Pulses of labile carbon cause transient decoupling of fermentation and respiration in permeable sediments

Philipp A. Nauer; Adam J. Kessler; Puspitaningsih Hall; Maria Elena Popa; Sophie ten Hietbrink; Tess Hutchinson; Wei Wen Wong; Karl Attard; Ronnie N. Glud; Chris Greening; Perran L.M. Cook

doi:10.1002/lno.12411

Pulses of labile carbon cause transient decoupling of fermentation and respiration in permeable sediments

Philipp A. Nauer, Adam J. Kessler, Puspitaningsih Hall, Maria Elena Popa, Sophie ten Hietbrink, Tess Hutchinson, Wei Wen Wong, Karl Attard, Ronnie N. Glud, Chris Greening, Perran L.M. Cook^*

^*Kontaktforfatter

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Abstract

Dihydrogen (H₂) is an important intermediate in anaerobic microbial processes, and concentrations are tightly controlled by thermodynamic limits of consumption and production. However, recent studies reported unusual H₂ accumulation in permeable marine sediments under anoxic conditions, suggesting decoupling of fermentation and sulfate reduction, the dominant respiratory process in anoxic permeable marine sediments. Yet, the extent, prevalence and potential triggers for such H₂ accumulation and decoupling remain unknown. We surveyed H₂ concentrations in situ at different settings of permeable sand and found that H₂ accumulation was only observed during a coral spawning event on the Great Barrier Reef. A flume experiment with organic matter addition to the water column showed a rapid accumulation of hydrogen within the sediment. Laboratory experiments were used to explore the effect of oxygen exposure, physical disturbance and organic matter inputs on H₂ accumulation. Oxygen exposure had little effect on H₂ accumulation in permeable sediments suggesting both fermenters and sulfate reducers survive and rapidly resume activity after exposure to oxygen. Mild physical disturbance mimicking sediment resuspension had little effect on H₂ accumulation; however, vigorous shaking led to a transient accumulation of H₂ and release of dissolved organic carbon suggesting mechanical disturbance and cell destruction led to organic matter release and transient decoupling of fermenters and sulfate reducers. In summary, the highly dynamic nature of permeable sediments and its microbial community allows for rapid but transient decoupling of fermentation and respiration after a C pulse, leading to high H₂ levels in the sediment.

Originalsprog	Engelsk
Tidsskrift	Limnology and Oceanography
Vol/bind	68
Udgave nummer	9
Sider (fra-til)	2141-2152
Antal sider	12
ISSN	0024-3590
DOI	https://doi.org/10.1002/lno.12411
Status	Udgivet - sep. 2023

Bibliografisk note

Funding Information:
The authors would like to thank the team of the Heron Island Research Station, Anni Glud, Tent Jirapanjawat, Ya‐You Chen, Tina Hines, Cami Plum, Caitlyn McNaughton, Vera Eate and Christopher Hill for technical support and help with field work. This study was supported by ARC Discovery Project grants (DP180101762 awarded to PLMC, CG, and RNG; DP210101595 awarded to PLMC, CG, and WWW), and an NHMRC EL2 Fellowship (APP1178715; salary for CG). Work at Heron Island was supported by Hermon Slade Foundation Grant HS17/11. Further was made available by the project HADES‐ERC funded by the European Research Council Advanced Investigator Grant 669947, the Council for Independent Research via the grant FNU‐7014‐00078 grant, and the Danish National Research Foundation through the Danish Center for Hadal Research, HADAL (No. DNRF145). Open access publishing facilitated by Monash University, as part of the Wiley ‐ Monash University agreement via the Council of Australian University Librarians.

Publisher Copyright:
© 2023 The Authors. Limnology and Oceanography published by Wiley Periodicals LLC on behalf of Association for the Sciences of Limnology and Oceanography.

