Insight

Nature Geoscience Insight - Marine cycles in flux

Insight issue:
September 2013 Volume 6 No 9

(Image credited to Photri Images / Alamy)

Microbes regulate the cycling of elements throughout the global ocean, from the icy surface waters that circulate at high latitudes, to the deep vents that dot the continental sea floor. Human activities are starting to modify the way in which microbes mediate these cycles, at least in the relatively well-characterized waters of the upper ocean. The deeper layers of the ocean are probably less affected, at least at present, and are definitely less well explored. However, technological advances are starting to shed light on the cycling of elements at depth, revealing microbial systems that are quite different from those at the surface. In this Nature Geoscience Insight we highlight some of the most intriguing advances in the microbial biogeochemistry of the oceans, a field that is very much in flux.

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Editorial

Marine cycles in flux p687

Anna Armstrong

doi:10.1038/ngeo1946

Full text | PDF (218 KB)

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Commentary

Where the genes flow pp688-690

Frank J. Stewart

doi:10.1038/ngeo1939

Particles of organic matter in the ocean host diverse communities of microorganisms. These particles may serve as hotspots of bacterial gene exchange, creating opportunities for microbial evolution.

Full text | PDF (243 KB)

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Reviews

Impact of Arctic meltdown on the microbial cycling of sulphur pp691-700

M. Levasseur

doi:10.1038/ngeo1910

The Arctic is warming faster than any other region in the world. The resultant large-scale shift in sea ice cover could increase oceanic emissions of dimethylsulphide, a climate-relevant trace gas generated by ice algae and phytoplankton.

First paragraph | Full text | PDF (1,735 KB)

Processes and patterns of oceanic nutrient limitation pp701-710

C. M. Moore, M. M. Mills, K. R. Arrigo, I. Berman-Frank, L. Bopp, P. W. Boyd, E. D. Galbraith, R. J. Geider, C. Guieu, S. L. Jaccard, T. D. Jickells, J. La Roche, T. M. Lenton, N. M. Mahowald, E. Marañón, I. Marinov, J. K. Moore, T. Nakatsuka, A. Oschlies, M. A. Saito, T. F. Thingstad, A. Tsuda & O. Ulloa

doi:10.1038/ngeo1765

Photosynthetic microbes, collectively termed phytoplankton, are responsible for the vast majority of primary production in marine waters. A synthesis of the latest research suggests that two broad nutrient limitation regimes dictate phytoplankton abundance and activity in the global ocean.

First paragraph | Full text | PDF (941 KB)

Microbial biogeochemistry of coastal upwelling regimes in a changing ocean pp711-717

Douglas G. Capone & David A. Hutchins

doi:10.1038/ngeo1916

Coastal upwelling regimes associated with eastern boundary currents are the most biologically productive ecosystems in the ocean. A suite of human-induced changes could perturb primary production and nutrient cycling in these highly dynamic systems.

First paragraph | Full text | PDF (1,356 KB)

Microbial control of the dark end of the biological pump pp718-724

Gerhard J. Herndl & Thomas Reinthaler

doi:10.1038/ngeo1921

The flux of carbon out of the ocean surface is not sufficient to meet the energy demands of microbes in the dark ocean. A review of the literature suggests that non-sinking particles and microbes that convert inorganic carbon into organic matter could help to meet this deep-ocean energy demand.

First paragraph | Full text | PDF (1,149 KB)

Seafloor oxygen consumption fuelled by methane from cold seeps pp725-731

Antje Boetius & Frank Wenzhöfer

doi:10.1038/ngeo1926

The leakage of cold, methane-rich fluids from subsurface reservoirs to the sea floor sustains some of the richest ecosystems on the sea bed. Microbial consumption of seep methane means that these cold-seep communities consume around two orders of magnitude more oxygen than non-seep seafloor communities.

First paragraph | Full text | PDF (1,954 KB)

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