Abstract P3072: Effects Of Antiviral Innate Immune Activation On Cytokine Secretion And Function Of Human Ipsc-derived Cardiomyocytes

Abstract

Introduction: Acute and long-term cardiovascular complications of COVID-19 have been reported, ranging from arrhythmias, ischemic heart disease, and heart failure to cerebrovascular and cardiometabolic disorders, yet the underlying molecular mechanisms are not well understood. Here, we examine the effects of stimulating the double-stranded RNA (dsRNA) pattern recognition receptor pathway, which is strongly induced to activate interferon-stimulated gene (ISG) expression in the heart during COVID-19, on excitation-contraction coupling and mitochondrial function. While providing antiviral protection, we hypothesize that, even in the absence of cardiac viral replication, this pathway might contribute to COVID-19-related cardiac dysfunction. Results: We used the viral dsRNA mimetic polyinosinic: polycytidylic (PIC) to induce a type I interferon response in iPSC-CM or A549 (lung epithelial) cells. In iPSC-CM, PIC induced robust protein expression of STAT1/pSTAT1, OAS2, OAS3, IRF7, pIRF7, IRF9 and MX1. A marked increase in cytokine protein secretion was also observed, with significant increases in CXCL-10 (~160 fold), IL6, CCL5 (~20-fold) IL8 (15-fold), and CXCL1 (~10-fold), and a 2-5-fold increase in ~30 other cytokines. Negative effects on excitation-contraction coupling were observed after 72 hours of PIC treatment, manifested as a 25% reduction in iPSC-CM Ca2+ transient amplitude. Microelectrode array analysis of iPSC-CM monolayers revealed electrophysiological dysfunction: PIC treatment increased cardiac field potential duration and spike amplitude, but reduced beat periods. A549 cells also showed increases in interferon pathway genes (STAT1, pSTAT1, IRF3, pIRF3, OAS1,2,3 and IFNb1), along with increased rates of RNA degradation after PIC treatment, consistent with activation of the OAS/RNAseL dsRNA sensor pathway. PIC-treated A549 cells also showed a large decrease in oxidative phosphorylation (maximal respiration and spare respiratory capacity), which was prevented by the mitochondrial antioxidant, mitoTEMPO. Conclusions: Activation of the viral dsRNA innate immune sensor pathway, even in the absence of active cardiac viral replication, might contribute to mitochondrial and cardiac dysfunction in COVID-19.