Biodiversity Literature Repository

Submit to community
Liberated Data
Published March 21, 2024 | Version v1
Taxonomic treatment Open

Diplosphaera chodatii

Authors/Creators

Description

Diplosphaera chodatii

is one of the most common species of photobionts which can be encountered in free-living state. Molecular data reveal its presence in sand and on rocks (Mikhailyuk et al. 2018a), on tree bark and freshwater habitats (Pröschold & Darienko 2020). Morphologically, it has been reported from a variety of environments and substrates. Indeed, it can be found both in deserts (Vinogradova et al. 2004; Büdel et al. 2009), representing the only Stichococcus - related species that occurs in this habitat (Hodač et al. 2016), and in environments that are mostly covered by snow and ice (Elster et al. 1999; Borchhardt et al. 2017; Ilchibaeva et al. 2018). It also survives in soils significantly altered by anthropogenic activities (Lukešová & Hoffmann 1996; Lukešová 2001; Neustupa & Škaloud 2005; Škaloud et al. 2008a) and sometimes even belongs to the most abundant species in such places (Sommer et al. 2020). It does not even mind the air of big cities (Freystein et al. 2008) and inhabits facades (Hofbauer 2007; Hofbauer & Gärtner 2021) as well as sand dunes (Schulz et al. 2016). It grows on a variety of substrates: soil (Zimonina 1998; Neustupa 2001; Škaloud et al. 2008b), tree bark (Johansen et al. 2007; Štifterová & Neustupa 2017), moss (Škaloud 2009) and rocks and caves (Vinogradova & Mikhailyuk 2009; Vinogradova et al. 2009). In some localities, it is a very abundant species (Elster et al. 1999; Mikhailyuk et al. 2003; Samolov et al. 2020).

Notes

Published as part of Veselá, Veronika, Malavasi, Veronica & Škaloud, Pavel, 2024, A synopsis of green-algal lichen symbionts with an emphasis on their free-living lifestyle, pp. 317-338 in Phycologia 63 (3) on page 325, DOI: 10.1080/00318884.2024.2325329, http://zenodo.org/record/15520507

Files

Files (2.0 kB)

Name Size Download all
md5:aae9aadd2c1eae6a80abe3e89f0172ca
2.0 kB Download

System files (17.2 kB)

Name Size Download all
md5:f83077c10d57b0b721ee11cf41f99ed3
17.2 kB Download

Linked records

Additional details

Identifiers

URL
http://treatment.plazi.org/id/5F246365FFE2FFF775C5FA044097FE5D

Is part of
Journal article: 10.1080/00318884.2024.2325329 (DOI)
Journal article: http://zenodo.org/record/15520507 (URL)
Journal article: http://publication.plazi.org/id/A31D1B1DFFEBFFFE7558FFCA4434FFDB (URL)
Is source of
https://biodiversitypmc.sibils.org/collections/plazi/5F246365FFE2FFF775C5FA044097FE5D (URL)
https://www.gbif.org/species/262401443 (URL)
https://www.checklistbank.org/dataset/310047/taxon/5F246365FFE2FFF775C5FA044097FE5D.taxon (URL)

Biodiversity

Scientific name authorship
Proschold & Darienko
Kingdom
Plantae
Phylum
Chlorophyta
Order
Prasiolales
Family
Prasiolaceae
Genus
Diplosphaera
Species
chodatii
Taxon rank
species
Taxonomic concept label
Diplosphaera chodatii (Proschold, 2020) sec. Veselá, Malavasi & Škaloud, 2024

