Dihydrofolate reductase proton transfer

The expansion in the power of computers and theoretical methods has made it possible to investigate the mechanism of action of enzymes by combinations of quantum-mechanical and molecular-mechanical calculations. A study of two possible mechanisms for dihydrofolate reductase catalysis was consistent with indirect proton transfer from aspartate to N-5 of the pterin as has been suggested for many years by crystallographic evidence <2003PCB14036>. This conclusion is also consistent with the outcome of a study that directly measured the of the active site aspartate in the Lactobacillus casei enzyme <1999B8038>. Observations of chemical shifts of... 

Fig. 14. Dihydrofolic acid. In the dihydrofolate reductase reaction, the double bond between N-5 and C-6 is reduced by hydride transfer from the 4-pro-R position of NADPH to C-6, and addition of a proton at N-5.

The use of pH variation and isotope effects in transient kinetics can be illustrated with a recent study on dihydrofolate reductase. Analysis by steady-state methods had indicated an apparent p/fa of 8.5 that was assigned to an active site aspartate residue required to stabilize the protonated state of the substrate (59). In addition, it was shown that there was an isotope effect on substitution of NADPD (the deuterated analog) for NADPH at high pH but not at low pH, below the apparent p/fa This somewhat puzzling finding was explained by transient-state kinetic analysis. Hydride transfer, the chemical reaction converting enzyme-bound NADPH and dihydrofolate to NAD+ and tetrahydrofolate, was shown to occur at a rate of approximately 1000 sec at low pH. The rate of reaction decreased with increasing pH with a of 6.5, a value more in line with expectations for an active site aspartate residue. As shown in Fig. 14, there was a threefold reduction in the rate of the chemical reaction with NADPD relative to NADPH. Thus direct measurement of the chemical reaction revealed the full isotope effect. 

Isotopes can be used in another way to measure the energy barrier heights for various steps in the catalytic mechanism as noted above for the reaction catalyzed by dihydrofolate reductase. For example, if a proton transfer is involved in the rate-limiting step, then substitution of that proton with one of the heavier isotopes of hydrogen (deuterium or tritium) will cause the step to proceed more slowly. These so-called kinetic isotope effect experiments in combination with steady-state rate measurements in the case of TIM allowed the elucidation of the rate constants for partitioning of the cw-enediol intermediate and construction of a detailed kinetic scheme as shown above for dihydrofolate reductase. 

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