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Published March 21, 2024 | Version v1
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Elliptochloris bilobata Tschermak-Woess 1980

Authors/Creators

Description

Elliptochloris bilobata

is a widely distributed free-living species. After numerous records of this alga on granite rock outcrops (Mikhailyuk et al. 2003; Mikhailyuk 2008, 2013), where it often dominates (Mikhailyuk et al. 2003; Mikhailyuk 2008) and even forms macroscopic growths (Mikhailyuk 2008). Mikhailyuk (2008) hypothesized a preference for rocky substrates in this genus. However, E. bilobata is much more commonly found in soils of various climates, especially in forests (Hoffmann et al. 2007; Temraleeva et al. 2015; Dirborne & Ramanujam 2017; Glaser et al. 2018). The species is also abundant in the soil of tundra (Andreyeva 2004, 2005; Andreyeva & Chaplygina 2007; Novakovskaya et al. 2012; Novakovskaya & Patova 2013; Patova & Novakovskaya 2018; Novakovskaya et al. 2020), whereas no occurrence in the desert has been recorded. Similarly to other photobiont species (see Diplosphaera chodatii below), E. bilobata shows a broad tolerance to air pollution and thus thrives in the highly polluted centre of Leipzig, Germany (Freystein et al. 2008). Furthermore, this alga is encountered in Antarctica (Garraza et al. 2011; Borchhardt et al. 2017) and has been identified in caves (Vinogradova et al. 2009).

Another symbiotic member of Elliptochloris is E. perforata, which occurs free-living on bark, epilithic on tombstone (Darienko et al. 2016), and in soil (Hoffmann et al. 2007; Samolov et al. 2020). A different species, E. reniformis, is also common in soil (Lukešová 2001; Neustupa & Škaloud 2005; Khaybullina et al. 2010; Temraleeva et al. 2015; Darienko et al. 2016; Novakovskaya et al. 2020). Additionally, the species was reported from rocks (Johansen et al. 2007) and from building facades (Hofbauer & Gärtner 2021).

In addition, E. subsphaerica is a very versatile species confirmed from lichen thalli (Voytsekhovich et al. 2011; Masumoto 2020) as well as from many different types of substrates. It is frequently reported from soil (Zancan et al. 2006; Hoffmann et al. 2007; Takeshita et al. 2010; Schulz et al. 2016; Samolov et al. 2020) even from soil in heavily anthropogenically affected areas (Lukešová 2001; Neustupa & Škaloud 2005) and city centres (Rindi & Guiry 2003; Freystein et al. 2008). Other substrates include tree bark (Freystein et al. 2008; Neustupa & Škaloud 2010; Masumoto 2020), building facades (Hofbauer 2007; Hofbauer & Gärtner 2021) and rocks (Rifón-Lastra & Noguerol-Seoane 2001; Johansen et al. 2007; Mikhailyuk 2013; Mikhailyuk et al. 2018a). Furthermore, E. subsphaerica represents the dominant species in some studies (Mikhailyuk et al. 2003; Mikhailyuk 2008; Novakovskaya et al. 2020). It was also observed in pine litter (Maltsev & Maltseva 2018).

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 pages 324-325, DOI: 10.1080/00318884.2024.2325329, http://zenodo.org/record/15520507

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Linked records

Additional details

Identifiers

URL
http://treatment.plazi.org/id/5F246365FFE3FFF77605FB0445D2FC5D

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/5F246365FFE3FFF77605FB0445D2FC5D (URL)
https://www.gbif.org/species/262401439 (URL)
https://www.checklistbank.org/dataset/310047/taxon/5F246365FFE3FFF77605FB0445D2FC5D.taxon (URL)

Biodiversity

Scientific name authorship
Tschermak-Woess
Kingdom
Plantae
Phylum
Chlorophyta
Order
Prasiolales
Genus
Elliptochloris
Species
bilobata
Taxon rank
species
Taxonomic concept label
Elliptochloris bilobata Tschermak-Woess, 1980 sec. Veselá, Malavasi & Škaloud, 2024

