Palmitoylation of human proteinase-activated receptor-2 differentially regulates receptor-triggered ERK1/2 activation, calcium signalling and endocytosis.

hPAR(2) (human proteinase-activated receptor-2) is a member of the novel family of proteolytically activated GPCRs (G-protein-coupled receptors) termed PARs (proteinase-activated receptors). Previous pharmacological studies have found that activation of hPAR(2) by mast cell tryptase can be regulated by receptor N-terminal glycosylation. In order to elucidate other post-translational modifications of hPAR(2) that can regulate function, we have explored the functional role of the intracellular cysteine residue Cys(361). We have demonstrated, using autoradiography, that Cys(361) is the primary palmitoylation site of hPAR(2). The hPAR(2)C361A mutant cell line displayed greater cell-surface expression compared with the wt (wild-type)-hPAR(2)-expressing cell line. hPAR(2)C361A also showed a decreased sensitivity and efficacy (intracellular calcium signalling) towards both trypsin and SLIGKV. In stark contrast, hPAR(2)C361A triggered greater and more prolonged ERK (extracellular-signal-regulated kinase) phosphorylation compared with that of wt-hPAR(2) possibly through Gi, since pertussis toxin inhibited the ability of this receptor to activate ERK. Finally, flow cytometry was utilized to assess the rate and extent of receptor internalization following agonist challenge. hPAR(2)C361A displayed faster internalization kinetics following trypsin activation compared with wt-hPAR(2), whereas SLIGKV had a negligible effect on internalization for either receptor. In conclusion, palmitoylation plays an important role in the regulation of PAR(2) expression, agonist sensitivity, desensitization and internalization.

The molecular cloning and functional expression of the dog CCR5.

Activation of CCR5 by specific chemokines is involved in the regulation of the immunological response of leukocytes at sites of inflammation. In addition, CCR5 serves as a fusion co-factor for macrophage-tropic strains of human immunodeficiency virus type 1 (HIV-1). Consequently, several CCR5 antagonists are currently in development for the treatment of HIV-1 infection. The dog CCR5 gene was cloned in order to characterise the chemokine binding site of the dog receptor for comparison across species. The deduced amino acid sequence of the dog CCR5 has close homology to the human receptor (80% identity). A HEK-293 cell line expressing the dog recombinant receptor was generated and immunoblot analysis with an anti-human CCR5 antibody revealed a 58kDa band in the cell lysate. In functional calcium signalling assays, the CCR5 endogenous ligands MIP-1alpha, MIP-1beta and RANTES evoked a robust response in the dog recombinant CCR5 cells. In a CRE-Luc (cAMP response element-luciferase) reporter gene assay, MIP-1beta (0.01-30nM) produced concentration-dependent inhibition of forskolin induced elevation in cAMP levels, and was equipotent in dog, human and macaque recombinant CCR5 cells (EC(50) 0.4, 0.21 and 0.47nM, respectively). These data suggest that chemokine signalling is conserved in the dog CCR5.

Inflammatory mediators modulate thrombin and cathepsin-G signaling in human bronchial fibroblasts by inducing expression of proteinase-activated receptor-4.

Human lung fibroblasts express proteinase-activated receptor-1 (PAR1), PAR2 and PAR3, but not PAR4. Because PAR2 has inflammatory effects on human primary bronchial fibroblasts (HPBF), we asked 1) whether the inflammatory mediators TNF-alpha and LPS could modify HPBF PAR expression and 2) whether modified PAR expression altered HPBF responsiveness to PAR agonists in terms of calcium signaling and cell growth. TNF-alpha and LPS induced PAR4 mRNA expression (RT-PCR) at 6 h and 24 h, respectively. TNF-alpha and LPS also upregulated PAR2 mRNA expression with similar kinetics but had negligible effect on PAR1 and PAR3. Flow cytometry for PAR1, PAR2, and PAR3 also demonstrated selective PAR2 upregulation in response to TNF-alpha and LPS. Intracellular calcium signaling to SLIGKV-NH2 (a selective PAR2-activating peptide; PAR2-AP) and AYPGQV-NH2 (PAR4-AP) revealed that TNF-alpha and LPS induced maximal responses to these PAR agonists at 24 h and 48 h, respectively. Upregulation of PAR2 by TNF-alpha heightened HPBF responses to trypsin, while PAR4 induction enabled cathepsin-G-mediated calcium signaling. Cathepsin-G also disarmed PAR1 and PAR2 in HPBF, while tryptase disarmed PAR2. Induction of PAR4 also enabled thrombin to elicit a calcium signal through both PAR1 and PAR4, as determined by a desensitization assay. In cell growth assays the PAR4 agonists cathepsin-G and AYPGQV-NH2 reduced HPBF cell number only in TNF-alpha-treated HPBF. Moreover, the mitogenic effect of thrombin (a PAR1/PAR4 agonist) but not the PAR1-AP TFLLR-NH2, was ablated in TNF-alpha-treated HPBF. These findings point to an important mechanism, whereby cellular responses to thrombin and cathepsin-G can be modified during an inflammatory response.