Molecular characterization of the calcium release channel deficiency syndrome
David J. Tester, … , Joel Temple, Michael J. Ackerman
David J. Tester, … , Joel Temple, Michael J. Ackerman
Published July 14, 2020
Citation Information: JCI Insight. 2020;5(15):e135952. https://doi.org/10.1172/jci.insight.135952.
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Research Article Cardiology Genetics

Molecular characterization of the calcium release channel deficiency syndrome

Abstract

We identified a potentially novel homozygous duplication involving the promoter region and exons 1–4 of the gene encoding type 2 cardiac ryanodine receptor (RYR2) that is responsible for highly penetrant, exertion-related sudden deaths/cardiac arrests in the Amish community without an overt phenotype to suggest RYR2-mediated catecholaminergic polymorphic ventricular tachycardia (CPVT). Homozygous RYR2 duplication (RYR2-DUP) induced pluripotent stem cell cardiomyocytes (iPSC-CMs) were generated from 2 unrelated patients. There was no difference in baseline Ca2+ handling measurements between WT-iPSC-CM and RYR2-DUP-iPSC-CM lines. However, compared with WT-iPSC-CMs, both patient lines demonstrated a dramatic reduction in caffeine-stimulated and isoproterenol-stimulated (ISO-stimulated) Ca2+ transient amplitude, suggesting RyR2 loss of function. There was a greater than 50% reduction in RYR2 transcript/RyR2 protein expression in both patient iPSC-CMs compared with WT. Delayed afterdepolarization was observed in the RYR2-DUP-iPSC-CMs but not in the WT-iPSC-CMs. Compared with WT-iPSC-CMs, there was significantly elevated arrhythmic activity in the RYR2-DUP-iPSC-CMs in response to ISO. Nadolol, propranolol, and flecainide reduced erratic activity by 8.5-fold, 6.8-fold, and 2.4-fold, respectively, from ISO challenge. Unlike the gain-of-function mechanism observed in RYR2-mediated CPVT, the homozygous multiexon duplication precipitated a dramatic reduction in RYR2 transcription and RyR2 protein translation, a loss of function in calcium handling, and a calcium-induced calcium release apparatus that is insensitive to catecholamines and caffeine.

Authors

David J. Tester, CS John Kim, Samantha K. Hamrick, Dan Ye, Bailey J. O’Hare, Hannah M. Bombei, Kristi K. Fitzgerald, Carla M. Haglund-Turnquist, Dianne L. Atkins, Luis A. Ochoa Nunez, Ian Law, Joel Temple, Michael J. Ackerman

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Figure 1

Amish pedigrees with recessively inherited exertion-associated SUDY.

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Amish pedigrees with recessively inherited exertion-associated SUDY. Sho...
Shown are 2 unrelated Amish pedigrees (pedigree 1 and pedigree 2) (A) with autopsy-negative sudden unexplained deaths or cardiac arrests. Open symbols (circles, women and girls; squares, men and boys) represent unaffected individuals. Black symbols represent affected family members. The age (in years) at sudden death is provided below the symbol representing sex. The yellow circles represent those family members whose iPSC-CMs were available for study. The red circle indicates the sudden death victim whose heart tissue was available for study. (B) A representative Sanger sequencing chromatogram from one of the RYR2-duplicated (RYR2 Dup) iPSC clones hosting the homozygous duplication and a graphical representation of the biallelic tandem 344,085 base pair (bp) duplication involving approximately 26,000 bp of intergenic sequence, RYR2’s 5′ UTR/promoter region, and exons 1–4 of RYR2. (C) Bar graph illustrating the calculated copy number of RYR2 alleles in genomic DNA derived from patients known to be negative (WT, 2 copies), heterozygous (3 copies), or homozygous (4 copies) for the RYR2 duplication as well as confirmation of genotype in each control and mutant iPSC clone.