Soil bacterial community and functional shifts in response to altered snow pack in moist acidic tundra of Northern Alaska

Soil microbial communities play a central role in the cycling of carbon (C) in Arctic tundra ecosystems, which contain a large portion of the global C pool. Climate change predictions for Arctic regions include increased temperature and precipitation (i.e. more snow), resulting in increased winter s...

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Bibliographic Details
Main Author: Michael Ricketts
Format: Dataset
Language:unknown
Published: Arctic Data Center 2016
Subjects:
Arctic
Climate change
Tundra
Alaska
Online Access:https://doi.org/10.18739/A2FS9J
id dataone:doi:10.18739/A2FS9J
record_format openpolar
spelling dataone:doi:10.18739/A2FS9J 2024-06-03T18:46:33+00:00 Soil bacterial community and functional shifts in response to altered snow pack in moist acidic tundra of Northern Alaska Michael Ricketts Arctic moist acidic tussock tundra at Toolik Field Station north of the Brook's Range in Alaska, U.S. ENVELOPE(-149.5967,-149.5967,68.6244,68.6244) BEGINDATE: 2012-08-01T00:00:00Z ENDDATE: 2012-08-01T00:00:00Z 2016-05-16T00:00:00Z https://doi.org/10.18739/A2FS9J unknown Arctic Data Center Dataset 2016 dataone:urn:node:ARCTIC https://doi.org/10.18739/A2FS9J 2024-06-03T18:08:19Z Soil microbial communities play a central role in the cycling of carbon (C) in Arctic tundra ecosystems, which contain a large portion of the global C pool. Climate change predictions for Arctic regions include increased temperature and precipitation (i.e. more snow), resulting in increased winter soil insulation, increased soil temperature and moisture, and shifting plant community composition. We utilized an 18-year snowfence study site designed to examine the effects of increased winter precipitation on Arctic tundra soil bacterial communities within the context of expected ecosystem response to climate change. Soil was collected from three pre-established treatment zones representing varying degrees of snow accumulation (DEEP, INT, LOW), soil physical properties (temperature, moisture, active layer thaw depth) were measured, and samples were analysed for C concentration, nitrogen (N) concentration, and pH. Soil microbial community DNA was extracted and the 16S rRNA gene was sequenced to reveal phylogenetic community differences between samples and determine how soil bacterial communities might respond (structurally and functionally) to changes in winter precipitation and soil chemistry. We analysed relative abundance changes of the six most abundant phyla (ranging from 82-96% of total detected phyla per sample) and found four (Acidobacteria, Actinobacteria, Verrucomicrobia, and Chloroflexi) responded to deepened snow. All six phyla correlated with at least one of the soil chemical properties (%C, %N, C:N, pH), however a single predictor was not identified suggesting that each bacterial phylum responds differently to soil characteristics. Overall bacterial community structure (beta diversity) was found to be associated with snow accumulation treatment and all soil chemical properties. Bacterial functional potential was inferred using ancestral state reconstruction to approximate functional gene abundance, revealing a decreased abundance of genes required for soil organic matter (SOM) decomposition in the organic horizon of the deep snow accumulation zones. These results suggest that predicted climate change scenarios may result in altered soil bacterial community structure and function, and indicate either a reduction in decomposition potential, or alleviated temperature limitations on extracellular enzymatic efficiency, or both. The fate of stored C in Arctic soils ultimately depends on the balance between these mechanisms. Dataset Arctic Climate change Tundra Alaska Arctic Data Center (via DataONE) Arctic ENVELOPE(-149.5967,-149.5967,68.6244,68.6244)
institution Open Polar
collection Arctic Data Center (via DataONE)
op_collection_id dataone:urn:node:ARCTIC
language unknown
description Soil microbial communities play a central role in the cycling of carbon (C) in Arctic tundra ecosystems, which contain a large portion of the global C pool. Climate change predictions for Arctic regions include increased temperature and precipitation (i.e. more snow), resulting in increased winter soil insulation, increased soil temperature and moisture, and shifting plant community composition. We utilized an 18-year snowfence study site designed to examine the effects of increased winter precipitation on Arctic tundra soil bacterial communities within the context of expected ecosystem response to climate change. Soil was collected from three pre-established treatment zones representing varying degrees of snow accumulation (DEEP, INT, LOW), soil physical properties (temperature, moisture, active layer thaw depth) were measured, and samples were analysed for C concentration, nitrogen (N) concentration, and pH. Soil microbial community DNA was extracted and the 16S rRNA gene was sequenced to reveal phylogenetic community differences between samples and determine how soil bacterial communities might respond (structurally and functionally) to changes in winter precipitation and soil chemistry. We analysed relative abundance changes of the six most abundant phyla (ranging from 82-96% of total detected phyla per sample) and found four (Acidobacteria, Actinobacteria, Verrucomicrobia, and Chloroflexi) responded to deepened snow. All six phyla correlated with at least one of the soil chemical properties (%C, %N, C:N, pH), however a single predictor was not identified suggesting that each bacterial phylum responds differently to soil characteristics. Overall bacterial community structure (beta diversity) was found to be associated with snow accumulation treatment and all soil chemical properties. Bacterial functional potential was inferred using ancestral state reconstruction to approximate functional gene abundance, revealing a decreased abundance of genes required for soil organic matter (SOM) decomposition in the organic horizon of the deep snow accumulation zones. These results suggest that predicted climate change scenarios may result in altered soil bacterial community structure and function, and indicate either a reduction in decomposition potential, or alleviated temperature limitations on extracellular enzymatic efficiency, or both. The fate of stored C in Arctic soils ultimately depends on the balance between these mechanisms.
format Dataset
author Michael Ricketts
spellingShingle Michael Ricketts
Soil bacterial community and functional shifts in response to altered snow pack in moist acidic tundra of Northern Alaska
author_facet Michael Ricketts
author_sort Michael Ricketts
title Soil bacterial community and functional shifts in response to altered snow pack in moist acidic tundra of Northern Alaska
title_short Soil bacterial community and functional shifts in response to altered snow pack in moist acidic tundra of Northern Alaska
title_full Soil bacterial community and functional shifts in response to altered snow pack in moist acidic tundra of Northern Alaska
title_fullStr Soil bacterial community and functional shifts in response to altered snow pack in moist acidic tundra of Northern Alaska
title_full_unstemmed Soil bacterial community and functional shifts in response to altered snow pack in moist acidic tundra of Northern Alaska
title_sort soil bacterial community and functional shifts in response to altered snow pack in moist acidic tundra of northern alaska
publisher Arctic Data Center
publishDate 2016
url https://doi.org/10.18739/A2FS9J
op_coverage Arctic moist acidic tussock tundra at Toolik Field Station north of the Brook's Range in Alaska, U.S.
ENVELOPE(-149.5967,-149.5967,68.6244,68.6244)
BEGINDATE: 2012-08-01T00:00:00Z ENDDATE: 2012-08-01T00:00:00Z
long_lat ENVELOPE(-149.5967,-149.5967,68.6244,68.6244)
geographic Arctic
geographic_facet Arctic
genre Arctic
Climate change
Tundra
Alaska
genre_facet Arctic
Climate change
Tundra
Alaska
op_doi https://doi.org/10.18739/A2FS9J
_version_ 1800867710363500544

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