An Ile to Met polymorphism in the catalytic domain of adenylyl cyclase type 9 confers reduced beta2-adrenergic receptor stimulation.

Adenylyl cyclase (AC) mediates signalling following activation of G(alphas)-coupled receptors such as the beta2-adrenergic receptor (beta2AR). Genetic variation in the receptor component of this pathway can alter signal transduction and the response to beta-agonists in asthma, but little is known about downstream effectors. Here, we characterize the population genomics and signalling effects of a polymorphism within the coding region of the AC9 gene that results in an Ile to Met substitution at amino acid 772 within the C1b region of the enzyme. Allele frequencies were 0.300 and 0.375 in Caucasians and Asians but were lower in African-Americans (0.163). The functional effects were studied in stably transfected HEK293 cells recombinantly expressing equivalent levels of wild-type (Ile772) and polymorphic (Met772) AC9. The polymorphic substitution results in a loss of function compared to wild-type AC9. Met772 AC9 has lower basal and beta2AR-mediated adenylyl cyclase activities compared to Ile772 AC9, as well as reduced activity following stimulation of G(alphas) by NaF. Direct stimulation of AC9 activity by Mn2+/- was also depressed in Met772 membranes, indicating decreased catalytic function, consistent with the location of residue 772. AC9 mRNA and protein were expressed in multiple human lung cell-types, including airway smooth muscle and airway epithelium. In the treatment of asthma, there is marked heterogeneity in the response to inhaled beta-agonists which is associated with polymorphisms of the beta2AR. Identification of a common AC9 variant that confers reduced enzyme activity reveals an additional polymorphism that should be considered in pharmacogenetic studies of beta-agonist therapy of asthma.

False positive non-synonymous polymorphisms of G-protein coupled receptor genes.

Polymorphisms of G-protein coupled receptor (GPCR) genes are associated with disease risk and modification, and the response to receptor-directed therapy. Genomic sequencing ( approximately 1700 automated runs) from as many as 120 chromosomes from 60 multiethnic individuals was performed to confirm non-synonymous coding polymorphisms reported in the dbSNP database from 25 randomly selected GPCR genes. These polymorphisms were in regions of the receptors responsible for structural integrity, ligand binding, G-protein coupling and phosphoregulation. However, most of these putative polymorphisms could not be confirmed (false positive rate of 68%). Based on these results, we suggest that the variability of the superfamily is not well defined, and we caution against exclusive reliance on databases for selection of candidate GPCR polymorphisms for disease association and pharmacogenetic studies.

Complex haplotypes derived from noncoding polymorphisms of the intronless alpha2A-adrenergic gene diversify receptor expression.

Alpha(2A)-adrenergic receptors (alpha(2A)AR) regulate multiple central nervous system, cardiovascular, and metabolic processes including neurotransmitter release, platelet aggregation, blood pressure, insulin secretion, and lipolysis. Complex diseases associated with alpha(2A)AR dysfunction display familial clustering, phenotypic heterogeneity, and interindividual variability in response to therapy targeted to alpha(2A)ARs, suggesting common, functional polymorphisms. In a multiethnic discovery cohort we identified 16 single-nucleotide polymorphisms (SNPs) in the alpha(2A)AR gene organized into 17 haplotypes of two major phylogenetic clades. In contrast to other adrenergic genes, variability of the alpha(2A)AR was primarily due to SNPs in the promoter, 5' UTR and 3' UTR, as opposed to the coding block. Marked ethnic variability in the frequency of SNPs and haplotypes was observed: one haplotype represented 70% of Caucasians, whereas Africans and Asians had a wide distribution of less common haplotypes, with the highest haplotype frequencies being 16% and 35%, respectively. Despite the compact nature of this intronless gene, local linkage disequilibrium between a number of SNPs was low and ethnic-dependent. Whole-gene transfections into BE(2)-C human neuronal cells using vectors containing the entire approximately 5.3-kb gene without exogenous promoters were used to ascertain the effects of haplotypes on alpha(2A)AR expression. Substantial differences (P < 0.001) in transcript and cell-surface protein expression, by as much as approximately 5-fold, was observed between haplotypes, including those with common frequencies. Thus, signaling by this virtually ubiquitous receptor is under major genetic influence, which may be the basis for highly divergent phenotypes in complex diseases such as systemic and pulmonary hypertension, heart failure, diabetes, and obesity.

