Abstract
The influence of sea ice on the species composition and cell density of phytoplankton was investigated in the eastern Bering Sea in spring 2008. Diatoms, particularly pennate diatoms, dominated the phytoplankton community. The dominant species were Grammonema islandica (Grunow in Van Heurck) Hasle, Fragilariopsis cylindrus (Grunow) Krieger, F. oceanica (Cleve) Hasle, Navicula vanhoeffenii Gran, Thalassiosira antarctica Comber, T. gravida Cleve, T. nordenskiöeldii Cleve, and T. rotula Meunier. Phytoplankton cell densities varied from 0.08×104 to 428.8×104 cells/L, with an average of 30.3×104 cells/L. Using cluster analysis, phytoplankton were grouped into three assemblages defined by ice-forming conditions: open water, ice edge, and sea ice assemblages. In spring, when the sea ice melts, the phytoplankton dispersed from the sea ice to the ice edge and even into open waters. Thus, these phytoplankton in the sea ice may serve as a “seed bank” for phytoplankton population succession in the subarctic ecosystem. Moreover, historical studies combined with these results suggest that the sizes of diatom species have become smaller, shifting from microplankton to nannoplankton-dominated communities.
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References
Aikawa H. 1932. On the summer plankton in the waters of the western Aleutian Islands in 1928. Bull. Jap. Soc. Sci. Fish., 1(2): 70–74. (in Japanese with English abstract)
Aizawa C, Tanimoto M, Jordan R W. 2005. Living diatom assemblages from North Pacific and Bering Sea surface waters during summer 1999. Deep-Sea Res. Pt. II, 52(16–18): 2 186–2 205.
Alexander V, Niebauer H J. 1981. Oceanography of the eastern Bering Sea ice edge zone in spring. Limnol. Oceanogr., 26(6): 1 111–1 125.
Banse K, English D C. 1999. Comparing phytoplankton seasonality in the eastern and western subarctic Pacific and the western Bering Sea. Prog. Oceanogr., 43(2–4): 235–288.
Hare C E, Leblanc K, DiTullio G R, Kudela R M, Zhang Y, Lee P A, Riseman S, Hutchins D A. 2007. Consequences of increased temperature and CO2 for phytoplankton community structure in the Bering Sea. Mar. Ecol.-Prog. Ser., 352: 9–16.
Hay M B, Pienitz R, Thomson R E. 2003. Distribution of diatom surface sediment assemblages within Effingham Inlet, a temperate fjord on the west coast of Vancouver Island (Canada). Mar. Micropaleontol., 48(3–4): 291–320.
He J F, Wang G Z, Li S J, Tushling K, Zheng S X. 2005. Community structure and biomass of ice algae and phytoplankton in the Laptev Sea (Arctic) in spring. Chin. J. Polar Res., 17(1): 1–10. (in Chinese with English abstract)
Hobson L A, McQuoid M R. 2001. Pelagic diatom assemblages are good indicators of mixed water intrusions into Saanich Inlet, a stratified fjord in Vancouver Island. Mar. Geol., 174(1–4): 125–138.
Humborg C, Ittekkot V, Cociasu A, Vonbodungen B. 1997. Effect of Danube River dam on Black Sea biogeochemistry and ecosystem structure. Nature, 386(6623): 385–388.
Hunt G L, Stabeno P, Walters G, Sinclair E, Brodeur R D, Napp J M, Bond N A. 2002. Climate change and control of the southeastern Bering Sea pelagic ecosystem. Deep-Sea Res. Pt. II, 49(26): 5 821–5 853.
Iverson R L, Coachman L K, Cooney R T, English T S, Goering J J, Hunt G L, Macauley M C, McRoy C P, Reeburg W S, Whitledge T E. 1979a. Ecological significance of fronts in the southeastern Bering Sea. In: Livingston R J ed. Ecological Processes in Coastal and Marine Systems. Plenum Press, New York. p.437–466.
Iverson R L, Whitledge T E, Goering J J. 1979b. Chlorophyll and nitrate fine structure in the southeastern Bering Sea shelf break front. Nature, 281: 664–666.
Karohji K. 1958. Report from the “Oshoro Maru” on oceanographic and biological investigations in the Bering Sea and northern North Pacific in the summer of 1955: IV. Diatom standing crops and the major constituents of the populations as observed by net sampling. Bull. Fac. Fish., Hokkaido Univ., 8(4): 243–252.
Karohji K. 1959. Report from the “Oshoro Maru” on oceanographic and biological investigations in the Bering Sea and northern North Pacific in the summer of 1955: IV. Diatom associations as observed by underway samplings. Bull. Fac. Fish., Hokkaido Univ., 9(4): 259–267.
Kawarada Y. 1957. A contribution of microplankton observations to the hydrography of the northern North Pacific and adjacent seas. II. Plankton diatoms in the Bering Sea in the summer of 1955. J. Oceanogr. Soc. Jap., 13: 151–155.
Lin G M, Yang Q L, Wang Y. 2013. Distribution pattern of microphytoplankton in the Bering Sea during the summer of 2010. Chin. J. Appl. Res., 24(9): 2 643–2 650. (in Chinese with English abstract)
Luchin V, Semiletov I, Weller G. 2002. Changes in the Bering Sea region: atmosphere-ice-water system in the second half of the twentieth century. Prog. Oceanogr., 55(1–2): 23–44.
