Dilated cardiomyopathy (DCM), clinically characterized by contractile dysfunction and ventricular chamber enlargement, is a heterogeneous heart disease leading to progressive systolic heart failure and sudden cardiac death. The etiology of the disease is multifactorial and involves genetic factors, viral infections, autoimmune phenomena, and toxic agents. Within the last two decades, a growing body of evidence has suggested that single-gene mutations play a pivotal role in the development of familial forms of dilated cardiomyopathies. Numerous genes encoding cytoskeletal, sarcomeric, and nuclear proteins have been linked to the pathogenesis of DCM, and most of the respective mutants disrupt the structural integrity of sarcomeres in cardiac myocytes. Frequently, point mutations in cytoskeletal proteins critically diminish force generation and interfere with mechanical transduction within the contractile apparatus of the myocardium, thereby ultimately leading to impaired systolic function. However, hitherto reported sarcomeric gene defects explain the etiology of the disease only in some families, leaving other forms of DCM subentities unresolved. Since one of the major factors in DCM pathogenesis involves autoimmune-mediated damage to cardiac tissue, candidate genes that are involved in controlling immune reactions have currently come into focus in genetic research. We and others have shown that a single-nucleotide polymorphism (SNP) in the gene encoding cytotoxic T-lymphocyte antigen 4 (CTLA4) is associated with the diagnosis of DCM. Cytotoxic T-lymphocyte antigen 4 is an inhibitory receptor molecule expressed on activated T lymphocytes, where it functions as an important negative regulator of T-cell activation by competing with the costimulatory CD28 receptor to bind to B7 receptors localized on the surface of antigen-presenting cells. The observed association between CTLA4 genotypes and DCM suggests that genetic factors contribute to both unbalanced immune responses in the myocardium and the development of left ventricular dysfunction. In this review, we will briefly discuss how these findings may stimulate the search for novel DCM-associated SNPs in human genes expressed in noncardiomyocytes.