Examining the Impact of Environmental and Genetic Factors that Influence Sarcospan Expression in the Heart

Abstract

Objective: Susceptibility to cardiac injury can be hereditary and the most common causes include genetic variations in proteins regulating lipid metabolism, arterial hypertension, diabetes, body-mass index as well as environmental causes such as smoking. Sarcospan (SSPN) is an integral member of the dystrophin-glycoprotein complex (DGC) and has an important role in stabilizing the muscle membrane of striated muscle. Genetic variants in the SSPN gene have been linked with increased cardiovascular disease risk and studies are ongoing to identify underlying mechanisms. Our studies using perfused mouse hearts subjected to acute ischemia/reperfusion injury indicate that SSPN deletion increases infarct size and arrhythmia risk (Hwang et al, IJMS, 2023). In addition, adult SSPN−/− cardiomyocytes were found to have decreased antioxidative capacity and heightened susceptibility to oxidative stress. Therefore, we hypothesize that genetic factors that decrease cardiac SSPN expression will increase cardiac susceptibility of mice exposed to conditions of prolonged oxidative stress. In this study we examine the role of SSPN to heart injury caused by chronic oxidative stress mediated by cigarette smoke (CS). Methods: To assess the impact of chronic oxidative stress conditions on SSPN expression in the heart 2 month-old WT C57BL/6J mice were exposed to 4 months CS. We found that SSPN expression was significantly reduced the CS exposed hearts. Since CS increases oxidative damage and deteriorates antioxidant defenses of the heart and vascular system, we examined the combined impact of SSPN deficiency and chronic oxidative stress. To address this, 7-month-old WT and SSPN−/− male and female mice were exposed to CS for 4 months. The mice were assessed after CS for body composition (EchoMRI), glucose tolerance testing and echocardiography. Tissue histology, immunoblotting of oxidative and inflammatory stress markers, serum inflammatory markers were assessed. Lung fibroblasts were isolated from the smoked and non-smoked groups to evaluate inflammatory, fibrotic, and oxidative stress pathway activation to respective stimuli. Results: Preliminary findings indicate that after CS SSPN−/− hearts exhibit larger areas of myocardial damage than WT mice. Surprisingly, after CS the SSPN−/− mice showed better glucose tolerance than WT mice and no significant changes in body mass. Minor decrements were found in the cardiac function of the CSE mice. Exposure of lung fibroblasts obtained from non-smoked SSPN−/− mice to innate immune ligands revealed activation of specific pro-inflammatory pathways.Conclusions: SSPN-deficiency increases susceptibility to cardiac injury in mice subjected to CS exposure, likely through crosstalk mechanisms that exist between oxidative and inflammatory pathways that SSPN appears to influence. Funding Sources: Florida Department of Health, James and Esther King #21K12. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.