Published November 1, 2022 | Version v1
Journal article Restricted

Jurassic mammaliaform petrosals from Western Siberia (Russia) and implications for early mammalian inner-ear anatomy

Description

Schultz, Julia A, Ruf, Irina, Averianov, Alexander O, Schellhorn, Rico, Lopatin, Alexey V, Martin, Thomas (2022): Jurassic mammaliaform petrosals from Western Siberia (Russia) and implications for early mammalian inner-ear anatomy. Zoological Journal of the Linnean Society 196 (3): 1175-1200, DOI: 10.1093/zoolinnean/zlab096, URL: https://academic.oup.com/zoolinnean/article/196/3/1175/6472402

Files

Restricted

The record is publicly accessible, but files are restricted to users with access.

Linked records

Additional details

Identifiers

LSID
urn:lsid:plazi.org:pub:FFB1683BA74BDB52FF90FFC12B601C25

References

  • Alifanov VR , Krasnolutskii SA , Markov VN , Martynovich NV. 2001. About discovery of the Middle Jurassic dinosaurs in the Krasnoyarsk Territory. Scientificpractical conference problems of the struggle against illegal excavations and illegal turnover of the objects of archaeology, mineralogy, and paleontology. Proceedings Volume. Krasnoyarsk: 71-74.
  • Averianov AO, Krasnolutskii SA. 2009. Stegosaur remains from the Middle Jurassic of West Siberia. Proceedings of the Zoological Institute of the Russian Academy of Sciences 313: 59-73.
  • Averianov AO, Lopatin AV. 2006. Itatodon tatarinovi (Tegotheriidae, Mammalia), a docodont from the Middle Jurassic of Western Siberia and phylogenetic analysis of Docodonta. Paleontological Journal 40: 668-677.
  • Averianov AO , Lopatin AV , Skutschas PP , Martynovich NV, Leshchinskiy SV, Rezvyi AS, Krasnolutskii SA, Fayngertz AV. 2005. Discovery of Middle Jurassic mammals from Siberia. Acta Palaeontologica Polonica 50: 789-797.
  • Averianov AO, Lopatin AV, Krasnolutskii SA. 2008. An amphilestid-grade eutriconodontan from the Middle Jurassic of Russia. Russian Journal of Theriology 7: 1-4.
  • Averianov AO, Krasnolutskii SA, Ivantsov SV. 2010a. A new basal coelurosaur (Dinosauria: Theropoda) from the Middle Jurassic of Siberia. Proceedings of the Zoological Institute of the Russian Academy of Sciences 314: 42-57.
  • Averianov AO, Lopatin AV, Krasnolutskii SA, Ivantsov SV. 2010b. New docodontans from the Middle Jurassic of Siberia and reanalysis of Docodonta interrelationships. Proceedings of the Zoological Institute of the Russian Academy of Sciences 314: 121-148.
  • Averianov AO, Lopatin AV, Krasnolutskii SA. 2011. The first haramiyid (Mammalia, Allotheria) from the Jurassic of Russia. Doklady Biological Sciences 437: 103-106.
  • Averianov AO, Martin T, Lopatin AV. 2014. The oldest dryolestid mammal from the Middle Jurassic of Siberia. Journal of Vertebrate Paleontology 34: 924-931.
  • Averianov AO, Martin T, Skutschas PP, Danilov I, Schultz JA, Schellhorn R, Obraztsova E, Lopatin AV, Sytchevskaya E , Kuzmin I, Krasnolutskii SA , Ivantsov SV. 2017a. Middle Jurassic vertebrate assemblage of Berezovsk coal mine in western Siberia (Russia). Global Geology 19: 187-204.
  • Averianov AO, Martin T, Lopatin AV, Schultz JA, Skutschas PP, Schellhorn R, Krasnolutskii SA. 2017b. A tritylodontid synapsid from the Middle Jurassic of Siberia and the taxonomy of derived tritylodontids. Journal of Vertebrate Paleontology 37: e1363767.
  • Averianov AO, Krasnolutskii S, Ivantsov S, Skutschas P, Schellhorn R, Schultz J, Martin T, 2019a. Sauropod remains from the Middle Jurassic Itat Formation of West Siberia, Russia. PalZ 93: 691-701.
  • Averianov AO, Martin T, Lopatin AV, Schultz JA, Schellhorn R, Krasnolutskii S, Skutschas P , Ivantsov S. 2019b. Haramiyidan mammals from the Middle Jurassic of Western Siberia, Russia. Part 1: Shenshouidae and Maiopatagium. Journal of Vertebrate Paleontology 39: e1669159.
