Regulatory haplotypes in ARG1 are associated with altered bronchodilator response.

RATIONALE: ß2-agonists, the most common treatment for asthma, have a wide interindividual variability in response, which is partially attributed to genetic factors. We previously identified single nucleotide polymorphisms in the arginase 1 (ARG1) gene, which are associated with ß2-agonist bronchodilator response (BDR). OBJECTIVES: To identify cis-acting haplotypes in the ARG1 locus that are associated with BDR in patients with asthma and regulate gene expression in vitro. METHODS: We resequenced ARG1 in 96 individuals and identified three common, 5' haplotypes (denoted 1, 2, and 3). A haplotype-based association analysis of BDR was performed in three independent, adult asthma drug trial populations. Next, each haplotype was cloned into vectors containing a luciferase reporter gene and transfected into human airway epithelial cells (BEAS-2B) to ascertain its effect on gene expression. MEASUREMENTS AND MAIN RESULTS: BDR varied by haplotype in each of the three populations with asthma. Individuals with haplotype 1 were more likely to have higher BDR, compared to those with haplotypes 2 and 3, which is supported by odds ratios of 1.25 (95% confidence interval, 1.03-1.71) and 2.18 (95% confidence interval, 1.34-2.52), respectively. Luciferase expression was 50% greater in cells transfected with haplotype 1 compared to haplotypes 2 and 3. CONCLUSIONS: The identified ARG1 haplotypes seem to alter BDR and differentially regulate gene expression with a concordance of decreased BDR and reporter activity from haplotypes 2 and 3. These findings may facilitate pharmacogenetic tests to predict individuals who may benefit from other therapeutic agents in addition to ß(2)-agonists for optimal asthma management. Clinical trial registered with www.clinicaltrials.gov (NCT00156819, NCT00046644, and NCT00073840).

Differential coupling of Arg- and Gly389 polymorphic forms of the beta1-adrenergic receptor leads to pathogenic cardiac gene regulatory programs.

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.

Bitransgenesis with beta(2)-adrenergic receptors or adenylyl cyclase fails to improve beta(1)-adrenergic receptor cardiomyopathy.

Cardiomyopathic effects of beta-adrenergic receptor (betaAR) signaling are primarily due to the beta(1)AR subtype. beta(1)/beta(2)AR and beta(1)/adenylyl cyclase type 5 (AC5) bitransgenic mice were created to test the hypothesis that beta(2)AR or AC5 co-overexpression has beneficial effects in beta(1)AR-mediated cardiomyopathy. In young mice, beta(1)/beta(2) hearts had a greater increase in basal and isoproterenol-stimulated contractility compared to beta(1)/AC5 and beta(1)AR hearts. By 6 months, beta(1)AR and beta(1)/beta(2) hearts retained elevated basal contractility but were unresponsive to agonist. In contrast, beta(1)/AC5 hearts maintained a small degree of agonist responsiveness, which may be due to a lack of beta(1)AR downregulation that was noted in beta(1)- and beta(1)/beta(2) hearts. However, by 9 -months, beta(1), beta(1)/beta(2), and beta(1)/AC5 mice had all developed severely depressed fractional shortening in vivo and little response to agonist. p38 mitogen activated protein kinase (MAPK) was minimally activated by beta(1)AR, but was markedly enhanced in the bitransgenics. Akt activation was only found with the bitransgenics. The small increase in cystosolic second mitochondria-derived activator of caspase (Smac), indicative of apoptosis in 9-month beta(1)AR hearts, was suppressed in beta(1)/AC5, but not in beta(1)/beta(2), hearts. Taken together, the unique signaling effects of enhanced beta(2)AR and AC5, which have the potential to afford benefit in heart failure, failed to salvage ventricular function in beta(1)AR-mediated cardiomyopathy.