Effect of Variations in Gap Junctional Coupling on the Frequency of Oscillatory Action Potentials in a Smooth Muscle Syncytium

Gap junctions provide pathways for intercellular communication between adjacent cells, allowing exchange of ions and small molecules. Based on the constituent protein subunits, gap junctions are classified into different subtypes varying in their properties such as unitary conductances, sensitivity...

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Bibliographic Details
Published inFrontiers in physiology Vol. 12; p. 655225
Main Authors Appukuttan, Shailesh, Brain, Keith L., Manchanda, Rohit
Format Journal Article
LanguageEnglish
Published Frontiers Media S.A 01.10.2021
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Summary:Gap junctions provide pathways for intercellular communication between adjacent cells, allowing exchange of ions and small molecules. Based on the constituent protein subunits, gap junctions are classified into different subtypes varying in their properties such as unitary conductances, sensitivity to transjunctional voltage, and gating kinetics. Gap junctions couple cells electrically, and therefore the electrical activity originating in one cell can affect and modulate the electrical activity in adjacent cells. Action potentials can propagate through networks of such electrically coupled cells, and this spread is influenced by the nature of gap junctional coupling. Our study aims to computationally explore the effect of differences in gap junctional properties on oscillating action potentials in electrically coupled tissues. Further, we also explore variations in the biophysical environment by altering the size of the syncytium, the location of the pacemaking cell, as well as the occurrence of multiple pacemaking cells within the same syncytium. Our simulation results suggest that the frequency of oscillations is governed by the extent of coupling between cells and the gating kinetics of different gap junction subtypes. The location of pacemaking cells is found to alter the syncytial behavior, and when multiple oscillators are present, there exists an interplay between the oscillator frequency and their relative location within the syncytium. Such variations in the frequency of oscillations can have important implications for the physiological functioning of syncytial tissues.
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Edited by: Silvina Ponce Dawson, University of Buenos Aires, Argentina
This article was submitted to Biophysics, a section of the journal Frontiers in Physiology
Reviewed by: Qing Yun Wang, Beihang University, China; Alejandra C. Ventura, Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET), Argentina; Daniel Fraiman, Universidad de San Andrés, Argentina
ISSN:1664-042X
1664-042X
DOI:10.3389/fphys.2021.655225