References

  • Mikhailyuk T. I., Vinogradova O., Glaser K., Demchenko E. & Karsten U. 2018 a. Diversity of terrestrial algae of Cape Kazantip (the Sea of Azov, Ukraine) and some remarks on their phylogeny and ecology. Algologia 20: 313-338.
  • Proschold T. & Darienko T. 2020. The green puzzle Stichococcus (Trebouxiophyceae, Chlorophyta): New generic and species concept among this widely distributed genus. Phytotaxa 441: 113-142.
  • Vinogradova O. N., Kovalenko O. V., Levanets A. A., Nevo E. & Wasser S. 2004. Epilithic algal communities of dry rocks of the Negev desert, Israel. Ukrainian Botanical Journal 61: 7-20.
  • Budel B., Darienko T., Deutschewitz K., Dojani S., Friedl T., Mohr K. I., Salisch M., Reisser W. & Weber B. 2009. Southern african biological soil crusts are ubiquitous and highly diverse in drylands, being restricted by rainfall frequency. Microbial Ecology 57: 229-247.
  • Hodac L., Hallmann C., Spitzer K., Elster J., Fasshauer F., Brinkmann N., Lepka D., Diwan V. & Friedl T. 2016. Widespread green algae Chlorella and Stichococcus exhibit polar-temperate and tropical-temperate biogeography. FEMS Microbiology Ecology 92: fiw 122.
  • Elster J., Lukesova A., Svoboda J., Kopecky J. & Kanda H. 1999. Diversity and abundance of soil algae in the polar desert, Sverdrup Pass, central Ellesmere Island. Polar Record 35: 231-254.
  • Borchhardt N., Schiefelbein U., Abarca N., Boy J., Mikhailyuk T., Sipman H. J. M. & Karsten U. 2017. Diversity of algae and lichens in biological soil crusts of Ardley and King George islands, Antarctica. Antarctic Science 29: 229-237.
  • Ilchibaeva K. V., Kunsbaeva D. F., Allaguvatova R. Z., Fazlutdinova A. A., Polokhin O. V., Sibirina L. A., Gontcharov A. A., Singh P. & Gaysina L. A. 2018. Preliminary data about algae and cyanobacteria of volcanic soils on Kuril Islands. Theoretical and Applied Ecology 4: 119-126.
  • Lukesova A. & Hoffmann L. 1996. Soil algae from acid rain impacted forest areas of the Krusne hory Mts. 1. Algal communities. Vegetatio 125: 123-136.
  • Lukesova A. 2001. Soil algae in brown coal and lignite post-mining areas in Central Europe (Czech Republic and Germany). Restoration Ecology 9: 341-350.
  • Neustupa J. & Skaloud P. 2005. Contribution to the knowledge of soil algae of two abandoned industrial sedimentation basins in eastern Bohemia. In Kovar P. (Ed.), Natural recovery of human-made deposits in landscape. Prague: Academia, 194-199.
  • Skaloud P., Neustupa J. & Skaloudova M. 2008 a. Species composition and diversity of algae on anthropogenic substrata. Novitates Botanicae Universitatis Carolinae 19: 33-37.
  • Sommer V., Karsten U. & Glaser K. 2020. Halophilic algal communities in biological soil crusts isolated from potash tailings pile areas. Frontiers in Ecology and Evolution 8: 46.
  • Freystein K., Salisch M. & Reisser W. 2008. Algal biofilms on tree bark to monitor airborne pollutants. Biologia 63: 866-872.
  • Hofbauer W. K. 2007 Aerophytische Organismen an Bauteiloberflachen. Thesis, Leopold-Franzens-Universitat, Innsbruck. 436 pp.
  • Hofbauer W. K. & Gartner G. 2021. Microbial Life on Facades. Berlin and Heidelberg: Springer Spektrum, 323 pp.
  • Schulz K., Mikhailyuk T., Dressler M., Leinweber P. & Karsten U. 2016. Biological soil crusts from coastal dunes at the Baltic Sea, cyanobacterial and algal biodiversity and related soil properties. Microbial Ecology 71: 178-193.
  • Zimonina N. M. 1998. Pochvennye vodorosli neftezagryaznennykh zemel [Soil algae of the oil contaminated land]. Kirov, 170 p.
  • Neustupa J. 2001. Soil algae from marlstone-based biotopes in the Nature park Dzban (Central Bohemia, Czech Republic) with special attention to the natural treeless localities. Algological Studies 101: 109-120.
  • Skaloud P., Pazoutova M., Vesela J. & Neustupa J. 2008 b. Species composition of algae and cyanobacteria in biological soil crusts on natural substrata. Novitates Botanicae Universitatis Carolinae 19: 15-18.
  • Johansen J. R., Lowe R. L., Carty S., Fucikova K., Olsen C. E., Fitzpatrick M. H., Ress J. A. & Furey P. C. 2007. New algal species records for Great Smoky Mountains National Park, with an annotated checklist of all reported algal taxa for the park. Southeastern Naturalist 6: 99-134.
  • Stifterova A. & Neustupa J. 2017. Small-scale variation of corticolous microalgal covers: Effects of microhabitat, season, and space. Phycological Research 65: 299-311.
  • Skaloud P. 2009. Species composition and diversity of aero-terrestrial algae and cyanobacteria of the Borec Hill ventaroles. Fottea 9: 65-80.
  • Vinogradova O. N. & Mikhailyuk T. I. 2009. Algal flora of the caves and grottoes of the National Nature Park ' Podilsky Tovtry' (Ukraine). International Journal on Algae 11: 289-304.
  • Mikhailyuk T. I., Demchenko E. M. & Kondratyuk S. Y. 2003. Algae of granite outcrops from the left bank of the river Pivdennyi Bug (Ukraine). Biologia 58: 589-601.
  • Samolov E., Baumann K., Budel B., Jung P., Leinweber P., Mikhailyuk T., Karsten U. & Glaser K. 2020. Biodiversity of algae and cyanobacteria in biological soil crusts collected along a climatic gradient in Chile using an integrative approach. Microorganisms 8: 1047.