Energetically Informed Niche Models of Hydrogenotrophs Detected in Sediments of Serpentinized Fluids of the Samail Ophiolite of Oman

Alta E.G. Howells; James A.M. Leong; Tucker Ely; Michelle Santana; Kirt Robinson; Sofia Esquivel-Elizondo; Alysia Cox; Amisha Poret-Peterson; Rosa Krajmalnik-Brown; Everett L. Shock

doi:10.1029/2021JG006317

Energetically Informed Niche Models of Hydrogenotrophs Detected in Sediments of Serpentinized Fluids of the Samail Ophiolite of Oman

Alta E.G. Howells, James A.M. Leong, Tucker Ely, Michelle Santana, Kirt Robinson, Sofia Esquivel-Elizondo, Alysia Cox, Amisha Poret-Peterson, Rosa Krajmalnik-Brown, Everett L. Shock

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

A geochemical gradient established by mixing between reduced, hyperalkaline (pH > 11), H₂-rich fluids generated through the process of serpentinization and surrounding surface water (pH ∼ 8) in the Samail Ophiolite of Oman provides an opportunity to characterize the geochemical and biological factors that influence the distribution of H₂ oxidizing chemotrophs, hydrogenotrophs. In this study, 16S rRNA gene amplicon sequencing was implemented to characterize hydrogenotrophs in sediments underlying surface expressed serpentinized fluids in Oman. Hydrogenotroph phylotype distribution was evaluated as functions of chemical energy supplies for their given metabolic redox reactions. Through this approach, it was discovered that hydrogenotrophic taxa are likely constrained to sediments with overlying fluids that have <∼60 μm O₂, including microorganisms of the genus, Hydrogenophaga. Sulfate reducers of the family, Thermodesulfovibrionaceae, likely require >∼10 μm SO₄⁻² for survival. In sediments with fluids having >∼10 μm SO₄⁻², sulfate reducers likely outcompete microorganisms of the methanogen genus, Methanobacterium, for H₂. Additionally, differences in distribution between Thermodesulfovibrionaceae and Methanobacterium may be driven by the availability of electron acceptors and the redox reaction that is most energy yielding in the fluid. Taken together, observations from the Oman geochemical gradient result in a hydrogenotroph niche model that can be used to evaluate global distribution patterns of hydrogenotrophs in continental serpentinized fluids. On a global scale, based on previous studies, Methanobacterium is constrained to fluids that have <∼10 μm SO₄⁻².

Original language	English (US)
Article number	e2021JG006317
Journal	Journal of Geophysical Research: Biogeosciences
Volume	127
Issue number	3
DOIs	https://doi.org/10.1029/2021JG006317
State	Published - Mar 2022

Keywords

methanogenesis
microbial ecology
niche model
redox-disequilibria
serpentinization
sulfate reduction

ASJC Scopus subject areas

Forestry
Aquatic Science
Ecology
Water Science and Technology
Soil Science
Atmospheric Science
Palaeontology

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10.1029/2021JG006317

Cite this

Howells, A. E. G., Leong, J. A. M., Ely, T., Santana, M., Robinson, K., Esquivel-Elizondo, S., Cox, A., Poret-Peterson, A., Krajmalnik-Brown, R., & Shock, E. L. (2022). Energetically Informed Niche Models of Hydrogenotrophs Detected in Sediments of Serpentinized Fluids of the Samail Ophiolite of Oman. Journal of Geophysical Research: Biogeosciences, 127(3), [e2021JG006317]. https://doi.org/10.1029/2021JG006317

Howells, AEG, Leong, JAM, Ely, T, Santana, M, Robinson, K, Esquivel-Elizondo, S, Cox, A, Poret-Peterson, A, Krajmalnik-Brown, R & Shock, EL 2022, 'Energetically Informed Niche Models of Hydrogenotrophs Detected in Sediments of Serpentinized Fluids of the Samail Ophiolite of Oman', Journal of Geophysical Research: Biogeosciences, vol. 127, no. 3, e2021JG006317. https://doi.org/10.1029/2021JG006317

@article{e0ed6f63a4c8435fb3a3d39b5c43d650,

title = "Energetically Informed Niche Models of Hydrogenotrophs Detected in Sediments of Serpentinized Fluids of the Samail Ophiolite of Oman",

