDS	0034-6667			REV PALAEOBOT PALYNO	Rev. Palaeobot. Palynology		1969	9	3-4					229	&		10.1016/0034-6667(69)90006-2	http://dx.doi.org/10.1016/0034-6667(69)90006-2			0	Plant Sciences; Paleontology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Paleontology	H1388					2025-03-11	WOS:A1969H138800006
J	SWIFT, E; TAYLOR, WR				SWIFT, E; TAYLOR, WR			BIOLUMINESCENCE AND CHLOROPLAST MOVEMENT IN DINOFLAGELLATE PYROCYSTIS LUNULA	JOURNAL OF PHYCOLOGY			English	Article								The lunate cysts of Pyrocystis lunula have a bioluminescent emission spectrum with a peak intensity of 477.5 [plus or minus] 1 m[mu]. The light originates from the protoplasm in the center of the cysts. Six to eight hr after the cysts were placed in the dark, they produced 300 to 800 times more luminescence than controls maintained under constant illumination. Plastids contract distally when the cysts are placed in the dark. If kept in the dark, the plastids contract dlstally and expand with a clrcadlan rhythm persisting several days. At intensities of 2200 [mu]w cm-2 or less, the plastlds are expanded. The plastlds are contracted into the central area of the cysts at light intensities of 4000 [mu]w cm-2 and above. The Gymnodinium stage of the life cycle is not blolumlnescent.										BERNIER CJ, 1962, 48 NATL TECH C ILL S; BIGGLEY WH, IN PRESS; BLACKMAN VH, 1902, NEW PHYTOL, V2, P178; BODE VC, 1963, ARCH BIOCHEM BIOPHYS, V103, P488, DOI 10.1016/0003-9861(63)90442-9; COWPERTHWAITE J, 1953, ANN NY ACAD SCI, V56, P972, DOI 10.1111/j.1749-6632.1953.tb30277.x; GIESE AC, 1964, PHOTOPHYSIOLOGY   ED, V1, P333; HASTINGS JW, 1957, J CELL COMPAR PHYSL, V49, P209, DOI 10.1002/jcp.1030490205; HASTINGS JW, 1964, PHOTOPHYSIOLOGY, V1, P333; HAUPT W, 1962, PHYSIOLOGY BIOCHEMIS, P567; HOPKINS JT, 1966, J MAR BIOL ASSOC UK, V46, P617, DOI 10.1017/S0025315400033373; KELLY MG, 1966, BIOL BULL-US, V131, P115, DOI 10.2307/1539652; Kofoid C.A., 1921, MEM U CALIF, V5, P538; LEWIN RA, 1962, PHYSIOLOGY BIOCHE ED, P567; MURRAY J, 1876, P ROY SOC LONDON, V24, P471; NICOL JA, 1960, BIOLOGY MARINE ANIMA; PALMER JD, 1964, NATURE, V203, P1087, DOI 10.1038/2031087a0; POVASOLI L, 1957, ARCHIV MIKROBIOL, V25, P392; SELIGER HH, 1962, J GEN PHYSIOL, V45, P1013; SELIGER HH, 1964, J GEN PHYSIOL, V48, P94; SELIGER HH, 1965, LIGHT PHYSICAL BIOLO; SOLI G, 1966, LIMNOL OCEANOGR, V11, P355, DOI 10.4319/lo.1966.11.3.0335; SWEENEY BM, 1959, J GEN PHYSIOL, V43, P285, DOI 10.1085/jgp.43.2.285; SWEENEY BM, 1957, J CELL COMPAR PHYSL, V49, P115, DOI 10.1002/jcp.1030490107; TAYLOR WR, 1966, J MAR RES, V24, P28	24	41	41	0	3	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0022-3646	1529-8817		J PHYCOL	J. Phycol.		1967	3	2					77	+		10.1111/j.1529-8817.1967.tb04634.x	http://dx.doi.org/10.1111/j.1529-8817.1967.tb04634.x			1	Plant Sciences; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Marine & Freshwater Biology	96927	27064806				2025-03-11	WOS:A19679692700004
