AAV9-mediated KCNH2 suppression-replacement gene therapy in a transgenic rabbit model of type 1 short QT syndrome

Saranda Nimani; Sahej Bains; Nicolò Alerni; Balázs Ördög; András Horváth; Lluis Matas; Julien Louradour; Lucilla Giammarino; David J Tester; Olgica Beslac; Ruben Lopez; Stefan Meier; Manuel Egle; Nicolas Christoforou; Miriam Barbieri; Varjany Vashanthakumar; Stefanie Perez-Feliz; Chiara Parodi; Luisana G Garcia Casalta; C S John Kim; Wei Zhou; Dan Ye; Jacqulyn Jurgensen; Michael A Barry; Mariana Bego; Lisa Keyes; Jane Owens; Jason Pinkstaff; Jan Christoph; Manfred Zehender; Michael Brunner; Jordi Heijman; Daniela Casoni; Fabien Praz; Andreas Haeberlin; Gabriel Brooks; Michael J Ackerman; Katja E Odening

doi:10.1093/eurheartj/ehaf660

AAV9-mediated KCNH2 suppression-replacement gene therapy in a transgenic rabbit model of type 1 short QT syndrome

Saranda Nimani, Sahej Bains, Nicolò Alerni, Balázs Ördög, András Horváth, Lluis Matas, Julien Louradour, Lucilla Giammarino, David J Tester, Olgica Beslac, Ruben Lopez, Stefan Meier, Manuel Egle, Nicolas Christoforou, Miriam Barbieri, Varjany Vashanthakumar, Stefanie Perez-Feliz, Chiara Parodi, Luisana G Garcia Casalta, C S John KimWei Zhou, Dan Ye, Jacqulyn Jurgensen, Michael A Barry, Mariana Bego, Lisa Keyes, Jane Owens, Jason Pinkstaff, Jan Christoph, Manfred Zehender, Michael Brunner, Jordi Heijman, Daniela Casoni, Fabien Praz, Andreas Haeberlin, Gabriel Brooks, Michael J Ackerman, Katja E Odening

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

BACKGROUND AND AIMS: Type 1 short QT syndrome (SQT1) is a genetic channelopathy caused by gain-of-function variants in KCNH2. This shortens cardiac repolarization and QT intervals, predisposing patients to ventricular arrhythmias and sudden cardiac death. This study aimed to investigate the therapeutic efficacy of KCNH2-specific suppression-and-replacement (KCNH2-SupRep) gene therapy in a transgenic rabbit model of SQT1. METHODS: KCNH2-SupRep was developed by combining a KCNH2-shRNA with its corresponding shRNA-immune KCNH2-cDNA into an AAV9 vector, delivered directly into the aortic root (1x1010 vg/kg). Therapeutic efficacy was evaluated in vivo by electrocardiogram, ex vivo by optical mapping, and at cellular levels by patch-clamp, calcium imaging, and qPCR in ventricular cardiomyocytes (VCMs). RESULTS: In vivo, KCNH2-SupRep normalized the heart rate-corrected QT (QTc) in SQT1 rabbits, without affecting repolarization heterogeneity. Ex vivo, KCNH2-SupRep corrected the action potential duration (APD90) and resolved the increased apicobasal APD90 heterogeneity observed in untreated (UT)-SQT1 hearts, supporting an antiarrhythmic effect, which was further validated by reduced re-entry formation in silico. At cellular levels, KCNH2-SupRep prolonged APD90 in VCMs from SupRep-SQT1 rabbits closer to wildtype levels compared to UT- and sham-SQT1. Additionally, KCNH2-SupRep restored the cellular surrogate of the electro-mechanical window and normalized IKr in nearly 50% of VCMs, in line with a 50-60% suppression of the mutant KCNH2 transcript. CONCLUSIONS: This proof-of-concept study is the first to demonstrate the efficacy of gene therapy for SQT1 in a medium-sized animal model. KCNH2-SupRep gene therapy successfully corrected the pathologic phenotype in vivo, ex vivo and at cellular levels in transgenic SQT1 rabbits.

