Early Somatic Mosaicism is a Rare Cause of Long-QT Syndrome

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2016 Sep 30

PMID 27681629

Citations 27

Authors

James Rush Priest

Charles Gawad

Kristopher M Kahlig

Joseph K Yu

Thomas OHara

Patrick M Boyle

Sridharan Rajamani

Michael J Clark

Sarah T K Garcia

Scott Ceresnak

Jason Harris

Sean Boyle

Frederick E Dewey

Lindsey Malloy-Walton

Kyla Dunn

Megan Grove

Marco V Perez

Norma F Neff

Richard Chen

Katsuhide Maeda

Anne Dubin

Luiz Belardinelli

John West

Christian Antolik

Daniela Macaya

Thomas Quertermous

Natalia A Trayanova

Stephen R Quake

Euan A Ashley

Affiliations

Soon will be listed here.

Abstract

Somatic mosaicism, the occurrence and propagation of genetic variation in cell lineages after fertilization, is increasingly recognized to play a causal role in a variety of human diseases. We investigated the case of life-threatening arrhythmia in a 10-day-old infant with long QT syndrome (LQTS). Rapid genome sequencing suggested a variant in the sodium channel Na1.5 encoded by SCN5A, NM_000335:c.5284G > T predicting p.(V1762L), but read depth was insufficient to be diagnostic. Exome sequencing of the trio confirmed read ratios inconsistent with Mendelian inheritance only in the proband. Genotyping of single circulating leukocytes demonstrated the mutation in the genomes of 8% of patient cells, and RNA sequencing of cardiac tissue from the infant confirmed the expression of the mutant allele at mosaic ratios. Heterologous expression of the mutant channel revealed significantly delayed sodium current with a dominant negative effect. To investigate the mechanism by which mosaicism might cause arrhythmia, we built a finite element simulation model incorporating Purkinje fiber activation. This model confirmed the pathogenic consequences of cardiac cellular mosaicism and, under the presenting conditions of this case, recapitulated 2:1 AV block and arrhythmia. To investigate the extent to which mosaicism might explain undiagnosed arrhythmia, we studied 7,500 affected probands undergoing commercial gene-panel testing. Four individuals with pathogenic variants arising from early somatic mutation events were found. Here we establish cardiac mosaicism as a causal mechanism for LQTS and present methods by which the general phenomenon, likely to be relevant for all genetic diseases, can be detected through single-cell analysis and next-generation sequencing.

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