The cardiac sodium ion channel (NaV1.5) is a protein with four domains (DI-DIV), each with six transmembrane segments. Its opening and subsequent inactivation results in the brief rapid influx of Na+ ions resulting in the depolarization of cardiomyocytes. The neurotoxin veratridine (VTD) inhibits NaV1.5 inactivation resulting in longer channel opening times, and potentially fatal action potential prolongation. VTD is predicted to bind at the channel pore, but alternative binding sites have not been ruled out. To determine the binding site of VTD on NaV1.5, we perform docking calculations and high-throughput electrophysiology experiments in the present study. The docking calculations identified two distinct binding regions. The first site was in the pore, close to the binding site of NaV1.4 and NaV1.5 blocking drugs in experimental structures. The second site was at the ``mouth'' of the pore at the cytosolic side, partly solvent-exposed. Mutations at this site (L409, E417, and I1466) had large effects on VTD binding, while residues deeper in the pore had no effect, consistent with VTD binding at the mouth site. Overall, our results suggest a VTD binding site close to the cytoplasmic mouth of the channel pore. Binding at this alternative site might indicate an allosteric inactivation mechanism for VTD at NaV1.5.
%0 Journal Article
%1 Gulsevin2022-va
%A Gulsevin, Alican
%A Glazer, Andrew M
%A Shields, Tiffany
%A Kroncke, Brett M
%A Roden, Dan M
%A Meiler, Jens
%D 2022
%I MDPI AG
%J Int. J. Mol. Sci.
%K topic_lifescience Rosetta; SCN5A; cardiac channels channels; docking; electrophysiology; molecular mutagenesis; site-directed sodium toxins; veratridine; voltage-gated
%N 4
%P 2225
%T Veratridine can bind to a site at the mouth of the channel pore at human cardiac sodium channel NaV1.5
%V 23
%X The cardiac sodium ion channel (NaV1.5) is a protein with four domains (DI-DIV), each with six transmembrane segments. Its opening and subsequent inactivation results in the brief rapid influx of Na+ ions resulting in the depolarization of cardiomyocytes. The neurotoxin veratridine (VTD) inhibits NaV1.5 inactivation resulting in longer channel opening times, and potentially fatal action potential prolongation. VTD is predicted to bind at the channel pore, but alternative binding sites have not been ruled out. To determine the binding site of VTD on NaV1.5, we perform docking calculations and high-throughput electrophysiology experiments in the present study. The docking calculations identified two distinct binding regions. The first site was in the pore, close to the binding site of NaV1.4 and NaV1.5 blocking drugs in experimental structures. The second site was at the ``mouth'' of the pore at the cytosolic side, partly solvent-exposed. Mutations at this site (L409, E417, and I1466) had large effects on VTD binding, while residues deeper in the pore had no effect, consistent with VTD binding at the mouth site. Overall, our results suggest a VTD binding site close to the cytoplasmic mouth of the channel pore. Binding at this alternative site might indicate an allosteric inactivation mechanism for VTD at NaV1.5.
@article{Gulsevin2022-va,
abstract = {The cardiac sodium ion channel (NaV1.5) is a protein with four domains (DI-DIV), each with six transmembrane segments. Its opening and subsequent inactivation results in the brief rapid influx of Na+ ions resulting in the depolarization of cardiomyocytes. The neurotoxin veratridine (VTD) inhibits NaV1.5 inactivation resulting in longer channel opening times, and potentially fatal action potential prolongation. VTD is predicted to bind at the channel pore, but alternative binding sites have not been ruled out. To determine the binding site of VTD on NaV1.5, we perform docking calculations and high-throughput electrophysiology experiments in the present study. The docking calculations identified two distinct binding regions. The first site was in the pore, close to the binding site of NaV1.4 and NaV1.5 blocking drugs in experimental structures. The second site was at the ``mouth'' of the pore at the cytosolic side, partly solvent-exposed. Mutations at this site (L409, E417, and I1466) had large effects on VTD binding, while residues deeper in the pore had no effect, consistent with VTD binding at the mouth site. Overall, our results suggest a VTD binding site close to the cytoplasmic mouth of the channel pore. Binding at this alternative site might indicate an allosteric inactivation mechanism for VTD at NaV1.5.},
added-at = {2024-09-10T11:54:51.000+0200},
author = {Gulsevin, Alican and Glazer, Andrew M and Shields, Tiffany and Kroncke, Brett M and Roden, Dan M and Meiler, Jens},
biburl = {https://puma.scadsai.uni-leipzig.de/bibtex/2e56450d73dcbf7fcc39a6f82e92912ce/scadsfct},
copyright = {https://creativecommons.org/licenses/by/4.0/},
interhash = {4871e9bf88947bf75e63908074c89d17},
intrahash = {e56450d73dcbf7fcc39a6f82e92912ce},
journal = {Int. J. Mol. Sci.},
keywords = {topic_lifescience Rosetta; SCN5A; cardiac channels channels; docking; electrophysiology; molecular mutagenesis; site-directed sodium toxins; veratridine; voltage-gated},
language = {en},
month = feb,
number = 4,
pages = 2225,
publisher = {MDPI AG},
timestamp = {2024-11-28T17:41:24.000+0100},
title = {Veratridine can bind to a site at the mouth of the channel pore at human cardiac sodium channel {NaV1.5}},
volume = 23,
year = 2022
}