Selenium-Containing Formate Dehydrogenase H from Escherichia coli: A Molybdopterin Enzyme That Catalyzes Formate Oxidation without Oxygen Transfer

Abstract

Formate dehydrogenase H, FDH(Se), from Escherichia coli contains a molybdopterin guanine dinucleotide cofactor and a selenocysteine residue in the polypeptide. Oxidation of ¹³C-labeled formate in ¹⁸O-enriched water catalyzed by FDH(Se) produces ¹³CO₂ gas that contains no ¹⁸O-label, establishing that the enzyme is not a member of the large class of Mo−pterin-containing oxotransferases which incorporate oxygen from water into product. An unusual Mo center of the active site is coordinated in the reduced Mo(IV) state in a square pyramidal geometry to the four equatorial dithiolene sulfur atoms from a pair of pterin cofactors and a Se atom of the selenocysteine-140 residue [Boyington, J. C., Gladyshev, V. N., Khangulov, S. V., Stadtman, T. C., and Sun, P. D. (1997) Science 275, 1305−1308]. EPR spectroscopy of the Mo(V) state indicates a square pyramidal geometry analogous to that of the Mo(IV) center. The strongest ligand field component is likely the single axial Se atom producing a ground orbital configuration Mo(d_xy). The Mo−Se bond was estimated to be covalent to the extent of 17−27% of the unpaired electron spin density residing in the valence 4s and 4p selenium orbitals, based on comparison of the scalar and dipolar hyperfine components to atomic ⁷⁷Se. Two electron oxidation of formate by the Mo(VI) state converts Mo to the reduced Mo(IV) state with the formate proton, H_f⁺, transferring to a nearby base Y^-. Transfer of one electron to the Fe₄S₄ center converts Mo(IV) to the EPR detectable Mo(V) state. The Y^- is located within magnetic contact to the [Mo−Se] center, as shown by its strong dipolar ¹H_f hyperfine couplings. Photolysis of the formate-induced Mo(V) state abolishes the ¹H_f hyperfine splitting from YH_f, suggesting photoisomerization of this group or phototransfer of the proton to a more distant proton acceptor group A^-. The minor effect of photolysis on the ⁷⁷Se-hyperfine interaction with [⁷⁷Se] selenocysteine suggests that the Y^- group is not the Se atom, but instead might be the imidazole ring of the His141 residue which is located in the putative substrate-binding pocket close to the [Mo−Se] center. We propose that the transfer of H_f⁺ from formate to the active site base Y^- is thermodynamically coupled to two-electron oxidation of the formate molecule, thereby facilitating formation of CO₂. Under normal physiological conditions, when electron flow is not limited by the terminal acceptor of electrons, the energy released upon oxidation of Mo(IV) centers by the Fe₄S₄ is used for deprotonation of YH_f and transfer of H_f⁺ against the thermodynamic potential.