Jesús Mendieta

Molecular dynamics simulations of the conformational changes of the glutamate receptor ligand‐binding core in the presence of glutamate and kainate

Excitatory synaptic transmission is mediated by ionotropic glutamate receptors (iGluRs) through the induced transient opening of transmembrane ion channels. The three‐dimensional structure of the extracellular ligand‐binding core of iGluRs shares the overall features of bacterial periplasmic binding proteins (PBPs). In both families of proteins, the ligand‐binding site is arranged in two domains separated by a cleft and connected by two peptide stretches. PBPs undergo a typical hinge motion of the two domains associated with ligand binding that leads to a conformational change from an open to a closed form. The common architecture suggests a similar closing mechanism in the ligand‐binding core of iGluRs induced by the binding of specific agonists. Starting from the experimentally determined kainate‐bound closed form of the S1S2 GluR2 construct, we have studied by means of molecular dynamics simulations the opening motion of the ligand‐binding core in the presence and in the absence of both glutamate and kainate. Our results suggest that the opening/closing interdomain hinge motions are coupled to conformational changes in the insertion region of the transmembrane segments. These changes are triggered by the interaction of the agonists with the essential Glu 209 residue. A plausible mechanism for the coupling of agonist binding to channel gating is discussed. Proteins 2001;44:460–469.

Simulation of catalytic water activation in mitochondrial F1-ATPase using a hybrid quantum mechanics/molecular mechanics approach: an alternative role for β-Glu 188.

The use of quantum mechanics/molecular mechanics simulations to study the free energy landscape of the water activation at the catalytic site of mitochondrial F(1)-ATPase affords us insight into the generation of the nucleophile OH(-) prior to ATP hydrolysis. As a result, the ATP molecule was found to be the final proton acceptor. In the simulated pathway, the transfer of a proton to the nucleotide was not direct but occurred via a second water molecule in a manner similar to the Grotthuss mechanism proposed for proton diffusion. Residue β-Glu 188, previously described as the putative catalytic base, was found to be involved in the stabilization of a transient hydronium ion during water activation. Simulations in the absence of the carboxylate moiety of β-Glu 188 support this role.

A practical quantum mechanics molecular mechanics method for the dynamical study of reactions in biomolecules

Quantum mechanics/molecular mechanics (QM/MM) methods are excellent tools for the modeling of biomolecular reactions. Recently, we have implemented a new QM/MM method (Fireball/Amber), which combines an efficient density functional theory method (Fireball) and a well-recognized molecular dynamics package (Amber), offering an excellent balance between accuracy and sampling capabilities. Here, we present a detailed explanation of the Fireball method and Fireball/Amber implementation. We also discuss how this tool can be used to analyze reactions in biomolecules using steered molecular dynamics simulations. The potential of this approach is shown by the analysis of a reaction catalyzed by the enzyme triose-phosphate isomerase (TIM). The conformational space and energetic landscape for this reaction are analyzed without a priori assumptions about the protonation states of the different residues during the reaction. The results offer a detailed description of the reaction and reveal some new features of the catalytic mechanism. In particular, we find a new reaction mechanism that is characterized by the intramolecular proton transfer from O1 to O2 and the simultaneous proton transfer from Glu 165 to C2.

Towards New Thymidine Phosphorylase/PD-ECGF Inhibitors Based on the Transition State of the Enzyme Reaction

Abstract Computational studies have been conducted to built a closed form of TPase and to characterize the transition state of the phosphorylisis reaction catalyzed by TPase. The results obtained point to a crucial role of His-85 and the O2 of thymine in the catalysis. This modelled transition state forms the basis for the design of new TPase inhibitors.