Original language	English
Journal	European Heart Journal
DOIs	https://doi.org/10.1093/eurheartj/ehaf660
Publication status	E-pub ahead of print - 30 Aug 2025

Keywords

KCNH2
short QT syndrome
AAV9
gene therapy
transgenic rabbit model of SQT1

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Nimani, S., Bains, S., Alerni, N., Ördög, B., Horváth, A., Matas, L., Louradour, J., Giammarino, L., Tester, D. J., Beslac, O., Lopez, R., Meier, S., Egle, M., Christoforou, N., Barbieri, M., Vashanthakumar, V., Perez-Feliz, S., Parodi, C., Garcia Casalta, L. G., ... Odening, K. E. (2025). AAV9-mediated KCNH2 suppression-replacement gene therapy in a transgenic rabbit model of type 1 short QT syndrome. European Heart Journal. Advance online publication. https://doi.org/10.1093/eurheartj/ehaf660

@article{69847c409d35425187c096a6297438bd,

title = "AAV9-mediated KCNH2 suppression-replacement gene therapy in a transgenic rabbit model of type 1 short QT syndrome",

abstract = "BACKGROUND AND AIMS: Type 1 short QT syndrome (SQT1) is a genetic channelopathy caused by gain-of-function variants in KCNH2. This shortens cardiac repolarization and QT intervals, predisposing patients to ventricular arrhythmias and sudden cardiac death. This study aimed to investigate the therapeutic efficacy of KCNH2-specific suppression-and-replacement (KCNH2-SupRep) gene therapy in a transgenic rabbit model of SQT1. METHODS: KCNH2-SupRep was developed by combining a KCNH2-shRNA with its corresponding shRNA-immune KCNH2-cDNA into an AAV9 vector, delivered directly into the aortic root (1x1010 vg/kg). Therapeutic efficacy was evaluated in vivo by electrocardiogram, ex vivo by optical mapping, and at cellular levels by patch-clamp, calcium imaging, and qPCR in ventricular cardiomyocytes (VCMs). RESULTS: In vivo, KCNH2-SupRep normalized the heart rate-corrected QT (QTc) in SQT1 rabbits, without affecting repolarization heterogeneity. Ex vivo, KCNH2-SupRep corrected the action potential duration (APD90) and resolved the increased apicobasal APD90 heterogeneity observed in untreated (UT)-SQT1 hearts, supporting an antiarrhythmic effect, which was further validated by reduced re-entry formation in silico. At cellular levels, KCNH2-SupRep prolonged APD90 in VCMs from SupRep-SQT1 rabbits closer to wildtype levels compared to UT- and sham-SQT1. Additionally, KCNH2-SupRep restored the cellular surrogate of the electro-mechanical window and normalized IKr in nearly 50\% of VCMs, in line with a 50-60\% suppression of the mutant KCNH2 transcript. CONCLUSIONS: This proof-of-concept study is the first to demonstrate the efficacy of gene therapy for SQT1 in a medium-sized animal model. KCNH2-SupRep gene therapy successfully corrected the pathologic phenotype in vivo, ex vivo and at cellular levels in transgenic SQT1 rabbits.",

keywords = "KCNH2, short QT syndrome, AAV9, gene therapy, transgenic rabbit model of SQT1",