J	BOUCK, GB; SWEENEY, BM				BOUCK, GB; SWEENEY, BM			FINE STRUCTURE AND ONTOGENY OF TRICHOCYSTS IN MARINE DINOFLAGELLATES	PROTOPLASMA			English	Article								Long, rigid, rod-like structures found in the culture medium of several marine dinoflagellates are shown in this report to have fine transverse bandings characteristic of extruded trichocysts. These structures in genera such as Gonyaulax are believed to pass through the heavily plated surface via narrow pores. In the resting or "charged" form, trichocysts are found to have an elaborate crystalline core connected by a series of fibers and still finer fibrils to the apex of an enclosing sac. The walls of this sac consist of a single membrane and fine thread-like hoops or spirals. The design of the whole charged trichocysts is suggestive of a mechanical sensing device. Trichocysts are found to originate in membrane-limited vesicles which are localized within a spherical shell composed of Golgi bodies. Initially these vesicles contain homogeneous materials, but with increasing development a crystal lattice appears and ultimately the resting trichocyst core evolves. At this point the trichocyst leaves the Golgi area and migrates elsewhere in the cytoplasm. The charged trichocyst core is found to be water- but not acetone-soluble in contrast to the discharged trichocyst which is unaffected by either solvent. These facts together with the finding of shafts apparently polymerizing from amorphous contents are interpreted as supporting the hydration theory of trichocyst discharge. Finally, the striking similarities between the origin and structure of extruded trichocyst shafts and the origin and structure of collagen fibers are discussed briefly.										AFZELIUS BA, 1964, 3RD EUR REG C EL MIC, P175; BURSA ADAM, 1959, CANADIAN JOUR BOT, V37, P1; Cheissin E. M., 1962, Archiv fuer Protistenkunde, V106, P181; DRAGESCO J, 1965, CR HEBD ACAD SCI, V260, P2073; DRAGESCO JEAN, 1952, BULL MICROSCOPIE APPLIQUEE, V2, P148; EHRET C, 1964, Z ZELLFORSCH, V64, P124; GRELL KG, 1957, SP Z ZELLFORSCH, V47, P7; HODGE AJ, 1960, P NATL ACAD SCI USA, V46, P186, DOI 10.1073/pnas.46.2.186; JAKUS MA, 1945, J EXP ZOOL, V100, P457, DOI 10.1002/jez.1401000311; KRUGER FRIEDRICH, 1934, ARCH PROTISTENK, V83, P275; LUFT JH, 1961, J BIOPHYS BIOCHEM CY, V9, P409, DOI 10.1083/jcb.9.2.409; MILLONIG G, 1961, J BIOPHYS BIOCHEM CY, V11, P736, DOI 10.1083/jcb.11.3.736; PEASE DC, 1947, J CELL COMPAR PHYSL, V29, P91, DOI 10.1002/jcp.1030290109; PITELKA DR, 1963, ELECTRON MICROSCOPIC; ROUILLER CHARLES, 1957, BULL MICROSC APPLIQUEE, V7, P135; SEDAR AW, 1955, J BIOPHYS BIOCHEM CY, V1, P583, DOI 10.1083/jcb.1.6.583; SHELDON H, 1962, J CELL BIOL, V12, P599, DOI 10.1083/jcb.12.3.599; SWEENEY BM, 1957, J CELL COMPAR PHYSL, V49, P115, DOI 10.1002/jcp.1030490107; VONBEYERSDORFER K, 1951, Z NATURFORSCH, VB6, P57; WOHLFARTHBOTTER.KE, 1952, ARCH