Climate Change Impact on the Marine Lakes and their Crustaceans: The Case of Marine Hypersaline Lake Bakalskoye (Ukraine)

Year 2013, Volume: 13 Issue: 4, - , 01.08.2013

Nickolai V. Shadrin * Elena V. Anufriieva

https://doi.org/10.4194/1303-2712-v13_4_05

Abstract

All over the world hypersaline lake/lagoons are threatened by climate change. The marine Bakalskoye Lake (Ukraine) was studied in 2000-2012. The paper considers changing crustaceans within the context of the lagoon changes. A sharp drop of salinity occurred in 2004 due to a changed wind rose because the strong winds of Western direction began to dominate, and as a result, washing away of the spit began to be more intensive; and marine water inflow into the lake increased. The structure of primary productivity has changed completely; the total primary production decreased. A list of crustacean species found in the lake includes 19 species. In 2004 there was a change of the composition of crustaceans due to three factors - a change of salinity, an increase of erosion, and massive transport of marine organisms into the lake. Integral characteristics of zooplankton also significantly changed. Impact of climate change on crustaceans is not only direct, but through an extensive network of intermediate effects which are discussed. The study results are of more than local relevance; it has a general ecological importance because can help to better understand that the realizations of general climate change impacts on local level are diverse.

Keywords

Crustacea, lagoon, climate change, Black Sea, sand spit dynamics

References

• Abbaspour, M., Javid, A.H., Mirbagheri, S.A., Ahmadi, F.G. and Moghimi, P. 2012. Investigation of lake drying attributed to climate change. International Journal of Environmental Science and Technology, 9: 257-2
• Aladin, N.V., Filippov, A.A., Plotnikov, I.S., Orlova, M.I. and Williams, W.D. 1998. Changes in the structure and function of biological communities in the Aral Sea, with particular reference to the northern part (Small Aral Sea), 1985-1994: A review. International Journal of Salt Lake Research, 7: 301-343.
• Aladin, N.V. and Potts, W.T. 1992. Changes in the Aral Sea ecosystems during the period 1960–1990. Hydrobiologia, 237: 67-79.
• Anufriieva, E.V. and Shadrin, N.V. 2012. Crustacean diversity in hypersaline Chersoness Lake (Crimea). Optimization and Protection of Ecosystems, 7: 55–61. (in Russian).
• Balushkina, E.V., Golubkov, S.M., Golubkov, M.S., Litvinchuk, L.F. and Shadrin, N.V. 2009. Effect of abiotic and biotic factors on the structural and functional organization of the saline lake ecosystems. Zhurnal Obshchei Biologii, 70: 504-14. (in Russian). Belmonte, G., Mazzocchi, M.G., Prusova, I.Yu. and Shadrin, N.V. 1994. Acartia tonsa: a species new for the Black Sea fauna. Hydrobiologia, 292-293: 9-15.
• Belmonte, G., Moscatello, S., Batogova, E.A., Pavlovskaya, T., Shadrin, N.V. and Litvinchuk, L.F. 2012. Fauna of hypersaline lakes of the Crimea (Ukraine). Thalassia Salentina, 34: 11–24.
• Belovsky, G.E., Stephens, D., Perschon, C., Birdsey, P., Paul, D., Naftz, D. and Allen, D.V. 2011. The Great Salt Lake Ecosystem (Utah, USA): long term data and a structural equation approach. Ecosphere, 2(3), art33: 1Carrasco, N.K. and Perissinotto, R. 2012. Development of a halotolerant community in the St. Lucia Estuary (South Africa) during a hypersaline phase. PLoS ONE, 7(1): e29927. doi:1371/journal.pone.0029927
