Identifying sulphate-reducing and magnetotactic bacteria in a hyperalkaline cave system

Lancaster Environment Centre

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Author_accepted_version_Identifying_sulphate_reducing_and_magnetotactic_bacteria_in_a_hyperalkaline_cave_system
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Keywords

Poole’s Cavern, sulphate-reducing bacteria, magnetotactic bacteria, 16S rRNA sequencing, extremotolerance

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Research output: Contribution to Journal/Magazine › Journal article › peer-review

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Identifying sulphate-reducing and magnetotactic bacteria in a hyperalkaline cave system. / Shen, J.; Smith, A.C.; Barnett, M.J. et al.
In: Cave and Karst Science, Vol. 50, No. 1, 30.04.2023, p. 16-20.

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Author

Shen, J. ; Smith, A.C. ; Barnett, M.J. et al. / Identifying sulphate-reducing and magnetotactic bacteria in a hyperalkaline cave system. In: Cave and Karst Science. 2023 ; Vol. 50, No. 1. pp. 16-20.

Bibtex

@article{d1f95969e8424ab0b95b65fa769889c0,

title = "Identifying sulphate-reducing and magnetotactic bacteria in a hyperalkaline cave system",

abstract = "Sulphate-reducing bacteria (SRB) and magnetotactic bacteria (MTB) are two special groups of prokaryotes that emerged early in Earth{\textquoteright}s history. These extremotolerant bacterial groups have rarely been identified or studied within cave and karst environments, especially hyperalkaline cave systems (pH > 9), such as Poole{\textquoteright}s Cavern in Derbyshire, England. In this study, we identify the sulphate-reducing MTB Desulfovibrio magneticus, within this hyperalkaline cave system. It appears to survive in a diverse range of environments including soil, stalactites and cave sediments. Additionally, we identify various extremotolerant SRB in similar Poole{\textquoteright}s Cavern environments. We show that these SRB and MTB can move successfully into subsurface environments and adapt concomitantly to the anomalous pH, saline, and relatively nutrient-poor conditions found in Poole{\textquoteright}s Cavern. These findings are significant to our understanding of microorganisms on early Earth because it is believed, but not proven, that underground environments might have been hot spots for early microbial life. We expect that these early bacteria would have been able to adopt similar adaptation strategies, transferring and acclimatizing to underground environments, in ways comparable to the SRB and MTB identified in this study.",

keywords = "Poole{\textquoteright}s Cavern, sulphate-reducing bacteria, magnetotactic bacteria, 16S rRNA sequencing, extremotolerance",

author = "J. Shen and A.C. Smith and M.J. Barnett and A. Morgan and P.M. Wynn",

year = "2023",

month = apr,

day = "30",

language = "English",

volume = "50",

pages = "16--20",

journal = "Cave and Karst Science",

number = "1",

}

RIS

TY - JOUR

T1 - Identifying sulphate-reducing and magnetotactic bacteria in a hyperalkaline cave system

AU - Shen, J.

AU - Smith, A.C.

AU - Barnett, M.J.

AU - Morgan, A.

AU - Wynn, P.M.

PY - 2023/4/30

Y1 - 2023/4/30

N2 - Sulphate-reducing bacteria (SRB) and magnetotactic bacteria (MTB) are two special groups of prokaryotes that emerged early in Earth’s history. These extremotolerant bacterial groups have rarely been identified or studied within cave and karst environments, especially hyperalkaline cave systems (pH > 9), such as Poole’s Cavern in Derbyshire, England. In this study, we identify the sulphate-reducing MTB Desulfovibrio magneticus, within this hyperalkaline cave system. It appears to survive in a diverse range of environments including soil, stalactites and cave sediments. Additionally, we identify various extremotolerant SRB in similar Poole’s Cavern environments. We show that these SRB and MTB can move successfully into subsurface environments and adapt concomitantly to the anomalous pH, saline, and relatively nutrient-poor conditions found in Poole’s Cavern. These findings are significant to our understanding of microorganisms on early Earth because it is believed, but not proven, that underground environments might have been hot spots for early microbial life. We expect that these early bacteria would have been able to adopt similar adaptation strategies, transferring and acclimatizing to underground environments, in ways comparable to the SRB and MTB identified in this study.

AB - Sulphate-reducing bacteria (SRB) and magnetotactic bacteria (MTB) are two special groups of prokaryotes that emerged early in Earth’s history. These extremotolerant bacterial groups have rarely been identified or studied within cave and karst environments, especially hyperalkaline cave systems (pH > 9), such as Poole’s Cavern in Derbyshire, England. In this study, we identify the sulphate-reducing MTB Desulfovibrio magneticus, within this hyperalkaline cave system. It appears to survive in a diverse range of environments including soil, stalactites and cave sediments. Additionally, we identify various extremotolerant SRB in similar Poole’s Cavern environments. We show that these SRB and MTB can move successfully into subsurface environments and adapt concomitantly to the anomalous pH, saline, and relatively nutrient-poor conditions found in Poole’s Cavern. These findings are significant to our understanding of microorganisms on early Earth because it is believed, but not proven, that underground environments might have been hot spots for early microbial life. We expect that these early bacteria would have been able to adopt similar adaptation strategies, transferring and acclimatizing to underground environments, in ways comparable to the SRB and MTB identified in this study.

KW - Poole’s Cavern

KW - sulphate-reducing bacteria

KW - magnetotactic bacteria

KW - 16S rRNA sequencing

KW - extremotolerance

M3 - Journal article

VL - 50

SP - 16

EP - 20

JO - Cave and Karst Science

JF - Cave and Karst Science

IS - 1

ER -

Research

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