Litcius/Paper detail

Eukaryotic Kv channel Shaker inactivates through selectivity filter dilation rather than collapse

Robyn Stix, Xiao-Feng Tan, Chanhyung Bae, Ana I. Fernández-Mariño, Kenton J. Swartz, José D. Faraldo‐Gómez

2023Science Advances15 citationsDOIOpen Access PDF

Abstract

Eukaryotic voltage-gated K + channels have been extensively studied, but the structural bases for some of their most salient functional features remain to be established. C-type inactivation, for example, is an auto-inhibitory mechanism that confers temporal resolution to their signal-firing activity. In a recent breakthrough, studies of a mutant of Shaker that is prone to inactivate indicated that this process entails a dilation of the selectivity filter, the narrowest part of the ion conduction pathway. Here, we report an atomic-resolution cryo–electron microscopy structure that demonstrates that the wild-type channel can also adopt this dilated state. All-atom simulations corroborate this conformation is congruent with the electrophysiological characteristics of the C-type inactivated state, namely, residual K + conductance and altered ion specificity, and help rationalize why inactivation is accelerated or impeded by certain mutations. In summary, this study establishes the molecular basis for an important self-regulatory mechanism in eukaryotic K + channels, laying a solid foundation for further studies.

Topics & Concepts

ShakerBiophysicsConductanceMutantChemistryElectrophysiologyIon channelDilation (metric space)Cell biologyBiologyBiochemistryPhysicsNeuroscienceGeneReceptorVibrationCondensed matter physicsMathematicsCombinatoricsQuantum mechanicsIon channel regulation and functionNicotinic Acetylcholine Receptors StudyMass Spectrometry Techniques and Applications
Eukaryotic Kv channel Shaker inactivates through selectivity filter dilation rather than collapse | Litcius