• Drinkwater, K.F., Beaugrand, Gr. and Kaeriyama, M. 2010. On the processes linking climate to ecosystem changes. Journal of Marine Systems, 79: 374–388.
• Golubkov, S., Kemp, R., Golubkov, M., Balushkina, E., Litvinchuk, L. and Gubelit, Yu. 2007. Biodiversity and the functioning of hypersaline lake ecosystems from Crimea Peninsula (Black Sea). Fundamental and Applied Limnology / Arch für Hydrobiologie, 169: 79Goryachkin, Yu.N., Udovik, V.F. and Kharitonov, L.V. 20 Recreational potential of the Black Sea coast of Ukraine. In: P.F. Gozhik and V.A. Ivanov (Eds), Marine Coastal Resources of Ukraine, Marine Hydrophysical Institute, Sevastopol: 156-181. (in Russian).
• Håkanson, L. 2010. Great Lakes – Form and Function, as Exemplified Using Data From Lake Vänern, the Fourth Largest Lake in Europe. In J. S. Donovan (Ed.), Great Lakes: Ecology, Management and Conservation, Nova Science Pub., New York: 1-39.
• Hawkins,S.J., Sugden, H.E. and Mieszkowska, N. 2009. Consequences of climate-driven biodiversity changes for ecosystem functioning of North European rocky shores. Marine Ecology Progress Series, 396: 245– 2
• Hutchinson, G.E. 1978. An introduction to population ecology. Yale University Press, New Haven, 260 pp.
• Kurnakov, N.S., Kuznetsov, V.G., Dzens-Lytovsky, A.I. and Ravich, M.I. 1936. The Crimean salt lakes. AN USSR Publ., Moscow, 278 pp. (in Russian).
• Kwak, T.J. and Peterson, J.T. 2007. Community indices, parameters, and comparisons. In: C. S. Guy and M. L. Brown (Eds.), Analysis and interpretation of freshwater fisheries data, American Fisheries Society, Bethesda: 677-763.
• McElroy, M. and Baker, D.J. 2012. Climate extremes: Recent trends with implications for national security. Harvard University Center for the Environment, 126 pp.
• Mikhodyuk, O.S., Orleansky, V.K., Shadrin, N.V. and Gerasimenko, L.M. 2005. The modern cyanobacterial mats as the analogues of the Precambrian biocenoses. In: A.Yu. Rosanov, A.V. Lopatin and P.Yu. Parkhaev (Eds), Modern Paleontology: classic and newest methods, Paleontological Institute, Moscow: 15-28 (in Russian).
• Mirabdullayev, I.M., Joldasova, I.M., Mustafaeva, Z.A., Kazakhbaev, S., Lyubimova, S.A. and Tashmukhamedov, B.A. 2004. Succession of the ecosystems of the Aral Sea during its transition from oligohaline to polyhaline water body. Journal of Marine Systems, 47: 101–107.
• Micklin, Ph. 2007. The Aral Sea Disaster. Annual Review of Earth and Planetary Sciences, 35: 47–72.
• Nevrova, E.L. and Shadrin, N.V. 2005. Benthic diatoms in Crimean saline lakes. Marine Ecological Journal, 4: 61- (in Russian).
• Rawson, D.S. 1955. Morphometry as a dominant factor in the productivity of large lakes. Verh. Int. Ver. Limnol., 12: 164-175.
• O’Reilly, C.M., Alin, S.R., Plisnier, P-D., Cohen, A.S. and McKee, B.A. 2003. Climate change decreases aquatic ecosystem productivity of Lake Tanganyika, Africa. Nature, 424: 766-768.
• Piovano, E.L., Ariztegui, D. and Moreira, S.D. 2002. Recent environmental changes in Laguna Mar Chiquita (central Argentina): a sedimentary model for a highly variable saline lake. Sedimentology, 49: 1371–1384.