  • Averianov AO, Osochnikova A , Skutschas P , Krasnolutskii S, Schellhorn R, Schultz JA, Martin T. 2021a. New data on the tyrannosauroid dinosaur Kileskus from the Middle Jurassic of Siberia, Russia. Historical Biology 33: 897-903.
  • Averianov AO, Martin T, Lopatin AV, Schultz JA, Schellhorn R , Krasnolutskii S , Skutschas P , Ivantsov S. 2021b. Multituberculate mammals from the Middle Jurassic of western Siberia, Russia, and the origin of Multituberculata. Papers in Palaeontology 7: 769-787.
  • Crompton AW, Luo Z-X. 1993. Relationships of the Liassic mammals Sinoconodon, Morganucodon oehleri, and Dinnetherium. In: Szalay FS, Novacek MJ, McKenna MC, eds. Mammal phylogeny: Mesozoic differentiation, multituberculates, monotremes, early therians, and marsupials. New York: Springer, 30-44.
  • Crompton AW, Sun A-L. 1985. Cranial structure and relationships of the Liassic mammal Sinoconodon. Zoological Journal of the Linnean Society 85: 99-119.
  • Denker A. 1901. Zur Anatomie des Gehororgans der Monotremata. Denkschriften der medicinisch- naturwissenschaftlichen Semon Zoologische Forschungsreisen in Australien 3: 635-662.
  • Doran AHG. 1878. XVIII. Morphology of the mammalian Ossicula auditus. Transactions of the Linnean Society of London, 2nd Series, Zoology 1: 371-497.
  • Ekdale EG. 2013. Comparative anatomy of the bony labyrinth (inner ear) of placental mammals. PLoS One 8: e66624.
  • Ekdale EG, Rowe T. 2011. Morphology and variation within the bony labyrinth of zhelestids (Mammalia, Eutheria) and other therian mammals. Journal of Vertebrate Paleontology 31: 658-675.
  • Ekdale EG, Archibald JD, Averianov, AO. 2004. Petrosal bones of placental mammals from the Late Cretaceous of Uzbekistan. Acta Palaeontologica Polonica 49: 161-176.
  • Fleischer G. 1973. Studien am Skelett des Gehororganes der Saugetiere, einschliesslich des Menschen. Saugetierkundliche Mitteilungen 21: 131-239.
  • Fox RC, Meng J. 1997. An X-radiographic and SEM study of the osseous inner ear of multituberculates and monotremes (Mammalia): implications for mammalian phylogeny and evolution of hearing. Zoological Journal of the Linnean Society 121: 249-291.
  • Frisch T, Sorensen MS, Overgaard S, Lind M, Bretlau P. 1998. Volume-referent bone turnover estimated from the interlabel area fraction after sequential labeling. Bone 22: 677-682.
  • Graybeal A, Rosowski JJ, Ketten DR, Crompton AW. 1989. Inner-ear structure in Morganucodon, an early Jurassic mammal. Zoological Journal of the Linnean Society 96: 107-117.
  • Hahn G. 1988. Die Ohr-Region der Paulchoffatiidae (Multituberculata, Ober-Jura). Palaeovertebrata 18: 155-185.
  • Han G, Mao F, Bi S, Wang Y, Meng J. 2017. A Jurassic gliding euharamiyidan mammal with an ear of five auditory bones. Nature 551: 451-456.
  • Harper T, Rougier GW. 2019. Petrosal morphology and cochlear function in Mesozoic stem therians. PLoS One 14: e0209457.
  • Hughes EM, Wible JR, Spaulding M, Luo Z-X. 2015. Mammalian petrosal from the Upper Jurassic Morrison Formation of Fruita, Colorado. Annals of Carnegie Museum 83: 1-17.
  • Hurum JH. 1998. The inner ear of two Late Cretaceous multituberculate mammals, and its implications for multituberculate hearing. Journal of Mammalian Evolution 5: 65-93.
  • Kearney M, Maisano JA, Rowe T. 2005. Cranial anatomy of the extinct amphisbaenian Rhineura hatcherii (Squamata, Amphisbaenia) based on high-resolution x-ray computed tomography. Journal of Morphology 264: 1-33.
  • Kermack KA, Mussett F, Rigney HW. 1981. The skull of Morganucodon. Zoological Journal of the Linnean Society 71: 1-158.
