The troponin T R92Q mutation alters tropomyosin positioning, increasing molecular and cellular force generation during calcium-based activation and driving early disease pathogenesis in familial HCM.
Does the troponin T R92Q mutation alter molecular and cellular force generation in models of familial hypertrophic cardiomyopathy?
The troponin T R92Q mutation drives early HCM pathogenesis through increased mechanical tension, activating adaptive mechanobiological signaling pathways.
Familial hypertrophic cardiomyopathy (HCM), a leading cause of sudden cardiac death, is primarily caused by mutations in sarcomeric proteins. The pathogenesis of HCM is complex, with functional changes that span scales, from molecules to tissues. This makes it challenging to deconvolve the biophysical molecular defect that drives the disease pathogenesis from downstream changes in cellular function. In this study, we examine an HCM mutation in troponin T, R92Q, for which several models explaining its effects in disease have been put forward. We demonstrate that the primary molecular insult driving disease pathogenesis is mutation-induced alterations in tropomyosin positioning, which causes increased molecular and cellular force generation during calcium-based activation. Computational modeling shows that the increased cellular force is consistent with the molecular mechanism. These changes in cellular contractility cause downstream alterations in gene expression, calcium handling, and electrophysiology. Taken together, our results demonstrate that molecularly driven changes in mechanical tension drive the early disease pathogenesis of familial HCM, leading to activation of adaptive mechanobiological signaling pathways.
Clippinger et al. (Fri,) conducted a other in Familial hypertrophic cardiomyopathy (HCM). Troponin T R92Q mutation was evaluated on Molecular and cellular force generation, gene expression, calcium handling, and electrophysiology. The troponin T R92Q mutation alters tropomyosin positioning, increasing molecular and cellular force generation during calcium-based activation and driving early disease pathogenesis in familial HCM.
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