Abstract
The 6-phosphate of 6-phosphogluconate (6PG) is proposed to anchor the sugar phosphate in the active site and aid in orientating the substrate for catalysis. In order to test this hypothesis, alanine mutagenesis was used to probe the contribution of residues in the vicinity of the 6-phosphate to binding of 6PG and catalysis. The crystal structure of sheep liver 6-phosphogluconate dehydrogenase shows that Tyr-191, Lys-260, Thr-262, Arg-287, and Arg-446 contribute a mixture of ionic and hydrogen bonding interactions to the 6-phosphate, and these interactions are likely to provide the majority of the binding energy for 6PG. All mutant enzymes, with the exception of T262A, exhibit an increase in K(6PG) that ranges from 5- to 800-fold. There is also a less pronounced increase in K(NADP), ranging from 3- to 15-fold, with the exception of T262A. The R287A and R446A mutant enzymes exhibit a dramatic decrease in V/E(t) (600- and 300-fold, respectively) as well as in V/K(6PG)E(t) (10(5) - and 10(4)-fold), and therefore no further characterization was carried out with these two mutant enzymes. No change in V/E(t) was observed for the Y191A mutant enzyme, whereas 20- and 3-fold decreases were obtained for the K260A and T262A mutant enzymes, respectively, resulting in a decrease in V/K(6PG)E(t) range from 3- to 120-fold. All mutant enzymes also exhibit at least an order of magnitude increase in 13C-isotope effect -1, indicating that the decarboxylation step has become more rate-limiting. Data are consistent with significant roles for Tyr-191, Lys-260, Thr-262, Arg-287, and Arg-446 in providing the binding energy for 6PG. In addition, these residues also likely ensure proper orientation of 6PG for catalysis and aid in inducing the conformation change that precedes, and sets up the active site for, catalysis.
Highlights
Gluconate (6PG), producing ribulose 5-phosphate (Ru5P) and CO2 with the concomitant reduction of NADP to NADPH
The resulting 3-keto-6-phosphogluconate intermediate is decarboxylated to produce the enediol of Ru5P with the general base used to protonate the carboxyl oxygen
Mutations were made at Arg-447 in 6PGDH from Lactococcus lactis [7], and all the mutants were devoid of enzyme activity, indicating that this residue is critical for activity
Summary
Gluconate (6PG), producing ribulose 5-phosphate (Ru5P) and CO2 with the concomitant reduction of NADP to NADPH. The pH dependence of kinetic parameters indicates a general acid-general base chemical mechanism [1, 2], and sitedirected mutagenesis [3, 4] studies suggest that Lys-183 and Glu190 are likely the general base and the general acid, respectively. In this mechanism, the general base (Lys-183) is required to accept a proton from the 3-hydroxyl group of 6PG concomitant with hydride transfer from C-3 of 6PG to the coenzyme. Data are consistent with the hypothesis that these residues are important in providing the binding energy for the 6-phosphate of 6PG They play a role in catalysis in the 6PGDH reaction as a result of properly orientating the substrate. Acetaldehyde, acetate kinase, ADP-agarose resin, ATP, ampicillin, glucose-6-phosphate dehydrogenase, hexokinase, kanamycin, lithium potassium acetyl phosphate, the trisodium salt of 6PG, NADP, and pyrophosphate were from Sigma. -D-(3-
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