  • Kielan-Jaworowska Z, Hurum JH, Lopatin AV. 2005. Skull structure in Catopsbaatar and the zygomatic ridges in multituberculate mammals. Acta Palaeontologica Polonica 50: 487-512.
  • Krause DW, Hoffmann S, Hu Y, Wible JR, Rougier GW, Kirk EC, Groenke JR, Rogers RR,Rossie JB,Schultz JA, Evans AR, Koenigswald Wv, Rahantarisoa LJ. 2020. Skeleton of a Cretaceous mammal from Madagascar reflects long-term insularity. Nature 581: 421-427.
  • Kuhn HJ, Zeller U. 1987. The cavum epiptericum in monotremes and therian mammals. Mammalia Depicta 13: 51-70.
  • Laass M. 2015. Bone-conduction hearing and seismic sensitivity of the late Permian anomodont Kawingasaurus fossilis. Journal of Morphology 276: 121-143.
  • Ladeveze S, de Muizon C, Colbert M, Smith T. 2010. 3D computational imaging of the petrosal of a new multituberculate mammal from the Late Cretaceous of China and its paleobiologic inferences. Comptes Rendus Palevol 9: 319-330.
  • Lewis ER, Narins PM. 1985. Do frogs communicate with seismic signals? Science 227: 187-189.
  • Lillegraven JA, Hahn G. 1993. Evolutionary analysis of the middle and inner ear of Late Jurassic multituberculates. Journal of Mammalian Evolution 1: 47-74.
  • Lopatin AV, Averianov AO. 2005. A new docodont (Docodonta, Mammalia) from the Middle Jurassic of Siberia. Doklady Biological Sciences 405: 434-436.
  • Lopatin AV, Averianov AO. 2007. The earliest Asiatic pretribosphenic mammal (Cladotheria, Amphitheriidae) from the Middle Jurassic of Siberia. Doklady Biological Sciences 417: 432-434.
  • Lopatin AV, Averianov AO. 2009. Mammals that coexisted with dinosaurs. Finds of the Russian territory. Herald of the Russian Academy of Sciences 79: 268-273.
  • Luo Z-X. 2001. The inner ear and its bony housing in tritylodontids and implications for evolution of the mammalian ear. Bulletin of the Museum of Comparative Zoology 156: 81-97.
  • Luo Z-X, Ketten DR. 1991. CT scanning and computerized reconstructions of the inner ear of multituberculate mammals. Journal of Vertebrate Paleontology 11: 220-228.
  • Luo Z-X, Manley G. 2020. Origins and early evolution of mammalian ears and hearing function. In: Fritzsch B, ed. The senses: a comprehensive reference, 2nd edn. London: Academic Press, 207-252.
  • Luo Z-X, Crompton AW, Lucas SG. 1995. Evolutionary origins of the mammalian promontorium and cochlea. Journal of Vertebrate Paleontology 15: 113-121.
  • Luo Z-X, Ruf I, Schultz JA, Martin T. 2011. Fossil evidence on evolution of inner ear cochlea in Jurassic mammals. Proceedings of the Royal Society, Series B 278: 28-34.
  • Luo Z-X, Ruf I, Martin T. 2012. The petrosal and inner ear of the Late Jurassic cladotherian mammal Dryolestes leiriensis and implications for ear evolution in therian mammals. Zoological Journal of the Linnean Society 166: 433-463.
  • Luo Z-X, Schultz JA, Ekdale EG. 2016. Evolution of the middle and inner ears of mammaliaforms: the approach to mammals. In: Clack JA, Fay RR, Popper AN, eds. Evolution of the vertebrate ear. Cham: Springer, 139-174.
  • Luo Z-X, Meng QJ, Grossnickle DM, Liu D, Neander AI, Zhang YG, Ji Q. 2017. New evidence for mammaliaform ear evolution and feeding adaptation in a Jurassic ecosystem. Nature 548: 326-329.
  • Martin T, Averianov AO, Lopatin AV, Schultz JA. 2014. Mammals from the Middle Jurassic of Western Siberia. 74th Annual Meeting of the Society of Vertebrate Paleontology in Berlin 2014. Supplement to the online Journal of Vertebrate Paleontology November 2014: 180.
  • Meng J, Wyss AR. 1995. Monotreme affinities and lowfrequency hearing suggested by multituberculate ear. Nature 377: 141-144.