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10.1002/lno.12411Licens: CC BY

Open Access VersionForlagets udgivne version, 1,61 MBLicens: CC BY

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title = "Pulses of labile carbon cause transient decoupling of fermentation and respiration in permeable sediments",

abstract = "Dihydrogen (H2) is an important intermediate in anaerobic microbial processes, and concentrations are tightly controlled by thermodynamic limits of consumption and production. However, recent studies reported unusual H2 accumulation in permeable marine sediments under anoxic conditions, suggesting decoupling of fermentation and sulfate reduction, the dominant respiratory process in anoxic permeable marine sediments. Yet, the extent, prevalence and potential triggers for such H2 accumulation and decoupling remain unknown. We surveyed H2 concentrations in situ at different settings of permeable sand and found that H2 accumulation was only observed during a coral spawning event on the Great Barrier Reef. A flume experiment with organic matter addition to the water column showed a rapid accumulation of hydrogen within the sediment. Laboratory experiments were used to explore the effect of oxygen exposure, physical disturbance and organic matter inputs on H2 accumulation. Oxygen exposure had little effect on H2 accumulation in permeable sediments suggesting both fermenters and sulfate reducers survive and rapidly resume activity after exposure to oxygen. Mild physical disturbance mimicking sediment resuspension had little effect on H2 accumulation; however, vigorous shaking led to a transient accumulation of H2 and release of dissolved organic carbon suggesting mechanical disturbance and cell destruction led to organic matter release and transient decoupling of fermenters and sulfate reducers. In summary, the highly dynamic nature of permeable sediments and its microbial community allows for rapid but transient decoupling of fermentation and respiration after a C pulse, leading to high H2 levels in the sediment.",

author = "Nauer, {Philipp A.} and Kessler, {Adam J.} and Puspitaningsih Hall and Popa, {Maria Elena} and {ten Hietbrink}, Sophie and Tess Hutchinson and Wong, {Wei Wen} and Karl Attard and Glud, {Ronnie N.} and Chris Greening and Cook, {Perran L.M.}",

note = "Funding Information: The authors would like to thank the team of the Heron Island Research Station, Anni Glud, Tent Jirapanjawat, Ya‐You Chen, Tina Hines, Cami Plum, Caitlyn McNaughton, Vera Eate and Christopher Hill for technical support and help with field work. This study was supported by ARC Discovery Project grants (DP180101762 awarded to PLMC, CG, and RNG; DP210101595 awarded to PLMC, CG, and WWW), and an NHMRC EL2 Fellowship (APP1178715; salary for CG). Work at Heron Island was supported by Hermon Slade Foundation Grant HS17/11. Further was made available by the project HADES‐ERC funded by the European Research Council Advanced Investigator Grant 669947, the Council for Independent Research via the grant FNU‐7014‐00078 grant, and the Danish National Research Foundation through the Danish Center for Hadal Research, HADAL (No. DNRF145). Open access publishing facilitated by Monash University, as part of the Wiley ‐ Monash University agreement via the Council of Australian University Librarians. Publisher Copyright: {\textcopyright} 2023 The Authors. Limnology and Oceanography published by Wiley Periodicals LLC on behalf of Association for the Sciences of Limnology and Oceanography.",

year = "2023",

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doi = "10.1002/lno.12411",

language = "English",

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T1 - Pulses of labile carbon cause transient decoupling of fermentation and respiration in permeable sediments

AU - Nauer, Philipp A.

AU - Kessler, Adam J.

AU - Hall, Puspitaningsih

AU - Popa, Maria Elena

AU - ten Hietbrink, Sophie

AU - Hutchinson, Tess

AU - Wong, Wei Wen

AU - Attard, Karl

AU - Glud, Ronnie N.

AU - Greening, Chris

AU - Cook, Perran L.M.

