Abstract
Ligand binding can change the pKa of protein residues and influence enzyme catalysis. Herein, we report three ultrahigh resolution X-ray crystal structures of CTX-M β-lactamase, directly visualizing protonation state changes along the enzymatic pathway: apo protein at 0.79 Å, precovalent complex with nonelectrophilic ligand at 0.89 Å, and acylation transition state (TS) analogue at 0.84 Å. Binding of the noncovalent ligand induces a proton transfer from the catalytic Ser70 to the negatively charged Glu166, and the formation of a low-barrier hydrogen bond (LBHB) between Ser70 and Lys73, with a length of 2.53 Å and the shared hydrogen equidistant from the heteroatoms. QM/MM reaction path calculations determined the proton transfer barrier to be 1.53 kcal/mol. The LBHB is absent in the other two structures although Glu166 remains neutral in the covalent complex. Our data represents the first X-ray crystallographic example of a hydrogen engaged in an enzymatic LBHB, and demonstrates that desolvation of the active site by ligand binding can provide a protein microenvironment conducive to LBHB formation. It also suggests that LBHBs may contribute to stabilization of the TS in general acid/base catalysis together with other preorganized features of enzyme active sites. These structures reconcile previous experimental results suggesting alternatively Glu166 or Lys73 as the general base for acylation, and underline the importance of considering residue protonation state change when modeling protein-ligand interactions. Additionally, the observation of another LBHB (2.47 Å) between two conserved residues, Asp233 and Asp246, suggests that LBHBs may potentially play a special structural role in proteins.
Highlights
The protonation states of protein side chains dictate their roles in enzyme catalysis and ligand binding
Protonation state change and low barrier hydrogen bond (LBHB) observed by X-ray crystallography
We considered that these compounds, which interact with many of the same active site residues as β-lactam substrates, might serve to mimic the pre-covalent complex formed transiently with β-lactam substrates
Summary
The protonation states of protein side chains dictate their roles in enzyme catalysis and ligand binding. The binding of small molecules often modifies the protein microenvironment and the pKa of catalytic residues Such effects can potentially promote proton transfer in a pre-covalent Michaelis complex and during general acid/base catalysis. This perturbation may induce the formation of a low barrier hydrogen bond (LBHB), where two functional groups with similar pKa’s share a proton, contributing to an unusually short (~2.5 Å), strong hydrogen bond (HB) 1. Opposing arguments supported by experimental and computational analysis have been put forward to challenge the existence of LBHBs in proteins and the contribution of such short LBHBs to enzyme catalysis[10,11,12,13,14]
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