Abstract
The chloroplastic NADP malate dehydrogenase is completely inactive in its oxidized form and is activated by thiol/disulfide interchange with reduced thioredoxin. To elucidate the molecular mechanism underlying the absence of activity of the oxidized enzyme, we used site-directed mutagenesis to delete or substitute the two most C-terminal residues (C-terminal Val, penultimate Glu, both bearing negative charges). We also combined these mutations with the elimination of one or both of the possible regulatory N-terminal disulfides by mutating the corresponding cysteines. Proteins mutated at the C-terminal residues had no activity in the oxidized form but were partially inhibited when pretreated with the histidine-specific reagent diethyl pyrocarbonate before activation, showing that the active site was partially accessible. Proteins missing both N-terminal regulatory disulfides reached almost full activity without activation upon elimination of the negative charge of the penultimate Glu. These results strongly support a model where the C-terminal extension is docked into the active site through a negatively charged residue, acting as an internal inhibitor. They show also that the reduction of both N-terminal bridges is necessary to release the C-terminal extension from the active site. This is the first report for a thiol-activated enzyme of a regulatory mechanism resembling the well known intrasteric inhibition of protein kinases.
Highlights
The chloroplastic NADP-dependent malate dehydrogenase (NADP MDH)1 [1] (EC 1.1.1.82) catalyzes the reduction of oxaloacetate into malate
We investigated a possible role for the two C-terminal residues in the shielding of the active site by using site-directed mutagenesis either to delete the last two C-terminal residues or to eliminate the negative charge of the penultimate residue
If the mutations of C-terminal negative charges were able to mimic the substitution of the Cys of the C-terminal disulfide, the mutants should exhibit the specific features of the latter, i.e. (I) WT-like, thioredoxin-dependent, activation kinetics, (II) total lack of inhibition of the activation by NADP, (III) discrete spontaneous activity (5% that of the activity of the reduced form), (IV) total inhibition by diethyl pyrocarbonate (DEPC) added before activation [5]
Summary
Materials—Restriction endonucleases, DNA modification enzymes, T4 DNA ligase, and T4 DNA polymerase were obtained from Appligene. E. coli strain BL21 (DE3) [14] was used for the production of mutated NADP MDHs encoded by recombinant pET vectors. The cDNAs containing the combined mutations C29S/C207A/E387Q and C29S/C207A/⌬(E387V388) were obtained by exchanging the NheI-NheI fragment of pET-mdh(C29S/C207A/C365A/C377A) [11] for the corresponding fragment of respectively pET-mdh(E387Q) and pETmdh(⌬EV), leading to vectors pET-mdh (C29S/C207A/E387Q) and pET-mdh (C29S/C207A/⌬(E387V388)). AUTODOCK [22] was used to dock a dipeptide corresponding to the last two C-terminal amino acids, Glu387 and Val388, into the active site of the sorghum MDH model. This program randomly maneuvers a ligand to simultaneously determine both the optimum position and conformation of a ligand bound to its macromolecule receptor. Each MonteCarlo cycle consisted in the evaluation of 3000 configurations. 50 independent cycles were carried out, and the energetically best configuration among all of them was taken to be the final “docked” configuration
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