Synthesis and overexpression of a gene encoding Escherichia coli UDP-galactose 4-epimerase and engineered to facilitate cassette mutagenesis are described. General acid-base catalysis at the active site of this epimerase has been studied by kinetic and spectroscopic analysis of the wild-type enzyme and its specifically mutated forms Y149F, S124A, S124V, and S124T. The X-ray crystal structure of Y149F as its abortive complex with UDP-glucose is structurally similar to that of the corresponding wild-type complex, except for the absence of the phenolic oxygen of Tyr 149. The major effects of mutations are expressed in the values of kcat and kcat/Km. The least active mutant is Y149F, for which the value of kcat is 0.010% of that of the wild-type epimerase. The activity of S124A is also very low, with a kcat value that is 0.035% of that of the native enzyme. The values of Km for Y149F and S124A are 12 and 21% of that of the wild-type enzyme, respectively. The value of kcat for S124T is about 30% of that of the wild-type enzyme, and the value of Km is similar to that of the native enzyme. The reactivities of the mutants in UMP-dependent reductive inactivation by glucose are similarly affected, with kobs being decreased by 6560-, 370-, and 3.4-fold for Y149F, S124A, and S124T, respectively. The second-order rate constants for reductive inactivation by NaBH3CN, which does not require general base catalysis, are similar to that for the native enzyme in the cases of S124A, S124T, and S124V. However, Y149F reacts with NaBH3CN 12-20-fold faster than the wild-type enzyme at pH 8.5 and 7.0, respectively. The increased rate for Y149F is attributed to the weakened charge-transfer interaction between Phe 149 and NAD+, which is present with Tyr 149 in the wild-type enzyme. The charge-transfer band is present in the serine mutants, and its intensity at 320 nm is pH-dependent. The pH dependencies of A320 showed that the pKa values for Tyr 149 are 6.08 for the wild-type epimerase, 6.71 for S124A, 6.86 for S124V, and 6.28 for S124T. The low pKa value for Tyr 149 is attributed mainly to the positive electrostatic field created by NAD+ and Lys 153 (4.5 kcal mol-1) and partly to hydrogen bonding with Ser 124 (1 kcal mol-1). The pKa of Tyr 149 is the same as the kinetic pKa for the Bronsted base that facilitates hydride transfer to NAD+. We concluded that Tyr 149 provides the driving force for general acid-base catalysis, with Ser 124 playing an important role in mediating proton transfer.
The transient complex of bovine myoglobin and cytochrome b(5) has been investigated using a combination of NMR chemical shift mapping, (15)N relaxation data, and protein docking simulations. Chemical shift perturbations observed for cytochrome b(5) amide resonances upon complex formation with either metmyoglobin (Fe(III)) or carbon monoxide-bound myoglobin (Fe(II)) are more than 10-fold smaller than in other transient redox protein complexes. From (15)N relaxation experiments, an increase in the overall correlation time of cytochrome b(5) in the presence of myoglobin is observed, confirming that complex formation is occurring. The chemical shift perturbations of proton and nitrogen amide nuclei as well as heme protons of cytochrome b(5) titrate with increasing myoglobin concentrations, also demonstrating the formation of a weak complex with a K(a) in the inverse millimolar range. The perturbed residues map over a wide surface area of cytochrome b(5), with patches of residues located around the exposed heme 6-propionate as well as at the back of the protein. The nature of the affected residues is mostly negatively charged contrary to perturbed residues in other transient complexes, which are mainly hydrophobic or polar. Protein docking simulations using the NMR data as constraints show several docking geometries both close to and far away from the exposed heme propionates of myoglobin. Overall, the data support the emerging view that this complex consists of a dynamic ensemble of orientations in which each protein constantly diffuses over the surface of the other. The characteristic NMR features may serve as a structural tool for the identification of such dynamic complexes.
UDP-galactose 4-epimerase from Escherichia coli contains tightly bound NAD+, which participates in catalyzing the interconversion of UDP-galactose and UDP-glucose through its redox properties. The purified enzyme is a dimer of identical subunits that consists of a mixture of catalytically active subunits designated E.NAD+ and inactive, abortive complexes designated E.NADH.uridine nucleotide, in which the uridine nucleotide may be UDP-glucose, UDP-galactose, or UDP [Vanhooke, J. L., & Frey, P. A. (1994) J. Biol. Chem. 269, 31496-31404]. The abortive complexes are transformed into active E.NAD+ by denaturation of the purified enzyme at 4 degrees C in 6 M guanidine hydrochloride buffered at pH 7.0 in the presence of 0.126 mM NAD+ for 3 h, followed by dilution of guanidine hydrochloride to 0.18 M and of NAD+ to 0.076 mM for 2 h. The renatured enzyme is fully active and contains negligible amounts of NADH and uridine nucleotides. The extinction coefficent of the epimerase at 280 nm is 1.81 +/- 0.15 mL mg-1 cm-1 (epsilon 280 = 137 +/- 11 mM-1 cm-1), as determined by quantitative amino acid analysis and spectrophotometric measurements. This value allows the value of the extinction coefficient for the reduced enzyme (E.NADH)to be calculated as epsilon 344 = 5.7 mM-1 cm-1. On the basis of the new value of epsilon 280, analytical measurements of the nAD+ content of epimerase show that there are two molecules of NAD+ per dimer, which confirms conclusions from X-ray crystallography and revises the earlier bioanalytical determinations. The ultraviolet/visible absorption spectrum of E.NAD+ from denaturation-renaturation experiments reveals the presence of a broad absorption band extending from 300 nm to beyond 360 nm that cannot be attributed to NADH and appears to be a charge-transfer band. This band is partially bleached by UMP and almost totally abolished by UDP, indicating that the interactions leading to the charge-transfer band are altered by the uridine nucleotide-induced conformational change in this enzyme. This conformational change is associated with control of the chemical reactivity of NAD+ in the reaction mechanism.
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