Abstract Body: Myocarditis is a leading cause of heart failure and sudden cardiac death. Often caused by viral infection, myocarditis is defined histopathologically as mononuclear immune infiltration in the heart muscle. While most patients recover with no long-term effects, some deteriorate rapidly. It is unknown what controls this variable susceptibility to severe disease. Without this knowledge, the ability to develop targeted therapies for acute myocarditis is limited. Previous studies utilizing mouse genetics identified a locus that controls susceptibility to viral myocarditis. Cardiomyocyte-specific kinase TNNI3K is one candidate gene within this locus, but its role in myocarditis has not been established. Importantly, millions of people throughout the world carry natural variants of TNNI3K. My overall hypothesis is that TNNI3K confers resistance to viral myocarditis in a kinase-dependent manner. In an initial study, we infected strain background-matched wild-type, Tnni3k knockout, and Tnni3k kinase-dead mice with heart-passaged coxsackievirus B3. After 10 days, during the peak of acute myocarditis, mice missing functional Tnni3k protein were found to have higher viral genomes and greater presence of immune cell markers (CD45+), clearly demonstrating the role of Tnni3k in the response to viral myocarditis. H&E-stained heart sections show large clusters of hematoxylin-stained nuclei, indicating infiltration of ventricular tissue by immune cells, with more of these clusters in Tnni3k knockout hearts. Because kinase-dead mutants are similarly compromised as fully null mice, this indicates that the kinase activity of TNNI3K is critical in the antiviral response. These results are the first demonstration of the in vivo activity of a specific gene that modifies viral myocarditis sensitivity. Future work will expand on this study by examining the effects of coxsackievirus B3 infection of Tnni3k mutant mice at early and late time points. Additionally, efforts are currently underway to identify the specific mechanisms by which TNNI3K regulates the immune response to viral infection.