8 research outputs found
Voltage-dependent structural models of the human Hv1 proton channel from long-timescale molecular dynamics simulations
A Computational Approach to Walsh Correlation Diagrams for the Inorganic Chemistry Curriculum
This article demonstrates how students can use quantum chemistry software to calculate correlation diagrams (also called Walsh diagrams) used to understand chemical bonding in the inorganic chemistry curriculum. Specifically, students can calculate how molecular orbital energetics change as dintrogen is stretched and as the bond angles of water and ammonia are distorted. The theoretical method B3LYP/6‑31G* is suitable for this purpose. Comparison to HF/6‑31G* results and correlation diagrams from the literature are made, to point out that computational methods and different authors disagree on some details
Insights on Small Molecule Binding to the Hv1 Proton Channel from Free Energy Calculations with Molecular Dynamics Simulations
Hv1 is a voltage-gated proton channel whose main function is to facilitate extrusion of protons from the cell. The development
of effective channel blockers for Hv1 can lead to new therapeutics for the treatment of maladies related to Hv1 dysfunction.
Although the mechanism of proton permeation in Hv1 remains to be elucidated, a series of small molecules have been
discovered to inhibit Hv1. Here, we compute relative binding free energies of a prototypical Hv1 blocker on a model of
human Hv1 in an open state. We use alchemical free energy perturbation techniques based on atomistic molecular dynamics
simulations. The results support our proposed open state model, sheds light on the preferred tautomeric state of the blocker
that binds Hv1, and lays the groundwork for future studies on adapting the blocker molecule for more effective channel blocking
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Insights on small molecule binding to the Hv1 proton channel from free energy calculations with molecular dynamics simulations.
Hv1 is a voltage-gated proton channel whose main function is to facilitate extrusion of protons from the cell. The development of effective channel blockers for Hv1 can lead to new therapeutics for the treatment of maladies related to Hv1 dysfunction. Although the mechanism of proton permeation in Hv1 remains to be elucidated, a series of small molecules have been discovered to inhibit Hv1. Here, we computed relative binding free energies of a prototypical Hv1 blocker on a model of human Hv1 in an open state. We used alchemical free energy perturbation techniques based on atomistic molecular dynamics simulations. The results support our proposed open state model and shed light on the preferred tautomeric state of the channel blocker. This work lays the groundwork for future studies on adapting the blocker molecule for more effective inhibition of Hv1
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Voltage-dependent structural models of the human Hv1 proton channel from long-timescale molecular dynamics simulations
The voltage-gated Hv1 proton channel is a ubiquitous membrane protein that has roles in a variety of cellular processes, including proton extrusion, pH regulation, production of reactive oxygen species, proliferation of cancer cells, and increased brain damage during ischemic stroke. A crystal structure of an Hv1 construct in a putative closed state has been reported, and structural models for the channel open state have been proposed, but a complete characterization of the Hv1 conformational dynamics under an applied membrane potential has been elusive. We report structural models of the Hv1 voltage-sensing domain (VSD), both in a hyperpolarized state and a depolarized state resulting from voltage-dependent conformational changes during a 10-μs-timescale atomistic molecular dynamics simulation in an explicit membrane environment. In response to a depolarizing membrane potential, the S4 helix undergoes an outward displacement, leading to changes in the VSD internal salt-bridge network, resulting in a reshaping of the permeation pathway and a significant increase in hydrogen bond connectivity throughout the channel. The total gating charge displacement associated with this transition is consistent with experimental estimates. Molecular docking calculations confirm the proposed mechanism for the inhibitory action of 2-guanidinobenzimidazole (2GBI) derived from electrophysiological measurements and mutagenesis. The depolarized structural model is also consistent with the formation of a metal bridge between residues located in the core of the VSD. Taken together, our results suggest that these structural models are representative of the closed and open states of the Hv1 channel
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Voltage-Dependent Profile Structures of a Kv-Channel via Time-Resolved Neutron Interferometry
Available experimental techniques cannot determine high-resolution three-dimensional structures of membrane proteins under a transmembrane voltage. Hence, the mechanism by which voltage-gated cation channels couple conformational changes within the four voltage sensor domains, in response to either depolarizing or polarizing transmembrane voltages, to opening or closing of the pore domain's ion channel remains unresolved. Single-membrane specimens, composed of a phospholipid bilayer containing a vectorially oriented voltage-gated K+ channel protein at high in-plane density tethered to the surface of an inorganic multilayer substrate, were developed to allow the application of transmembrane voltages in an electrochemical cell. Time-resolved neutron reflectivity experiments, enhanced by interferometry enabled by the multilayer substrate, were employed to provide directly the low-resolution profile structures of the membrane containing the vectorially oriented voltage-gated K+ channel for the activated, open and deactivated, closed states of the channel under depolarizing and hyperpolarizing transmembrane voltages applied cyclically. The profile structures of these single membranes were dominated by the voltage-gated K+ channel protein because of the high in-plane density. Importantly, the use of neutrons allowed the determination of the voltage-dependent changes in both the profile structure of the membrane and the distribution of water within the profile structure. These two key experimental results were then compared to those predicted by three computational modeling approaches for the activated, open and deactivated, closed states of three different voltage-gated K+ channels in hydrated phospholipid bilayer membrane environments. Of the three modeling approaches investigated, only one state-of-the-art molecular dynamics simulation that directly predicted the response of a voltage-gated K+ channel within a phospholipid bilayer membrane to applied transmembrane voltages by utilizing very long trajectories was found to be in agreement with the two key experimental results provided by the time-resolved neutron interferometry experiments