A metagenomic assessment of winter and summer bacterioplankton from Antarctic Peninsula coastal surface waters

Antarctic surface oceans are well-studied during summer when irradiance levels are high, sea ice is melting and primary productivity is at a maximum. Coincident with this timing, the bacterioplankton respond with significant increases in secondary productivity. Little is known about bacterioplankton...

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Bibliographic Details
Published in:The ISME Journal
Main Authors: Grzymski, J, Riesenfeld, C, Williams, TJ, Dussaq, A, Ducklow, H, Erickson, M, Cavicchioli, R, Murray, A
Format: Article in Journal/Newspaper
Language:unknown
Published: International Society for Microbial Ecology 2012
Subjects:
14 Life Below Water
Antarctic Regions
Archaea
Autotrophic Processes
Bacteria
DNA
Archaeal
Bacterial
Gene Library
Heterotrophic Processes
Metagenomics
Phylogeny
Plankton
RNA
Ribosomal
Seasons
Seawater
Sequence Analysis
anzsrc-for: 060504 Microbial Ecology
anzsrc-for: 05 Environmental Sciences
anzsrc-for: 06 Biological Sciences
anzsrc-for: 10 Technology
Antarc*
Antarctic
Antarctic Peninsula
Sea ice
Southern Ocean
Online Access:http://hdl.handle.net/1959.4/unsworks_49920
https://unsworks.unsw.edu.au/bitstreams/a90c4a23-39ed-48be-b1f1-0049a2f47043/download
https://doi.org/10.1038/ismej.2012.31
Description
Summary:Antarctic surface oceans are well-studied during summer when irradiance levels are high, sea ice is melting and primary productivity is at a maximum. Coincident with this timing, the bacterioplankton respond with significant increases in secondary productivity. Little is known about bacterioplankton in winter when darkness and sea ice cover inhibit photoautotrophic primary production. We report here an environmental genomic and SSU rRNA analysis of winter and summer Antarctic Peninsula coastal seawater bacterioplankton. Intense inter-seasonal differences reflected through shifts in community composition and functional capacities encoded in winter and summer environmental genomes with significantly higher phylogenetic and functional diversity in winter. In general, inferred metabolisms of summer bacterioplankton were characterized by chemoheterotrophy, photoheterotrophy and aerobic anoxygenic photosynthesis while the winter community included the capacity for bacterial and archaeal chemolithoautotrophy. Chemolithoautotrophic pathways are dominant in winter and are similar to those recently reported in global ‘dark ocean’ mesopelagic waters. If chemolithoautotrophy is widespread in the Southern Ocean in winter, this process may be a previously unaccounted for carbon sink and may help account for unexplained anomalies in surface inorganic nitrogen content.

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