High-throughput screens identify genotype-specific therapeutics for channelopathies
Christian L. Egly, … , Brett M. Kroncke, Björn C. Knollmann
Christian L. Egly, … , Brett M. Kroncke, Björn C. Knollmann
Published September 30, 2025
Citation Information: JCI Insight. 2025;10(22):e191697. https://doi.org/10.1172/jci.insight.191697.
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Research Article Cardiology Genetics

High-throughput screens identify genotype-specific therapeutics for channelopathies

Abstract

Genetic diseases such as ion channelopathies substantially burden human health. Existing treatments are limited and not genotype specific. Here, we report a 2-step high-throughput approach to rapidly identify drug candidates for repurposing as genotype-specific therapy. We first screened 1,680 medicines using a thallium-flux trafficking assay against Kv11.1 gene variants causing long QT syndrome (LQTS), an ion channelopathy associated with fatal cardiac arrhythmia. We identified evacetrapib as a suitable drug candidate that improves membrane trafficking and activates channels. We then used deep mutational scanning to prospectively identify all Kv11.1 missense variants in an LQTS hotspot region responsive to treatment with evacetrapib. Combining high-throughput drug screens with deep mutational scanning establishes a paradigm for mutation-specific drug discovery translatable to personalized treatment of carriers with rare genetic disorders.

Authors

Christian L. Egly, Alex Shen, Tri Q. Do, Carlos Tellet Cabiya, Paxton A. Ritschel, Suah Woo, Matthew Ku, Brian P. Delisle, Brett M. Kroncke, Björn C. Knollmann

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Figure 3

Evacetrapib increases Kv11.1 currents and modulates Kv11.1 channel activation, with limited effects on inactivation.

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Evacetrapib increases Kv11.1 currents and modulates Kv11.1 channel activ...
(A) Typical current traces recorded in HEK-293 cells expressing Kv11.1 exposed to vehicle or evacetrapib. (B) Plot of current-voltage (I-V) relationship from peak tail currents measured in the presence of vehicle (n = 13 cells) or evacetrapib (n = 10 cells). (C and D) Voltage dependence of Kv11.1 channel activation. (C) Typical current traces used to assess voltage dependence of activation. (D) I-V relationship of tail currents measured from –40 mV step potential (solid line shows fit of a Boltzmann function, top) and steady-state currents measured at the end of each step potential (bottom) in the presence of vehicle or evacetrapib (n = 11 cells/treatment). All current traces and analyses in the presence of vehicle (0.1% DMSO, black) or evacetrapib (15 μmol/L, blue) in bath solution. All data are reported as mean ± SD.