Abstract
Protein function depends on conformational flexibility and folding stability. Loose packing of hydrophobic cores is not infrequent in proteins, as the enhanced flexibility likely contributes to their biological function. Here, using experimental and computational approaches, we show that eukaryotic pentameric ligand-gated ion channels are characterized by loose packing of their extracellular domain β-sandwich cores, and that loose packing contributes to their ability to rapidly switch from closed to open channel states in the presence of ligand. Functional analyses of GABA(A) receptors show that increasing the β-core packing disrupted GABA-mediated currents, with impaired GABA efficacy and slowed GABA current activation and desensitization. We propose that loose packing of the hydrophobic β-core developed as an evolutionary strategy aimed to facilitate the allosteric mechanisms of eukaryotic pentameric ligand-gated ion channels.
Highlights
ObjectivesWe aimed to determine how the loose -core packing in nAChR affects its thermodynamic stability compared with AChBPs and GLIC
PLGICs are allosteric proteins that exist in at least three distinct, interconvertible states: resting, activated, and desensitized. These receptors respond to neurotransmitter binding with allosteric transitions that switch the protein from a non-conducting closed conformation to an ion-conducting open conformation rapidly and with high probability
A second model suggests that a concerted quaternary twist of the ECD drives channel activation [32, 53]
Summary
We aimed to determine how the loose -core packing in nAChR affects its thermodynamic stability compared with AChBPs and GLIC
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