Bacterial community succession in a high‐altitude subarctic glacier foreland is a three‐stage process

Abstract Alpine glaciers are retreating rapidly, exposing foreland minerals, which develop into soils. Bacterial communities in glacier forelands exhibit high rates of turnover and undergo dramatic shifts in composition within the first 50 years after deglaciation, followed by relative stabilization...

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Bibliographic Details
Published in:Molecular Ecology
Main Authors: Kazemi, Sina, Hatam, Ido, Lanoil, Brian
Other Authors: Science and Engineering Research Council, Association of Canadian Universities for Research in Astronomy, Polar Continental Shelf Program of Canada, Northern Scientific Training Program of Canada, Kluane Lake Research Station, Trans North Helicopters
Format: Article in Journal/Newspaper
Language:English
Published: Wiley 2016
Subjects:
glacier*
Subarctic
Yukon
Online Access:http://dx.doi.org/10.1111/mec.13835
https://api.wiley.com/onlinelibrary/tdm/v1/articles/10.1111%2Fmec.13835
https://onlinelibrary.wiley.com/doi/pdf/10.1111/mec.13835
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Summary:Abstract Alpine glaciers are retreating rapidly, exposing foreland minerals, which develop into soils. Bacterial communities in glacier forelands exhibit high rates of turnover and undergo dramatic shifts in composition within the first 50 years after deglaciation, followed by relative stabilization and convergence. This period of microbial development occurs simultaneously with plant colonization in most systems; thus, it remains unclear whether the changes in the bacterial communities occur primarily as the result of edaphic, climatic or biotic factors. We examined bacterial community structure along two replicate chronosequences within the glacial foreland of Duke River Glacier, Yukon, Canada. This foreland is estimated to include >200 years of bare soils before an appreciable grassline, likely due to the high latitude and altitude of the glacier. This enabled us to examine bacterial community development prior to plant colonization over a longer period than previous studies. We observed three successional groups in the chronosequence: (i) an ‘early’ group in soils of less than approximately 50 years since deglaciation; (ii) an ‘intermediate’ group within bare soils, after the early period but before the grassline, containing communities with a relatively high degree of variability in composition; and (iii) a ‘grassline’ group in soils collected after plant colonization with higher diversity but lower age‐group variability in community composition. These findings suggest rapid replacement and addition of species better adapted to glacier foreland conditions followed by slower community shifts over the next 150 years and, finally, indications of a possible response to plant colonization.

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