Abstract
Anaerobic Ni-containing carbon-monoxide dehydrogenases (Ni-CODHs) catalyze the reversible conversion between carbon monoxide and carbon dioxide as multi-enzyme complexes responsible for carbon fixation and energy conservation in anaerobic microbes. However, few biochemically characterized model enzymes exist, with most Ni-CODHs remaining functionally unknown. Here, we performed phylogenetic and structure-based Ni-CODH classification using an expanded dataset comprised of 1942 non-redundant Ni-CODHs from 1375 Ni-CODH-encoding genomes across 36 phyla. Ni-CODHs were divided into seven clades, including a novel clade. Further classification into 24 structural groups based on sequence analysis combined with structural prediction revealed diverse structural motifs for metal cluster formation and catalysis, including novel structural motifs potentially capable of forming metal clusters or binding metal ions, indicating Ni-CODH diversity and plasticity. Phylogenetic analysis illustrated that the metal clusters responsible for intermolecular electron transfer were drastically altered during evolution. Additionally, we identified novel putative Ni-CODH-associated proteins from genomic contexts other than the Wood–Ljungdahl pathway and energy converting hydrogenase system proteins. Network analysis among the structural groups of Ni-CODHs, their associated proteins and taxonomies revealed previously unrecognized gene clusters for Ni-CODHs, including uncharacterized structural groups with putative metal transporters, oxidoreductases, or transcription factors. These results suggested diversification of Ni-CODH structures adapting to their associated proteins across microbial genomes.
Highlights
We performed a comprehensive analysis of an expanded Ni-CO dehydrogenases (CODHs) dataset focusing on their structures and genomic contexts in order to classify Ni-containing CODH (Ni-CODH) and their related proteins and predict their novel functions
The previous two comprehensive studies for classification of Ni-CODHs have only focused on specific genomic contexts (i.e., CODH/acetyl-CoA synthase (ACS), CODH/energy converting hydrogenase (ECH), and CODH/CooF) or clades (Techtmann et al, 2012; Adam et al, 2018)
Techtmann et al (2012) focuses on CODH/ACS, CODH/ECH, and CODH/CooF, whereas Adam et al (2018) focuses on CODH/ACS subunits in more detail
Summary
The reversible conversion between carbon monoxide (CO) and carbon dioxide (CO2) catalyzed by CO dehydrogenases (CODHs) constitutes a key reaction in carbon fixation and energy conservation (King and Weber, 2007; Oelgeschläger and Rother, 2008; Sokolova et al, 2009; Nitschke and Russell, 2013; Can et al, 2014). Organisms termed carboxydotrophs utilize CO as an energy source through this reaction due to its low redox potential (King and Weber, 2007; Oelgeschläger and Rother, 2008; Sokolova et al, 2009) Aerobic carboxydotrophs, such as Oligotropha carboxidovorans, use oxygen as a terminal electron acceptor from CO oxidation, with Mo- and Cu-containing CODHs belonging to the xanthine oxidase family (King and Weber, 2007; Hille et al, 2015). Hydrogenogenic carboxydotrophs, such as Carboxydothermus hydrogenoformans and Rhodospirillum rubrum, couple CO oxidation with proton reduction to produce hydrogen, in which the proton motive force might be generated with residual energy via the CODH/energy converting hydrogenase (ECH) complex (Fox et al, 1996; Soboh et al, 2002)
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