Methanotroph populations and CH4 oxidation potentials in high-Arctic peat are altered by herbivory induced vegetation change.

Edda M Rainer,Mette M Svenning,Christophe V W Seppey,Alexander T Tveit

doi:10.1093/femsec/fiaa140

Edda M Rainer, Mette M Svenning + Show 2 more

Open Access

https://doi.org/10.1093/femsec/fiaa140

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Abstract

ABSTRACTMethane oxidizing bacteria (methanotrophs) within the genus Methylobacter constitute the biological filter for methane (CH4) in many Arctic soils. Multiple Methylobacter strains have been identified in these environments but we seldom know the ecological significance of the different strains. High-Arctic peatlands in Svalbard are heavily influenced by herbivory, leading to reduced vascular plant and root biomass. Here, we have measured potential CH4 oxidation rates and identified the active methantrophs in grazed peat and peat protected from grazing by fencing (exclosures) for 18 years. Grazed peat sustained a higher water table, higher CH4 concentrations and lower oxygen (O2) concentrations than exclosed peat. Correspondingly, the highest CH4 oxidation potentials were closer to the O2 rich surface in the grazed than in the protected peat. A comparison of 16S rRNA genes showed that the majority of methanotrophs in both sites belong to the genus Methylobacter. Further analyses of pmoA transcripts revealed that several Methylobacter OTUs were active in the peat but that different OTUs dominated the grazed peat than the exclosed peat. We conclude that grazing influences soil conditions, the active CH4 filter and that different Methylobacter populations are responsible for CH4 oxidation depending on the environmental conditions.

Highlights

High-Arctic peatlands store large amounts of organic carbon that is a source for microbial production of the greenhouse gas methane (CH4)
Herbivory in Svalbard leads to reduced vascular plant and root biomass in peatlands, resulting in increased soil water content, higher in situ pore water CH4 concentrations and reduced O2 concentrations
These changes correspond with a shallower and more potent zone of maximal CH4 oxidation in grazed peat compared to peat protected from grazing

Summary

Introduction

High-Arctic peatlands store large amounts of organic carbon that is a source for microbial production of the greenhouse gas methane (CH4). Methane oxidizing bacteria (MOB), or methanotrophs, act as the dominant biological CH4 filter in peat soils, consuming CH4 produced in deeper anaerobic peat before it is released to the atmosphere MOB are a diverse group of bacteria, found within the classes Gammaproteobacteria, Alphaproteobacteria and Verrucomicrobia (Hanson and Hanson 1996; Knief 2015). Many cold ecosystems with a neutral pH are found to be dominated by MOB within Gammaproteobacteria

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