Abstract
Ion channels are proteins which form gated nanopores in biological membranes. Many channels exhibit hydrophobic gating, whereby functional closure of a pore occurs by local dewetting. The pentameric ligand gated ion channels (pLGICs) provide a biologically important example of hydrophobic gating. Molecular simulation studies comparing additive vs polarizable models indicate predictions of hydrophobic gating are robust to the model employed. However, polarizable models suggest favorable interactions of hydrophobic pore-lining regions with chloride ions, of relevance to both synthetic carriers and channel proteins. Electrowetting of a closed pLGIC hydrophobic gate requires too high a voltage to occur physiologically but may inform designs for switchable nanopores. Global analysis of ∼200 channels yields a simple heuristic for structure-based prediction of (closed) hydrophobic gates. Simulation-based analysis is shown to provide an aid to interpretation of functional states of new channel structures. These studies indicate the importance of understanding the behavior of water and ions within the nanoconfined environment presented by ion channels.
Highlights
ION CHANNELS AND HYDROPHOBIC GATINGIon channels are proteins that form nanoscale pores in biological membranes
Studies of large and complex ion channel structures (Figure 1C) either may employ the intact channel protein embedded in a lipid bilayer (Figure 1D) or may focus on either the transmembrane (TM)
Potential of mean force (PMF) calculations provide estimates of the free energy landscape encountered by ions as they pass through a transmembrane pore
Summary
MD simulations have been widely employed to study hydrophobic gating, both in simple model systems (Figure 1B and below) and in biological ion channels.
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