Ab initio models for receptor-ligand interactions in proteins. 4. Model assembly study of the catalytic mechanism of triosephosphate isomerase

Over the past 3.5 billion years of evolution, enzymes have adopted a myriad of conformations to suit life on earth. However, torsional angles of proteins have settled into limited zones of energetically favorable dihedrals observed in Ramachandran plots. Areas outside said zones are believed to be disallowed to all amino acids, except glycine, due to steric hindrance. Triosephosphate isomerase (TIM), a homodimer with a catalytic rate approaching the diffusion limit, contains an active site lysine residue (K13) with dihedrals within the fourth quadrant (Φ = +51/Ψ = −143). Both the amino acid and the dihedral angles are conserved across all species of TIM and known crystal structures regardless of ligand. Only crystal structures of the engineered monomeric version (1MSS) show accepted β‐sheet dihedral values of Φ = ‐135/Ψ = +170 but experiments show a 1000‐fold loss in activity. Based on these results, we hypothesized that adopting the unfavorable torsion angle for K13 contributes to catalysis. Using both, computational and experimental approaches, four residues that interact with K13 (N11, M14, E97, and Q64) were mutated to alanine. In silico molecular dynamics (MD) simulations were performed using 2JK2 unliganded human TIM as a starting structure. Ramachandran plots, containing K13 dihedral values reveal full or partial loss of disallowed zone angles. N11A showed no detectable catalytic activity and lost the unfavorable K13 dihedral angles across four separate force fields during simulation while all other mutants plus wild type retained activity and retained the conserved K13 dihedral angles.

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Energetically unfavorable protein angles: Exploration of a conserved dihedral angle in triosephosphate isomerase

Allen

Cook

Colquhoun

et al. 2022

Biopolymers

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The intramolecular mechanism for the second proton transfer in triosephosphate isomerase (TIM): A QM/FE approach

2002

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The intramolecular mechanism we earlier proposed [Alagona, G.; Desmeules, P.; Ghio, C.; Kollman, P. A. J Am Chem Soc 1984, 106, 3623] for the second proton transfer of the reaction catalyzed by triosephosphate isomerase (TIM) is examined ab initio at the HF and MP2/6-31+G** levels in vacuo for two conformers of the enediolate phosphate (ENEP), with the ethereal oxygen of the phosphate group either syn (X), as in the crystal structure, or anti (Y) with respect to the enediolate carbonyl O. The barrier height for the intramolecular proton transfer occurring in enediolate is very sensitive to electron correlation corrections. The MP2 internal energy barrier is much lower than the HF one, while the free energy (FE) barrier is even more favorable, indicating that the enzyme presence is not requested to speed up that step. An investigation of the dynamical aspects of the mechanism, along the pathway from ENEP A (with H on O(1)) to TS and from TS to ENEP B (with H on O(2)), was, however, carried out in the presence of the enzyme field while using a neutral His-95 with its proton on Ndelta. To perform the FE simulations, it was necessary to parametrize in the AMBER force-field the ENEP A, TS and B species, whose partial charges have been determined with the RESP procedure, with the X and Y arrangements of the phosphate head. Actually, the FE/QM approach produced a low barrier and a substantial balance between A and B, especially at the MP2 level. The trajectories, analyzed paying a particular attention to the positions assumed by His-95 and by the other active site residues, put forward somewhat different H-bond patterns around the X or Y enediolate phosphate.

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Triosephosphate Isomerase: 15N and 13C Chemical Shift Assignments and Conformational Change upon Ligand Binding by Magic-Angle Spinning Solid-State NMR Spectroscopy

Lorieau

McDermott

2010

Journal of Molecular Biology

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Microcrystalline uniformly 13C,15N-enriched yeast triosephosphate isomerase (TIM) is sequentially assigned by high-resolution solid-state NMR (SSNMR). Assignments are based on intraresidue and interresidue correlations, using dipolar polarization transfer methods, and guided by solution NMR assignments of the same protein. We obtained information on most of the active-site residues involved in chemistry, including some that were not reported in a previous solution NMR study, such as the side-chain carbons of His95. Chemical shift differences comparing the microcrystalline environment to the aqueous environment appear to be mainly due to crystal packing interactions. Site-specific perturbations of the enzyme's chemical shifts upon ligand binding are studied by SSNMR for the first time. These changes monitor proteinwide conformational adjustment upon ligand binding, including many of the sites probed by solution NMR and X-ray studies. Changes in Gln119, Ala163, and Gly210 were observed in our SSNMR studies, but were not reported in solution NMR studies (chicken or yeast). These studies identify a number of new sites with particularly clear markers for ligand binding, paving the way for future studies of triosephosphate isomerase dynamics and mechanism.

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Ab initio models for receptor-ligand interactions in proteins. 4. Model assembly study of the catalytic mechanism of triosephosphate isomerase

Cited by 11 publications

References 66 publications

Energetically unfavorable protein angles: Exploration of a conserved dihedral angle in triosephosphate isomerase

Energetically unfavorable protein angles: Exploration of a conserved dihedral angle in triosephosphate isomerase

The intramolecular mechanism for the second proton transfer in triosephosphate isomerase (TIM): A QM/FE approach

Triosephosphate Isomerase: 15N and 13C Chemical Shift Assignments and Conformational Change upon Ligand Binding by Magic-Angle Spinning Solid-State NMR Spectroscopy

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