author = "Saranda Nimani and Sahej Bains and Nicol{\`o} Alerni and Bal{\'a}zs {\"O}rd{\"o}g and Andr{\'a}s Horv{\'a}th and Lluis Matas and Julien Louradour and Lucilla Giammarino and Tester, \{David J\} and Olgica Beslac and Ruben Lopez and Stefan Meier and Manuel Egle and Nicolas Christoforou and Miriam Barbieri and Varjany Vashanthakumar and Stefanie Perez-Feliz and Chiara Parodi and \{Garcia Casalta\}, \{Luisana G\} and Kim, \{C S John\} and Wei Zhou and Dan Ye and Jacqulyn Jurgensen and Barry, \{Michael A\} and Mariana Bego and Lisa Keyes and Jane Owens and Jason Pinkstaff and Jan Christoph and Manfred Zehender and Michael Brunner and Jordi Heijman and Daniela Casoni and Fabien Praz and Andreas Haeberlin and Gabriel Brooks and Ackerman, \{Michael J\} and Odening, \{Katja E\}",

year = "2025",

month = aug,

day = "30",

doi = "10.1093/eurheartj/ehaf660",

language = "English",

journal = "European Heart Journal",

issn = "0195-668X",

publisher = "Oxford University Press",

}

Nimani, S, Bains, S, Alerni, N, Ördög, B, Horváth, A, Matas, L, Louradour, J, Giammarino, L, Tester, DJ, Beslac, O, Lopez, R, Meier, S, Egle, M, Christoforou, N, Barbieri, M, Vashanthakumar, V, Perez-Feliz, S, Parodi, C, Garcia Casalta, LG, Kim, CSJ, Zhou, W, Ye, D, Jurgensen, J, Barry, MA, Bego, M, Keyes, L, Owens, J, Pinkstaff, J, Christoph, J, Zehender, M, Brunner, M, Heijman, J, Casoni, D, Praz, F, Haeberlin, A, Brooks, G, Ackerman, MJ & Odening, KE 2025, 'AAV9-mediated KCNH2 suppression-replacement gene therapy in a transgenic rabbit model of type 1 short QT syndrome', European Heart Journal. https://doi.org/10.1093/eurheartj/ehaf660

TY - JOUR

T1 - AAV9-mediated KCNH2 suppression-replacement gene therapy in a transgenic rabbit model of type 1 short QT syndrome

