Adding labile carbon to peatland soils triggers deep carbon breakdown

Sumudu Rajakaruna; Ghiwa Makke; Nathalia Graf Grachet; Christian Ayala-Ortiz; John Bouranis; David W. Hoyt; Jason Toyoda; Elizabeth H. Denis; James J. Moran; Tianze Song; Xiaoxu Sun; Elizabeth K. Eder; Allison R. Wong; Rosalie Chu; Heino Heyman; Max Kolton; Jeffrey P. Chanton; Rachel M. Wilson; Joel Kostka; Malak M. Tfaily

doi:10.1038/s43247-024-01954-y

Communications Earth & Environment (Dec 2024)

Adding labile carbon to peatland soils triggers deep carbon breakdown

Sumudu Rajakaruna,
Ghiwa Makke,
Nathalia Graf Grachet,
Christian Ayala-Ortiz,
John Bouranis,
David W. Hoyt,
Jason Toyoda,
Elizabeth H. Denis,
James J. Moran,
Tianze Song,
Xiaoxu Sun,
Elizabeth K. Eder,
Allison R. Wong,
Rosalie Chu,
Heino Heyman,
Max Kolton,
Jeffrey P. Chanton,
Rachel M. Wilson,
Joel Kostka,
Malak M. Tfaily

Affiliations

Sumudu Rajakaruna: Department of Environmental Science, University of Arizona
Ghiwa Makke: Department of Environmental Science, University of Arizona
Nathalia Graf Grachet: Department of Environmental Science, University of Arizona
Christian Ayala-Ortiz: Department of Environmental Science, University of Arizona
John Bouranis: Department of Environmental Science, University of Arizona
David W. Hoyt: Pacific Northwest National Laboratory
Jason Toyoda: Pacific Northwest National Laboratory
Elizabeth H. Denis: Pacific Northwest National Laboratory
James J. Moran: Pacific Northwest National Laboratory
Tianze Song: School of Biological Sciences, Georgia Institute of Technology
Xiaoxu Sun: School of Biological Sciences, Georgia Institute of Technology
Elizabeth K. Eder: Pacific Northwest National Laboratory
Allison R. Wong: Pacific Northwest National Laboratory
Rosalie Chu: Pacific Northwest National Laboratory
Heino Heyman: Pacific Northwest National Laboratory
Max Kolton: The Jacob Blaustein Institutes for Desert Research, Ben-Gurion University of the Negev
Jeffrey P. Chanton: Department of Earth, Ocean & Atmospheric Science, Florida State University
Rachel M. Wilson: Department of Earth, Ocean & Atmospheric Science, Florida State University
Joel Kostka: School of Biological Sciences, Georgia Institute of Technology
Malak M. Tfaily: Department of Environmental Science, University of Arizona

DOI: https://doi.org/10.1038/s43247-024-01954-y
Journal volume & issue: Vol. 5, no. 1
pp. 1 – 14

Abstract

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Abstract Peatlands store vast amounts of carbon, with deep peat carbon remaining stable due to limited thermodynamic energy and transport. However, climate change-induced increases in labile carbon inputs could destabilize these stores. Here, we combined DNA stable isotope probing with stable isotope-assisted metabolomics employing a multi-platform approach to investigate microbial dynamics driving deep peat carbon degradation upon labile carbon (e.g., glucose) amendment. Our findings highlight the vulnerability of deep peat carbon, as glucose addition triggers the breakdown of older organic matter. By uniquely integrating these techniques, we identified active glucose metabolizers to specific microbial populations and mapped carbon flow through microbial networks, elucidating their role in priming recalcitrant carbon mineralization. This multi-omics approach offers crucial insights into how changing resources reshape the peatland microbiome, enhancing our understanding of deep carbon processing, and refining model parameterization to predict microbial responses and carbon cycle feedbacks under global change pressures.

Published in Communications Earth & Environment

ISSN: 2662-4435 (Online)
Publisher: Nature Portfolio
Country of publisher: United Kingdom
LCC subjects: Science: Geology; Geography. Anthropology. Recreation: Environmental sciences
Website: https://www.nature.com/commsenv/

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