  • Meng J, Fox RC. 1995. Osseous inner ear structures and hearing in early marsupials and placentals. Zoological Journal of the Linnean Society 115: 47-71.
  • Meng J, Hou SL. 2016. Earliest known mammalian stapes from an Early Cretaceous eutriconodontan mammal and implications for evolution of mammalian middle ear. Palaeontologia Polonica 67: 181-196.
  • Meng J, Bi S, Zheng X, Wang X. 2018. Ear ossicle morphology of the Jurassic euharamiyidan Arboroharamiya and evolution of mammalian middle ear. Journal of Morphology 279: 441-457.
  • Meng J, Mao F, Han G, Zheng XT, Wang XL, Wang Y. 2020. A comparative study on auditory and hyoid bones of Jurassic euharamiyidans and contrasting evidence for mammalian middle ear evolution. Journal of Anatomy 236: 50-71.
  • Miao D. 1988. Skull morphology of Lambdopsalis bulla (Mammalia, Multituberculata) and its implications to mammalian evolution. Contributions to Geology, University of Wyoming, Special Paper 4: 1-104.
  • Nummela S, Sanchez-Villagra MR. 2006. Scaling of the marsupial middle ear and its functional significance. Journal of Zoology 270: 256-267.
  • Panciroli E, Schultz JA, Luo Z-X. 2019. Morphology of the petrosal and stapes of Borealestes (Mammaliaformes, Docodonta) from the Middle Jurassic of Skye, Scotland. Papers in Palaeontology 5: 139-156.
  • Panciroli E, Benson RBJ, Fernandez V, Butler RJ, Fraser NC, Luo Z-X, Walsh S. 2021. New species of mammaliaform and the cranium of Borealestes (Mammaliformes: Docodonta) from the Middle Jurassic of the British Isles. Zoological Journal of the Linnean Society 192: 1323-1362.
  • Presley R. 1993. Development and the phylogenetic features of the middle ear region. In: Szalay FS, Novacek MJ, McKenna MC, eds. Mammal phylogeny: Mesozoic differentiation, multituberculates, monotremes, early therians, and marsupials. New York: Springer, 31-39.
  • Rougier GW, Wible JR. 2006. Major changes in the ear region and basicranium of early mammals. In: Carrano MT, Gaudin TJ, Blob RW,Wible JR, eds.Amniote paleobiology: perspectives on the evolution of mammals, birds and reptiles. Chicago: University of Chicago Press, 269-311.
  • Rougier GW, Wible JR, Hopson JA. 1992. Reconstruction of the cranial vessels in the Early Cretaceous mammal Vincelestes neuquenianus: implications for the evolution of the mammalian cranial vascular system. Journal of Vertebrate Paleontology 12: 188-216.
  • Rougier GW, Wible JR, Hopson JA. 1996. Basicranial anatomy of Priacodon fruitaensis (Triconodontidae, Mammalia) from the Late Jurassic of Colorado, and a reappraisal of mammaliaform interrelationships. American Museum Novitates 3183: 1-38.
  • Rougier GW, Wible JR, Beck RMD, Apesteguia S. 2012. The Miocene mammal Necrolestes demonstrates the survival of a Mesozoic nontherian lineage into the late Cenozoic of South America. Proceedings of the National Academy of Sciences 109: 20053-20058.
  • Rodrigues PG, Ruf I, Schultz CL . 2013. Digital reconstruction of the otic region and inner ear of the nonmammalian cynodont Brasilitherium riograndensis (Late Triassic, Brazil) and its relevance to the evolution of the mammalian ear. Journal of Mammalian Evolution 20: 291-307.
  • Rougier GW, Sheth AS, Spurlin BK, Bolortsetseg M, Novacek MJ. 2016. Cranio dental anatomy of a new Late Cretaceous multituberculate mammal from Udan Sayr, Mongolia. Palaeontologia Polonica 67: 197-248.
  • Rowe T. 1988. Definition, diagnosis, and origin of Mammalia. Journal of Vertebrate Paleontology 8: 241-264.
  • Ruf I, Luo Z-X, Wible JR, Martin T. 2009. Petrosal anatomy and inner ear structures of the Late Jurassic Henkelotherium (Mammalia, Cladotheria, Dryolestoidea): insight into the early evolution of the ear region in cladotherian mammals. Journal of Anatomy 214: 679-693.
