Effect of enzyme and ligand protonation on the binding of folates to recombinant human dihydrofolate reductase: implications for the evolution of eukaryotic enzyme efficiency.

There is marked pH dependence of the rate constant (koff) for tetrahydrofolate (H4folate) dissociation from its ternary complex with human dihydrofolate reductase (hDHFR) and NADPH. Similar pH dependence of H4folate dissociation from the ternary complex of a variant of hDHFR with the substitution Phe31----Leu (F31L hDHFR) causes this dissociation to become rate limiting in the enzyme mechanism at pH approximately 5, and this accounts for the marked decrease in kcat for this variant as the pH is decreased from 7 to 5. This decreased kcat at low pH is not seen for most DHFRs. koff for dissociation of folate, dihydrofolate (H2folate), and H4folate from their binary complexes with hDHFR is similarly pH dependent. For all the complexes examined, the pH dependence of koff in the range pH 5-7 is well described by a pKa of about 6.2 and must be due to ionization of a group on the enzyme. In the higher pH range (7-10), koff increases further as the pH is raised, and this relation is governed by a second pKa which is close to the pKa for ionization of the amide group (HN3-C4O) of the respective ligands. Thus, ionization of the ligand amide group also increases koff. Evidence is presented that the dependence of pH on koff for hDHFR accounts for the shape of the kcat versus pH curve for both hDHFR as well as its F31L variant and contributes to the higher efficiency of hDHFR compared with bacterial DHFR.