Arrhythmia risk rises early in many forms of cardiac stress, often before contractile failure is evident. Stressed cardiomyocytes accumulate biomolecular condensates, known as stress granules (SGs), whose contribution to this electrical vulnerability has been unclear. We mapped where SGs reside and followed their life cycle under acute and chronic oxidative stress across complementary model systems and assessed electrophysiological consequences with pharmacological tools targeting granule assembly, microtubule integrity, and calcium channel function. Under both stress regimes, SGs localized preferentially to z-lines and intercalated discs, marking these mechanically critical sites as hubs of condensate assembly. Merging of granules, referred to as coarsening, rather than initial formation, emerged as a pathological connection. Early granules were broadly cytoprotective, whereas progressive coarsening was accompanied by disruption of alpha-actinin and L-type calcium channel (Cav1.2) nanodomains and by shortening of action potential (AP) duration. Coarsened granules disorganized Cav1.2 nanodomains through a microtubule-dependent mechanism, and arresting coarsening with nocodazole preserved nanodomain integrity and restored AP morphology. The transition from nascent to coarsened SGs therefore represents a targetable inflection point, and limiting coarsening may prevent proarrhythmic remodeling during cardiac oxidative stress.
Struckman, H. L., Field, I., Li, A. Z., Marquez, E., Seidel, M. M., Schuster, T. M., Chou, C., Giangrasso, S., Lavine, K. J., Matsiukevich, D., Ornitz, D. M., Huebsch, N., Khokhlova, A., Silva, J. R.
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