Quinone extraction drives atmospheric carbon monoxide oxidation in bacteria

Kropp, Ashleigh; Gillett, David L.; Venugopal, Hari; Gonzálvez, Miguel A.; Lingford, James P.; Barlow, Christopher K.; Zhang, Jie; Greening, Chris; Grinter, Rhys

doi:10.1101/2024.01.09.574806

2024

DOI: 10.1101/2024.01.09.574806

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Quinone extraction drives atmospheric carbon monoxide oxidation in bacteria

Ashleigh Kropp,

David L. Gillett,

Hari Venugopal

et al.

Abstract: Diverse bacteria and archaea use atmospheric carbon monoxide (CO) as an energy source during long-term survival. This process enhances the biodiversity of soil and marine ecosystems globally and removes 250 million tonnes of a toxic, climate-relevant pollutant from the atmosphere each year. Bacteria use [MoCu]-carbon monoxide dehydrogenases (Mo-CODH) to convert CO to carbon dioxide, then transfer the liberated high-energy electrons to the aerobic respiratory chain. However, given no high-affinity Mo-CODH has b… Show more

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[MoCu]‐Dependent Carbon Monoxide Dehydrogenases

Gillett,

Grinter,

Greening

2024

Encyclopedia of Inorganic and Bioinorganic Chemistry

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[MoCu]‐dependent carbon monoxide dehydrogenases (Mo‐CODH) catalyze the hydroxylation of CO, which produces CO 2 and consumes H 2 O in the process. Aerobic carbon monoxide oxidizing bacteria and archaea use Mo‐CODH to generate energy by providing the respiratory chain with CO‐derived electrons, and aerobic CO‐oxidizers that possess the genes for CO 2 fixation can also use CO as a carbon source. Due to the pervasive nature of CO in the atmosphere as a trace gas, and the numerous marine and terrestrial environments enriched in CO due to its production during the decomposition of organic matter, aerobic CO‐oxidizers are widespread and significantly contribute to the biogeochemical cycle of CO. Mo‐CODH has been structurally characterized by both X‐ray crystallography and cryo‐EM. Structural and biochemical characterization of the purified Mo‐CODH enzyme has focused on bacteria that mediate carboxydotrophic growth such as Afipia carboxidovorans , which were isolated from environments with elevated concentrations of CO. Only recently has a Mo‐CODH enzyme capable of oxidizing CO to subatmospheric levels been isolated and characterized, from Mycobacterium smegmatis, providing the first insights into structural features that enable high‐affinity CO oxidation. In all aerobic CO oxidizers, CO oxidation occurs at a unique [MoSCu] dimetallic site within the active site of Mo‐CODH, through a mechanism that has been the subject of several computational and biochemical studies. Two [2Fe–2S] clusters facilitate the transport of electrons from the active site to a FAD cofactor, which then donates electrons to an electron carrier. Quinones are believed to be the primary physiological electron acceptor of Mo‐CODH, which can be transported from the cell membrane through the cytoplasm to the soluble Mo‐CODH complex by the CoxG shuttle protein.

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[MoCu]‐Dependent Carbon Monoxide Dehydrogenases

Gillett,

Grinter,

Greening

2024

Encyclopedia of Inorganic and Bioinorganic Chemistry

View full text Add to dashboard Cite

show abstract

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Quinone extraction drives atmospheric carbon monoxide oxidation in bacteria

Cited by 1 publication

References 73 publications

[MoCu]‐Dependent Carbon Monoxide Dehydrogenases

[MoCu]‐Dependent Carbon Monoxide Dehydrogenases

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