Distribution of viable resting stage cells of diatoms in sediments and water columns of the Chukchi Sea, Arctic Ocean

REFERENCES

• Aagaard K. & Roach A.T. 1990. Arctic Ocean-shelf exchange: measurements in Barrow Canyon. Journal of Geophysical Research 95: 18163–18175.
   Web of Science ®Google Scholar
• Arrigo K.R. & Van Dijken G.L. 2011. Secular trends in Arctic Ocean net primary production. Journal of Geophysical Research 116: C09011.
   Web of Science ®Google Scholar
• Arrigo K.R., Perovich D.K., Pickart R.S., Brown Z.W., van Dijken G.L., Lowry K.E., Mills M.M., Palmer M.A., Balch W.M., Bahr F., Bates N.R., Benitez-Nelson C., Bowler B., Brownlee E., Ehn J.K., Frey K.E., Garley R., Laney S.R., Lubelczyk L., Mathis J., Matsuoka A., Mitchell B.G., Moore G.W.K., Ortega-Retuerta E., Pal S., Polashenski C.M., Reynolds R.A., Scheiber B., Sosik H.M., Stephens M. & Swift J.H. 2012. Massive phytoplankton blooms under Arctic sea ice. Science 336: 1408.
   PubMed Web of Science ®Google Scholar
• Arrigo K.R., Perovich D.K., Pickart R.S., Brown Z.W., van Dijken G.L., Lowry K.E., Mills M.M., Palmer M.A., Balch W.M., Bates N.R., Benitez-Nelson C.R., Brownlee E., Frey K.E., Laney S.R., Mathis J., Matsuoka A., Mitchell B.G., Moore G.W.K., Reynolds R.A., Sosik H.M. & Swift J.H. 2014. Phytoplankton blooms beneath the sea ice in the Chukchi Sea. Deep Sea Research Part II 105: 1–16.
   Web of Science ®Google Scholar
• Bienfang P.K. 1981. Sinking rates of heterogeneous, temperate phytoplankton populations. Journal of Plankton Research 3: 235–253.
   Google Scholar
• Booth B.C. & Horner R.A. 1997. Microalgae on the Arctic Ocean Section, 1994: species abundance and biomass. Deep Sea Research Part II 44: 1607–1622.
   Web of Science ®Google Scholar
• Bursa A.S. 1961. The annual oceanographic cycle at Igloolik in the Canadian Arctic: II. The phytoplankton. Journal of the Fisheries Research Board of Canada 18: 563–615.
   Web of Science ®Google Scholar
• Chen L.C.M., Edelstein T. & Mclachlan J. 1969. Bonnemaisonia hamifera Hariot in nature and in culture. Journal of Phycology 5: 211–220.
   PubMed Web of Science ®Google Scholar
• Coachman L.K., Aagaard K. & Tripp R.B. 1975. Bering Strait: the regional physical oceanography. University of Washington Press, Seattle. 172 pp.
   Google Scholar
• Cupp E.E. 1943. Marine plankton diatoms of the west coast of North America. In: Bulletin of the Scripps Institution of Oceanography (Ed. by H.U. Sverdrup, R.H. Fleming, L.H. Miller & C.E. Zobell), vol. 5. University of California Press, Berkeley. 238 pp.
   Google Scholar
• Doucette G.J. & Fryxell G.A. 1983. Thalassiosira antarctica: vegetative and resting stage chemical composition of an ice-related marine diatom. Marine Biology 78: 1–6.
   Web of Science ®Google Scholar
• Garrison D.L. 1981. Monterey Bay phytoplankton. II. Resting spore cycles in coastal diatom populations. Journal of Plankton Research 3: 137–156.
   Google Scholar
• Garrison D.L. 1984. Planktonic diatoms. In: Marine plankton life cycle strategies (Ed. by K.A. Steidinger & L.M. Walker), pp. 1–17. CRC Press Inc., Boca Raton.
