Diversity patterns and drivers of methanotrophic gene distributions in forest soils across a large latitudinal gradient

Aim Methane oxidation driven by soil aerobic methanotrophs exhibits the largest methane sink capacity in forest ecosystems and plays important roles in the alleviation of global warming. Many studies have revealed the distribution of methanotrophs in forest ecosystems at field scales; however, the b...

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Published inGlobal ecology and biogeography Vol. 30; no. 10; pp. 2004 - 2015
Main Authors Kou, Yongping, Zhao, Wenqiang, Liu, Yanjiao, Wu, Yanhong, Xiao, Jiangtao, Wang, Xiaohu, Bing, Haijian, Liu, Qing, Hickler, Thomas
Format Journal Article
LanguageEnglish
Published Oxford Wiley Subscription Services, Inc 01.10.2021
Subjects
Aerobic capacity
Ammonia
Aridity
Assembly
biogeographical distribution
biogeography
China
Climate change
community assembly
dry environmental conditions
Ecosystems
Environment models
Environmental factors
environmental selection
Forest ecosystems
Forest soils
forest type
Forests
genes
Geographical distribution
Global warming
Methane
Methanotrophic bacteria
methanotrophs
Multivariate statistical analysis
normalized difference vegetation index
Normalized difference vegetative index
Oxidation
Phylogeny
pmoA diversity
prediction
Predictions
Relative abundance
Soil chemistry
soil methanotrophs
Soil pH
Soils
Statistical analysis
Terrestrial ecosystems
upland soils
Vegetation
Vegetation index
China
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Abstract Aim Methane oxidation driven by soil aerobic methanotrophs exhibits the largest methane sink capacity in forest ecosystems and plays important roles in the alleviation of global warming. Many studies have revealed the distribution of methanotrophs in forest ecosystems at field scales; however, the biogeographical patterns of methanotrophic communities and related ecological processes and the drivers shaping methanotrophic communities at a large scale remain poorly understood. Location China’s forests. Time period 2012–2013. Major taxa studied Methanotrophic communities. Methods We evaluated the geographical distributions of soil methanotrophic communities across 26 forests along a 4,000‐km north–south transect in China using a MiSeq high‐throughput sequencing technique. The assembly processes and drivers of the methanotrophic communities were evaluated using the phylogenetic null model approach and structural equation modelling, respectively. Results The results showed that the upland soil cluster α (USCα) and ammonia‐ oxidizing bacteria‐related (AOB‐rel) methanotrophs were the most abundant taxa in forest soils and exhibited contrasting distributions of relative abundance across different climate zones, suggesting that they occupy different environmental niches. The α‐diversity pattern of the soil methanotrophic community followed a hump‐shaped pattern along a large latitudinal gradient. Statistical analyses suggest that aridity and vegetation productivity [here represented with the normalized difference vegetation index (NDVI)] are major drivers of the α‐diversity of the methanotrophic community, whereas soil pH is the key environmental factor shaping the β‐diversity of the methanotrophic community at a large scale. Additionally, the community assembly of the methanotrophs primarily resulted from deterministic processes, among which heterogeneous selection had a greater contribution in shaping the methanotrophic community than homogeneous selection. Main conclusions Our study provides new insights into the biogeographical distributions, assembly processes and ecological predictors of the methanotrophic community in forest soil at a large scale. These results can be used to improve simulation models for the better prediction of ecosystem functions under predicted global changes.
AbstractList AimMethane oxidation driven by soil aerobic methanotrophs exhibits the largest methane sink capacity in forest ecosystems and plays important roles in the alleviation of global warming. Many studies have revealed the distribution of methanotrophs in forest ecosystems at field scales; however, the biogeographical patterns of methanotrophic communities and related ecological processes and the drivers shaping methanotrophic communities at a large scale remain poorly understood.LocationChina’s forests.Time period2012–2013.Major taxa studiedMethanotrophic communities.MethodsWe evaluated the geographical distributions of soil methanotrophic communities across 26 forests along a 4,000‐km north–south transect in China using a MiSeq high‐throughput sequencing technique. The assembly processes and drivers of the methanotrophic communities were evaluated using the phylogenetic null model approach and structural equation modelling, respectively.ResultsThe results showed that the upland soil cluster α (USCα) and ammonia‐ oxidizing bacteria‐related (AOB‐rel) methanotrophs were the most abundant taxa in forest soils and exhibited contrasting distributions of relative abundance across different climate zones, suggesting that they occupy different environmental niches. The α‐diversity pattern of the soil methanotrophic community followed a hump‐shaped pattern along a large latitudinal gradient. Statistical analyses suggest that aridity and vegetation productivity [here represented with the normalized difference vegetation index (NDVI)] are major drivers of the α‐diversity of the methanotrophic community, whereas soil pH is the key environmental factor shaping the β‐diversity of the methanotrophic community at a large scale. Additionally, the community assembly of the methanotrophs primarily resulted from deterministic processes, among which heterogeneous selection had a greater contribution in shaping the methanotrophic community than homogeneous selection.Main conclusionsOur study provides new insights into the biogeographical distributions, assembly processes and ecological predictors of the methanotrophic community in forest soil at a large scale. These results can be used to improve simulation models for the better prediction of ecosystem functions under predicted global changes.
