Sulfate-dependant microbially induced corrosion of mild steel in the deep sea: a 10-year microbiome study.

Rajala, P; Cheng, D-Q; Rice, SA; Lauro, FM

Sulfate-dependant microbially induced corrosion of mild steel in the deep sea: a 10-year microbiome study.

Rajala, P Cheng, D-Q Rice, SA Lauro, FM

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Publisher:: BMC
Publication Type:: Journal Article
Citation:: Microbiome, 2022, 10, (1), pp. 4
Issue Date:: 2022-01-13

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Field	Value	Language
dc.contributor.author	Rajala, P
dc.contributor.author	Cheng, D-Q
dc.contributor.author	Rice, SA
dc.contributor.author	Lauro, FM
dc.date.accessioned	2022-04-01T04:20:08Z
dc.date.available	2021-11-13
dc.date.available	2022-04-01T04:20:08Z
dc.date.issued	2022-01-13
dc.identifier.citation	Microbiome, 2022, 10, (1), pp. 4
dc.identifier.issn	2049-2618
dc.identifier.issn	2049-2618
dc.identifier.uri	http://hdl.handle.net/10453/155876
dc.description.abstract	BACKGROUND: Metal corrosion in seawater has been extensively studied in surface and shallow waters. However, infrastructure is increasingly being installed in deep-sea environments, where extremes of temperature, salinity, and high hydrostatic pressure increase the costs and logistical challenges associated with monitoring corrosion. Moreover, there is currently only a rudimentary understanding of the role of microbially induced corrosion, which has rarely been studied in the deep-sea. We report here an integrative study of the biofilms growing on the surface of corroding mooring chain links that had been deployed for 10 years at ~2 km depth and developed a model of microbially induced corrosion based on flux-balance analysis. METHODS: We used optical emission spectrometry to analyze the chemical composition of the mooring chain and energy-dispersive X-ray spectrometry coupled with scanning electron microscopy to identify corrosion products and ultrastructural features. The taxonomic structure of the microbiome was determined using shotgun metagenomics and was confirmed by 16S amplicon analysis and quantitative PCR of the dsrB gene. The functional capacity was further analyzed by generating binned, genomic assemblies and performing flux-balance analysis on the metabolism of the dominant taxa. RESULTS: The surface of the chain links showed intensive and localized corrosion with structural features typical of microbially induced corrosion. The microbiome on the links differed considerably from that of the surrounding sediment, suggesting selection for specific metal-corroding biofilms dominated by sulfur-cycling bacteria. The core metabolism of the microbiome was reconstructed to generate a mechanistic model that combines biotic and abiotic corrosion. Based on this metabolic model, we propose that sulfate reduction and sulfur disproportionation might play key roles in deep-sea corrosion. CONCLUSIONS: The corrosion rate observed was higher than what could be expected from abiotic corrosion mechanisms under these environmental conditions. High corrosion rate and the form of corrosion (deep pitting) suggest that the corrosion of the chain links was driven by both abiotic and biotic processes. We posit that the corrosion is driven by deep-sea sulfur-cycling microorganisms which may gain energy by accelerating the reaction between metallic iron and elemental sulfur. The results of this field study provide important new insights on the ecophysiology of the corrosion process in the deep sea.
dc.format	Electronic
dc.language	eng
dc.publisher	BMC
dc.relation.ispartof	Microbiome
dc.relation.isbasedon	10.1186/s40168-021-01196-6
dc.rights	info:eu-repo/semantics/openAccess
dc.subject	0602 Ecology, 0605 Microbiology, 1108 Medical Microbiology
dc.subject.mesh	Bacteria
dc.subject.mesh	Biofilms
dc.subject.mesh	Corrosion
dc.subject.mesh	Microbiota
dc.subject.mesh	Steel
dc.subject.mesh	Sulfates
dc.title	Sulfate-dependant microbially induced corrosion of mild steel in the deep sea: a 10-year microbiome study.
dc.type	Journal Article
utslib.citation.volume	10
utslib.location.activity	England
utslib.for	0602 Ecology
utslib.for	0605 Microbiology
utslib.for	1108 Medical Microbiology
pubs.organisational-group	/University of Technology Sydney
pubs.organisational-group	/University of Technology Sydney/Faculty of Science
pubs.organisational-group	/University of Technology Sydney/Strength - ithree - Institute of Infection, Immunity and Innovation
utslib.copyright.status	open_access	*
dc.date.updated	2022-04-01T04:20:03Z
pubs.issue	1
pubs.publication-status	Published online
pubs.volume	10
utslib.citation.issue	1

Abstract:

BACKGROUND: Metal corrosion in seawater has been extensively studied in surface and shallow waters. However, infrastructure is increasingly being installed in deep-sea environments, where extremes of temperature, salinity, and high hydrostatic pressure increase the costs and logistical challenges associated with monitoring corrosion. Moreover, there is currently only a rudimentary understanding of the role of microbially induced corrosion, which has rarely been studied in the deep-sea. We report here an integrative study of the biofilms growing on the surface of corroding mooring chain links that had been deployed for 10 years at ~2 km depth and developed a model of microbially induced corrosion based on flux-balance analysis. METHODS: We used optical emission spectrometry to analyze the chemical composition of the mooring chain and energy-dispersive X-ray spectrometry coupled with scanning electron microscopy to identify corrosion products and ultrastructural features. The taxonomic structure of the microbiome was determined using shotgun metagenomics and was confirmed by 16S amplicon analysis and quantitative PCR of the dsrB gene. The functional capacity was further analyzed by generating binned, genomic assemblies and performing flux-balance analysis on the metabolism of the dominant taxa. RESULTS: The surface of the chain links showed intensive and localized corrosion with structural features typical of microbially induced corrosion. The microbiome on the links differed considerably from that of the surrounding sediment, suggesting selection for specific metal-corroding biofilms dominated by sulfur-cycling bacteria. The core metabolism of the microbiome was reconstructed to generate a mechanistic model that combines biotic and abiotic corrosion. Based on this metabolic model, we propose that sulfate reduction and sulfur disproportionation might play key roles in deep-sea corrosion. CONCLUSIONS: The corrosion rate observed was higher than what could be expected from abiotic corrosion mechanisms under these environmental conditions. High corrosion rate and the form of corrosion (deep pitting) suggest that the corrosion of the chain links was driven by both abiotic and biotic processes. We posit that the corrosion is driven by deep-sea sulfur-cycling microorganisms which may gain energy by accelerating the reaction between metallic iron and elemental sulfur. The results of this field study provide important new insights on the ecophysiology of the corrosion process in the deep sea.

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http://hdl.handle.net/10453/155876