   Google Scholar
• Garrison D.L., Ackley S.F. & Buck K.R. 1983. A physical mechanism for establishing algal populations in frazil ice. Nature 306: 363–365.
   Web of Science ®Google Scholar
• Gosselin M., Levasseur M., Wheeler P.A., Horner R.A. & Booth B.C. 1997. New measurements of phytoplankton and ice algal production in the Arctic Ocean. Deep Sea Research Part II 44: 1623–1644.
   Web of Science ®Google Scholar
• Grebmeier J.M., McRoy C.P. & Feder H.M. 1988. Pelagic-benthic coupling on the shelf of the northern Bering and Chukchi Seas. I. Food supply source and benthic biomass. Marine Ecology Progress Series 48: 57–67.
   Web of Science ®Google Scholar
• Grøntved J. & Seidenfaden G. 1938. The Godthaab Expedition 1928. The phytoplankton of the waters west of Greenland. In: Meddelelser om Grønland, 82. Bianco Lunos Bogtrykkeri, Copenhagen. 380 pp.
   Google Scholar
• Hargraves P.E. & French F.W. 1983. Diatom resting spores: significance and strategies. In: Survival strategies of the algae (Ed. by G.A. Fryxell), pp. 49–68. Cambridge University Press, Cambridge.
   Google Scholar
• Harris A.S.D., Jones K.J. & Lewis J. 1998. An assessment of the accuracy and reproducibility of the most probable number (MPN) technique in estimating numbers of nutrient stressed diatoms in sediment samples. Journal of Experimental Marine Biology and Ecology 231: 21–30.
   Web of Science ®Google Scholar
• Hasle G.R. 1990. Arctic plankton diatoms: dominant species, biogeography. In: Polar marine diatoms (Ed. by L.K. Medlin & J. Priddle), pp. 53–56. British Antarctic Survey, Cambridge.
   Google Scholar
• Hollibaugh J.T., Seibert D.L.R. & Thomas W.H. 1981. Observations on the survival and germination of resting spores of three Chaetoceros (Bacillariophyceae) species. Journal of Phycology 17: 1–9.
   Web of Science ®Google Scholar
• Hoogstraten A., Timmermans K.R. & De Baar H.J.W. 2012. Morphological and physiological effects in Proboscia alata (bacillariophyceae) grown under different light and CO2 conditions of the modern Southern Ocean. Journal of Phycology 48: 559–568.
   Web of Science ®Google Scholar
• Horner R. 1984. Phytoplankton abundance, chlorophyll a, and primary productivity in the western Beaufort Sea. In: The Alaskan Beaufort Sea (Ed. by P.W. Barnes, D.M. Schell & E. Reimnitz), pp . 295–310. Academic Press, New York.
   Google Scholar
• Horner R. & Alexander V. 1972. Algal populations in Arctic Sea ice: an investigation of heterotrophy. Limnology and Oceanography 17: 454–458.
   Web of Science ®Google Scholar
• Horner R. & Schrader G.C. 1982. Relative contributions of ice algae, phytoplankton, and benthic microalgae to primary production in nearshore regions of the Beaufort Sea. Arctic 35: 485–503.
   Web of Science ®Google Scholar
• Hsiao S.I.C. 1980. Quantitative composition, distribution, community structure and standing stock of sea ice microalgae in the Canadian Arctic. Arctic 33: 768–793.
   Web of Science ®Google Scholar
• Hsiao S.I.C. 1992. Dynamics of ice algae and phytoplankton in Frobisher Bay. Polar Biology 12: 645–651.
   Web of Science ®Google Scholar
• Imai I., Itoh K. & Anraku M. 1984. Extinction dilution method for enumeration of dormant cells of red tide organisms in marine sediments. Bulletin of Plankton Society of Japan 31: 123–124.
