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Accessing the subsurface biosphere within rocks undergoing active low-temperature serpentinization in the Samail Ophiolite (Oman Drilling Project)

Accessing the subsurface biosphere within rocks undergoing active low-temperature serpentinization in the Samail Ophiolite (Oman Drilling Project)
Accessing the subsurface biosphere within rocks undergoing active low-temperature serpentinization in the Samail Ophiolite (Oman Drilling Project)
The Oman Drilling Project established an “Active Alteration” multi-borehole observatory in peridotites undergoing low-temperature serpentinization in the Samail Ophiolite. The highly serpentinized rocks are in contact with strongly reducing fluids. Distinct hydrological regimes, governed by differences in rock porosity and fracture density, give rise to steep redox (Eh +200 to −750 mV) and pH (pH range 8.5–11.2) gradients within the 300–400 m deep boreholes. The serpentinites and fluids host an active subsurface ecosystem. Microbial cell abundances in serpentinite vary at least six orders of magnitude, from ≤3.5 × 101 to 2.9 × 107 cells/g. Low levels of biological sulfate reduction (2–1,000 fmol/cm3/day) can be detected in rock cores, particularly in rocks in contact with reduced groundwaters with pH < 10.5. Thermodesulfovibrio is the predominant sulfate reducer identified via metagenomic sequencing of adjacent groundwater communities. We infer that transport and reaction of microbially
generated sulfide with the serpentine and brucite assemblages gives rise to optical darkening and sulfide overprinting, including the formation of tochilinite-vallerite group minerals, potentially serving as an indicator that this system is inhabited by microbial life. Olivine mesh-cores replaced with ferroan brucite and minor awaruite, abundant veins containing hydroandradite garnet and polyhedral serpentine, and late-stage carbonate veins are suggested as targets for future spatially resolved life detection investigations. The high-quality whole-round core samples that have been preserved can be further probed to define how life distributes itself and functions within a system where chemical disequilibria are sustained by lowtemperature water/rock interaction, and how biosignatures of in situ microbial activity are generated.
2169-8953
Templeton, Alexis S.
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Ellison, Eric T.
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Glombitza, Clemens
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Morono, Yuki
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Rempfert, Kaitlin R.
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Hoehler, Tori
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Zeigler, Spencer
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Spear, J.
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Kraus, Emily
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Nothaft, Daniel
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Fones, Elizabeth
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Boyd, Eric S.
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Munro-Ehrlich, Mason
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Mayhew, Lisa
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Cardace, Dawn
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Matter, Juerg
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Kelemen, P.B.
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Oman Drilling Project Science Party
Templeton, Alexis S.
f65afca4-9076-4bdb-8214-91bbd6c775b0
Ellison, Eric T.
7feb77ff-0ede-4bce-9a7f-0ca7c5a0384f
Glombitza, Clemens
d59dcec9-3807-46d8-87ee-422efa80d466
Morono, Yuki
aaf49da1-d9ee-4c0a-8fba-23dfbc57dad8
Rempfert, Kaitlin R.
f9684cb0-b63d-4bca-b47b-e049a2aad131
Hoehler, Tori
088d3afa-a3d6-4aca-ada2-43e8c35d9dac
Zeigler, Spencer
7ecad313-1c5b-4220-8664-053ea6c8a572
Spear, J.
f22c2d52-9db6-4c5f-a168-51ca1c904cd5
Kraus, Emily
b2187fd4-1450-4894-888d-d151900cf22f
Nothaft, Daniel
f0654729-4128-466d-8b44-f74279ede779
Fones, Elizabeth
bac9228e-68be-440f-9e7e-c3bbeeaa7e4d
Boyd, Eric S.
7c0b0e4b-c2cb-4028-ae8a-3a3ad1d8fac0
Munro-Ehrlich, Mason
536f4294-085f-4eca-87e1-f44f861c9620
Mayhew, Lisa
1c4ccb54-94f2-4c34-af2e-7cd3d8c81fd1
Cardace, Dawn
636b7583-a006-40c9-a332-fe79d47ef65c
Matter, Juerg
abb60c24-b6cb-4d1a-a108-6fc51ee20395
Kelemen, P.B.
88693442-a912-40e1-bda3-3b54d29c18a1

Templeton, Alexis S., Ellison, Eric T., Glombitza, Clemens, Morono, Yuki, Rempfert, Kaitlin R., Hoehler, Tori, Zeigler, Spencer, Spear, J., Kraus, Emily, Nothaft, Daniel, Fones, Elizabeth, Boyd, Eric S., Munro-Ehrlich, Mason, Mayhew, Lisa, Cardace, Dawn, Matter, Juerg and Kelemen, P.B. , Oman Drilling Project Science Party (2021) Accessing the subsurface biosphere within rocks undergoing active low-temperature serpentinization in the Samail Ophiolite (Oman Drilling Project). Journal of Geophysical Research: Biogeosciences, 126 (10). (doi:10.1029/2021JG006315).

Record type: Article

Abstract

The Oman Drilling Project established an “Active Alteration” multi-borehole observatory in peridotites undergoing low-temperature serpentinization in the Samail Ophiolite. The highly serpentinized rocks are in contact with strongly reducing fluids. Distinct hydrological regimes, governed by differences in rock porosity and fracture density, give rise to steep redox (Eh +200 to −750 mV) and pH (pH range 8.5–11.2) gradients within the 300–400 m deep boreholes. The serpentinites and fluids host an active subsurface ecosystem. Microbial cell abundances in serpentinite vary at least six orders of magnitude, from ≤3.5 × 101 to 2.9 × 107 cells/g. Low levels of biological sulfate reduction (2–1,000 fmol/cm3/day) can be detected in rock cores, particularly in rocks in contact with reduced groundwaters with pH < 10.5. Thermodesulfovibrio is the predominant sulfate reducer identified via metagenomic sequencing of adjacent groundwater communities. We infer that transport and reaction of microbially
generated sulfide with the serpentine and brucite assemblages gives rise to optical darkening and sulfide overprinting, including the formation of tochilinite-vallerite group minerals, potentially serving as an indicator that this system is inhabited by microbial life. Olivine mesh-cores replaced with ferroan brucite and minor awaruite, abundant veins containing hydroandradite garnet and polyhedral serpentine, and late-stage carbonate veins are suggested as targets for future spatially resolved life detection investigations. The high-quality whole-round core samples that have been preserved can be further probed to define how life distributes itself and functions within a system where chemical disequilibria are sustained by lowtemperature water/rock interaction, and how biosignatures of in situ microbial activity are generated.

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Published date: 12 September 2021

Identifiers

Local EPrints ID: 490497
URI: http://eprints.soton.ac.uk/id/eprint/490497
ISSN: 2169-8953
PURE UUID: 37cd65cd-055e-4536-99e5-f2ca45147cc7
ORCID for Juerg Matter: ORCID iD orcid.org/0000-0002-1070-7371

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Date deposited: 29 May 2024 16:30
Last modified: 30 May 2024 01:44

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Contributors

Author: Alexis S. Templeton
Author: Eric T. Ellison
Author: Clemens Glombitza
Author: Yuki Morono
Author: Kaitlin R. Rempfert
Author: Tori Hoehler
Author: Spencer Zeigler
Author: J. Spear
Author: Emily Kraus
Author: Daniel Nothaft
Author: Elizabeth Fones
Author: Eric S. Boyd
Author: Mason Munro-Ehrlich
Author: Lisa Mayhew
Author: Dawn Cardace
Author: Juerg Matter ORCID iD
Author: P.B. Kelemen
Corporate Author: Oman Drilling Project Science Party

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