Spectroscopic States of the CO Oxidation/CO2 Reduction Active Site of Carbon Monoxide Dehydrogenase and Mechanistic Implications

Abstract

CO dehydrogenases catalyze the reversible oxidation of CO to CO₂, at an active site (called the C-cluster) composed of an Fe₄S₄ cube with what appears to be a 5-coordinate Fe (called FCII), linked to a Ni (Hu, Z., Spangler, N. J., Anderson, M. E., Xia, J., Ludden, P. W., Lindahl, P. A., & Münck, E. (1996) J. Am. Chem. Soc. 118, 830−845). During catalysis, electrons are transferred from the C-cluster to an [Fe₄S₄]^2+/1+ electron-transfer cluster called the B-cluster. An S = ¹/₂ form of the C-cluster (called C_red1) converts to another S = ¹/₂ form (called C_red2) upon reduction with CO, at a rate well within the turnover frequency of the enzyme (Kumar, M., Lu, W.-P., Liu, L., & Ragsdale, S. W. (1993) J. Am. Chem. Soc.115, 11646−11647). This suggests that the conversion is part of the catalytic mechanism. Dithionite is reported in this paper to effect this conversion as well, but at a much slower rate (k_so = 5.3 × 10^-2 M^-1 s^-1 for dithionite vs 4.4 × 10⁶ M^-1 s^-1 for CO). By contrast, dithionite reduces the oxidized B-cluster much faster, possibly within the turnover frequency of the enzyme. Dithionite apparently effects the C_red1/C_red2 conversion directly, rather than through an intermediate. The conversion rate varies with dithionite concentration. The C_red1/C_red2 conversion occurs at least 10² times faster in the presence of CO₂ than in its absence. CO₂ alters the g values of the g_av = 1.82 signal, indicating that CO₂ binds to a C-cluster-sensitive site at mild potentials. CN^- inhibits CO oxidation by binding to FCII (Hu et al., 1996), and CO, CO₂ in the presence of dithionite, or CS₂ in dithionite accelerate CN^- dissociation from this site (Anderson, M. E., & Lindahl, P. A. (1994) Biochemistry33, 8702−8711). The effect of CO, CO₂, and CS₂ on CN^- dissociation suggested that these molecules bind at a site (called the modulator) other than that to which CN^- binds. The effects of CO₂, CS₂, CO, and dithionite on the C_red1/C_red2 conversion rate followed a similar pattern, suggesting that this rate is also influenced by modulator binding. Some batches of enzyme cannot convert to the C_red2 form using dithionite, but pretreatment with CO or CO₂/dithionite effectively “cures” such batches of this disability. The results presented suggest that the Ni of the C-cluster is the modulator and the substrate binding site for CO/CO₂. The inhibitor CS₂ in the presence of dithionite also accelerates the decline of C_red1, leading first to an EPR-silent state of the C-cluster, and eventually to a state yielding an EPR signal with g_av = 1.66. CS₂ binding thus shares some resemblance to CO₂ binding. Approximately 90% of the absorbance changes at 420 nm that occur when oxidized CODH_Ct is reduced by dithionite occur within 2 min at 10 °C. This absorbance change occurs in concert with the g_av = 1.94 signal development. The remaining 10% of the A₄₂₀ changes occur over the course of ∼50 min, apparently coincident with the C_red1/C_red2 conversion. One possibility is that the conversion involves reduction of an (unidentified) Fe-S cluster. A three-state model of catalysis is proposed in which C_red1 binds and oxidizes CO, C_red2 is two electrons more reduced than C_red1 and is the state that binds and reduces CO₂, and C_int is a one-electron-reduced state that is proposed to exist because of constraints imposed by the nature of the CO/CO₂ reaction and the properties of the clusters involved in catalysis.