Variable-length poly-C tract polymorphisms of the beta2-adrenergic receptor 3'-UTR alter expression and agonist regulation.

Beta(2)-adrenergic receptors (beta(2)-AR) expressed on airway epithelial and smooth muscle cells regulate mucociliary clearance and relaxation and are the targets for beta-agonists in the treatment of obstructive lung disease. However, the clinical responses display extensive interindividual variability, which is not adequately explained by genetic variability in the 5'-flanking or coding region of the intronless beta(2)-AR gene. The nonsynonymous coding polymorphism most often associated with a bronchodilator phenotype (Arg16) is found within three haplotypes that differ by the number of Cs (11, 12, or 13) within a 3'-untranslated region (UTR) poly-C tract.

Heterogeneity of transcription factor expression and regulation in human airway epithelial and smooth muscle cells.

Transcription factors represent a major mechanism by which cells establish basal and conditional expression of proteins, the latter potentially being adaptive or maladaptive in disease. The complement of transcription factors in two major structural cells of the lung relevant to asthma, airway epithelial and smooth muscle cells, is not known. A plate-based platform using nuclear extracts from these cells was used to assess potential expression by binding to oligonucleotide consensus sequences representing >300 transcription factors.

Allele-specific binding of airway nuclear extracts to polymorphic beta2-adrenergic receptor 5' sequence.

Like other intronless G protein-coupled receptor genes, the beta(2)-adrenergic receptor (beta(2)AR) has minimal genetic space for population variability, and has attained such via multiple coding and noncoding polymorphisms. Yet most clinical studies use the two nonsynonymous polymorphisms of the coding region for association analysis despite low levels of linkage disequilibrium with some promoter and 5'UTR polymorphisms. To assess the potential for allele-specific transcription factor binding to beta(2)AR 5'-flanking sequence, 3'-biotin-labeled oligonucleotide duplexes were synthesized.

Pleiotropic beta-agonist-promoted receptor conformations and signals independent of intrinsic activity.

Beta-agonists used for treatment of obstructive lung disease have a variety of different structures but are typically classified by their intrinsic activities for stimulation of cAMP, and predictions are made concerning other downstream signals based on such a classification. We generated modified beta(2)-adrenergic receptors with insertions of energy donor and acceptor moieties to monitor agonist-promoted conformational changes of the receptor using intramolecular bioluminescence resonance energy transfer in live cells. These studies suggested unique conformations stabilized by various agonists that were not based on their classic intrinsic activities.

Airway smooth muscle prostaglandin-EP1 receptors directly modulate beta2-adrenergic receptors within a unique heterodimeric complex.

Multiple and paradoxical effects of airway smooth muscle (ASM) 7-transmembrane-spanning receptors activated during asthma, or by treatment with bronchodilators such as beta(2)-adrenergic receptor (beta(2)AR) agonists, indicate extensive receptor crosstalk. We examined the signaling of the prostanoid-EP(1) receptor, since its endogenous agonist prostaglandin E(2) is abundant in the airway, but its functional implications are poorly defined. Activation of EP(1) failed to elicit ASM contraction in mouse trachea via this G(alphaq)-coupled receptor.

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.