   Google Scholar
• Imai I., Itakura S. & Itoh K. 1990. Distribution of diatom resting cells in sediments of Harima-Nada and northern Hiroshima Bay, the Seto Inland Sea, Japan. Bulletin on Coastal Oceanography 28: 75–84.
   Google Scholar
• Imai I., Itakura S., Matsuyama Y. & Yamaguchi M. 1996a. Selenium requirement for growth of a novel red tide flagellate Chattonella verruculosa (Raphidophyceae) in culture. Fisheries Science 62: 834–835.
   Web of Science ®Google Scholar
• Imai I., Itakura S., Yamaguchi M. & Honjo T. 1996b. Selective germination of Heterosigma akashiwo (Raphidophyceae) cysts in bottom sediments under low light conditions: a possible mechanism of red tide initiation. In: Harmful and toxic algal blooms (Ed. by T. Yasumoto, Y. Oshima & Y. Fukuyo), pp. 197–200. International Oceanographic Commission of UNESCO, Paris.
   Google Scholar
• Ishikawa A. & Furuya K. 2004. The role of diatom resting stages in the onset of the spring bloom in the East China Sea. Marine Biology 145: 633–639.
   Web of Science ®Google Scholar
• Ishikawa A., Yabushita Y., Furuya K. & Masuda T. 2001. Potential importance of diatom resting stage cells in the onset of blooms on the shelf of the East China Sea. Bulletin of Plankton Society of Japan 48: 85–94.
   Google Scholar
• Itakura S. & Imai I. 1994. Distribution of Chaetoceros (Bacillariophyceae) resting spores observed in the surface water of Harima-Nada, in the summer of 1991, with reference to the oceanographic conditions. Bulletin of the Japanese Society of Fisheries Oceanography 58: 29–42. (in Japanese)
   Google Scholar
• Itakura S., Imai I. & Itoh K. 1992. Morphology and rejuvenation of Skeletonema costatum (Bacillariophyceae) resting cells from the bottom sediments of Hiroshima Bay, the Seto Inland Sea, Japan. Bulletin of Plankton Society of Japan 38: 135–145. (in Japanese with English abstract)
   Google Scholar
• Itakura S., Yamaguchi M. & Imai I. 1993. Resting spore formation and germination of Chaetoceros didymus var. protuberans (Bacillariophyceae) in clonal culture. Bulletin of the Japanese Society of Scientific Fisheries 59: 807–813. (in Japanese with English abstract)
   Web of Science ®Google Scholar
• Itakura S., Imai I. & Itoh K. 1997. “Seed bank” of coastal planktonic diatoms in bottom sediments of Hiroshima Bay, Seto Inland Sea, Japan. Marine Biology 128: 497–508.
   Web of Science ®Google Scholar
• Itakura S., Nagasaki K., Yamaguchi M. & Imai I. 1999. Abundance and spatial distribution of viable resting stage cells of planktonic diatoms in bottom sediments of the Seto Inland Sea, Japan. In: Proceedings of 14th International Diatom Symposium (Ed. by S. Mayama, M. Idei & I. Koizumi), pp. 213–226. Koeltz Scientific Books, Koenigstein, Germany.
   Google Scholar
• Itoh K. & Imai I. 1987. Rafido so (Raphidophyceae). In: A guide for studies of red tide organisms (Ed. by Japan Fisheries Resource Conservation Association), pp. 122–130. Shuwa, Tokyo. (in Japanese)
   Google Scholar
• Kamiyama T. 1996. Determination of the abundance of viable tintinnid cysts in marine sediments in Hiroshima Bay, the Seto Inland Sea of Japan, using a modified MPN method. Journal of Plankton Research 18: 1253–1259.
   Web of Science ®Google Scholar
• Kuwata A. & Takahashi M. 1990. Life-form population responses of a marine planktonic diatom, Chaetoceros pseudocurvisetus, to oligotrophication in regionally upwelled water. Marine Biology 107: 503–512.