AU - Nimani, Saranda

AU - Bains, Sahej

AU - Alerni, Nicolò

AU - Ördög, Balázs

AU - Horváth, András

AU - Matas, Lluis

AU - Louradour, Julien

AU - Giammarino, Lucilla

AU - Tester, David J

AU - Beslac, Olgica

AU - Lopez, Ruben

AU - Meier, Stefan

AU - Egle, Manuel

AU - Christoforou, Nicolas

AU - Barbieri, Miriam

AU - Vashanthakumar, Varjany

AU - Perez-Feliz, Stefanie

AU - Parodi, Chiara

AU - Garcia Casalta, Luisana G

AU - Kim, C S John

AU - Zhou, Wei

AU - Ye, Dan

AU - Jurgensen, Jacqulyn

AU - Barry, Michael A

AU - Bego, Mariana

AU - Keyes, Lisa

AU - Owens, Jane

AU - Pinkstaff, Jason

AU - Christoph, Jan

AU - Zehender, Manfred

AU - Brunner, Michael

AU - Heijman, Jordi

AU - Casoni, Daniela

AU - Praz, Fabien

AU - Haeberlin, Andreas

AU - Brooks, Gabriel

AU - Ackerman, Michael J

AU - Odening, Katja E

PY - 2025/8/30

Y1 - 2025/8/30

N2 - BACKGROUND AND AIMS: Type 1 short QT syndrome (SQT1) is a genetic channelopathy caused by gain-of-function variants in KCNH2. This shortens cardiac repolarization and QT intervals, predisposing patients to ventricular arrhythmias and sudden cardiac death. This study aimed to investigate the therapeutic efficacy of KCNH2-specific suppression-and-replacement (KCNH2-SupRep) gene therapy in a transgenic rabbit model of SQT1. METHODS: KCNH2-SupRep was developed by combining a KCNH2-shRNA with its corresponding shRNA-immune KCNH2-cDNA into an AAV9 vector, delivered directly into the aortic root (1x1010 vg/kg). Therapeutic efficacy was evaluated in vivo by electrocardiogram, ex vivo by optical mapping, and at cellular levels by patch-clamp, calcium imaging, and qPCR in ventricular cardiomyocytes (VCMs). RESULTS: In vivo, KCNH2-SupRep normalized the heart rate-corrected QT (QTc) in SQT1 rabbits, without affecting repolarization heterogeneity. Ex vivo, KCNH2-SupRep corrected the action potential duration (APD90) and resolved the increased apicobasal APD90 heterogeneity observed in untreated (UT)-SQT1 hearts, supporting an antiarrhythmic effect, which was further validated by reduced re-entry formation in silico. At cellular levels, KCNH2-SupRep prolonged APD90 in VCMs from SupRep-SQT1 rabbits closer to wildtype levels compared to UT- and sham-SQT1. Additionally, KCNH2-SupRep restored the cellular surrogate of the electro-mechanical window and normalized IKr in nearly 50% of VCMs, in line with a 50-60% suppression of the mutant KCNH2 transcript. CONCLUSIONS: This proof-of-concept study is the first to demonstrate the efficacy of gene therapy for SQT1 in a medium-sized animal model. KCNH2-SupRep gene therapy successfully corrected the pathologic phenotype in vivo, ex vivo and at cellular levels in transgenic SQT1 rabbits.

AB - BACKGROUND AND AIMS: Type 1 short QT syndrome (SQT1) is a genetic channelopathy caused by gain-of-function variants in KCNH2. This shortens cardiac repolarization and QT intervals, predisposing patients to ventricular arrhythmias and sudden cardiac death. This study aimed to investigate the therapeutic efficacy of KCNH2-specific suppression-and-replacement (KCNH2-SupRep) gene therapy in a transgenic rabbit model of SQT1. METHODS: KCNH2-SupRep was developed by combining a KCNH2-shRNA with its corresponding shRNA-immune KCNH2-cDNA into an AAV9 vector, delivered directly into the aortic root (1x1010 vg/kg). Therapeutic efficacy was evaluated in vivo by electrocardiogram, ex vivo by optical mapping, and at cellular levels by patch-clamp, calcium imaging, and qPCR in ventricular cardiomyocytes (VCMs). RESULTS: In vivo, KCNH2-SupRep normalized the heart rate-corrected QT (QTc) in SQT1 rabbits, without affecting repolarization heterogeneity. Ex vivo, KCNH2-SupRep corrected the action potential duration (APD90) and resolved the increased apicobasal APD90 heterogeneity observed in untreated (UT)-SQT1 hearts, supporting an antiarrhythmic effect, which was further validated by reduced re-entry formation in silico. At cellular levels, KCNH2-SupRep prolonged APD90 in VCMs from SupRep-SQT1 rabbits closer to wildtype levels compared to UT- and sham-SQT1. Additionally, KCNH2-SupRep restored the cellular surrogate of the electro-mechanical window and normalized IKr in nearly 50% of VCMs, in line with a 50-60% suppression of the mutant KCNH2 transcript. CONCLUSIONS: This proof-of-concept study is the first to demonstrate the efficacy of gene therapy for SQT1 in a medium-sized animal model. KCNH2-SupRep gene therapy successfully corrected the pathologic phenotype in vivo, ex vivo and at cellular levels in transgenic SQT1 rabbits.

KW - KCNH2

KW - short QT syndrome

KW - AAV9

KW - gene therapy

KW - transgenic rabbit model of SQT1

U2 - 10.1093/eurheartj/ehaf660

DO - 10.1093/eurheartj/ehaf660

M3 - Article

SN - 0195-668X

JO - European Heart Journal

JF - European Heart Journal

ER -

AAV9-mediated KCNH2 suppression-replacement gene therapy in a transgenic rabbit model of type 1 short QT syndrome

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