Methane Production Pathway Regulated Proximally by Substrate Availability and Distally by Temperature in a High‐Latitude Mire Complex

Chang, Kuang-Yu; Riley, William J.; Brodie, Eoin L.; McCalley, C. K.; Crill, Patrick; Grant, R. F.

doi:10.1029/2019jg005355

Cited by 25 publications

(37 citation statements)

References 63 publications

(148 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Although the ecological roles and properties of resource generalists and specialists in many discontinuous permafrost areas have been examined via extensive metagenomic and metatranscriptomics analysis (Liao et al, 2016;Sriswasdi et al, 2017;Singleton et al, 2018;Woodcroft et al, 2018), highly resolved molecular characterization of the OM is an essential foundation upon which we can understand ecosystem C cycling by both plants and microbes in peatlands for predicting future changes in CO 2 and CH 4 production potential (Qualls and Richardson, 2003). Moreover, current models for estimating permafrost soil carbon loss rates are lacking representations of key microbial processes that control OM transformations, leading to enormous uncertainty in model simulations (Burke et al, 2012;Koven et al, 2015;Chang et al, 2019). At most, such models only include a quantitative measure of OM concentration (Lucchese et al, 2010) but neglect the fact that the rate of OM degradation is dependent on the abundance and diversity of active microbes and OM quality and diversity.…”

Section: Introductionmentioning

confidence: 99%

Controls on Soil Organic Matter Degradation and Subsequent Greenhouse Gas Emissions Across a Permafrost Thaw Gradient in Northern Sweden

et al. 2020

View full text Add to dashboard Cite

Warming-induced permafrost thaw could enhance microbial decomposition of previously stored soil organic matter (SOM) to carbon dioxide (CO 2) and methane (CH 4), one of the most significant potential feedbacks from terrestrial ecosystems to the atmosphere in a changing climate. The environmental parameters regulating microbe-organic matter interactions and greenhouse gas (GHG) emissions in northern permafrost peatlands are however still largely unknown. The objective of this work is to understand controls on SOM degradation and its impact on porewater GHG concentrations across the Stordalen Mire, a thawing peat plateau in Northern Sweden. Here, we applied high-resolution mass spectrometry to characterize SOM molecular composition in peat soil samples from the active layers of a Sphagnum-dominated bog and rich fen sites in the Mire. Microbe-organic matter interactions and porewater GHG concentrations across the thaw gradient were controlled by aboveground vegetation and soil pH. An increasingly high abundance of reduced organic compounds experiencing greater humification rates due to enhanced microbial activity were observed with increasing thaw, in parallel with higher CH 4 and CO 2 porewater concentrations. Bog SOM however contained more Sphagnum-derived phenolics, simple carbohydrates, and organic-acids. The low degradation of bog SOM by microbial communities, the enhanced SOM transformation by potentially abiotic mechanisms, and the accumulation of simple carbohydrates in the bog sites could be attributed in part to the low pH conditions of the system associated with Sphagnum mosses. We show that Gibbs free energy of C half reactions based on C oxidation state for OM can be used as a quantifiable measure for OM decomposability and quality to enhance current biogeochemical models to predict C decomposition rates. We found a direct association between OM chemical diversity and δ 13 C-CH 4 in peat porewater; where higher substrate diversity was positively correlated with enriched δ 13 C-CH 4 in fen sites. Oxidized sulfur-containing compounds, produced by Sphagnum, were AminiTabrizi et al. SOM Composition in Permafrost Peatlands further hypothesized to control GHG emissions by acting as electron acceptors for a sulfate-reducing electron transport chain, inhibiting methanogenesis in peat bogs. These results suggest that warming-induced permafrost thaw might increase organic matter lability, in subset of sites that become wetlands, and shift biogeochemical processes toward faster decomposition with an increasing proportion of carbon released as CH 4 .

show abstract

Section: Introductionmentioning

confidence: 99%

Controls on Soil Organic Matter Degradation and Subsequent Greenhouse Gas Emissions Across a Permafrost Thaw Gradient in Northern Sweden

et al. 2020

View full text Add to dashboard Cite

show abstract

“…The results from Chang et al (2019) may also have far-reaching implications beyond the permafrost-thawing areas. Tropical peatlands are among the largest wetland sources of methane, despite covering a Figure 1.…”

