Formate dehydrogenase H ofEscherichia coli contains selenocysteine as an integral amino acid. We have purified a mutant form of the enzyme in which cysteine replaces selenocysteine. To elucidate the essential catalytic role of selenocysteine, kinetic and physical properties of the mutant enzyme were compared with those of wild type. The mutant and wild-type enzymes displayed similar pH dependencies with respect to activity and stability, although the mutant enzyme profiles were slightly shifted to more alkaline pH. Both enzymes were inactivated by reaction with iodoacetamide; however, addition of the substrate, formate, was necessary to render the enzymes susceptible to alkylation. Alkylation-induced inactivation was highly dependent on pH, with each enzyme displaying an alkylation vs. pH profile suggestive of an essential selenol or thiol. Both forms of the enzyme use a ping-pong bi-bi kinetic mechanism. The mutant enzyme binds formate with greater affinity than does the wild-type enzyme, as shown by reduced values of Km and Kd. However, the mutant enzyme has a turnover number which is more than two orders of magnitude lower than that of the native selenium-containing enzyme. The lower turnover number results from a diminished reaction rate for the initial step of the overall reaction, as found in kinetic analyses that employed the alternative substrate deuterioformate. These results indicate that the selenium of formate dehydrogenase H is directly involved in formate oxidation. The observed differences in kinetic properties may help explain the evolutionary conservation of selenocysteine at the enzyme's active site.
Structural information obtained from the analysis of nickel K-edge X-ray absorption spectroscopic data of [NiFe]hydrogenases from Desulfovibrio gigas, Thiocapsa roseopersicina, Desulfovibrio desulfuricans (ATCC 27774), Escherichia coli (hydrogenase-1), Chromatium vinosum, and Alcaligenes eutrophus H16 (NAD+-reducing, soluble hydrogenase), poised in different redox states, is reported. The data allow the active-site structures of enzymes from several species to be compared, and allow the effects of redox poise on the structure of the nickel sites to be examined. In addition, the structure of the nickel site obtained from recent crystallographic studies of the D. gigas enzyme (Volbeda, A.; Charon, M.-H.; Piras, C.; Hatchikian, E. C.; Frey, M.; Fontecilla-Camps, J. C. Nature 1995, 373, 580−587) is compared with the structural features obtained from the analysis of XAS data from the same enzyme. The nickel sites of all but the oxidized (as isolated) sample of A. eutrophus hydrogenase are quite similar. The nickel K-edge energies shift 0.9−1.5 eV to lower energy upon reduction from oxidized (forms A and B) to fully reduced forms. This value is comparable with no more than a one-electron metal-centered oxidation state change. With the exception of T. roseopersicina hydrogenase, most of the edge energy shift (∼0.8 eV) occurs upon reduction of the oxidized enzymes to the EPR-silent intermediate redox level (SI). Analysis of the XANES features assigned to 1s → 3d electronic transitions indicates that the shift in energy that occurs for reduction of the enzymes to the SI level may be attributed at least in part to an increase in the coordination number from five to six. The smallest edge energy shift is observed for the T. roseopersicina enzyme, where the XANES data indicate that the nickel center is always six-coordinate. With the exception of the oxidized sample of A. eutrophus hydrogenase, the EXAFS data are dominated by scattering from S-donor ligands at ∼2.2 Å. The enzyme obtained from T. roseopersicina also shows evidence for the presence of O,N-donor ligands. The data from A. eutrophus hydrogenase are unique in that they indicate that a significant structural change occurs upon reduction of the enzyme. EXAFS data obtained from the oxidized (as isolated) A. eutrophus enzyme indicate that the EXAFS is dominated by scattering from 3−4 N,O-donor atoms at 2.06(2) Å, with contributions from 2−3 S-donor ligands at 2.35(2) Å. This changes upon reduction to a more typical nickel site composed of ∼4 S-donor ligands at a Ni−S distance of 2.19(2) Å. Evidence for the presence of atoms in the 2.4−2.9 Å distance range is found in most samples, particularly the reduced enzymes (SI, form C, and R). The analysis of these data is complicated by the fact that it is difficult to distinguish between S and Fe scattering atoms at this distance, and by the potential presence of both S and another metal atom at similar distances. The results of EXAFS analysis are shown to be in general agreement with the published crystal structure of th...
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