PROTISTENKD, V98, P169; YUSA A, 1963, J PROTOZOOL, V10, P253, DOI 10.1111/j.1550-7408.1963.tb01673.x	21	85	87	0	4	SPRINGER WIEN	Vienna	Prinz-Eugen-Strasse 8-10, A-1040 Vienna, AUSTRIA	0033-183X	1615-6102		PROTOPLASMA	Protoplasma		1966	61	1-2					205	+		10.1007/BF01247920	http://dx.doi.org/10.1007/BF01247920			1	Plant Sciences; Cell Biology	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences; Cell Biology	77413	5920039				2025-03-11	WOS:A19667741300012
J	HOCHACHKA, PW; TEAL, JM				HOCHACHKA, PW; TEAL, JM			RESPIRATORY METABOLISM IN A MARINE DINOFLAGELLATE	BIOLOGICAL BULLETIN			English	Article								The respiration of suspensions of Gymnodinium was inhibited by fluoroacetate, malonate, azide, arsenite, cyanide and iodoacetate listed in order of decreasing effectiveness. Cells grown in alternating light and dark were most sensitive to malonate in the middle of the light and beginning of the dark period. Succinate, malate and fumarate increased respiration while oxaloacetate, citrate and ketoglutarate markedly decreased it. Ascorbate and reduced glutathione greatly increased respiration. This was further stimulated by cyanide and arsenite, insensitive to diethyldithiocarbamate and azide, and completely blocked by cysteine, ethylene-diaminetetraacetic acid and fluoroacetate.										GUILLARD RR, 1962, CAN J MICROBIOL, V8, P229, DOI 10.1139/m62-029; HASTINGS JW, 1961, J GEN PHYSIOL, V45, P69, DOI 10.1085/jgp.45.1.69; HOCHACHKA PW, 1962, CAN J BIOCHEM PHYS, V40, P1043; KANWISHER J, 1959, LIMNOL OCEANOGR, V4, P210, DOI 10.4319/lo.1959.4.2.0210; KOLESNIKOV PO, 1931, UKRAIN BOT Z, V18, P46; KOLESNIKOV PO, 1962, Z BIOL, V4, pV23; KRATZ WA, 1955, PLANT PHYSIOL, V30, P275, DOI 10.1104/pp.30.3.275; MAPSON LW, 1958, ANNU REV PLANT PHYS, V9, P119, DOI 10.1146/annurev.pp.09.060158.001003; MOSHKINA L. V., 1961, FIZIOL RASTENII [TRANSL J, V8, P129; SOROKIN C, 1957, J GEN PHYSIOL, V40, P579, DOI 10.1085/jgp.40.4.579; STERN H, 1959, BOT REV, V25, P351, DOI 10.1007/BF02860042; SWEENEY BM, 1958, J PROTOZOOL, V5, P217, DOI 10.1111/j.1550-7408.1958.tb02555.x; TOKUYAMA K, 1962, BIOCHIM BIOPHYS ACTA, V56, P427, DOI 10.1016/0006-3002(62)90594-2; WANGERSKY PJ, 1960, NATURE, V185, P689, DOI 10.1038/185689a0; WARD JM, 1955, PLANT PHYSIOL, V30, P58, DOI 10.1104/pp.30.1.58; WEBSTER GC, 1953, PLANT PHYSIOL, V28, P63, DOI 10.1104/pp.28.1.63; YOUNG LCT, 1956, PLANT PHYSIOL, V31, P205, DOI 10.1104/pp.31.3.205	17	6	6	0	4	UNIV CHICAGO PRESS	CHICAGO	1427 E 60TH ST, CHICAGO, IL 60637-2954 USA	0006-3185	1939-8697		BIOL BULL-US	Biol. Bull.		1964	126	2					274	281		10.2307/1539525	http://dx.doi.org/10.2307/1539525			8	Biology; Marine & Freshwater Biology	Science Citation Index Expanded (SCI-EXPANDED)	Life Sciences & Biomedicine - Other Topics; Marine & Freshwater Biology	WS737		Green Submitted			2025-03-11	WOS:A1964WS73700009
