Data from: Peatland vascular plant functional types affect methane dynamics by altering microbial community structure

1. Peatlands are natural sources of atmospheric methane (CH4), an important greenhouse gas. It is established that peatland methane dynamics are controlled by both biotic and abiotic conditions, yet the interactive effect of these drivers is less studied and consequently poorly understood. 2. Climat...

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Main Authors: Robroek, Bjorn J. M., Jassey, Vincent E. J., Kox, Martine A. R., Berendsen, Roeland L., Mills, Robert T. E., Cécillon, Lauric, Puissant, Jéremy, Meima–Franke, Marion, Bakker, Peter A. H. M., Bodelier, Paul L. E., Meima-Franke, Marion
Format: Dataset
Language:unknown
Published: 2021
Subjects:
path analysis
Sphagnum magellanicum
Vaccinium oxycoccus
mid–infrared spectroscopy
Graminoids
Plant–soil (below-ground) interactions
Empetrum nigrum
Sphagnum spp.
Eriophorum vaginatum
Calluna vulgaris
methanotrophic communities
methanogenesis
CH4
PLFA
Sphagnum cuspidatum
Sphagnum–dominated peatlands
Rhynchospora alba
Eriophorum angustifolium
Andromeda polifolia
pmoA
Ericoids
Sphagnum rubellum
Erica tetralix
Holocene
Sphagnum spp
Northern Europe
Southern Sweden
Online Access:https://doi.org/10.5061/dryad.3216c
http://hdl.handle.net/2066/218020
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author Robroek, Bjorn J. M.
Jassey, Vincent E. J.
Kox, Martine A. R.
Berendsen, Roeland L.
Mills, Robert T. E.
Cécillon, Lauric
Puissant, Jéremy
Meima–Franke, Marion
Bakker, Peter A. H. M.
Bodelier, Paul L. E.
Meima-Franke, Marion
author_facet Robroek, Bjorn J. M.
Jassey, Vincent E. J.
Kox, Martine A. R.
Berendsen, Roeland L.
Mills, Robert T. E.
Cécillon, Lauric
Puissant, Jéremy
Meima–Franke, Marion
Bakker, Peter A. H. M.
Bodelier, Paul L. E.
Meima-Franke, Marion
author_sort Robroek, Bjorn J. M.
collection Unknown
description 1. Peatlands are natural sources of atmospheric methane (CH4), an important greenhouse gas. It is established that peatland methane dynamics are controlled by both biotic and abiotic conditions, yet the interactive effect of these drivers is less studied and consequently poorly understood. 2. Climate change affects the distribution of vascular plant functional types (PFTs) in peatlands. By removing specific PFTs, we assessed their effects on peat organic matter chemistry, microbial community composition and on potential methane production (PMP) and oxidation (PMO) in two microhabitats (lawns and hummocks). 3. Whilst PFT removal only marginally altered the peat organic matter chemistry, we observed considerable changes in microbial community structure. This resulted in altered PMP and PMO. PMP was slightly lower when graminoids were removed, whilst PMO was highest in the absence of both vascular PFTs (graminoids and ericoids), but only in the hummocks. 4. Path analyses demonstrate that different plant–soil interactions drive PMP and PMO in peatlands and that changes in biotic and abiotic factors can have auto-amplifying effects on current CH4 dynamics. 5. Synthesis. Changing environmental conditions will, both directly and indirectly, affect peatland processes, causing unforeseen changes in CH4 dynamics. The resilience of peatland CH4 dynamics to environmental change therefore depends on the interaction between plant community composition and microbial communities. Microbial PFLA dataIn early June 2011, 48 experimental plots (50 × 50 cm) were established in lawn (n = 24) and hummock microhabitats (n = 24) in a Sphagnum-dominated ombrotrophic peatland in the Store Mosse National Park, Sweden (57°17’54 N, 14°00’39 E). In both microhabitats, the vascular plant functional type (PFT) composition was manipulated by removing (clipping) ericoids (–Eric), graminoids (–Gram), or both. A set of control plots remained intact. One year later, peat samples (c. 20 g. f. wt) were collected from all plots (n =48) at the ...
