MODELLING β2AR REGULATION

The β2 adrenergic receptor (β2AR) regulates smooth muscle relaxation in the vasculature and airways. Long- and Short-acting β-agonists (LABAs/SABAs) are widely used in treatment of chronic obstructive pulmonary disorder (COPD) and asthma. Despite their widespread clinical use we do not understand well the dominant β2AR regulatory pathways that are stimulated during therapy and bring about tachyphylaxis, which is the loss of drug effects. Thus, an understanding of how the β2AR responds to various β-agonists is crucial to their rational use. Towards that end we have developed deterministic models that explore the mechanism of drug- induced β2AR regulation. These mathematical models can be classified into three classes; (i) Six quantitative models of SABA-induced G protein coupled receptor kinase (GRK)-mediated β2AR regulation; (ii) Three phenomenological models of salmeterol (a LABA)-induced GRK-mediated β2AR regulation; and (iii) One semi-quantitative, unified model of SABA-induced GRK-, protein kinase A (PKA)-, and phosphodiesterase (PDE)-mediated regulation of β2AR signalling. The various models were constrained with all or some of the following experimental data; (i) GRK-mediated β2AR phosphorylation in response to various LABAs/SABAs; (ii) dephosphorylation of the GRK site on the β2AR; (iii) β2AR internalisation; (iv) β2AR recycling; (v) β2AR desensitisation; (vi) β2AR resensitisation; (vii) PKA-mediated β2AR phosphorylation in response to a SABA; and (viii) LABA/SABA induced cAMP profile ± PDE inhibitors. The models of GRK-mediated β2AR regulation show that plasma membrane dephosphorylation and recycling of the phosphorylated β2AR are required to reconcile with the measured dephosphorylation kinetics. We further used a consensus model to predict the consequences of rapid pulsatile agonist stimulation and found that although resensitisation was rapid, the β2AR system retained the memory of prior stimuli and desensitised much more rapidly and strongly in response to subsequent stimuli. This could explain tachyphylaxis of SABAs over repeated use in rescue therapy of asthma patients. The LABA models show that the long action of salmeterol can be explained due to decreased stability of the arrestin/β2AR/salmeterol complex. This could explain long action of β-agonists used in maintenance therapy of asthma patients. Our consensus model of PKA/PDE/GRK-mediated β2AR regulation is being used to identify the dominant β2AR desensitisation pathways under different therapeutic regimens in human airway cells. In summary our models represent a significant advance towards understanding agonist-specific β2AR regulation that will aid in a more rational use of the β2AR agonists in the treatment of asthma.

Cloning, characterization and regulation of the soluble guanylyl cyclase alpha1 and beta1 genes

Cell signaling by nitric oxide (NO) through soluble guanylyl cyclase (sGC) and cGMP production regulates physiological responses such as smooth muscle relaxation, neurotransmission, and cell growth and differentiation. Although the NO receptor, sGC, has been studied extensively at the protein level, information on regulation of the sGC genes remains elusive. In order to understand the molecular mechanisms involved at the level of gene expression, cDNA and genomic fragments of the murine sGCα1 subunit gene were obtained through library screenings. Using the acquired clones, the sGCα 1 gene structure was determined following primer extension, 3 ′RACE and intron/exon boundary analyses. The basal activity of several 5′-flanking regions (putative promoter regions) for both the α1 and β1 sGC subunits were determined following their transfection into mouse N1E-115 neuroblastoma and rat RENE1Δ14 uterine epithelial cells using a luciferase reporter plasmid. Using the sGC sequences, real-time RT-PCR assays were designed to measure mRNA levels of the sGC α1 and β1 genes in rat, mouse and human. Subsequent studies found that uterine sGC mRNA and protein levels decreased rapidly in response to 17β-estradiol (estrogen) in an in vivo rat model. As early as 1 hour following treatment, mRNA levels of both sGC mRNAs decreased, and reached their lowest level of expression after 3 hours. This in vivo response was completely blocked by the pure estrogen receptor antagonist, ICI 182,780, was not seen in several other tissues examined, did not occur in response to other steroid hormones, and was due to a post-transcriptional mechanism. Additional studies ex vivo and in various cell culture models suggested that the estrogen-mediated decreased sGC mRNA expression did not require signals from other tissues, but may require cell communication or paracrine factors between different cell types within the uterus. Using chemical inhibitors and molecular targeting in other related studies, it was revealed that c-Jun-N-terminal kinase (JNK) signaling was responsible for decreased sGC mRNA expression in rat PC12 and RFL-6 cells, two models previously determined to exhibit rapid decreased sGC mRNA expression in response to different stimuli. To further investigate the post-transcriptional gene regulation, the full length sGCα1 3′-untranslated region (3′UTR) was cloned from rat uterine tissue and ligated downstream of the rabbit β-globin gene and expressed as a chimeric mRNA in the rat PC12 and RFL-6 cell models. Expression studies with the chimeric mRNA showed that the sGCα 1 3′UTR was not sufficient to mediate the post-transcriptional regulation of its mRNA by JNK or cAMP signaling in PC12 and RFL-6 cells. This study has provided numerous valuable tools for future studies involving the molecular regulation of the sGC genes. Importantly, the present results identified a novel paradigm and a previously unknown signaling pathway for sGC mRNA regulation that could potentially be exploited to treat diseases such as uterine cancers, neuronal disorders, hypertension or various inflammatory conditions. ^