Somatic Mutations in the Connexin 40 Gene (GJA5) in Atrial Fibrillation

doi:10.1056/NEJMoa052800

Volume 354:2677-2688		June 22, 2006		Number 25

Somatic Mutations in the Connexin 40 Gene (GJA5) in Atrial Fibrillation

Michael H. Gollob, M.D., Douglas L. Jones, Ph.D., Andrew D. Krahn, M.D., Lynne Danis, M.L.T., Xiang-Qun Gong, Ph.D., Qing Shao, Ph.D., Xiaoqin Liu, M.D., John P. Veinot, M.D., Anthony S.L. Tang, M.D., Alexandre F.R. Stewart, Ph.D., Frederique Tesson, Ph.D., George J. Klein, M.D., Raymond Yee, M.D., Allan C. Skanes, M.D., Gerard M. Guiraudon, M.D., Lisa Ebihara, M.D., Ph.D., and Donglin Bai, Ph.D.

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by Saffitz, J. E.

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ABSTRACT

Background Atrial fibrillation is the most common type of cardiacarrhythmia and a leading cause of cardiovascular morbidity,particularly stroke. The cardiac gap-junction protein connexin40 is expressed selectively in atrial myocytes and mediatesthe coordinated electrical activation of the atria. We hypothesizedthat idiopathic atrial fibrillation has a genetic basis andthat tissue-specific mutations in GJA5, the gene encoding connexin40, may predispose the atria to fibrillation.

Methods We sequenced GJA5 from genomic DNA isolated from resectedcardiac tissue and peripheral lymphocytes from 15 patients withidiopathic atrial fibrillation. Identified GJA5 mutations weretransfected into a gap-junction–deficient cell line toassess their functional effects on protein transport and intercellularelectrical coupling.

Results Four novel heterozygous missense mutations were identifiedin 4 of the 15 patients. In three patients, the mutations werefound in the cardiac-tissue specimens but not in the lymphocytes,indicating a somatic source of the genetic defects. In the fourthpatient, the sequence variant was detected in both cardiac tissueand lymphocytes, suggesting a germ-line origin. Analysis ofthe expression of mutant proteins revealed impaired intracellulartransport or reduced intercellular electrical coupling.

Conclusions Mutations in GJA5 may predispose patients to idiopathicatrial fibrillation by impairing gap-junction assembly or electricalcoupling. Our data suggest that common diseases traditionallyconsidered to be idiopathic may have a genetic basis, with mutationsconfined to the diseased tissue.

Source Information

From the Department of Medicine, University of Ottawa Heart Institute, Ottawa (M.H.G., L.D., J.P.V., A.S.L.T., A.F.R.S., F.T.), and the Departments of Medicine (M.H.G., D.L.J., A.D.K., G.J.K., R.Y., A.C.S.), Physiology and Pharmacology (D.L.J., X.-Q.G., D.B.), Anatomy and Cell Biology (Q.S.), and Surgery (G.M.G.), University of Western Ontario, London, Ont. — both in Canada; and the Department of Physiology and Biophysics, Rosalind Franklin University of Medicine and Science, North Chicago, Ill. (X.L., L.E.).

Address reprint requests to Dr. Gollob at the Arrhythmia Research Laboratory and Division of Cardiology, University of Ottawa Heart Institute, Rm. H350, 40 Ruskin St., Ottawa, ON K1Y 4W7, Canada, or at mgollob{at}ottawaheart.ca.

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