J	CHANG, JJ				CHANG, JJ			ELECTROPHYSIOLOGICAL STUDIES OF A NON-LUMINESCENT FORM OF THE DINOFLAGELLATE NOCTILUCA MILIARIS	JOURNAL OF CELLULAR AND COMPARATIVE PHYSIOLOGY			English	Article								A detailed study of the electrophysiological properties of Noctiluca was made using hyper-fine microelectrodes, a unity-gain amplifier, pulse generators and a dual-beam oscilloscope. In more than 200 cells successfully impaled, no significant resting potential was observed. The resistance of the recording electrode was continuously monitored before, during and after each impalement. An electrical response which has a polarity opposite to the potential variations in the (depolarizing) responses of most other cells, was elicited when a sufficient inward current flows across the cell surface. This response is all-or-none in character with a definite threshold. Such electric response did not decrease its amplitude when all but 10% of the Na normally present in the sea water was replaced with either K, choline or sucrose. Ten per cent isotonic tetraethylammonium chloride (TEA), 0.005% cocaine and 3% urethane solutions in sea water prolonged the duration of response without decreasing its amplitude. Current voltage relations in Noctiluca show a linear relationship which exhibits a discontinuity and a change in its slope at the threshold current strength. An increase in conductivity associated with activity was also recorded using an a. c. bridge circuit. Membrane resistance and capacitance during the inactive state averaged 1.4 x 103 ohm. cm2 and 1.3 [mu]F/cm2 respectively. The alternative possibilities of whether such a phenomenon is a true "hyperpolarizing" response or an intracellular response have been discussed.										CHANG JJ, 1960, NATURWISSENSCHAFTEN, V47, P259, DOI 10.1007/BF00601834; Cole KS, 1939, J GEN PHYSIOL, V22, P649, DOI 10.1085/jgp.22.5.649; Curtis HJ, 1938, J GEN PHYSIOL, V21, P757, DOI 10.1085/jgp.21.6.757; Harvey E.N., 1952, BIOLUMINESCENCE; HASTINGS JW, 1957, BIOLUMINESCENCE MARI; HISADA M, 1957, J CELL COMPAR PHYSL, V50, P57, DOI 10.1002/jcp.1030500105; KAO CY, 1956, J GEN PHYSIOL, V40, P107, DOI 10.1085/jgp.40.1.107; LUNDBERG A, 1955, ACTA PHYSIOL SCAND, V35, P1, DOI 10.1111/j.1748-1716.1955.tb01258.x; LUNDBERG A, 1957, ACTA PHYSIOL SCAND, V40, P21, DOI 10.1111/j.1748-1716.1957.tb01475.x; MUELLER P, 1958, J GEN PHYSIOL, V42, P163, DOI 10.1085/jgp.42.1.163; NICOL JAC, 1958, J MAR BIOL ASSOC UK, V37, P535; Osterhout WJV, 1934, J GEN PHYSIOL, V18, P215, DOI 10.1085/jgp.18.2.215; SEGAL JR, 1958, NATURE, V182, P1370, DOI 10.1038/1821370a0; SPYROPOULOS CS, 1959, SCIENCE, V129, P1366, DOI 10.1126/science.129.3359.1366; SPYROPOULOS CS, 1956, J GEN PHYSIOL, V40, P19, DOI 10.1085/jgp.40.1.19; STAMPFLI R, 1958, Helv Physiol Pharmacol Acta, V16, P127; TASAKI I, 1955, AM J PHYSIOL, V181, P639, DOI 10.1152/ajplegacy.1955.181.3.639; TASAKI I, 1948, J NEUROPHYSIOL, V11, P305, DOI 10.1152/jn.1948.11.4.305; TASAKI I, 1959, NATURE, V184, P1574, DOI 10.1038/1841574a0; TASAKI I, 1959, J PHYSIOL-LONDON, V148, P306, DOI 10.1113/jphysiol.1959.sp006290; TYLER A, 1956, BIOL BULL-US, V111, P153, DOI 10.2307/1539191	21	25	25	0	1	WILEY-LISS	HOBOKEN	DIV JOHN WILEY & SONS INC, 111 RIVER ST, HOBOKEN, NJ 07030 USA	0095-9898			J CELL COMPAR PHYSL	J. Cell. Comp. Physiol.		