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Physicochemical and biological dynamics in a coastal Antarctic lake as it transitions from frozen to open water

Published online by Cambridge University Press:  07 March 2013

Markus Dieser
Affiliation:
Montana State University, Center for Biofilm Engineering and Department of Land Resources and Environmental Sciences, 366 EPS Building, Bozeman, MT 59717, USA Louisiana State University, Department of Biological Sciences, 202 Life Sciences Building, Baton Rouge, LA 70803, USA
Christine M. Foreman*
Affiliation:
Montana State University, Center for Biofilm Engineering and Department of Land Resources and Environmental Sciences, 366 EPS Building, Bozeman, MT 59717, USA
Christopher Jaros
Affiliation:
INSTAAR, University of Colorado, 1560 30th Street, Boulder, CO 80309, USA
John T. Lisle
Affiliation:
USGS, Center for Coastal and Watershed Studies, St Petersburg, FL 33701, USA
Mark Greenwood
Affiliation:
Montana State University, Department of Mathematical Sciences, Bozeman, MT 59717, USA
Johanna Laybourn-Parry
Affiliation:
University of Bristol, Bristol Glaciology Centre, School of Geographical Sciences, Bristol BS8 1SS, UK
Penney L. Miller
Affiliation:
Rose-Hulman Institute of Technology, Department of Chemistry, 5500 Wabash Ave, Terre Haute, IN 47803, USA
Yu-Ping Chin
Affiliation:
The Ohio State University, School of Earth Sciences, 285 Mendenhall Laboratory, Columbus, OH 43210, USA
Diane M. Mcknight
Affiliation:
INSTAAR, University of Colorado, 1560 30th Street, Boulder, CO 80309, USA
*
*Corresponding author: [email protected]

Abstract

Pony Lake, at Cape Royds, Antarctica, is a shallow, eutrophic, coastal lake that freezes solid in the winter. Changes in Pony Lake's physicochemical parameters and microbial community were studied during the transition from ice to open water. Due to rising water temperatures, the progressive melt of the ice column and the gradual mixing of basal brines into the remaining water column, Pony Lake evolved physically and chemically over the course of the summer, thereby affecting the microbial community composition. Temperature, pH, conductivity, nutrients and major ion concentrations reached their maximum in January. Pony Lake was colonized by bacteria, viruses, phytoflagellates, ciliates, and a small number of rotifers. Primary and bacterial production were highest in mid-December (2.66 mg C l-1 d-1 and 30.5 μg C l-1 d-1, respectively). A 16S rRNA gene analysis of the bacterioplankton revealed 34 unique sequences dominated by members of the β- and γ-proteobacteria lineages. Cluster analyses on denaturing gradient gel electrophoresis (DGGE) banding patterns and community structure indicated a shift in the dominant members of the microbial community during the transition from winter ice, to early, and late summer lakewater. Our data demonstrate that temporal changes in physicochemical parameters during the summer months determine community dynamics and mediate changes in microbial species composition.

