The beta(1)-adrenergic receptor (beta(1)AR; ADRB1) polymorphism Arg389Gly is located in an intracellular loop and is associated with distinct human and mouse cardiovascular phenotypes. To test the hypothesis that beta(1)-Arg389 and beta(1)-Gly389 alleles could differentially couple to pathways beyond that of classic G(s)-adenylyl cyclase (AC)/cAMP signaling, we performed comparative gene expression profile analyses on hearts from wild-type and transgenic mice that expressed either human beta(1)-Arg389 or beta(1)-Gly389 receptors, or AC5, sampling at an early age prior to the onset of pathological features. All three models upregulated the expression of genes associated with RNA metabolism and translation and downregulated genes associated with mitochondria and energy metabolism, consistent with shared cAMP-driven increase in cardiac contractility, protein synthesis, and compensatory downregulation of mitochondrial energy production. Both beta(1)AR alleles activated additional genes associated with other pathways. Uniquely, beta(1)-Arg389 hearts exhibited upregulated expression of genes associated with inflammation, programmed cell death, and extracellular matrix. These observations expand the scope of 7-transmembrane domain receptor signaling propagation beyond known cognate G protein couplings. Moreover, they implicate alterations of a repertoire of processes evoked by a single amino acid variation in the cardiac beta(1)AR that might be exploited for genotype-specific heart failure diagnostics and therapeutics.