   Web of Science ®Google Scholar
• Kuwata A., Hama T. & Takahashi M. 1993. Ecophysiological characterization of two life forms, resting spores and resting cells, of a marine planktonic diatom, Chaetoceros pseudocurvisetus, formed under nutrient depletion. Marine Ecology Progress Series 102: 245–255.
   Web of Science ®Google Scholar
• Laney S.R. & Sosik H.M. 2014. Phytoplankton assemblage structure in and around a massive under-ice bloom in the Chukchi Sea. Deep Sea Research Part II 105: 30–41.
   Web of Science ®Google Scholar
• McQuoid M.R. 2002. Pelagic and benthic environmental controls on the spatial distribution of a viable diatom propagule bank on the Swedish west coast. Journal of Phycology 38: 881–893.
   Web of Science ®Google Scholar
• McQuoid M.R. & Godhe A. 2004. Recruitment of coastal planktonic diatoms from benthic versus pelagic cells: variations in bloom development and species composition. Limnology and Oceanography 49: 1123–1133.
   Web of Science ®Google Scholar
• McQuoid M.R. & Hobson L.A. 1996. Diatom resting stages. Journal of Phycology 32: 889–902.
   Web of Science ®Google Scholar
• McQuoid M.R. & Nordberg K. 2006. Composition and origin of benthic flocculent layers in Swedish fjords following the spring bloom – contribution of diatom frustules and resting stages. Nova Hedwigia 83: 1–16.
   Web of Science ®Google Scholar
• McRoy C.P. & Goering J.J. 1976. Annual budget of primary production in the Bering Sea. Marine Science Communications 2: 255–267.
   Google Scholar
• Melnikov I., Kolosova E.G., Welch H.E. & Zhitina L.S. 2002. Sea ice biological communities and nutrient dynamics in the Canada Basin of the Arctic Ocean. Deep Sea Research Part I 49: 1623–1649.
   Web of Science ®Google Scholar
• Mitbavkar S. & Anil A.C. 2002. Diatoms of the microphytobenthic community: population structure in a tropical intertidal sand flat. Marine Biology 140: 41–57.
   Web of Science ®Google Scholar
• Montresor M., Di Prisco C., Sarno D., Margiotta F. & Zingone A. 2013. Diversity and germination patterns of diatom resting stages at a coastal Mediterranean site. Marine Ecology Progress Series 484: 79–95.
   Web of Science ®Google Scholar
• Niemi A., Michel C., Hille K. & Poulin M. 2011. Protist assemblages in winter sea ice: setting the stage for the spring ice algal bloom. Polar Biology 34: 1803–1817.
   Web of Science ®Google Scholar
• Odate T. & Maita Y. 1990. Seasonal distribution and vertical flux of resting spores of Chaetoceros (Bacillariophyceae) species in the neritic water of Funka Bay, Japan. Bulletin of the Faculty of Fisheries Hokkaido University 41: 1–7.
   Google Scholar
• Olsen L.M., Laney S.R., Duarte P., Kauko H.M., Fernández-Méndez M., Mundy C.J., Rösel A., Meyer A., Itkin P., Cohen L., Peeken I., Tatarek A., Róźańska-Pluta M., Wiktor J., Taskjelle T., Pavlov A.K., Hudson S.R., Granskog M.A., Hop H. & Assmy P. 2017. The seeding of ice algal blooms in Arctic pack ice: the multiyear ice seed repository hypothesis. Journal of Geophysical Research: Biogeosciences 122: 1529–1548.
   Web of Science ®Google Scholar
• Perovich D.K. 1998. The optical properties of sea ice. In: Physics of ice-covered seas, vol. 1 (Ed. by M. Leppäranta), pp. 195–230. Helsinki University Press, Helsinki.
   Google Scholar
• Perovich D.K. & Polashenski C. 2012. Albedo evolution of seasonal Arctic sea ice. Geophysical Research Letters 39: L08501.