AIM: Methane oxidation driven by soil aerobic methanotrophs exhibits the largest methane sink capacity in forest ecosystems and plays important roles in the alleviation of global warming. Many studies have revealed the distribution of methanotrophs in forest ecosystems at field scales; however, the biogeographical patterns of methanotrophic communities and related ecological processes and the drivers shaping methanotrophic communities at a large scale remain poorly understood. LOCATION: China’s forests. TIME PERIOD: 2012–2013. MAJOR TAXA STUDIED: Methanotrophic communities. METHODS: We evaluated the geographical distributions of soil methanotrophic communities across 26 forests along a 4,000‐km north–south transect in China using a MiSeq high‐throughput sequencing technique. The assembly processes and drivers of the methanotrophic communities were evaluated using the phylogenetic null model approach and structural equation modelling, respectively. RESULTS: The results showed that the upland soil cluster α (USCα) and ammonia‐ oxidizing bacteria‐related (AOB‐rel) methanotrophs were the most abundant taxa in forest soils and exhibited contrasting distributions of relative abundance across different climate zones, suggesting that they occupy different environmental niches. The α‐diversity pattern of the soil methanotrophic community followed a hump‐shaped pattern along a large latitudinal gradient. Statistical analyses suggest that aridity and vegetation productivity [here represented with the normalized difference vegetation index (NDVI)] are major drivers of the α‐diversity of the methanotrophic community, whereas soil pH is the key environmental factor shaping the β‐diversity of the methanotrophic community at a large scale. Additionally, the community assembly of the methanotrophs primarily resulted from deterministic processes, among which heterogeneous selection had a greater contribution in shaping the methanotrophic community than homogeneous selection. MAIN CONCLUSIONS: Our study provides new insights into the biogeographical distributions, assembly processes and ecological predictors of the methanotrophic community in forest soil at a large scale. These results can be used to improve simulation models for the better prediction of ecosystem functions under predicted global changes.
Aim Methane oxidation driven by soil aerobic methanotrophs exhibits the largest methane sink capacity in forest ecosystems and plays important roles in the alleviation of global warming. Many studies have revealed the distribution of methanotrophs in forest ecosystems at field scales; however, the biogeographical patterns of methanotrophic communities and related ecological processes and the drivers shaping methanotrophic communities at a large scale remain poorly understood. Location China’s forests. Time period 2012–2013. Major taxa studied Methanotrophic communities. Methods We evaluated the geographical distributions of soil methanotrophic communities across 26 forests along a 4,000‐km north–south transect in China using a MiSeq high‐throughput sequencing technique. The assembly processes and drivers of the methanotrophic communities were evaluated using the phylogenetic null model approach and structural equation modelling, respectively. Results The results showed that the upland soil cluster α (USCα) and ammonia‐ oxidizing bacteria‐related (AOB‐rel) methanotrophs were the most abundant taxa in forest soils and exhibited contrasting distributions of relative abundance across different climate zones, suggesting that they occupy different environmental niches. The α‐diversity pattern of the soil methanotrophic community followed a hump‐shaped pattern along a large latitudinal gradient. Statistical analyses suggest that aridity and vegetation productivity [here represented with the normalized difference vegetation index (NDVI)] are major drivers of the α‐diversity of the methanotrophic community, whereas soil pH is the key environmental factor shaping the β‐diversity of the methanotrophic community at a large scale. Additionally, the community assembly of the methanotrophs primarily resulted from deterministic processes, among which heterogeneous selection had a greater contribution in shaping the methanotrophic community than homogeneous selection. Main conclusions Our study provides new insights into the biogeographical distributions, assembly processes and ecological predictors of the methanotrophic community in forest soil at a large scale. These results can be used to improve simulation models for the better prediction of ecosystem functions under predicted global changes.
Author Xiao, Jiangtao
Liu, Yanjiao
Wu, Yanhong
Zhao, Wenqiang
Bing, Haijian
Liu, Qing
Wang, Xiaohu
Kou, Yongping
Hickler, Thomas
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Snippet Aim Methane oxidation driven by soil aerobic methanotrophs exhibits the largest methane sink capacity in forest ecosystems and plays important roles in the...
AimMethane oxidation driven by soil aerobic methanotrophs exhibits the largest methane sink capacity in forest ecosystems and plays important roles in the...
AIM: Methane oxidation driven by soil aerobic methanotrophs exhibits the largest methane sink capacity in forest ecosystems and plays important roles in the...
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SubjectTerms Aerobic capacity
Ammonia
Aridity
Assembly
biogeographical distribution
biogeography
China
Climate change
community assembly
dry environmental conditions
Ecosystems
Environment models
Environmental factors
environmental selection
Forest ecosystems
Forest soils
forest type
Forests
genes
Geographical distribution
Global warming
Methane
Methanotrophic bacteria
methanotrophs
Multivariate statistical analysis
normalized difference vegetation index
Normalized difference vegetative index
Oxidation
Phylogeny
pmoA diversity
prediction
Predictions
Relative abundance
Soil chemistry
soil methanotrophs
Soil pH
Soils
Statistical analysis
Terrestrial ecosystems
upland soils
Vegetation
Vegetation index
Title Diversity patterns and drivers of methanotrophic gene distributions in forest soils across a large latitudinal gradient
URI https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fgeb.13362
https://www.proquest.com/docview/2574572209
https://www.proquest.com/docview/2636388767
Volume 30
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