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https://dx.doi.org/10.5061/dryad.3216c
http://hdl.handle.net/2066/218020
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spelling fttriple:oai:gotriple.eu:50|dedup_wf_001::9a918f00a26f1589c61e4ffa2e4a6ff1 2025-01-16T21:43:58+00:00 Data from: Peatland vascular plant functional types affect methane dynamics by altering microbial community structure Robroek, Bjorn J. M. Jassey, Vincent E. J. Kox, Martine A. R. Berendsen, Roeland L. Mills, Robert T. E. Cécillon, Lauric Puissant, Jéremy Meima–Franke, Marion Bakker, Peter A. H. M. Bodelier, Paul L. E. Meima-Franke, Marion 2021-06-27 https://doi.org/10.5061/dryad.3216c http://hdl.handle.net/2066/218020 undefined unknown http://dx.doi.org/10.5061/dryad.3216c https://dx.doi.org/10.5061/dryad.3216c http://hdl.handle.net/2066/218020 lic_creative-commons oai:metis.ru.nl:Products/652818 10.5061/dryad.3216c oai:easy.dans.knaw.nl:easy-dataset:89177 oai:services.nod.dans.knaw.nl:Products/dans:oai:easy.dans.knaw.nl:easy-dataset:89177 rudata:oai:repository.ubn.ru.nl:2066/218020 10|MetisRadboud::f66f1bd369679b5b077dcdf006089556 10|openaire____::9e3be59865b2c1c335d32dae2fe7b254 re3data_____::r3d100000044 10|re3data_____::84e123776089ce3c7a33db98d9cd15a8 10|eurocrisdris::fe4903425d9040f680d8610d9079ea14 10|eurocrisdris::c49e0fe4b9ba7b7fab717d1f0f0a674d 10|re3data_____::94816e6421eeb072e7742ce6a9decc5f 10|openaire____::fdb035c8b3e0540a8d9a561a6c44f4de 10|openaire____::081b82f96300b6a6e3d282bad31cb6e2 path analysis Sphagnum magellanicum Vaccinium oxycoccus mid–infrared spectroscopy Graminoids Plant–soil (below-ground) interactions Empetrum nigrum Sphagnum spp. Eriophorum vaginatum Calluna vulgaris methanotrophic communities methanogenesis CH4 PLFA Sphagnum cuspidatum Sphagnum–dominated peatlands Rhynchospora alba Eriophorum angustifolium Andromeda polifolia pmoA Ericoids Sphagnum rubellum Erica tetralix Holocene Sphagnum spp Northern Europe Southern Sweden Dataset https://vocabularies.coar-repositories.org/resource_types/c_ddb1/ 2021 fttriple https://doi.org/10.5061/dryad.3216c 2023-01-22T16:53:39Z 1. Peatlands are natural sources of atmospheric methane (CH4), an important greenhouse gas. It is established that peatland methane dynamics are controlled by both biotic and abiotic conditions, yet the interactive effect of these drivers is less studied and consequently poorly understood. 2. Climate change affects the distribution of vascular plant functional types (PFTs) in peatlands. By removing specific PFTs, we assessed their effects on peat organic matter chemistry, microbial community composition and on potential methane production (PMP) and oxidation (PMO) in two microhabitats (lawns and hummocks). 3. Whilst PFT removal only marginally altered the peat organic matter chemistry, we observed considerable changes in microbial community structure. This resulted in altered PMP and PMO. PMP was slightly lower when graminoids were removed, whilst PMO was highest in the absence of both vascular PFTs (graminoids and ericoids), but only in the hummocks. 4. Path analyses demonstrate that different plant–soil interactions drive PMP and PMO in peatlands and that changes in biotic and abiotic factors can have auto-amplifying effects on current CH4 dynamics. 5. Synthesis. Changing environmental conditions will, both directly and indirectly, affect peatland processes, causing unforeseen changes in CH4 dynamics. The resilience of peatland CH4 dynamics to environmental change therefore depends on the interaction between plant community composition and microbial communities. Microbial PFLA dataIn early June 2011, 48 experimental plots (50 × 50 cm) were established in lawn (n = 24) and hummock microhabitats (n = 24) in a Sphagnum-dominated ombrotrophic peatland in the Store Mosse National Park, Sweden (57°17’54 N, 14°00’39 E). In both microhabitats, the vascular plant functional type (PFT) composition was manipulated by removing (clipping) ericoids (–Eric), graminoids (–Gram), or both. A set of control plots remained intact. One year later, peat samples (c. 20 g. f. wt) were collected from all plots (n =48) at the ... Dataset Empetrum nigrum Unknown
spellingShingle path analysis
Sphagnum magellanicum
Vaccinium oxycoccus
mid–infrared spectroscopy
Graminoids
Plant–soil (below-ground) interactions
Empetrum nigrum
Sphagnum spp.