   Web of Science ®Google Scholar
• Perrette M., Yool A., Quartly G.D. & Popova E.E. 2011. Near-ubiquity of ice-edge blooms in the Arctic. Biogeosciences 8: 515–524.
   Web of Science ®Google Scholar
• Pitcher G.C. 1990. Phytoplankton seed populations of the Cape Peninsula upwelling plume, with particular reference to resting spores of Chaetoceros (Bacillariophyceae) and their role in seeding upwelling waters. Estuarine, Coastal and Shelf Science 31: 283–301.
   Web of Science ®Google Scholar
• Pitcher G.C., Walker D.R., Mitchell-Innes B.A. & Moloney C.L. 1991. Short-term variability during an anchor station study in the southern Benguela upwelling system: phytoplankton dynamics. Progress in Oceanography 28: 39–64.
   Web of Science ®Google Scholar
• Poulin M., Daugbjerg N., Gradinger R., Ilyash L., Ratkova T. & Von Quillfeldt C.H. 2011. The pan-Arctic biodiversity of marine pelagic and sea-ice unicellular eukaryotes: a first-attempt assessment. Marine Biodiversity 41: 13–28.
   Google Scholar
• Ratkova T.N. & Wassman P. 2005. Sea ice algae in the White and Barents Seas: composition and origin. Polar Research 24: 95–110.
   Web of Science ®Google Scholar
• Reimnitz E., Marincovich L. Jr., McCormick M. & Briggs W.M. 1992. Suspension freezing of bottom sediment and biota in the Northwest Passage and implications for Arctic Ocean sedimentation. Canadian Journal of Earth Sciences 29: 693–703.
   Web of Science ®Google Scholar
• Reimnitz E., Clayton J.R., Kempema E.W., Payne J.R. & Weber W.S. 1993. Interaction of rising frazil with suspended particles: tank experiments with applications to nature. Cold Regions Science and Technology 21: 117–135.
   Web of Science ®Google Scholar
• Saito K. & Taniguchi A. 1978. Phytoplankton communities in the Bering Sea and adjacent seas. II. Spring and summer communities in seasonally ice-covered areas. Astarte 11: 27–35.
   Google Scholar
• Sakshaug E. 2004. Primary and secondary production in the Arctic seas. In: The organic carbon cycle in the Arctic Ocean (Ed. by R. Stein & R.W. Macdonald), pp. 57–81. Springer-Verlag, Berlin.
   Google Scholar
• Sergeeva V.M., Sukhanova I.N., Flint M.V., Pautova L.A., Grebmeier J.M. & Cooper L.W. 2010. Phytoplankton community in the Western Arctic in July–August 2003. Oceanology 50: 184–197.
   Web of Science ®Google Scholar
• Shimada K., Carmack E.C., Hatakeyama K. & Takizawa T. 2001. Varieties of shallow temperature maximum waters in the western Canadian Basin of the Arctic Ocean. Geophysical Research Letters 28: 3441–3444.
   Web of Science ®Google Scholar
• Smetacek V.S. 1985. Role of sinking in diatom life-history cycles: ecological, evolutionary and geological significance. Marine Biology 84: 239–251.
   Web of Science ®Google Scholar
• Springer A.M. & McRoy C.P. 1993. The paradox of pelagic food webs in the northern Bering Sea-III. Patterns of primary production. Continental Shelf Research 13: 575–599.
   Web of Science ®Google Scholar
• Sugie K. & Kuma K. 2008. Resting spore formation in the marine diatom Thalassiosira nordenskioeldii under iron- and nitrogen-limited conditions. Journal of Plankton Research 30: 1245–1255.
   Web of Science ®Google Scholar
• Sukhanova I.N., Flint M.V., Whitledge T.E., Stockwell D.A. & Rho T.K. 2006. Mass development of the planktonic diatom Proboscia alata over the Bering Sea shelf in the summer season. Oceanology 46: 200–216.