abstract = "A geochemical gradient established by mixing between reduced, hyperalkaline (pH > 11), H2-rich fluids generated through the process of serpentinization and surrounding surface water (pH ∼ 8) in the Samail Ophiolite of Oman provides an opportunity to characterize the geochemical and biological factors that influence the distribution of H2 oxidizing chemotrophs, hydrogenotrophs. In this study, 16S rRNA gene amplicon sequencing was implemented to characterize hydrogenotrophs in sediments underlying surface expressed serpentinized fluids in Oman. Hydrogenotroph phylotype distribution was evaluated as functions of chemical energy supplies for their given metabolic redox reactions. Through this approach, it was discovered that hydrogenotrophic taxa are likely constrained to sediments with overlying fluids that have <∼60 μm O2, including microorganisms of the genus, Hydrogenophaga. Sulfate reducers of the family, Thermodesulfovibrionaceae, likely require >∼10 μm SO4−2 for survival. In sediments with fluids having >∼10 μm SO4−2, sulfate reducers likely outcompete microorganisms of the methanogen genus, Methanobacterium, for H2. Additionally, differences in distribution between Thermodesulfovibrionaceae and Methanobacterium may be driven by the availability of electron acceptors and the redox reaction that is most energy yielding in the fluid. Taken together, observations from the Oman geochemical gradient result in a hydrogenotroph niche model that can be used to evaluate global distribution patterns of hydrogenotrophs in continental serpentinized fluids. On a global scale, based on previous studies, Methanobacterium is constrained to fluids that have <∼10 μm SO4−2.",

keywords = "methanogenesis, microbial ecology, niche model, redox-disequilibria, serpentinization, sulfate reduction",

author = "Howells, {Alta E.G.} and Leong, {James A.M.} and Tucker Ely and Michelle Santana and Kirt Robinson and Sofia Esquivel-Elizondo and Alysia Cox and Amisha Poret-Peterson and Rosa Krajmalnik-Brown and Shock, {Everett L.}",

note = "Funding Information: The authors thank Alexis Templeton, the director of RPL. The authors thank Peter Kelemen and J{\"u}rg Matter for help with fieldwork and logistics of conducting research in Oman. The authors thank Kris Fecteau, Vincent Debes, Grayson Boyer, Peter Canovas, Natasha Zolotova, and Panjai Prapaopong for help with chemical analyses at ASU. The authors thank William Brazelton for help with the development of DNA extraction protocols. The authors thank Tori Hoehler for help establishing dissolved gas analysis at ASU and insights into biological interactions between sulfate reducers and methanogens. This work was supported by NASA Exobiology Grant NNX12AB38G, the NASA Astrobiology Institute Rock‐Powered Life (RPL) project Grant NNA15BB02A, and NSF Grant EAR‐1515513. Funding to Rosa Krajmalnik‐Brown and Sofia Esquivel‐Elizondo was provided by the National Science Foundation (NSF) Engineering Research Center for Bio‐mediated and Bioinspired Geotechnics (CBBG) under NSF CA no. EEC1449501. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the authors and do not necessarily reflect those of the NSF. Funding Information: The authors thank Alexis Templeton, the director of RPL. The authors thank Peter Kelemen and J?rg Matter for help with fieldwork and logistics of conducting research in Oman. The authors thank Kris Fecteau, Vincent Debes, Grayson Boyer, Peter Canovas, Natasha Zolotova, and Panjai Prapaopong for help with chemical analyses at ASU. The authors thank William Brazelton for help with the development of DNA extraction protocols. The authors thank Tori Hoehler for help establishing dissolved gas analysis at ASU and insights into biological interactions between sulfate reducers and methanogens. This work was supported by NASA Exobiology Grant NNX12AB38G, the NASA Astrobiology Institute Rock-Powered Life (RPL) project Grant NNA15BB02A, and NSF Grant EAR-1515513. Funding to Rosa Krajmalnik-Brown and Sofia Esquivel-Elizondo was provided by the National Science Foundation (NSF) Engineering Research Center for Bio-mediated and Bioinspired Geotechnics (CBBG) under NSF CA no. EEC1449501. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the authors and do not necessarily reflect those of the NSF. Publisher Copyright: {\textcopyright} 2022. American Geophysical Union. All Rights Reserved.",

year = "2022",

month = mar,

doi = "10.1029/2021JG006317",

language = "English (US)",

volume = "127",

journal = "Journal of Geophysical Research: Biogeosciences",

issn = "2169-8953",

number = "3",

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T1 - Energetically Informed Niche Models of Hydrogenotrophs Detected in Sediments of Serpentinized Fluids of the Samail Ophiolite of Oman

AU - Howells, Alta E.G.

AU - Leong, James A.M.

AU - Ely, Tucker

AU - Santana, Michelle

AU - Robinson, Kirt

AU - Esquivel-Elizondo, Sofia

AU - Cox, Alysia

AU - Poret-Peterson, Amisha

AU - Krajmalnik-Brown, Rosa

AU - Shock, Everett L.