N1 - Funding Information: The authors would like to thank the team of the Heron Island Research Station, Anni Glud, Tent Jirapanjawat, Ya‐You Chen, Tina Hines, Cami Plum, Caitlyn McNaughton, Vera Eate and Christopher Hill for technical support and help with field work. This study was supported by ARC Discovery Project grants (DP180101762 awarded to PLMC, CG, and RNG; DP210101595 awarded to PLMC, CG, and WWW), and an NHMRC EL2 Fellowship (APP1178715; salary for CG). Work at Heron Island was supported by Hermon Slade Foundation Grant HS17/11. Further was made available by the project HADES‐ERC funded by the European Research Council Advanced Investigator Grant 669947, the Council for Independent Research via the grant FNU‐7014‐00078 grant, and the Danish National Research Foundation through the Danish Center for Hadal Research, HADAL (No. DNRF145). Open access publishing facilitated by Monash University, as part of the Wiley ‐ Monash University agreement via the Council of Australian University Librarians. Publisher Copyright: © 2023 The Authors. Limnology and Oceanography published by Wiley Periodicals LLC on behalf of Association for the Sciences of Limnology and Oceanography.

PY - 2023/9

Y1 - 2023/9

N2 - Dihydrogen (H2) is an important intermediate in anaerobic microbial processes, and concentrations are tightly controlled by thermodynamic limits of consumption and production. However, recent studies reported unusual H2 accumulation in permeable marine sediments under anoxic conditions, suggesting decoupling of fermentation and sulfate reduction, the dominant respiratory process in anoxic permeable marine sediments. Yet, the extent, prevalence and potential triggers for such H2 accumulation and decoupling remain unknown. We surveyed H2 concentrations in situ at different settings of permeable sand and found that H2 accumulation was only observed during a coral spawning event on the Great Barrier Reef. A flume experiment with organic matter addition to the water column showed a rapid accumulation of hydrogen within the sediment. Laboratory experiments were used to explore the effect of oxygen exposure, physical disturbance and organic matter inputs on H2 accumulation. Oxygen exposure had little effect on H2 accumulation in permeable sediments suggesting both fermenters and sulfate reducers survive and rapidly resume activity after exposure to oxygen. Mild physical disturbance mimicking sediment resuspension had little effect on H2 accumulation; however, vigorous shaking led to a transient accumulation of H2 and release of dissolved organic carbon suggesting mechanical disturbance and cell destruction led to organic matter release and transient decoupling of fermenters and sulfate reducers. In summary, the highly dynamic nature of permeable sediments and its microbial community allows for rapid but transient decoupling of fermentation and respiration after a C pulse, leading to high H2 levels in the sediment.

AB - Dihydrogen (H2) is an important intermediate in anaerobic microbial processes, and concentrations are tightly controlled by thermodynamic limits of consumption and production. However, recent studies reported unusual H2 accumulation in permeable marine sediments under anoxic conditions, suggesting decoupling of fermentation and sulfate reduction, the dominant respiratory process in anoxic permeable marine sediments. Yet, the extent, prevalence and potential triggers for such H2 accumulation and decoupling remain unknown. We surveyed H2 concentrations in situ at different settings of permeable sand and found that H2 accumulation was only observed during a coral spawning event on the Great Barrier Reef. A flume experiment with organic matter addition to the water column showed a rapid accumulation of hydrogen within the sediment. Laboratory experiments were used to explore the effect of oxygen exposure, physical disturbance and organic matter inputs on H2 accumulation. Oxygen exposure had little effect on H2 accumulation in permeable sediments suggesting both fermenters and sulfate reducers survive and rapidly resume activity after exposure to oxygen. Mild physical disturbance mimicking sediment resuspension had little effect on H2 accumulation; however, vigorous shaking led to a transient accumulation of H2 and release of dissolved organic carbon suggesting mechanical disturbance and cell destruction led to organic matter release and transient decoupling of fermenters and sulfate reducers. In summary, the highly dynamic nature of permeable sediments and its microbial community allows for rapid but transient decoupling of fermentation and respiration after a C pulse, leading to high H2 levels in the sediment.

U2 - 10.1002/lno.12411

DO - 10.1002/lno.12411

M3 - Journal article

C2 - 38516532

AN - SCOPUS:85166399236

SN - 0024-3590

VL - 68

SP - 2141

EP - 2152

JO - Limnology and Oceanography

JF - Limnology and Oceanography

IS - 9

ER -

Pulses of labile carbon cause transient decoupling of fermentation and respiration in permeable sediments

Abstract

Bibliografisk note

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