Local and regional influences over soil microbial metacommunities in the Transantarctic Mountains

The metacommunity concept provides a useful framework to assess the influence of local and regional controls over diversity patterns. Culture-independent studies of soil microbial communities in the McMurdo Dry Valleys of East Antarctica (77 degrees S) have shown that bacterial diversity is related...

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Bibliographic Details
Published in:Ecosphere
Main Authors: Sokol, Eric R., Herbold, C. W., Lee, C. K., Cary, S. Craig, Barrett, John E.
Other Authors: Biological Sciences, Virginia Tech
Format: Article in Journal/Newspaper
Language:English
Published: Ecological Society of America 2013
Subjects:
Antarctica
beta diversity
biogeography
diversity partitioning
McMurdo Dry Valleys
metacommunities
soil microbial ecology
Transantarctic Mountains
variation partitioning
polar desert ecosystem
southern victoria land
ross sea region
cyanobacterial diversity
community ecology
taylor
valley
bacterial diversity
spatial scales
Environmental Sciences & Ecology
Beardmore
Beardmore Glacier
East Antarctica
Marsden
New Zealand
Ross Sea
Taylor Valley
Victoria Land
Antarc*
polar desert
Online Access:http://hdl.handle.net/10919/24807
http://www.esajournals.org/doi/pdf/10.1890/ES13-00136.1
https://doi.org/10.1890/es13-00136.1
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Summary:The metacommunity concept provides a useful framework to assess the influence of local and regional controls over diversity patterns. Culture-independent studies of soil microbial communities in the McMurdo Dry Valleys of East Antarctica (77 degrees S) have shown that bacterial diversity is related to soil geochemical gradients, while studies targeting edaphic cyanobacteria have linked local diversity patterns to dispersal-based processes. In this study, we increased the spatial extent of observed soil microbial communities to cover the Beardmore Glacier region in the central Transantarctic Mountains (84 degrees S). We used community profiling techniques to characterize diversity patterns for bacteria and the cyanobacterial subcomponent of the microbial community. Diversity partitioning was used to calculate beta diversity and estimate among-site dissimilarity in the metacommunity. We then used variation partitioning to assess the relationship between beta diversity and environmental and spatial gradients. We found that dominant groups in the soil bacterial metacommunity were influenced by gradients in pH and soil moisture at the Transantarctic scale (800 km). Conversely, beta diversity for the cyanobacterial component of the edaphic microbial metacommunity was decoupled from these environmental gradients, and was more related to spatial filters, suggesting that wind-driven dispersal dynamics created cyanobacterial biogeography at a local scale (<3 km). US National Science Foundation OPP-0944560, OPP-1246292, OPP-0944556 New Zealand Marsden Fund UOW0802, UOW1003 Foundation for Research, Science and Technology of New Zealand UOWX0715

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