N1 - Funding Information: The authors thank Alexis Templeton, the director of RPL. The authors thank Peter Kelemen and Jürg Matter for help with fieldwork and logistics of conducting research in Oman. The authors thank Kris Fecteau, Vincent Debes, Grayson Boyer, Peter Canovas, Natasha Zolotova, and Panjai Prapaopong for help with chemical analyses at ASU. The authors thank William Brazelton for help with the development of DNA extraction protocols. The authors thank Tori Hoehler for help establishing dissolved gas analysis at ASU and insights into biological interactions between sulfate reducers and methanogens. This work was supported by NASA Exobiology Grant NNX12AB38G, the NASA Astrobiology Institute Rock‐Powered Life (RPL) project Grant NNA15BB02A, and NSF Grant EAR‐1515513. Funding to Rosa Krajmalnik‐Brown and Sofia Esquivel‐Elizondo was provided by the National Science Foundation (NSF) Engineering Research Center for Bio‐mediated and Bioinspired Geotechnics (CBBG) under NSF CA no. EEC1449501. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the authors and do not necessarily reflect those of the NSF. Funding Information: The authors thank Alexis Templeton, the director of RPL. The authors thank Peter Kelemen and J?rg Matter for help with fieldwork and logistics of conducting research in Oman. The authors thank Kris Fecteau, Vincent Debes, Grayson Boyer, Peter Canovas, Natasha Zolotova, and Panjai Prapaopong for help with chemical analyses at ASU. The authors thank William Brazelton for help with the development of DNA extraction protocols. The authors thank Tori Hoehler for help establishing dissolved gas analysis at ASU and insights into biological interactions between sulfate reducers and methanogens. This work was supported by NASA Exobiology Grant NNX12AB38G, the NASA Astrobiology Institute Rock-Powered Life (RPL) project Grant NNA15BB02A, and NSF Grant EAR-1515513. Funding to Rosa Krajmalnik-Brown and Sofia Esquivel-Elizondo was provided by the National Science Foundation (NSF) Engineering Research Center for Bio-mediated and Bioinspired Geotechnics (CBBG) under NSF CA no. EEC1449501. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the authors and do not necessarily reflect those of the NSF. Publisher Copyright: © 2022. American Geophysical Union. All Rights Reserved.

PY - 2022/3

Y1 - 2022/3

N2 - A geochemical gradient established by mixing between reduced, hyperalkaline (pH > 11), H2-rich fluids generated through the process of serpentinization and surrounding surface water (pH ∼ 8) in the Samail Ophiolite of Oman provides an opportunity to characterize the geochemical and biological factors that influence the distribution of H2 oxidizing chemotrophs, hydrogenotrophs. In this study, 16S rRNA gene amplicon sequencing was implemented to characterize hydrogenotrophs in sediments underlying surface expressed serpentinized fluids in Oman. Hydrogenotroph phylotype distribution was evaluated as functions of chemical energy supplies for their given metabolic redox reactions. Through this approach, it was discovered that hydrogenotrophic taxa are likely constrained to sediments with overlying fluids that have <∼60 μm O2, including microorganisms of the genus, Hydrogenophaga. Sulfate reducers of the family, Thermodesulfovibrionaceae, likely require >∼10 μm SO4−2 for survival. In sediments with fluids having >∼10 μm SO4−2, sulfate reducers likely outcompete microorganisms of the methanogen genus, Methanobacterium, for H2. Additionally, differences in distribution between Thermodesulfovibrionaceae and Methanobacterium may be driven by the availability of electron acceptors and the redox reaction that is most energy yielding in the fluid. Taken together, observations from the Oman geochemical gradient result in a hydrogenotroph niche model that can be used to evaluate global distribution patterns of hydrogenotrophs in continental serpentinized fluids. On a global scale, based on previous studies, Methanobacterium is constrained to fluids that have <∼10 μm SO4−2.

AB - A geochemical gradient established by mixing between reduced, hyperalkaline (pH > 11), H2-rich fluids generated through the process of serpentinization and surrounding surface water (pH ∼ 8) in the Samail Ophiolite of Oman provides an opportunity to characterize the geochemical and biological factors that influence the distribution of H2 oxidizing chemotrophs, hydrogenotrophs. In this study, 16S rRNA gene amplicon sequencing was implemented to characterize hydrogenotrophs in sediments underlying surface expressed serpentinized fluids in Oman. Hydrogenotroph phylotype distribution was evaluated as functions of chemical energy supplies for their given metabolic redox reactions. Through this approach, it was discovered that hydrogenotrophic taxa are likely constrained to sediments with overlying fluids that have <∼60 μm O2, including microorganisms of the genus, Hydrogenophaga. Sulfate reducers of the family, Thermodesulfovibrionaceae, likely require >∼10 μm SO4−2 for survival. In sediments with fluids having >∼10 μm SO4−2, sulfate reducers likely outcompete microorganisms of the methanogen genus, Methanobacterium, for H2. Additionally, differences in distribution between Thermodesulfovibrionaceae and Methanobacterium may be driven by the availability of electron acceptors and the redox reaction that is most energy yielding in the fluid. Taken together, observations from the Oman geochemical gradient result in a hydrogenotroph niche model that can be used to evaluate global distribution patterns of hydrogenotrophs in continental serpentinized fluids. On a global scale, based on previous studies, Methanobacterium is constrained to fluids that have <∼10 μm SO4−2.

KW - methanogenesis

KW - microbial ecology

KW - niche model

KW - redox-disequilibria

KW - serpentinization

KW - sulfate reduction

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Energetically Informed Niche Models of Hydrogenotrophs Detected in Sediments of Serpentinized Fluids of the Samail Ophiolite of Oman

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