CODH M

In enzymology, carbon monoxide dehydrogenase (CODH) () is an enzyme that catalyzes the chemical reaction

:CO + H₂O + A $\rightleftharpoons$ CO₂ + AH₂

The chemical process catalyzed by carbon monoxide dehydrogenase is similar to the water-gas shift reaction.

The 3 substrates of this enzyme are CO, H₂O, and A, whereas its two products are CO₂ and AH₂.

A variety of electron donors/receivers (Shown as "A" and "AH₂" in the reaction equation above) are observed in micro-organisms which utilize CODH. Several examples of electron transfer cofactors have been proposed, including Ferredoxin, NADP+/NADPH and flavoprotein complexes like flavin adenine dinucleotide (FAD) as well as hydrogenases. CODHs support the metabolisms of diverse prokaryotes, including methanogens, aerobic carboxidotrophs, acetogens, sulfate-reducers, and hydrogenogenic bacteria. The bidirectional reaction catalyzed by CODH plays a role in the carbon cycle allowing organisms to both make use of CO as a source of energy and utilize CO₂ as a source of carbon. CODH can form a monofunctional enzyme, as is the case in ''Rhodospirillum rubrum'', or can form a cluster with acetyl-CoA synthase as has been shown in ''M. thermoacetica''. When acting in concert, either as structurally independent enzymes or in a bifunctional CODH/ACS unit, the two catalytic sites are key to carbon fixation in the reductive acetyl-CoA pathway. Microbial organisms (Both aerobic and anaerobic) encode and synthesize CODH for the purpose of carbon fixation (CO oxidation and CO₂ reduction). Depending on attached accessory proteins (A,B,C,D-Clusters), serve a variety of catalytic functions, including reduction of Fe-4Sclusters and insertion of nickel.

This enzyme belongs to the family of oxidoreductases, specifically those acting on the aldehyde or oxo group of donor with other acceptors. The systematic name of this enzyme class is carbon-monoxide:acceptor oxidoreductase. Other names in common use include anaerobic carbon monoxide dehydrogenase, carbon monoxide oxygenase, carbon-monoxide dehydrogenase, and carbon-monoxide:(acceptor) oxidoreductase.

Diversity

CODH are a rather diverse group of enzymes, containing two unrelated types of CODH. A copper-molybdenum flavoenzymes is found in some aerobic carboxydotrophic bacteria. Anaerobic bacteria utilize nickel-iron based CODHs. Both classes of CODH catalyze the conversion of carbon monoxide (CO) to carbon dioxide (CO₂). Only the Ni containing CODH is able to also catalyze the back reaction. CODHs exist in both monofunctional and bifunctional forms. An example for the latter case, Ni,Fe-CODHs form a bifunctional cluster with acetyl-CoA synthase, as has been well characterized in the anaerobic bacteria ''Moorella thermoacetica'', ''Clostridium autoethanogenum'' and ''Carboxydothermus hydrogenoformans'' ''.'' While the ACS subunits of the complex of ''C. autoethanogenum'' show a rather extended arrangement those of the ''M. thermoacetica'' and ''C. hydrogenoformans'' complex are closer to the CODH subunits forming a tight tunnel network connecting cluster C and cluster A.

Ni,Fe-CODH

Nickel containing CODH (Ni,Fe-CODH) can be further divided into structural clades, dependent on their phylogenetic relationship

Structure

Ni,Fe-CODH

Homodimeric Ni,Fe-CODHs contain five- metal clusters. They exist either in a homodimeric form (also called monofunctional) or in a bifunctional α₂β₂-tetrameric complex with acetyl-CoA synthase (ACS).