  • Ruf I, Luo Z-X, Martin T. 2013. Reinvestigation of the basicranium of Haldanodon exspectatus (Mammaliaformes, Docodonta). Journal of Vertebrate Paleontology 33: 382-400.
  • Sanchez-Villagra MR, Schmelzle T. 2007. Anatomy and development of the bony inner ear in the woolly opossum, Caluromys philander (Didelphimorphia, Marsupialia). Mastozoologia Neotropical 14: 53-60.
  • Schultz JA, Zeller U, Luo Z-X. 2017. Inner ear labyrinth anatomy of monotremes and implications for mammalian inner ear evolution. Journal of Morphology 278: 236-263.
  • Schultz JA, Ruf I , Martin T. 2018. Oldest known multituberculate stapes suggests an asymmetric bicrural pattern as ancestral for Multituberculata. Proceedings of the Royal Society, Series B 285: 20172779.
  • Segall W. 1970. Morphological parallelisms of the bulla and auditory ossicles in some insectivores and marsupials. Fieldiana Zoology 51: 169-205.
  • Skutschas PP. 2006. Mesozoic amphibians from Siberia, Russia. In: Barrett PM, Evans SE, eds. 9th International Symposium on Mesozoic Terrestrial Ecosystems and Biota. Abstracts and Proceedings Volume, Natural History Museum, London, 123-126.
  • Skutschas PP, Krasnolutskii SA. 2011. A new genus and species of basal salamanders from the Jurassic of Western Siberia, Russia. Proceedings of the Zoological Institute of the Russian Academy of Sciences 315: 167-175.
  • Skutschas PP, Leshchinskiy SV,Rezvyi AS, Fayngerts AV, Krasnolutskii SA. 2005. Remains of salamanders from the Middle Jurassic of the Krasnoyarsk Territory. In: Rozanov AY, Lopatin AV, Parkhaev PY, eds. Modern paleontology: classical and newest methods. Moscow: Paleontological Institute Russian Academy of Sciences, 121-124 [In Russian].
  • Skutschas P , Kolchanov V , Krasnolutskii S , Averianov AO, Schellhorn R, Schultz JA, Martin T. 2020. A new small-sized stem salamander from the Middle Jurassic of Western Siberia, Russia. PLoS One 15: e0228610.
  • Wever EG. 1985. The amphibian ear. Princeton: Princeton University Press, 488.
  • Wible JR. 1990. Petrosals of Late Cretaceous marsupials from North America, and a cladistic analysis of the petrosal in therian mammals. Journal of Vertebrate Paleontology 10: 183-205.
  • Wible JR, Hopson JA. 1993. Basicranial evidence for early mammal phylogeny. In: Szalay FS, Novacek MJ, McKenna MC, eds. Mammal phylogeny: Mesozoic differentiation, multituberculates, monotremes, early therians, and marsupials. New York: Springer, 45-62.
  • Wible JR, Hopson JA. 1995. Homologies of the prootic canal in mammals and non-mammalian cynodonts. Journal of Vertebrate Paleontology 15: 331-356.
  • Wible JR, Rougier GW. 2000. The cranial anatomy of Kryptobaatar dashzevegi (Mammalia, Multituberculata), and its bearing on the evolution of mammalian characters. Bulletin of the American Museum of Natural History 247: 1-120.
  • Wible JR, Shelley SL, Bi S. 2019. New genus and species of djadochtatheriid multituberculate (Allotheria, Mammalia) from the Upper Cretaceous Bayan Mandahu Formation of Inner Mongolia. Annals of Carnegie Museum 85: 285-327.
  • Wible JR, Rougier GW, Novacek MJ, McKenna MC. 2001. Earliest eutherian ear region: a petrosal referred to Prokennalestes from the Early Cretaceous of Mongolia. American Museum Novitates 3322: 1-44.
  • Zeller U. 1993. Ontogenetic evidence for cranial homologies in monotremes and therians, with special reference to Ornithorhynchus. In: Szalay FS, Novacek MJ, McKenna MC, eds. Mammal phylogeny: Mesozoic differentiation, multituberculates, monotremes, early therians, and marsupials. New York: Springer, 45-62.