Asporin Improves Cardiac Myocyte Response to Ischemia and Reperfusion Stress

BackgroundMyocardial Infarction (MI) remains a leading cause of mortality worldwide, despite advancements in clinical therapies and interventions. MI results from prolonged ischemia, leading to hypoxia-induced damage to cardiac tissue and reperfusion-injury (R/I) that aggravates cardiomyocyte (CM) loss. One key cellular event during this process is accumulation of dysfunctional mitochondria, resulting from environmental hypoxia and subsequent oxidative stress upon reperfusion. Post-MI cardiac-remodeling involves changes in both cellular and extracellular matrix (ECM). Ubiquitin-dependent and independent autophagy are crucial for cardio protection during this phase. The ECM provides structural integrity and functions as a reservoir for signaling molecules. Asporin (ASPN), a small leucine-rich proteoglycan, plays a role in modulating cardiac-remodeling by limiting excessive fibrosis and protecting CMs from cell death. MethodsWe investigated the therapeutic potential of ASPN by using an exogenous recombinant peptide of ASPN (rASPN), testing its effects using an in-vitro ischemia-reperfusion (I/R) model simulating MI conditions. Two I/R models were developed using an immortalized human embryonic cardiac cell line to reflect the hypoxia-reperfusion (H/R) phases of MI. In the No-Reoxygenation (No-ReOx) model, cells were subjected to hypoxia for 18 hours, with or without exogenous rASPN. In the Reoxygenation (ReOx) model, cells underwent 18 hours of hypoxia, then 12 hours of reoxygenation (simulating reperfusion), with or without rASPN. ResultsProteomics revealed that ASPN modulates key pathways involved in apoptosis, non-canonical autophagy, and metabolic reprogramming. Additionally, ASPN influenced immune response pathways and significantly affected TGF-{beta} signaling, a central mediator of cardiac fibrosis and remodeling post-MI. These findings indicate that ASPN plays a multifaceted role in regulating cellular responses to hypoxia and R/I. ConclusionsOur H/R model simulates key aspects of MI and R/I. The protective role of ASPN observed in this model suggests it as a promising candidate for developing cardioprotective therapies to minimize R/I and adverse cardiac-remodeling following MI.