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Contributed by Francisco Bezanilla, April 5, 2014 (sent for review January 29, 2014)
Significance
Voltage sensors are integral membrane protein domains that regulate ion channels and enzymes by transporting electrically charged residues across a narrow constriction that focuses the membrane electrical field. Here, we investigated how this constriction, also called the “gating pore,” controls this transport by studying the effects of a large number of point mutations. Our analysis indicates the presence of nonambiguous statistical correlations between specific amino acid lateral-chain physicochemical properties (size, hydrophobicity) and specific functional features of the voltage sensor (voltage sensitivity and transport kinetics). This study allowed us to propose engineering-like mechanisms by which gating pore residues control the voltage sensor operation.
Abstract
Voltage sensor domains (VSDs) regulate ion channels and enzymes by transporting electrically charged residues across a hydrophobic VSD constriction called the gating pore or hydrophobic plug. How the gating pore controls the gating charge movement presently remains debated. Here, using saturation mutagenesis and detailed analysis of gating currents from gating pore mutations in the Shaker Kv channel, we identified statistically highly significant correlations between VSD function and physicochemical properties of gating pore residues. A necessary small residue at position S240 in S1 creates a “steric gap” that enables an intracellular access pathway for the transport of the S4 Arg residues. In addition, the stabilization of the depolarized VSD conformation, a hallmark for most Kv channels, requires large side chains at positions F290 in S2 and F244 in S1 acting as “molecular clamps,” and a hydrophobic side chain at position I237 in S1 acting as a local intracellular hydrophobic barrier. Finally, both size and hydrophobicity of I287 are important to control the main VSD energy barrier underlying transitions between resting and active states. Taken together, our study emphasizes the contribution of several gating pore residues to catalyze the gating charge transfer. This work paves the way toward understanding physicochemical principles underlying conformational dynamics in voltage sensors.
Footnotes
↵1J.J.L. and H.C.H. contributed equally to this work.
- ↵2To whom correspondence should be addressed. E-mail: fbezanilla{at}uchicago.edu.
Author contributions: J.J.L. and F.B. designed research; J.J.L. and F.V.C. performed research; H.C.H. and F.B. contributed new reagents/analytic tools; J.J.L., H.C.H., and F.B. analyzed data; and J.J.L., H.C.H., and F.B. wrote the paper.
The authors declare no conflict of interest.
This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10.1073/pnas.1406161111/-/DCSupplemental.
Freely available online through the PNAS open access option.
Gating pore in a Kv channel voltage sensor
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