WWP2 and PPP1R3A are abnormally regulated in arrhythmia-induced cardiac damage.

The present work aimed to identify the roles of WWP2 (an E3 ubiquitin-protein ligase) and protein phosphatase 1 regulatory subunit 3A (PPP1R3A) in different pathological stages of cardiac arrhythmia development. Leptin-deficient mice (C57BLKS-Lepr/Lepr) were used for the development of initial and severe stages of cardiac arrhythmia. Histology, ECG, immunohistochemistry and Western blotting were used to analyse cardiac arrhythmia, WWP2 and PPP1R3A expression. Histopathological studies of 4-month-old mice showed cardiac degeneration, cellular lesions, and swollen tissue structure with loss of tissue elasticity, indicative of the initial condition of cardiac arrhythmia. The leptin-deficient 7-month-old mice showed cardiac tissue hardening with increased secretion of extracellular matrix. The development of initial- and severe-cardiac arrhythmia was further evident with electrocardiogram studies, which showed more PP interval variations as the disease progressed. At the molecular level, WWP2 showed marginal upregulation in the initial stages of arrhythmia and was predominantly expressed within nuclei. WWP2 was overexpressed 6.6-fold in the severe stage of cardiac arrhythmia and was spread throughout the tissue layer. Interestingly, PPP1R3A was significantly overexpressed in initial cardiac arrhythmia conditions, but was downregulated and restricted to more nuclear expression in advanced cardiac arrhythmia. Silencing of PPP1R3A, enhances the expression of WWP2 to 5.3-fold in initial stages, but remarkable variation not observed in advanced cardiac arrhythmia conditions. Our results suggest that PPP1R3A had a control over WWP2 in the initial stages of cardiac arrhythmia. In particular, PPP1R3A overexpression implies its potential protective effect in initial cardiac arrhythmia stages.