Type
Biological Sciences
Copyright
Copyright © Antarctic Science Ltd 2013 

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References

Armitage, K.B.House, H.B. 1962. A limnological reconnaissance in the area of McMurdo Sound, Antarctica. Limnology and Oceanography, 7, 3641.CrossRefGoogle Scholar
Bell, E.M.Laybourn-Parry, J. 1999. The plankton community of a young, eutrophic, Antarctic saline lake. Polar Biology, 22, 248253.CrossRefGoogle Scholar
Benner, R.Biddanda, B. 1998. Photochemical transformations of surface and deep marine dissolved organic matter: effects on bacterial growth. Limnology and Oceanography, 43, 13731378.CrossRefGoogle Scholar
Brown, A., McKnight, D.A., Chin, Y., Roberts, E.C.Uhle, M. 2004. Chemical characterization of dissolved organic material in Pony Lake, a saline coastal pond in Antarctica. Marine Chemistry, 89, 327337.CrossRefGoogle Scholar
Butler, H.G. 1999. Seasonal dynamics of the planktonic microbial community in a Maritime Antarctic lake undergoing eutrophication. Journal of Plankton Research, 21, 23932419.CrossRefGoogle Scholar
Butler, H.G., Edworthy, M.G.Ellis-Evans, J.C. 2000. Temporal plankton dynamics in an oligotrothic Maritime Antarctic lake. Freshwater Biology, 43, 215230.CrossRefGoogle Scholar
Dieser, M. 2009. Ecosystem dynamics and temporal variations in a microbially dominated, coastal Antarctic lake. PhD thesis, Montana State University, 253 pp. [Unpublished.]Google Scholar
Foreman, C.M., Dieser, M., Greenwood, M., Cory, R.M., Laybourn-Parry, J., Lisle, J.T., Jaros, C., Miller, P.L., Chin, Y.P.McKnight, D.M. 2011. When a habitat freezes solid: microorganisms over-winter within the ice column of a coastal Antarctic lake. FEMS Microbiology Ecology, 76, 401412.CrossRefGoogle Scholar
Glatz, R.E., Lepp, P.W., Ward, B.B.Francis, C.A. 2006. Planktonic microbial community composition across steep physical/chemical gradients in permanently ice-covered Lake Bonney, Antarctica. Geology, 4, 5367.Google Scholar
Greenwood, M. 2012. A comparison of plots for monothetic clustering, with applications to microbial communities and educational test development. Electronic Journal of Applied Statistical Analysis, 5, 114.Google Scholar
Hawes, I. 1983. Nutrients and their effects on phytoplankton populations in lakes of Signy Island, Antarctica. Polar Biology, 2, 115126.CrossRefGoogle Scholar
Hawes, I., Safi, K., Sorrell, B., Webster-Brown, J.Arscott, D. 2011. Summer–winter transitions in Antarctic ponds I: The physical environment. Antarctic Science, 23, 235242.CrossRefGoogle Scholar
Healy, M., Webster-Brown, J.G., Brown, K.L.Lane, V. 2006. Chemistry and stratification of Antarctic meltwater ponds II: Inland ponds in the McMurdo Dry Valleys, Victoria Land. Antarctic Science, 18, 525533.CrossRefGoogle Scholar
Howard-Williams, C.Hawes, I. 2007. Ecological processes in Antarctic inland waters: interactions between physical processes in the nitrogen cycle. Antarctic Science, 19, 205217.CrossRefGoogle Scholar
Laybourn-Parry, J. 2009. No place too cold. Science, 324, 15211522.CrossRefGoogle ScholarPubMed
Laybourn-Parry, J.Marshall, W.A. 2003. Photosynthesis, mixotrophy and microbial plankton dynamics in two high Arctic lakes during summer. Polar Biology, 26, 517524.CrossRefGoogle Scholar
Laybourn-Parry, J., Quayle, W.Henshaw, T. 2002. The biology and evolution of Antarctic saline lakes in relation to salinity and trophy. Polar Biology, 25, 542552.CrossRefGoogle Scholar
Lisle, J.T.Priscu, J.C. 2004. The occurrence of lysogenic bacteria and microbial aggregates in the lakes of the McMurdo Dry Valleys, Antarctica. Microbial Ecology, 47, 427439.CrossRefGoogle ScholarPubMed
Lizotte, M.P., Sharp, T.R.Priscu, J.C. 1996. Phytoplankton dynamics in the stratified water column of Lake Bonney, Antarctica. I. Biomass and productivity during the winter-spring transition. Polar Biology, 16, 155162.CrossRefGoogle Scholar
Madan, N.J., Marshall, W.A.Laybourn-Parry, J. 2005. Virus and microbial loop dynamics over an annual cycle in three contrasting Antarctic lakes. Freshwater Biology, 50, 12911300.CrossRefGoogle Scholar
Mao, J., Cory, R.M., McKnight, D.M.Schmidt-Rohr, K. 2007. Characterization of a nitrogen-rich fulvic acid and its precursor algae from solid state NMR. Organic Geochemistry, 38, 12771292.CrossRefGoogle Scholar
