Data from: Positron-emitting radiotracers spatially resolve unexpected biogeochemical relationships linked with methane oxidation in Arctic soils

Arctic soils are marked by cryoturbic features, which impact soil-atmosphere methane (CH 4 ) dynamics vital to global climate regulation. Cryoturbic diapirism alters C/N chemistry within frost boils by introducing soluble organic carbon and nutrients, potentially influencing microbial CH 4 oxidation...

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Main Authors: Schmidt, Michael, Mamet, Steven, Senger, Curtis, Schebel, Alixandra, Ota, Mitsuaki, Tian, Tony, Aziz, Umair, Stein, Lisa, Regier, Tom, Stanley, Kevin, Peak, Derek, Siciliano, Steven
Format: Other/Unknown Material
Language:unknown
Published: Zenodo 2022
Subjects:
Arctic
Online Access:https://doi.org/10.5061/dryad.jwstqjqbs
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spelling ftzenodo:oai:zenodo.org:6544067 2024-09-09T19:20:40+00:00 Data from: Positron-emitting radiotracers spatially resolve unexpected biogeochemical relationships linked with methane oxidation in Arctic soils Schmidt, Michael Mamet, Steven Senger, Curtis Schebel, Alixandra Ota, Mitsuaki Tian, Tony Aziz, Umair Stein, Lisa Regier, Tom Stanley, Kevin Peak, Derek Siciliano, Steven 2022-05-12 https://doi.org/10.5061/dryad.jwstqjqbs unknown Zenodo https://github.com/mpschmidt02/Methane-Oxidation-Imaging https://doi.org/10.5281/zenodo.6543557 https://zenodo.org/communities/dryad https://doi.org/10.5061/dryad.jwstqjqbs oai:zenodo.org:6544067 info:eu-repo/semantics/openAccess Creative Commons Zero v1.0 Universal https://creativecommons.org/publicdomain/zero/1.0/legalcode info:eu-repo/semantics/other 2022 ftzenodo https://doi.org/10.5061/dryad.jwstqjqbs10.5281/zenodo.6543557 2024-07-25T18:00:32Z Arctic soils are marked by cryoturbic features, which impact soil-atmosphere methane (CH 4 ) dynamics vital to global climate regulation. Cryoturbic diapirism alters C/N chemistry within frost boils by introducing soluble organic carbon and nutrients, potentially influencing microbial CH 4 oxidation. CH 4 oxidation in soils, however, requires a spatio-temporal convergence of ecological factors to occur. Spatial delineation of microbial activity with respect to these key microbial and biogeochemical factors at relevant scales is experimentally challenging in inherently complex and heterogeneous natural soil matrices. This work aims to overcome this barrier by spatially linking microbial CH 4 oxidation with C/N chemistry and metagenomic characteristics. This is achieved by using positron-emitting radiotracers to visualize millimeter-scale active CH 4 uptake areas in Arctic soils with and without diapirism. X-ray absorption spectroscopic speciation of active and inactive areas shows CH 4 uptake spatially associates with greater proportions of inorganic N in diapiric frost boils. Metagenomic analyses reveal Ralstonia pickettii associates with CH 4 uptake across soils along with pertinent CH 4 and inorganic N metabolism associated genes. This study highlights the critical relationship between CH 4 and N cycles in Arctic soils, with potential implications for better understanding future climate. Furthermore, our experimental framework presents a novel, widely applicable strategy for unraveling ecological relationships underlying greenhouse gas dynamics under global change. Other/Unknown Material Arctic Zenodo Arctic
institution Open Polar
collection Zenodo
op_collection_id ftzenodo
language unknown
description Arctic soils are marked by cryoturbic features, which impact soil-atmosphere methane (CH 4 ) dynamics vital to global climate regulation. Cryoturbic diapirism alters C/N chemistry within frost boils by introducing soluble organic carbon and nutrients, potentially influencing microbial CH 4 oxidation. CH 4 oxidation in soils, however, requires a spatio-temporal convergence of ecological factors to occur. Spatial delineation of microbial activity with respect to these key microbial and biogeochemical factors at relevant scales is experimentally challenging in inherently complex and heterogeneous natural soil matrices. This work aims to overcome this barrier by spatially linking microbial CH 4 oxidation with C/N chemistry and metagenomic characteristics. This is achieved by using positron-emitting radiotracers to visualize millimeter-scale active CH 4 uptake areas in Arctic soils with and without diapirism. X-ray absorption spectroscopic speciation of active and inactive areas shows CH 4 uptake spatially associates with greater proportions of inorganic N in diapiric frost boils. Metagenomic analyses reveal Ralstonia pickettii associates with CH 4 uptake across soils along with pertinent CH 4 and inorganic N metabolism associated genes. This study highlights the critical relationship between CH 4 and N cycles in Arctic soils, with potential implications for better understanding future climate. Furthermore, our experimental framework presents a novel, widely applicable strategy for unraveling ecological relationships underlying greenhouse gas dynamics under global change.
format Other/Unknown Material
author Schmidt, Michael
Mamet, Steven
Senger, Curtis
Schebel, Alixandra
Ota, Mitsuaki
Tian, Tony
Aziz, Umair
Stein, Lisa
Regier, Tom
Stanley, Kevin
Peak, Derek
Siciliano, Steven
spellingShingle Schmidt, Michael
Mamet, Steven
Senger, Curtis
Schebel, Alixandra
Ota, Mitsuaki
Tian, Tony
Aziz, Umair
Stein, Lisa
Regier, Tom
Stanley, Kevin
Peak, Derek
Siciliano, Steven
Data from: Positron-emitting radiotracers spatially resolve unexpected biogeochemical relationships linked with methane oxidation in Arctic soils
author_facet Schmidt, Michael
Mamet, Steven
Senger, Curtis
Schebel, Alixandra
Ota, Mitsuaki
Tian, Tony
Aziz, Umair
Stein, Lisa
Regier, Tom
Stanley, Kevin
Peak, Derek
Siciliano, Steven
author_sort Schmidt, Michael
title Data from: Positron-emitting radiotracers spatially resolve unexpected biogeochemical relationships linked with methane oxidation in Arctic soils
title_short Data from: Positron-emitting radiotracers spatially resolve unexpected biogeochemical relationships linked with methane oxidation in Arctic soils
title_full Data from: Positron-emitting radiotracers spatially resolve unexpected biogeochemical relationships linked with methane oxidation in Arctic soils
title_fullStr Data from: Positron-emitting radiotracers spatially resolve unexpected biogeochemical relationships linked with methane oxidation in Arctic soils
title_full_unstemmed Data from: Positron-emitting radiotracers spatially resolve unexpected biogeochemical relationships linked with methane oxidation in Arctic soils
title_sort data from: positron-emitting radiotracers spatially resolve unexpected biogeochemical relationships linked with methane oxidation in arctic soils
publisher Zenodo
publishDate 2022
url https://doi.org/10.5061/dryad.jwstqjqbs
geographic Arctic
geographic_facet Arctic
genre Arctic
genre_facet Arctic
op_relation https://github.com/mpschmidt02/Methane-Oxidation-Imaging
https://doi.org/10.5281/zenodo.6543557
https://zenodo.org/communities/dryad
https://doi.org/10.5061/dryad.jwstqjqbs
oai:zenodo.org:6544067
op_rights info:eu-repo/semantics/openAccess
Creative Commons Zero v1.0 Universal
https://creativecommons.org/publicdomain/zero/1.0/legalcode
op_doi https://doi.org/10.5061/dryad.jwstqjqbs10.5281/zenodo.6543557
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