Sinus Bradycardia in Carriers of the SCN5A-1795insD Mutation: Unraveling the Mechanism Through Computer Simulations

Overview

Journal Int J Mol Sci

Publisher MDPI

Specialties Biochemistry
Chemistry
Molecular Biology

Date 2018 Feb 24

PMID 29473904

Citations 7

Authors

Ronald Wilders

Affiliations

Soon will be listed here.

Abstract

The gene encodes the pore-forming α-subunit of the ion channel that carries the cardiac fast sodium current (). The 1795insD mutation in causes sinus bradycardia, with a mean heart rate of 70 beats/min in mutation carriers vs. 77 beats/min in non-carriers from the same family (lowest heart rate 41 vs. 47 beats/min). To unravel the underlying mechanism, we incorporated the mutation-induced changes in into a recently developed comprehensive computational model of a single human sinoatrial node cell (Fabbri-Severi model). The 1795insD mutation reduced the beating rate of the model cell from 74 to 69 beats/min (from 49 to 43 beats/min in the simulated presence of 20 nmol/L acetylcholine). The mutation-induced persistent per se resulted in a substantial increase in beating rate. This gain-of-function effect was almost completely counteracted by the loss-of-function effect of the reduction in conductance. The further loss-of-function effect of the shifts in steady-state activation and inactivation resulted in an overall loss-of-function effect of the 1795insD mutation. We conclude that the experimentally identified mutation-induced changes in can explain the clinically observed sinus bradycardia. Furthermore, we conclude that the Fabbri-Severi model may prove a useful tool in understanding cardiac pacemaker activity in humans.

Citing Articles

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