Biochemistry
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Biosynthesis of the NiFe hydrogenase active site is a complex process involving the action of the Hyp proteins: HypA-HypF. Here we investigate the mechanism of NiFe site biosynthesis in Ralstonia eutropha by examining the interactions between HypC, HypD, HypE, and HypF1. Using an affinity purification procedure based on the Strep-tag II, we purified HypC and HypE from different genetic backgrounds as complexes with other hydrogenase-related proteins and characterized them using immunological analysis. ⋯ On the basis of these results, we propose a complete catalytic cycle for HypE. First, it is modified by HypF1, and then it can form a complex with HypC/HypD. This activated HypE/HypC/HypD complex could then decompose by donating active site components to the immature hydrogenase and regenerate unmodified HypE.
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This study directly examines the enthalpic contributions to binding in aqueous solution of closely related anesthetic haloethers (desflurane, isoflurane, enflurane, and sevoflurane), a haloalkane (halothane), and an intravenous anesthetic (propofol) to bovine and human serum albumin (BSA and HSA) using isothermal titration calorimetry. Binding to serum albumin is exothermic, yielding enthalpies (DeltaH(obs)) of -3 to -6 kcal/mol for BSA with a rank order of apparent equilibrium association constants (K(a) values): desflurane > isoflurane approximately enflurane > halothane >or= sevoflurane, with the differences being largely ascribed to entropic contributions. Competition experiments indicate that volatile anesthetics, at low concentrations, share the same sites in albumin previously identified in crystallographic and photo-cross-linking studies. ⋯ The enhanced stabilities of the albumin/anesthetic complexes and -DeltaC(p) are consistent with favorable solvent rearrangements that promote binding. This idea is supported by substitution of D(2)O for H(2)O that significantly reduces the favorable binding enthalpy observed for desflurane and isoflurane, with an opposing increase of DeltaS(obs). From these results, we infer that solvent restructuring, resulting from release of water weakly bound to anesthetic and anesthetic-binding sites, is a dominant and favorable contributor to the enthalpy and entropy of binding to proteins.