Desmoglein-2 deficiency results in cardiac dysfunction by compromising both Z-disc- and intercalated disc-mediated mechanotransduction
Landim-Vieira, M.; Jani, V. P.; Shiel, E.; Rastegarpouyani, H.; Engel, M.; Paradine, F.; Chastain, R.; Farra, W.; Ma, W.; Toepfer, C.; Chase, P. B.; Kass, D. A.; Pinto, J. R.; Chelko, S. P.
Show abstract
Desmoglein-2 (DSG2), a critical component of the cardiac desmosome and located at the cardiomyocyte-cardiomyocyte intercalated disc, is essential for cell-cell adhesion, cardiomyocyte mechanical stability, and electrical coupling between cells. However, its relative contribution in maintaining cardiac function at the sarcomere level remains unclear. Using 4-week-old (adolescent) and 16-week-old (adult) homozygous knock-in Dsg2-mutant (Dsg2mut/mut) mice, we found that loss of DSG2 leads to early onset chamber- and age-dependent cardiac dysfunction driven by Z-disc structural defects and increased myosin detachment rate. Interestingly, Ca{superscript 2}-activated force was markedly reduced in adolescent Dsg2mut/mut permeabilized left ventricular cardiac muscle bundles but preserved in permeabilized isolated cardiomyocytes. This disparity demonstrates that DSG2 is not only crucial for mechanical coupling between cardiomyocytes but also for force transmission within and between sarcomeres, revealing a novel role for DSG2 in maintaining contractile integrity at both the cellular and tissue levels.
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