References

  • 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.
  • Hoffmann L., Ector L. & Kostikov I. 2007. Algal flora from limed and unlimed forest soils in the Ardenne (Belgium). Systematics and Geography of Plants 77: 15-90.
  • Temraleeva A. D., Dronova S. A., Moskalenko S. V., Vagapov I. M. & Ovchinnikov A. Y. 2015. Additions to the algaflora (Chlorophyta) of gray forest soil. Нovoсti Сiсtiмatiki Нizsik Рaсtiнiй 49: 92-109.
  • Dirborne C. M. & Ramanujam P. 2017. Diversity and ecology of soil algae in broadleaf sacred grove and pine forest in East Khasi Hills, Meghalaya. Nelumbo 59: 195.
  • Glaser K., Baumann K., Leinweber P., Mikhailyuk T. & Karsten U. 2018. Algal richness in BSCs in forests under different management intensity with some implications for P cycling. Biogeosciences 15: 4181-4192.
  • Andreyeva V. M. 2004. Terrestrial nonmotile green algae (Chlorophyta) of Vorkuta tundra (Komi Republic). Novosti sistematiki nizshikh rastenii 37: 3-8.
  • Andreyeva V. M. 2005. Nonmotile green algae (Chlorophyta) from soils of the right-bank of the river Ortina (estuary of the River Pechora). Novosti sistematiki nizshikh rastenii 41: 3-7.
  • Andreyeva V. M. & Chaplygina O. 2007. Terrestrial nonmotile green microalgae (Chlorophyta) of the Polar Urals. Novosti sistematiki nizshikh rastenii 41: 15-18.
  • Novakovskaya I. V., Patova E. N. & Shabalina Y. N. 2012. Soil algae of mountain tundra communities of Subpolar Urals (National park " Yugydva "). Botanicheskii Zhurnal 97: 305-320.
  • Novakovskaya I. V. & Patova E. N. 2013. Algae of mountain tundra soils in the north end Polar Urals. Byulleten' Moskovskogo Obshchestva Ispytatelei Prirody 118: 57-66.
  • Patova E. N. & Novakovskaya I. V. 2018. Soil algae of the Northeastern European Russia. Novosti Sistematiki Nizshikh Rastenii 52: 311-353.
  • Novakovskaya I. V., Dubrovskiy Y. A., Patova E. N., Novakovskiy A. B. & Sterlyagova I. N. 2020. Influence of ecological factors on soil algae in different types of mountain tundra and sparse forests in the Northern Urals. Phycologia 59: 320-329.
  • Freystein K., Salisch M. & Reisser W. 2008. Algal biofilms on tree bark to monitor airborne pollutants. Biologia 63: 866-872.
  • Garraza G. G., Mataloni G., Fermani P. & Vinocur A. 2011. Ecology of algal communities of different soil types from Cierva Point, Antarctic Peninsula. Polar Biology 34: 339-351.
  • 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.
  • Darienko T., Gustavs L. & Proschold T. 2016. Species concept and nomenclatural changes within the genera Elliptochloris and Pseudochlorella (Trebouxiophyceae) based on an integrative approach. Journal of Phycology 52: 1125-1145.
  • 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.
  • 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.
  • Khaybullina L. S., Gaysina L. A., Johansen J. R. & Krautova M. 2010. Examination of the terrestrial algae of the Great Smoky Mountains National Park, USA. Fottea 10: 201-215.
  • 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.
  • Hofbauer W. K. & Gartner G. 2021. Microbial Life on Facades. Berlin and Heidelberg: Springer Spektrum, 323 pp.
  • Voytsekhovich A., Dymytrova L. & Nadyeina O. 2011. Photobiont composition of some taxa of the genera Micarea and Placynthiella (Lecanoromycetes, lichenized Ascomycota) from Ukraine. Folia Cryptogamica Estonica 48: 135-148.
  • Masumoto H. 2020. Taxonomic studies on lichenized basidiomycetes and their photobionts in Japan: towards the establishment of a model coculture system of lichen symbiosis. Ph. D. thesis, University of Tsukuba. 158 pp.
  • Zancan S., Trevisan R. & Paoletti M. G. 2006. Soil algae composition under different agro-ecosystems in North-Eastern Italy. Agriculture, Ecosystems and Environment 112: 1-12.
  • Takeshita S., Tokizawa M., Handa S. & Okamoto T. 2010. A report of the photobiont isolated from Multiclavula clara (Berk. and Curt.) R. H. Peterson (Clavariaceae, lichenized Basidiomycetes). Hikobia 15: 493-497.
  • 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.
  • Rindi F. & Guiry M. D. 2003. Composition and distribution of subaerial algal assemblages in Galway City, western Ireland. Cryptogamie, Algologie 24: 245-267.
  • Neustupa J. & Skaloud P. 2010. Diversity of subaerial algae and cyanobacteria growing on bark and wood in the lowland tropical forests of Singapore. Plant Ecology and Evolution 143: 51-62.
  • Hofbauer W. K. 2007 Aerophytische Organismen an Bauteiloberflachen. Thesis, Leopold-Franzens-Universitat, Innsbruck. 436 pp.
  • Rifon-Lastra A. & Noguerol-Seoane A. 2001. Green algae associated with the granite walls of monuments in Galicia (NW Spain). Cryptogamie, Algologie 22: 305-326.
  • Mikhailyuk T. I. 2013. Terrestrial algae from the granite outcrops of river valleys of the Ukraine. International Journal on Algae 15: 311-330.
  • 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.
  • Maltsev Y. & Maltseva I. 2018. The influence of forest-forming tree species on diversity and spatial distribution of algae in forest litter. Folia Oecologica 45: 72-91.