• Salameh., E. and El-Naser, H. 2000. Changes in the Dead Sea level and their impacts on the surrounding groundwater bodies. Acta Hydrochimica et Hydrobiologica, 28: 24–33.
• Senicheva, M.I., Gubelit, Yu., Prazukin, A.V. and Shadrin, N.V. 2008. Phytoplankton of the Crimean hypersaline lakes. In: Yu.N. Tokarev, Z.Z. Finenko and N.V. Shadrin (Eds), The Black Sea microalgae: problems of biodiversity preservation and biotechnological usage, ECOSI- Gidrofizika, Sevastopol: 5-18. (in Russian).
• Shadrin, N.V. 1985. The dependence of production characteristics on morphometric parameters of the water body. In: A.F. Alimov and V.N. Kuzmich (Eds.) The hydrobiology and hydroparasitology of Near Bajkal region, Nauka, Novosibirsk: 201-205 (in Russian).
• Shadrin, N.V. 2003. Is it possible to quantitatively assess the role of algobacterial films in a water body? In: W.G. Krumbein, D.M. Paterson and G.A. Zavarzin (Eds.), Fossil and recent biofilms - A natural history of life on Earth, Kluwer Academic Publishers, Dordrech: 353-361.
• Shadrin, N.V. 2008. The Crimean hypersaline lakes: general peculiarities. In: Yu.N. Tokarev, Z.Z. Finenko and N.V. Shadrin (Eds), The Black Sea microalgae: problems of biodiversity preservation and biotechnological usage, ECOSIGidrofizika, Sevastopol: 85-118. (in Russian).
• Shadrin, N.V. 2009. The Crimean hypersaline lakes: towards development of scientific basis of integrated sustainable management. In: Proceedings of 13th World Lake Conference, 1-5 November, Wuhan, China, Shadrin, N.V., Golubkov, S.M., Balushkina, E.V., Orleansky, V.K. and Mikhodyuk, O.S. 2004. Ecosystem response of hypersaline Bakalskoye Lake (Crimea, Black Sea) on climatic peculiarities of 2004. Marine Ecological Journal, 3: 74-75. (in Russian).
• Shadrin, N.V., Mironov, S.S. and Ferat, T.A. 2012. Interrelations between the losses of sandy beaches and biodiversity in seas: Case of the Bakalskaya Spit (Crimea, Ukraine, Black sea). Turkish Journal of Fisheries and Aquatic Sciences, 12: 411-415.
• Shadrin, N.V., Zagorodnyaya, Yu.A., Nevrova, E.L., Naidanova, O.G. and Senicheva, M.I. (2001) Hydroecological system of Bakalskaya spit (Crimea): Problems of investigation and preservation of the unique biodiversity. Naukovi Zapiski Ternopolskogo Universiteta, 14: 168–170. (in Russian).
• Smol, J.P., Wolfe, A.P. and Birks, H.J.B. 2005. Climatedriven regime shifts in the biological communities of arctic lakes. Proceedings of the National Academy of Sciences, 102: 4397–4402.
• Velasco, J., Millan, A., Hernandez, J., Gutierrez, C., Abellan, P., Sanchez, A. and Ruiz, M. 2006. Response of biotic communities to salinity changes in a Mediterranean hypersaline stream. Saline Systems, 12: 1-15. doi: 10.1186/1746-1448-2-12: Walther G.R., Post, E., Convey, P., Menzel, A., Parmesan, C., Beebee, T.J., Fromentin, J.M., Hoegh-Goldberg, O. and Bairlein, F. 2002. Ecological responses to recent climate change. Nature, 416: 389–395.
• Zagorodnyaya, Yu.A., Batogova, E.A. and Shadrin, N.V. 200 Long-term transformation of zooplankton in the hypersaline lake Bakalskoe (Crimea) under salinity fluctuations. Marine Ecological Journal, 7: 41-50. (in Russian). Zenkovich, V.P. 1960. Morphology and dynamics of Soviet Shoreline of the Black Sea. AN SSSR, Moscow, 215 pp. (in Russian).
• Zheng, M. 2001. On salinology. Hydrobiologia, 466: 3393