1960	56	1					33	42		10.1002/jcp.1030560106	http://dx.doi.org/10.1002/jcp.1030560106			10	Physiology	Science Citation Index Expanded (SCI-EXPANDED)	Physiology	WX984	13692328				2025-03-11	WOS:A1960WX98400005
J	SWEENEY, BM				SWEENEY, BM			CULTURE OF THE DINOFLAGELLATE GYMNODINIUM WITH SOIL EXTRACT	AMERICAN JOURNAL OF BOTANY			English	Article								The isolation and culture of an un-armored dinoflagellate, tentatively identified as G. splendens is descr. This organism could not be subcultured indefinitely without the presence of a factor present in extracts of garden soil. Soil extract was not active freshly prepared, but became active after aging for a period of 4-6 wks. in a sterile condition. Extracts lost activity after a period of 2-3 mos. but could be preserved by deep-freezing. Activity was also present in plasmoptysate of Prorocentrum micans cells and in sea water collected during a bloom of Gymnodinium. Ferric citrate, Na citrate, Hoagland and Arnon''s minor mineral nutrients, alanine, cystine, asparagine, a mixture of growth substances and amino acids, peptone, dextrose, yeast extract, bean extract, and extracts of leaf mold and steer manure were all inactive at the concns. assayed.										Arnon DI, 1938, AM J BOT, V25, P322, DOI 10.2307/2436754; BACHRACH E, 1931, REV ALGOLOGIQUE, V5, P55; BARKER H. ALBERT, 1935, ARCH MIKROBIOL, V6, P157, DOI 10.1007/BF00407285; Bonner DM, 1939, P NATL ACAD SCI USA, V25, P184, DOI 10.1073/pnas.25.4.184; BRAARUD T, 1945, NORSKE VIDENSKAPS MN; Garnjobst Laura, 1943, JOUR CELL AND COMP PHYSIOL, V21, P199, DOI 10.1002/jcp.1030210302; GRAN HH, 1930, SKRIFTER UTGITT A MN, V5, P1; Griessmann Karl, 1913, Archiv fuer Protistenkunde Jena, V32; GROSS F, 1937, J MAR BIOL ASSOC UK, V21, P756; HARVEY H. W., 1939, JOUR MARINE BIOL ASSOC UNITED KINGDOM, V23, P499; KING G, 1950, 2ND GULF CAR FISH I, P107; KOFOID CA, 1931, CONTRI TOHOKU IMPERI, V61, P51; Kofoid Charles Atwood, 1921, FREE LIVING UNARMORE; KUSTER E, 1908, ARCH PROTISTENKD, V2, P351; Lebour M.V., 1925, DINOFLAGELLATES NO S; Lwoff A, 1935, CR SOC BIOL, V119, P971; PRINGSHEIM EG, 1936, BEIH BOT ZBL, V55, P101; PRINGSHEIM EG, 1912, BEITR BIOL PFLANZ, V2, P305; RILEY GA, 1947, J MAR RES, V6, P114; SCHREIBER E., 1927, WISS MEERESUNTERSUCH ABT HELGOLAND, V16, P1	20	16	16	0	3	WILEY	HOBOKEN	111 RIVER ST, HOBOKEN 07030-5774, NJ USA	0002-9122	1537-2197		AM J BOT	Am. J. Bot.		1951	38	9					669	677		10.2307/2437913	http://dx.doi.org/10.2307/2437913			9	Plant Sciences	Science Citation Index Expanded (SCI-EXPANDED)	Plant Sciences	UF025					2025-03-11	WOS:A1951UF02500001