Section: Methanogenic Pathways Beyond the Permafrost Regionmentioning

confidence: 93%

“…Such understanding is even more relevant to rapid-changing wetland environments, such as peatlands in boreal regions, where permafrost thawing is shifting plant communities (from a bog-to fen-like vegetation) and, hence, the primary substrates for methanogenesis. Chang et al (2019) used the ecosys model to show how the changes to the type of vegetation resulting from persistent permafrost thawing drive shifts in the methanogenesis pathway (i.e., AM or HM), substrate composition, and the magnitude in methane emissions and modulate their sensitivity to temperature change. Along with the vegetation shift, soil temperature increases in fens, which, in turn, increases biological activity and, consequently, net emissions from both the AM and HM pathways.…”

Section: Temperature Affects Methanogenic Pathways Asymmetricallymentioning

confidence: 99%

“…VILLA measurements and geographical coverage. Then, a mechanistic approach based on plant functional types, analogous to Chang et al (2019) approach to methanogenesis, could be a reasonable compromise between model enhancement and degrees of freedom. Further work will be needed to elucidate if such an avenue is feasible and the parameters that better describe each plant functional type.…”

Section: Journal Of Geophysical Research: Biogeosciencesmentioning

confidence: 99%

“…The ecosys model (Grant et al, 2017), a comprehensive biogeochemical model, is one the few models capable of integrating most of these processes simultaneously and robustly represents the two main methanogenic pathways involved in methane production (i.e., acetoclastic methanogenesis [AM] and hydrogenotrophic methanogenesis [HM]) ( Figure 1). Although laboratory experiments have shown how different biophysical factors may influence the methanogenic pathways, simulations performed with ecosys by Chang et al (2019) provide, for the first time, a valuable insight on how temperature may be changing methane production in a high-latitude peatland at a landscape scale.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Functional Representation of Biological Components in Methane‐Cycling Processes in Wetlands Improves Modeling Predictions

Villa

2020

JGR Biogeosciences

View full text Add to dashboard Cite

Wetlands are important natural sources of methane. However, methane predictions are unconstrained due in part to simplified representations in biogeochemical models of complex interactions between biological components and biophysical drivers. Chang et al. (2019, https://doi.org/ 10.1029/2019JG005355) demonstrate how mechanistic descriptions of processes mediated by biological components and their drivers help improve methane prediction in the thawing permafrost peatlands, where biological components are shifting as a response to current climate change. These findings underscore the need for accounting for the different methanogenic pathways in biogeochemical models to predict methane cycling under a changing climate scenario. This comment presents some implications of considering the methanogenic pathways when simulating different wetland ecosystems and discusses the relevance of including other processes mediated by biological components in the methane cycle in models. Plain Language Summary Methane is a potent greenhouse gas emitted from wetlands. Determining how emissions are affected by changes in vegetation and microorganisms in the soil is crucial to understanding the effects of climate change. Models used to predict methane emissions from wetlands represent plant and microbial processes through different mathematical approaches, some in more realistic ways than others. This comment highlights findings by Chang et al. (2019, https://doi.org/ 10.1029/2019JG005355) on the importance of considering detailed microbial processes involved in the production of methane in soils of peatlands and other wetland ecosystems and discusses the relevance of including other processes mediated by biological components in the methane cycle in models.

show abstract

Causality guided machine learning model on wetland CH4 emissions across global wetlands

Yuan

Zhu²,

Li³

et al. 2022

Agricultural and Forest Meteorology

View full text Add to dashboard Cite

Methane Production Pathway Regulated Proximally by Substrate Availability and Distally by Temperature in a High‐Latitude Mire Complex

Cited by 25 publications

References 63 publications

Controls on Soil Organic Matter Degradation and Subsequent Greenhouse Gas Emissions Across a Permafrost Thaw Gradient in Northern Sweden

Controls on Soil Organic Matter Degradation and Subsequent Greenhouse Gas Emissions Across a Permafrost Thaw Gradient in Northern Sweden

Functional Representation of Biological Components in Methane‐Cycling Processes in Wetlands Improves Modeling Predictions

Causality guided machine learning model on wetland CH4 emissions across global wetlands

Contact Info

Product

Resources

About