High-throughput screening identifies a trafficking corrector for long QT syndrome–associated KCNQ1 variants
Katherine R. Clowes Moster, Carlos G. Vanoye, Ana C. Chang-Gonzalez, Ian M. Romaine, Katherine M. Stefanski, Mason C. Wilkinson, Joshua A. Bauer, Thomas P. Hasaka, Emily L. Days, Reshma R. Desai, Kathryn R. Butcher, Gary A. Sulikowski, Alex G. Waterson, Jens Meiler, Kaitlyn V. Ledwitch, Alfred L. George Jr., Charles R. Sanders
Katherine R. Clowes Moster, Carlos G. Vanoye, Ana C. Chang-Gonzalez, Ian M. Romaine, Katherine M. Stefanski, Mason C. Wilkinson, Joshua A. Bauer, Thomas P. Hasaka, Emily L. Days, Reshma R. Desai, Kathryn R. Butcher, Gary A. Sulikowski, Alex G. Waterson, Jens Meiler, Kaitlyn V. Ledwitch, Alfred L. George Jr., Charles R. Sanders
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Research Article Cardiology Genetics

High-throughput screening identifies a trafficking corrector for long QT syndrome–associated KCNQ1 variants

Abstract

Congenital long QT syndrome (LQTS) promotes risk for life-threatening cardiac arrhythmia and sudden death in children and young adults. Pathogenic variants in the voltage-gated potassium channel KCNQ1 are the most frequently discovered genetic cause. Most LQTS-associated KCNQ1 variants cause loss of function secondary to impaired trafficking of the channel to the plasma membrane. There are currently no therapeutic approaches that address this underlying molecular defect. Using a high-throughput screening paradigm, we identified VU0494372, a small molecule that increases total and cell surface levels and trafficking efficiency of WT KCNQ1 as well as three LQTS-associated variants. Additionally, 16-hour treatment of cells with VU0494372 increased IKs (KCNQ1-KCNE1 current) for WT KCNQ1 and the LQTS-associated variant V207M in cells coexpressing KCNE1. VU0494372 had no impact on KCNQ1 transcription, degradation, or thermal stability, and increased the rate of KCNQ1 reaching the cell surface. We identified a potential direct interaction site with KCNQ1 at or near the binding site of the KCNQ1 potentiator ML277. Together, these findings demonstrate that small molecules can increase the expression levels and cell surface trafficking efficiency of KCNQ1 and introduce a potential new pharmacological approach for treating LQTS.

Authors

Katherine R. Clowes Moster, Carlos G. Vanoye, Ana C. Chang-Gonzalez, Ian M. Romaine, Katherine M. Stefanski, Mason C. Wilkinson, Joshua A. Bauer, Thomas P. Hasaka, Emily L. Days, Reshma R. Desai, Kathryn R. Butcher, Gary A. Sulikowski, Alex G. Waterson, Jens Meiler, Kaitlyn V. Ledwitch, Alfred L. George Jr., Charles R. Sanders

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Figure 5

Treatment with VU0494372 leads to an increase in WT and V207M KCNQ1-KCNE1 activity.

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Treatment with VU0494372 leads to an increase in WT and V207M KCNQ1-KCNE...
(AC) KCNQ1 channel function quantified in CHO-K1 cells stably expressing KCNE1 (CHO-KCNE1) and transfected with WT or variant KCNQ1 using automated patch clamp electrophysiology (n = 10–60 cells per group). Error bars represent standard deviation, and P values were determined with 2-tailed unpaired t tests. (A) Peak current density (left) recorded 1,900 milliseconds after the start of the voltage pulse, and V1/2 of activation (right) of WT KCNQ1 after 16-hour (chronic) treatment with 0.2% DMSO or 20 μM VU0494372. Compound was removed before recording (n = 18–35 cells were quantified from 2 separate experimental replicates). (B) Peak channel current density (top) and V1/2 of activation (bottom) for CHO-KCNE1 cells transiently transfected with WT or LQT1 variant G179S, G189E, or V207M KCNQ1 after chronic treatment with 0.2% DMSO or 20 μM VU0494372. Compound or DMSO was washed off before recording (n = 15–60 cells per group). N.D., not determined, due to low current amplitude. (C) Peak current density (left) and V1/2 of activation (right), as determined for CHO-KCNE1 cells transfected with WT KCNQ1. Cells were treated with 0.2% DMSO or 20 μM VU0494372 for 5 minutes (acute treatment) before recording, and treatment remained present during recording (n = 10–29). Average whole current traces for all electrophysiology experiments are shown in Supplemental Figure 8.