Margalef R D. 1958. Information theory in ecology. Gen. Syst., 3: 36–71.
McQuoid M R, Hobson L A. 1998. Assessment of palaeoenvironmental conditions on southern Vancouver Island, British Columbia, Canada, using the marine tychoplankter Paralia sulcata. Diatom Res., 13(2): 311–321.
Merico A, Tyrrell T, Brown C W, Groom S B, Miller P I. 2003. Analysis of satellite imagery for Emiliania huxleyi blooms in the Bering Sea before 1997. Geophys. Res. Lett., 30(6): 1 337.
Merico A, Tyrrell T, Lessard E J, Oguz T, Stabeno P J, Zeeman S I, Whitledge T E. 2004. Modelling phytoplankton succession on the Bering Sea shelf: role of climate influences and trophic interactions in generating Emiliania huxleyi blooms 1997–2000. Deep Sea Res. Pt. I, 51(12): 1 803–1 826.
Motoda S, Kawarada Y. 1955. Diatom communities in western Aleutian waters on the basis of net samples collected in May–June 1953. Bull. Fac. Fish., Hokkaido Univ., 6(3): 191–200.
Napp J M, Hunt G L. 2001. Anomalous conditions in the south-eastern Bering Sea 1997: linkages among climate, weather, ocean, and biology. Fish. Oceanogr., 10(1): 61–68.
Niebauer H J, Alexander V. 1985. Oceanographic frontal structure and biological production at an ice edge. Cont. Shelf Res., 4(4): 367–388.
Ohwada M, Kon H. 1963. A microplankton survey as a contribution to the hydrography of the North Pacific and adjacent seas. 2. Distribution of the microplankton and their relation to the character of water masses in the Bering Sea and northern North Pacific Ocean in the summer of 1960. Oceanogr. Mag., 14(2): 87–99.
Olson M B, Strom S L. 2002. Phytoplankton growth, microzooplankton herbivory and community structure in the southeast Bering Sea: insight into the formation and temporal persistence of an Emiliania huxleyi bloom. Deep-Sea Res. Pt. II, 49(26): 5 969–5 990.
Pielou E. 1966. The measurement of diversity in different types of biological collections. J. Theor. Biol., 13: 131–144.
Ran L H, Chen J F, Jin H Y, Li H L, Lu Y, Wang K. 2013. Diatom distribution of surface sediment in the Bering Sea and Chukchi Sea. Adv. Polar. Sci., 24(2): 106–112.
Sambrotto R N, Niebauer H J, Goering J J, Iverson R L. 1986. Relationships among vertical mixing, nitrate uptake, and phytoplankton growth during the spring bloom in the southeast Bering Sea middle shelf. Cont. Shelf Res., 5(1–2): 161–198.
Schandelmeier L, Alexander V. 1981. An analysis of the influence of ice on spring phytoplankton population structure in the southeast Bering Sea. Limnol. Oceanogr., 26(5): 935–943.
Schumacher D, Bond N, Brodeur R, Livingston P, Navp J, Stabeno P. 2003. Climate change in the southeastern Bering Sea and some consequences for its biota. In: Hempel G ed. Large Marine Ecosystems of the World: Trends in Exploitation, Protection, and Research. 1st edn. Elsevier Science, Netherlands. p.17–51.
Shannon C, Wiener W. 1949. The Mathematical Theory of Communication. The University of Illinois Press, Urbana. 125p.
Shen Z L. 2002. Long-term changes in nutrient structure and its influences on ecology and environment in Jiaozhou Bay. Oceanogr. et Limnol. Sin., 33(3): 322–331. (in Chinese with English abstract)
Taniguchi A, Saito K, Koyama A, Fukuchi M. 1976. Phytoplankton communities in the Bering Sea and adjacent seas I. Communities in early warming season in southern areas. J. Oceanogr. Soc. Jap., 32(3): 99–106.
Tsukazaki C, Ishii K I, Saito R, Matsuno K, Yamaguchi A, Imai I. 2013. Distribution of viable diatom resting stage cells in bottom sediments of the eastern Bering Sea shelf. Deep-Sea Res. Pt. II, 94(2013): 22–30.
Whitledge T E, Stockwell D A, Zeeman S I, Coyle K O, Napp J M, Brodeur R D, Pinchuk A I, Hunt G L. 2001. Anomalous conditions in the south-eastern Bering Sea, 1997: nutrients, phytoplankton and zooplankton. Fish. Oceanogr., 10(1): 99–116.
Yang Q L, Lin G M, Lin M, Lin J H, Dai Y Y. 2002. Species composition and distribution of phytoplankton in Chukchi Sea and Bering Sea. Chin. J. Polar. Res., 14(2): 113–125. (in Chinese with English abstract)
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Supported by the National Natural Science Foundation of China (Nos. 41276128, 41476116) and the National Basic Research Program of China (973 Program) (No. 2010CB428704)
ZHOU Qianqian and WANG Peng contributed equally to this work.
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Zhou, Q., Wang, P., Chen, C. et al. Influences of sea ice on eastern Bering Sea phytoplankton. Chin. J. Ocean. Limnol. 33, 458–467 (2015). https://doi.org/10.1007/s00343-015-3367-8
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DOI: https://doi.org/10.1007/s00343-015-3367-8