TY - JOUR
T1 - Voltage sensor conformations induced by LQTS-associated mutations in hERG potassium channels
AU - Chan, Aaron N.
AU - Quach, Co D.
AU - Handlin, Lucas J.
AU - Lessie, Erin N.
AU - Tajkhorshid, Emad
AU - Dai, Gucan
N1 - We thank Natalie L. Macchi for technical support; Joel C. Eissenberg for editing the manuscript; Enrico Di Cera and Nicola Pozzi for feedback, E. James Petersson and Venkatesh Yarra (University of Pennsylvania) for sharing the noncanonical amino acid Acd and providing advice; Ryan A. Mehl (GCE4All Research Center, Oregon State University) for sharing the Acd RS1 aminoacyl tRNA synthetase and tRNA pair plasmid. This research is supported by National Institutes of Health (NIH) grants R35GM154778 (to G.D.) and R56HL169176 (to G.D. and E.T.). We gratefully acknowledge support from the Doisy Fund of the Edward A. Doisy Department of Biochemistry and Molecular Biology at Saint Louis University School of Medicine. In addition, the authors acknowledge funding from the NIH grant R24GM145965 (to E.T.) and National Science Foundation (NSF) QCB grant: 221835 (to E.T.). Computing resources were provided by the NSF ACCESS award: MCA06N060 (to E.T.).
PY - 2025/12
Y1 - 2025/12
N2 - Voltage sensors are essential for electromechanical coupling in hERG K+ channels, critical to cardiac rhythm. These sensors respond to membrane potential changes by moving within the transmembrane electric field. Mutations in hERG voltage-sensing arginines, associated with Long-QT syndrome, alter channel gating, though underlying mechanisms remain unclear. Using live-cell fluorescence lifetime imaging microscopy, transition metal FRET, an improved dual stop-codon-mediated strategy for noncanonical amino-acid incorporation, and molecular dynamics simulations, we identify intermediate voltage-sensor conformations induced by neutralizing key arginines in the charge transfer center. Phasor plot analysis of lifetime data reveals multiple voltage-dependent FRET states in these mutants, in contrast to the single high-FRET state observed in controls. These intermediate FRET states reflect distinct conformations of the voltage sensor, corresponding to predicted structures of voltage sensors in molecular dynamics simulations. This study provides insights into cardiac channelopathies, highlighting a structural mechanism that impairs voltage sensing in cardiac arrhythmias.
AB - Voltage sensors are essential for electromechanical coupling in hERG K+ channels, critical to cardiac rhythm. These sensors respond to membrane potential changes by moving within the transmembrane electric field. Mutations in hERG voltage-sensing arginines, associated with Long-QT syndrome, alter channel gating, though underlying mechanisms remain unclear. Using live-cell fluorescence lifetime imaging microscopy, transition metal FRET, an improved dual stop-codon-mediated strategy for noncanonical amino-acid incorporation, and molecular dynamics simulations, we identify intermediate voltage-sensor conformations induced by neutralizing key arginines in the charge transfer center. Phasor plot analysis of lifetime data reveals multiple voltage-dependent FRET states in these mutants, in contrast to the single high-FRET state observed in controls. These intermediate FRET states reflect distinct conformations of the voltage sensor, corresponding to predicted structures of voltage sensors in molecular dynamics simulations. This study provides insights into cardiac channelopathies, highlighting a structural mechanism that impairs voltage sensing in cardiac arrhythmias.
UR - https://www.scopus.com/pages/publications/105012633421
UR - https://www.scopus.com/pages/publications/105012633421#tab=citedBy
U2 - 10.1038/s41467-025-62472-9
DO - 10.1038/s41467-025-62472-9
M3 - Article
C2 - 40753176
AN - SCOPUS:105012633421
SN - 2041-1723
VL - 16
JO - Nature communications
JF - Nature communications
IS - 1
M1 - 7126
ER -