Abstract
A key question concerning the catalytic cycle of Escherichia coli dihydrofolate reductase (ecDHFR) is whether the Met20 loop is dynamically coupled to the chemical step during catalysis. A more basic, yet unanswered question is whether the Met20 loop adopts a closed conformation during the chemical hydride transfer step. To examine the most likely conformation of the Met20 loop during the chemical step, we studied the hydride transfer in wild type (WT) ecDHFR using hybrid quantum mechanics-molecular mechanics free energy simulations with the Met20 loop in a closed and disordered conformation. Additionally, we investigated three mutant forms (I14X; X = Val, Ala, Gly) of the enzyme that have increased active site flexibility and donor-acceptor distance dynamics in closed and disordered Met20 loop states. We found that the conformation of the Met20 loop has a dramatic effect on the ordering of active site hydration, although the Met20 loop conformation only has a moderate effect on the hydride transfer rate and donor-acceptor distance dynamics. Finally, we evaluated the pKa of the substrate N5 position in closed and disordered Met20 loop states and found a strong correlation between N5 basicity and the conformation of the Met20 loop.
Highlights
A key question concerning the catalytic cycle of Escherichia coli dihydrofolate reductase is whether the Met20 loop is dynamically coupled to the chemical step during catalysis
A question concerning the catalytic cycle of Escherichia coli dihydrofolate reductase (ecDHFR) that has garnered significant interest is whether the Met20 loop motion is coupled to the hydride transfer step
We examined whether the Met20 loop is preferably closed during hydride transfer or not and whether this influences the donor-acceptor distance (DAD)
Summary
A key question concerning the catalytic cycle of Escherichia coli dihydrofolate reductase (ecDHFR) is whether the Met loop is dynamically coupled to the chemical step during catalysis. A more basic, yet unanswered question is whether the Met loop adopts a closed conformation during the chemical hydride transfer step. Brooks and co-workers [12,13,14] suggested that rapid hydride transfer is correlated with a selected subset of Met conformational states. This raises the question of whether the Met loop is closed during the chemical step and more generally whether the Met loop plays a role during hydride transfer
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