Alpha2A- and alpha2C-adrenergic receptors form homo- and heterodimers: the heterodimeric state impairs agonist-promoted GRK phosphorylation and beta-arrestin recruitment.

Dimerization of seven transmembrane-spanning receptors diversifies their pharmacologic and physiologic properties. The alpha(2)-adrenergic receptor (alpha(2)AR) subtypes A and C are both expressed on presynaptic nerves and act to inhibit norepinephrine release via negative feedback. However, in vivo and in vitro studies examining the roles of the two individual alpha(2A)- and alpha(2C)AR subtypes are not readily reconciled. We tested the hypothesis that the receptors form homo- and heterodimers and that the alpha(2A)-alpha(2C) heterodimer has unique properties. SDS-PAGE of epitope-tagged receptors revealed potential oligomers including dimers. BRET of live HEK-293 cells transfected with the subtypes fused to Rluc or YFP revealed that both subtypes form dimers and the heterodimer. A lower BRET(50) for the alpha(2A)-alpha(2C) heterodimer (0.79 +/- 0.20) compared to that of the alpha(2A) or alpha(2C) homodimer (2.331 +/- 0.44 or 3.67 +/- 0.69, respectively) suggests that when both subtypes are expressed, there is a greater likelihood that the two receptors will form the heterodimer than homodimers. Co-immunoprecipitation studies confirmed homo- and heterodimer formation. The presence of the alpha(2C)AR within the heterodimer resulted in a marked reduction in the level of GRK2-mediated alpha(2A)AR phosphorylation, which was accompanied by a qualitative attenuation of beta-arrestin recruitment. Signaling of the alpha(2A)-alpha(2C) heterodimer to the beta-arrestin-dependent activation of Akt was decreased compared to that of the alpha(2A)AR homodimer, while p44/p42 MAP kinase activation was unaffected. Thus, the alpha(2C)AR alters alpha(2A)AR signaling by forming oligomers, and these complexes, which appear to be preferred over the homodimers, should be considered a functional signaling unit in cells in which both subtypes are expressed.

Polymorphisms of cardiac presynaptic alpha2C adrenergic receptors: Diverse intragenic variability with haplotype-specific functional effects.

The presynaptic alpha2C adrenergic receptors (AR) act to inhibit norepinephrine release in cardiac and other presynaptic nerves. We have recently shown that a genetic variant in the alpha2CAR coding region (Del322-325), which renders the receptor partially uncoupled from Gi, is a risk factor for heart failure. However, variability of heart failure phenotypes and a dominance of Del322-325 in those of African descent led us to hypothesize that other regions of this gene have functional polymorphisms. In a multiethnic population, we found 20 polymorphisms within 4,625 bp of contiguous sequence of this intronless gene encompassing the promoter, 5' UTR, coding, and 3' UTR. These polymorphisms occur in 24 distinct haplotypes with complex organizations, including multiple 5'-upstream polymorphisms in regions known to direct expression, a 3' UTR substitution polymorphism within an insertion/deletion sequence, and the radical coding polymorphism that deletes four amino acids. Relatively low linkage disequilibrium between many polymorphisms, few cosmopolitan haplotypes, prevalent ethnic-specific haplotypes, and substantial genetic divergence among haplotypes was noted. The dysfunctional Del322-325 allele was partitioned into multiple haplotypes, with frequencies of 48% to 2%. The functional implications of the haplotypes were ascertained by whole-gene transfections of human neuronal cells, where haplotype was significantly related (P < 0.001) to expression levels of receptor transcript and protein. Expression varied by as much as approximately 50% by haplotype, and such studies enabled haplotype clustering by phenotypic, rather than genotypic, similarities. Thus, depending on phenotype, expression-specific haplotypes may amplify, attenuate, or dominate the cardiomyopathic effect attributed to the alpha2CDel322-325 marker.