Eriophorum vaginatum
Calluna vulgaris
methanotrophic communities
methanogenesis
CH4
PLFA
Sphagnum cuspidatum
Sphagnum–dominated peatlands
Rhynchospora alba
Eriophorum angustifolium
Andromeda polifolia
pmoA
Ericoids
Sphagnum rubellum
Erica tetralix
Holocene
Sphagnum spp
Northern Europe
Southern Sweden
Robroek, Bjorn J. M.
Jassey, Vincent E. J.
Kox, Martine A. R.
Berendsen, Roeland L.
Mills, Robert T. E.
Cécillon, Lauric
Puissant, Jéremy
Meima–Franke, Marion
Bakker, Peter A. H. M.
Bodelier, Paul L. E.
Meima-Franke, Marion
Data from: Peatland vascular plant functional types affect methane dynamics by altering microbial community structure
title Data from: Peatland vascular plant functional types affect methane dynamics by altering microbial community structure
title_full Data from: Peatland vascular plant functional types affect methane dynamics by altering microbial community structure
title_fullStr Data from: Peatland vascular plant functional types affect methane dynamics by altering microbial community structure
title_full_unstemmed Data from: Peatland vascular plant functional types affect methane dynamics by altering microbial community structure
title_short Data from: Peatland vascular plant functional types affect methane dynamics by altering microbial community structure
title_sort data from: peatland vascular plant functional types affect methane dynamics by altering microbial community structure
topic path analysis
Sphagnum magellanicum
Vaccinium oxycoccus
mid–infrared spectroscopy
Graminoids
Plant–soil (below-ground) interactions
Empetrum nigrum
Sphagnum spp.
Eriophorum vaginatum
Calluna vulgaris
methanotrophic communities
methanogenesis
CH4
PLFA
Sphagnum cuspidatum
Sphagnum–dominated peatlands
Rhynchospora alba
Eriophorum angustifolium
Andromeda polifolia
pmoA
Ericoids
Sphagnum rubellum
Erica tetralix
Holocene
Sphagnum spp
Northern Europe
Southern Sweden
topic_facet path analysis
Sphagnum magellanicum
Vaccinium oxycoccus
mid–infrared spectroscopy
Graminoids
Plant–soil (below-ground) interactions
Empetrum nigrum
Sphagnum spp.
Eriophorum vaginatum
Calluna vulgaris
methanotrophic communities
methanogenesis
CH4
PLFA
Sphagnum cuspidatum
Sphagnum–dominated peatlands
Rhynchospora alba
Eriophorum angustifolium
Andromeda polifolia
pmoA
Ericoids
Sphagnum rubellum
Erica tetralix
Holocene
Sphagnum spp
Northern Europe
Southern Sweden
url https://doi.org/10.5061/dryad.3216c
http://hdl.handle.net/2066/218020

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