Mataloni, G., Tesolin, G.Tell, G. 1998. Characterization of a small eutrophic Antarctic lake (Otero Lake, Cierva Point) on the basis of algal assemblages and water chemistry. Polar Biology, 19, 107114.CrossRefGoogle Scholar
McKnight, D.M., Andrews, E.D., Spaulding, S.A.Aiken, G.R. 1994. Aquatic fulvic acids in algal-rich Antarctic ponds. Limnology and Oceanography, 39, 19721979.CrossRefGoogle Scholar
Murray, A.E., Hollibaugh, J.T.Orrego, C. 1996. Phylogenetic compositions of bacterioplankton from two California estuaries compared by denaturing gradient gel electrophoresis of 16S rDNA fragments. Applied Environmental Microbiology, 62, 26762680.CrossRefGoogle ScholarPubMed
Muyzer, G., Hottentrager, S., Teske, A.Wawer, C. 1996. Denaturing gradient gel electrophoresis of PCR-amplified 16S rDNA - a new molecular approach to analyse the genetic diversity of mixed microbial communities. In Akkermans, A.D.L., van Elsas, J.D.&De Bruijn, F.J., eds. Molecular microbial ecology manual. Dordrecht: Kluwer Academic, 3.4.4.1–3.4.4.22.Google Scholar
Pearce, D.A. 2005. The structure and stability of the bacterioplankton community in Antarctic freshwater lakes, subject to extremely rapid environmental change. FEMS Microbiology Ecology, 53, 6172.CrossRefGoogle ScholarPubMed
Perriss, S.J.Laybourn-Parry, J. 1997. Microbial communities in saline lakes of Vestfold Hills (eastern Antarctica). Polar Biology, 18, 135144.CrossRefGoogle Scholar
Priscu, J.C., Wolf, C.F. 2000. Limnological methods for the McMurdo Dry Valleys Long-term Ecological Research Program. www.mcmlter.org/data/lakes/MCM_Limno_Methods.pdf.Google Scholar
Priscu, J.C., Wolf, C.F., Takacs, C.D., Fritsens, C.H., Laybourn-Parry, J., Roberts, E.C.Lynos, B. 1999. Organic carbon transformations in the water column of a perennially ice-covered Antarctic lake. Biosciences, 49, 9971008.CrossRefGoogle Scholar
Roberts, E.C., Priscu, J.C.Laybourn-Parry, J. 2004. Microplankton dynamics in a perennially ice-covered Antarctic lake - Lake Hoare. Freshwater Biology, 49, 853869.CrossRefGoogle Scholar
Säwström, C., Lisle, J., Anesio, A.M., Priscu, J.C.Laybourn-Parry, J. 2008. Bacteriophage in polar inland waters. Extremophiles, 12, 167175.CrossRefGoogle ScholarPubMed
Schmidt, S., Moskal, W., De Moraz, S.J., Howard-Williams, C.Vincent, W.F. 1991. Limnological properties of Antarctic ponds during winter freezing. Antarctic Science, 3, 379388.CrossRefGoogle Scholar
Stackebrandt, E.Liesack, W. 1993. Nucleic acids and classification. In Goodfellow, M.&O'Donnell, A.G.,eds. Handbook of new bacterial systematic. London: Academic Press, 151194.Google Scholar
Takacs, C.T.Priscu, J.C. 1998. Bacterioplankton dynamics in the McMurdo Dry Valley lakes: production and biomass loss over four seasons. Microbial Ecology, 36, 239250.CrossRefGoogle ScholarPubMed
Torii, T., Matsumoto, G.I.Nakaya, S. 1988. The chemical characteristics of Antarctic lakes and ponds, with special emphasis on the distribution of nutrients. Polarforschung, 58, 219230.Google Scholar
Van Trappen, S., Mergaert, J., van Eygen, S., Dawyndt, P., Cnockaert, M.C.Swings, J. 2002. Diversity of 746 heterotrophic bacteria isolated from microbial mats from ten Antarctic lakes. Systematic and Applied Microbiology, 25, 603610.CrossRefGoogle ScholarPubMed
Villaescusa, J.A., Casamayor, E.O., Rochera, C., Velázquez, D., Chicote, Á., Quesada, A.Camacho, A. 2010. A close link between bacterial community composition and environmental heterogeneity in Maritime Antarctic lakes. International Microbiology, 13, 6777.Google ScholarPubMed
Vincent, W.F.Vincent, C.L. 1982. Response to nutrient enrichment by the plankton of Antarctic coastal lakes and the inshore Ross Sea. Polar Biology, 1, 159165.CrossRefGoogle Scholar
Webster-Brown, J., Hawes, I., Safi, K., Sorrell, B.Wilson, N. 2012. Summer–winter transitions in Antarctic ponds: III. Chemical changes. Antarctic Science, 24, 121130.CrossRefGoogle Scholar
Weinbauer, M.G. 2004. Ecology of prokaryotic viruses. FEMS Microbiology Reviews, 28, 127181.CrossRefGoogle ScholarPubMed
West, W.West, G.S. 1911. Freshwater algae. In Murray, J.,ed. Biology. Vol. 1. Reports on the Scientific Investigations, British Antarctic expedition 1907–09. London: Heinemann, 263298.Google Scholar
Zhang, Z., Schwartz, S., Wagner, L.Miller, W. 2000. A greedy algorithm for aligning DNA sequences. Journal of Computational Biology, 7, 203214.CrossRefGoogle ScholarPubMed