Paleolimnological studies from the Antarctic and subantarctic islands
Hodgson, D.A.; Doran, P.T.; Roberts, D.; McMinn, A.. 2004 Paleolimnological studies from the Antarctic and subantarctic islands. In: Pienitz, R.; Douglas, M.S.V.; Smol, J.P., (eds.) Long-term environmental change in Arctic and Antarctic lakes. Dordrecht, Springer, 419-474. (Developments in paleoenvironmental research, Vol. 8).Full text not available from this repository. (Request a copy)
To compile reference data for palaeolimnological studies using fossil pigment, we examined the extent to which environmental variables, gross morphology and species composition influence the modern pigment content of in situ microbial communities in 62 east Antarctic lakes. Pigment contents, measured using HPLC, were compared with 32 environmental variables, gross microbial mat morphology and cyanobacterial species composition in each lake. Results showed low concentrations or an absence of pigments in the water columns of most lakes. For benthic microbial communities, multivariate statistical analyses identified lake depth as the most important factor explaining pigment composition. In deeper lakes the pigment composition was dominated by chlorophylls, in intermediate depth lakes by chlorophylls and carotenoids, and in shallow lakes by scytonemins, ultraviolet-screening pigments found in cyanobacteria. In addition to lake depth, conductivity, turbidity, dissolved oxygen, sulphate and geographical location were all significant (p<0.05) in explaining variance in the pigment content. Significant differences in microbial mat gross morphologies ocurred at different lake depths (p<0.01), and were characterised by significant differences in their pigment content(p<0.004). Despite the high abundance of scytonemin in shallow lakes, there were only limited changes in the absolute concentrations of chlorophylls and carotenoids. We conclude that lake depth is the most significant factor influencing both gross mat morphology and pigment content presumably as a result of its influence on the light climate. In general, the ability of the cyanobacteria to regulate their pigment content, morphology, community composition and motility to best exploit thelight environment at different lake depths may explain their dominance in these systems.
|Item Type:||Publication - Book Section|
|Digital Object Identifier (DOI):||10.1007/978-1-4020-2126-8_14|
|Programmes:||BAS Programmes > Antarctic Science in the Global Context (2000-2005) > Signals in Antarctica of Past Global Changes|
|Date made live:||18 Jan 2012 11:33|
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