Muscarinic Receptors Promote Pacemaker Fate at the Expense of Secondary Conduction System Tissue in Zebrafish

Overview

Journal JCI Insight

Specialties Biomedical Engineering
General Medicine

Date 2019 Oct 18

PMID 31619590

Citations 7

Authors

Martina S Burczyk

Martin D Burkhalter

Teresa Casar Tena

Laurel A Grisanti

Michael Kauk

Sabrina Matysik

Cornelia Donow

Monika Kustermann

Melanie Rothe

Yinghong Cui

Farah Raad

Svenja Laue

Allessandra Moretti

Wolfram-H Zimmermann

Jurgen Wess

Michael Kuhl

Carsten Hoffmann

Douglas G Tilley

Melanie Philipp

Affiliations

Soon will be listed here.

Abstract

Deterioration or inborn malformations of the cardiac conduction system (CCS) interfere with proper impulse propagation in the heart and may lead to sudden cardiac death or heart failure. Patients afflicted with arrhythmia depend on antiarrhythmic medication or invasive therapy, such as pacemaker implantation. An ideal way to treat these patients would be CCS tissue restoration. This, however, requires precise knowledge regarding the molecular mechanisms underlying CCS development. Here, we aimed to identify regulators of CCS development. We performed a compound screen in zebrafish embryos and identified tolterodine, a muscarinic receptor antagonist, as a modifier of CCS development. Tolterodine provoked a lower heart rate, pericardiac edema, and arrhythmia. Blockade of muscarinic M3, but not M2, receptors induced transcriptional changes leading to amplification of sinoatrial cells and loss of atrioventricular identity. Transcriptome data from an engineered human heart muscle model provided additional evidence for the contribution of muscarinic M3 receptors during cardiac progenitor specification and differentiation. Taken together, we found that muscarinic M3 receptors control the CCS already before the heart becomes innervated. Our data indicate that muscarinic receptors maintain a delicate balance between the developing sinoatrial node and the atrioventricular canal, which is probably required to prevent the development of arrhythmia.

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