How Do Preorganized Electric Fields Function in Catalytic Cycles? The Case of the Enzyme Tyrosine Hydroxylase

Nature has devised intrinsic electric fields (IEFs) that are engaged in electrostatic catalysis of enzymes. But, how does the IEF target its function in enzymes that involve several reaction steps in catalytic cycles? To decipher the impact of the IEF on the catalytic cycle of an enzyme system, we have performed molecular dynamics and quantum-mechanical/molecular-mechanical (QM/MM) simulations on tyrosine hydroxylase (TyrH). The catalytic cycle of TyrH involves two reaction stages: the activation of H2O2 to form the active species of compound I (Cpd I), in the first stage, and the Cpd I-mediated hydroxylation of l-tyrosine to l-DOPA, in the second stage. For the first stage, the QM/MM calculations show that a heme-propionate group functions as a base to catalyze the O–O heterolysis reaction. For the second stage, the study reveals that the reaction is initiated by the His88-mediated proton-coupled electron transfer followed by the oxygen atom transfer from compound II (Cpd II) to the l-Tyr substrate. Importantly, our calculations demonstrate that the IEF in TyrH is optimized to promote the O–O bond heterolysis that generates the active species of the enzyme, Cpd I. However, the same IEF slows down the subsequent aromatic hydroxylation. Thus, the IEF in the TyrH enzymes does not catalyze the product formation step, but will selectively boost one or more challenging steps in the catalytic cycle. These findings have general implications on O2/H2O2-dependent metalloenzymes, which can expand our understanding of how nature has used electric fields as "smart reagents" in modulating the catalytic reactivity.