   Web of Science ®Google Scholar
• Sukhanova I.N., Flint M.V., Pautova L.A., Stockwell D.A., Grebmeier J.M. & Sergeeva V.M. 2009. Phytoplankton of the western Arctic in the spring and summer of 2002: structure and seasonal changes. Deep Sea Research Part II 56: 1223–1236.
   Web of Science ®Google Scholar
• Syvertsen E.E. 1991. Ice algae in the Barents Sea: types of assemblages, origin, fate and role in the ice-edge phytoplankton bloom. Polar Research 10: 277–288.
   Web of Science ®Google Scholar
• 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. Journal of the Oceanographical Society of Japan 32: 99–106.
   Google Scholar
• Throndsen J. 1978. The dilution-culture method. In: Phytoplankton manual (Ed. by A. Sournia), pp. 218–224. UNESCO, Paris.
   Google Scholar
• Tomas C.R. 1997. Identifying marine phytoplankton. Academic Press, San Diego. 858 pp.
   Google Scholar
• Von Quillfeldt C.H. 1997. Distribution of diatoms in Northeast Water Polynya, Greenland. Journal of Marine Systems 10: 211–240.
   Web of Science ®Google Scholar
• Von Quillfeldt C.H. 2004. The diatom Fragilariopsis cylindrus and its potential as an indicator species for cold water rather than for sea ice. Vie et Milieu 54: 137–143.
   Web of Science ®Google Scholar
• Von Quillfeldt C.H., Ambrose W.G., Jr. & Clough L.M. 2003. High number of diatom species in first-year ice from the Chukchi Sea. Polar Biology 26: 806–818.
   Web of Science ®Google Scholar
• Walsh J.J., McRoy C.P., Coachman L.K., Goering J.J., Nihoul J.J., Whitledge T.E., Blackburn T.H., Parker P.L., Wirick C.D., Shuert P.G., Grebmeier J.M., Springer A.M., Tripp R.D., Hansell D.A., Djenidi S., Deleersnijder E., Henriksen K., Lund B.A., Andersen P., Mueller-Karger F.E. & Dean K. 1989. Carbon and nitrogen cycling within the Bering/Chukchi Seas: source regions for organic matter effecting AOU demands of the Arctic Ocean. Progress in Oceanography 22: 277–359.
   Web of Science ®Google Scholar
• Weingartner T.J., Cavalieri D.J., Aagaard K. & Sasaki Y. 1998. Circulation, dense water formation and outflow on the northeast Chukchi Sea shelf. Journal of Geophysical Research 103: 7647–7661.
   Web of Science ®Google Scholar
• Weingartner T., Aagaard K., Woodgate R., Danielson S., Sasaki Y. & Cavalieri D. 2005. Circulation on the north central Chukchi Sea shelf. Deep Sea Research Part II 52: 3150–3174.
   Web of Science ®Google Scholar
• Weissenberger J. & Grossmann S. 1998. Experimental formation of sea ice: importance of water circulation and wave action for incorporation of phytoplankton and bacteria. Polar Biology 20: 178–188.
   Web of Science ®Google Scholar
• Werner I., Ikävalko J. & Schünemann H. 2007. Sea-ice algae in Arctic pack ice during late winter. Polar Biology 30: 1493–1504.
   Web of Science ®Google Scholar
• Woodgate R.A., Aagaard K. & Weingartner T.J. 2005. A year in the physical oceanography of the Chukchi Sea: moored measurements from autumn 1990–1991. Deep Sea Research Part II 52: 3116–3149.
   Web of Science ®Google Scholar
• Zhang Q., Gradinger R. & Spindler M. 1995. Dark survival of marine microalgae in the high Arctic (Greenland Sea). Polarforschung 65: 111–116.
   Google Scholar
• Zheng S., Wang G., Zhang F., Cai M. & He J. 2011. Dominant diatom species in the Canadian Basin in summer 2003, a reported serious melting season. Polar Record 47: 244–261.
   Web of Science ®Google Scholar