Monofunctional

The best studied monofunctional CODHs are those of ''Desulfovibrio vulgaris'', ''Rhodospirillum rubrum'' and ''Carboxydothermus hydrogenoformans.'' '''' They are homodimers of around 130 kDa sharing a central Fe4Scluster at the surface of the protein - cluster D. The electrons are probably transferred to another Fe4Scluster (cluster B) located 10 A inside the protein and from there to the active site - cluster C, being an i4Fe4Scluster. ''''

Bifunctional

The CODH/ACS complex is an α₂β₂ tetrameric enzyme. The structures of CODH/ACS complexes of the anaerobic bacteria ''Moorella thermoacetica'', ''Clostridium autoethanogenum'' and ''Carboxydothermus hydrogenoformans'' have been solved. The two CODH subunits form the central core of the enzyme to which an ACS subunit is attached at each side. Each α unit contains a single metal cluster. Together, the two β units contains five clusters of three types. CODH catalytic activity occurs at the Ni- Fe-4SC-clusters while the interior Fe-4SB and D clusters transfer electrons away from the C-cluster to external electron carriers such as ferredoxin. The ACS activity occurs in A-cluster located in the outer two α units.

All CODH/ACS complexes have a gas tunnel connecting the multiple active sites, while the tunnel system in the ''C. autoethanogenum'' enzyme is comparatively open and those of ''M. thermoacetica'' and ''C. hydrogenoformans'' rather tight. For the ''Moorella'' enzyme the rate of acetyl-CoA synthase activity from CO₂ is not affected by the addition of hemoglobin, which would compete for CO in bulk solution, and isotopic labeling studies show that carbon monoxide derived from the C-cluster is preferentially used at the A-cluster over unlabeled CO in solution. Protein engineering of the CODH/ACS in ''M.thermoacetica'' revealed that mutating residues, so as to functionally block the tunnel, stopped acetyl-CoA synthesis when only CO₂ was present. The discovery of a functional CO tunnel places CODH on a growing list of enzymes that independently evolved this strategy to transfer reactive intermediates from one active site to another.

Reaction mechanisms

Ni,Fe-CODH

The CODH catalytic site, referred to as the C-cluster, is a Fe-4Scluster bonded to a Ni-Fe moiety. Two basic amino acids (Lys587 and His 113 in ''M.thermoacetica'') reside in proximity to the C-cluster and facilitate acid-base chemistry required for enzyme activity. Furthermore, other residues (i.e. an isoleucine apical to the Ni atom) fine-tune the binding and conversion of CO. Based on IR spectra suggesting the presence of an Ni-CO complex, the proposed first step in the oxidative catalysis of CO to CO₂ involves the binding of CO to Ni²⁺ and corresponding complexing of Fe²⁺ to a water molecule.

It has been proposed that CO binds to square-planar nickel where it converts to a carboxy bridge between the Ni and Fe atom. A decarboxylation leads to the release of CO₂ and the reduction of the cluster.

The electrons in the reduced C-cluster are transferred to nearby B and D Fe-4Sclusters, returning the Ni- Fe-4SC-cluster to an oxidized state and reducing the single electron carrier ferredoxin.

Given CODH's role in CO₂ fixation, the reductive mechanism is sometimes inferred as the “direct reverse” of the oxidative mechanism by the ”principle of microreversibility.”

Environmental relevance

Carbon monoxide dehydrogenase regulates atmospheric CO and CO₂ levels. Anaerobic micro-organisms like Acetogens use the Wood–Ljungdahl pathway, relying on CODH to reduce CO₂ to CO, needed along with a methyl, coenzyme a (CoA) and corrinoid iron-sulfur protein for the synthesis of Acetyl-CoA. Other types show CODH being utilized to generate a proton motive force for the purposes of energy generation. CODH is used for the CO oxidation, producing two protons which are subsequently reduced to form dihydrogen (H₂.

References

Further reading

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{{Expand German, Carbonmonoxid Dehydrogenase, date=April 2022

EC 1.2.99
Iron enzymes
Zinc enzymes
Nickel enzymes
Iron-sulfur enzymes
Enzymes of known structure
Protein families
Dehydrogenase