KnE Life Sciences
ISSN: 2413-0877
The latest conference proceedings on life sciences, medicine and pharmacology.
Comparative Analysis of Soil Algal Flora of the Tundra, Mountain and Boreal Ecosystems of the European Northeast
Published date: Oct 29 2018
Journal Title: KnE Life Sciences
Issue title: The Fourth International Scientific Conference Ecology and Geography of Plants and Plant Communities
Pages: 151–159
Authors:
Abstract:
Soil algae is a group of photoautotrophic organisms able to live on the soil surface and in the soil profile. Algae participate in the accumulation of organic compounds and the main biogenic exchange cycles in terrestrial ecosystems. Their importance increases in northern and mountain ecosystems with extreme environments. The aim of our research was to summarize the results of studies into soil algae in tundra, mountaintundra and boreal ecosystems in the Russian Northeast Europe based on literature and original data. We created a list of soil algae including 695 species from five divisions, 12 classes, 40 orders, 107 families and 245 genera. In tundra ecosystems, 348 species were found, 272 in mountain-tundra and 104 in boreal ecosystems. Taxonomical and
eco-geographical analysis of the algal flora was also performed. We revealed the species with high frequencies of occurrence and the prevalent algal complexes in the different nature zones. Cosmopolite species widespread in typical soil or edaphophilic species indifferent to soil acidity were prevalent.
Keywords: soil algae, tundra, mountain and boreal ecosystems
References:
[1] Shtina, E. A. and Gollerbakh, M. M. (1976). Ecology of Soil Algae. Moscow: Nauka.
[2] Dorogostayskaya, E. V. and Novichkova-Ivanova, L. N. (1967). About changes of algal flora of tundra soils under their development. Botanicheskij zhurnal, vol. 52, no. 4, pp. 461–468.
[3] Getsen, M. V. (1985). Algae in the Ecosystems at the Far North (On the Example of Bolshezemelskaya Tundra). Leningrad: Nauka.
[4] Getsen, M. V., Stenina, A. S., and Patova, E. N. (1994). Algal Flora of the Bolshezemelskaya Tundra under Anthropogenic Impact. Ekaterinburg: Nauka.
[5] Zimonina, N. M. (1998). Soil Algae of Oil Contaminated Lands. Kirov: Vyatka State Humanitarian University.
[6] Stenina, A. S., Teteryuk, B. Y., and Patova, E. N. (2001). Plant communities of riverside ecotones of the lake in the River Vangyr Valley at the Subpolar Urals, Botanical Studies at the protected areas of the European Northeast, Syktyvkar. Proceedings of the Komi Scientific Centre UrB RAS, no. 165, pp. 20–36.
[7] Dorokhova, M. (2003). Diatom algae as indicators of technogenic changes in soils adjacent to coal mine. Acta Botanica Warmiae et Masuriae, no. 3, pp. 145–154.
[8] Andreyeva, V. M. (2004). Terrestrial nonmotile green algae (chlorophyta) of the Vorkuta Tundra (Komi Republic). Novosti Sist. Nizsh. Rast., vol. 37, pp. 3–8.
[9] Andreyeva, V. M. (2005). Nonmotile green algae (chlorophyta) from soils of the right-bank of the River Ortina (Estuary of the River Pechora). Novosti Sist. Nizsh. Rast., vol. 41, pp. 3–7.
[10] Patova, E. N. and Dorokhova, M. P. (2005). Soil algae and the nature of tundra in open coal mining (the Yunyaginskoe Mine), in The Reaction of Components of Plant Communities to Pollution. Soil Algae, pp. 126–143. Syktyvkar: Republican Environmental Center for the Study and Protection of Eastern European Tundra.
[11] Andreyeva, V. M. and Czaplygina, O. Ya. (2006). Terrestrial Nonmotile Green Microalgae (Chlorophyta) in Area of Industrial Pollution of Vorkuta (Komi Republic). Novosti Sist. Nizsh. Rast., vol. 40, pp. 13–18.
[12] Andreyeva, V. M. and Czaplygina, O. Ya. (2007). Terrestrial nonmotile green microalgae (Chlorophyta) of the Polar Urals. Novosti Sist. Nizsh. Rast., vol. 41, 15– 18.
[13] Novakovskaya, I. V. and Patova, E. N. (2011). Soil Algae of Spruce Forests and Their Changes under Aerotechnogenic Impact. Syktyvkar: Komi Science Center Ural Div. RAS.
[14] Novakovskaya, I. V., Patova, E. N., and Shabalina, J. N. (2012). Soil Algae of Mountain Tundra Communities of Pre-Polar Urals (Yugyd Va National Park). Botanicheskij zhurnal, vol. 97, no. 3, pp. 305–320.
[15] Novakovskaya, I. V. and Patova, E. N. (2013). Algae of mountain tundra soils in the north End Polar Urals. Bul. MOIP. Otd. biol., vol. 118, no. 5, pp. 57–66.
[16] Novakovskaya, I. V. and Patova, E. N. (2018). Soil algoflora of the northeast of the European Part of Russia. Novosti Sist. Nizsh. Rast., vol. 2. (in print).
[17] Ettl, H. and Gärtner, G. (2014). Syllabus der Boden-, Luft-und Flechtenalgen 2. Auflage. Stuttgart: G. Fischer.
[18] Komárek, J. (2013). Cyanoprokaryota III: Nostocales, Stigonematales, Süßwasserflora von Mitteleuropa. Bd. 19/3. Berlin: Springer Spektrum.
[19] Komárek, J. and Anagnostidis, K. (1998). Cyanoprokaryota I. Teil: Chroococcales, Süßwasserflora von Mitteleuropa. 19/1. Heidelberg, Berlin: Spektrum, Akademischer Verlag.
[20] Komárek, J. and Anagnostidis, K. (2005). Cyanoprokaryota II, Teil: Oscillatoriales, Süβwasserflora von Mitteleuropa. 19/2. München: Elsevier Spektrum Akademischer Verlag.
[21] Barinova, S. S., Medvedeva, L. A., and Anisimova, O. V. (2006). Biodiversity of AlgaeIndicators of the Environment. Tel Aviv: Pilies Studio.
[22] Novakovskiy, A. B. (2016). Cooperation of Excel and Statistical Package R to proceed the data in ecology. Newsletter of the Institute of Biology KSC RAS, no. 3, pp. 26–33.
[23] Shtina, E. A. (1997). Algal Flora of the River Vyatka Basin. Kirov: Kirov Regional Printing House.
[24] Egorova, I. N. and Sudakova, E. A. (2011). Algae in the terrestrial ecosystems of Siberian Baikal, in Algae: Taxonomy, Ecology and Use in Monitoring, pp. 100–104. Ekaterinburg: UB RAS.