Regulation of formyl peptide receptor agonist affinity by reconstitution with arrestins and heterotrimeric G proteins.

Although heptahelical chemoattractant and chemokine receptors are known to play a significant role in the host immune response and the pathophysiology of disease, the molecular mechanisms and transient macroassemblies underlying their activation and regulation remain largely uncharacterized. We report herein real time analyses of molecular assemblies involving the formyl peptide receptor (FPR), a well described member of the chemoattractant subfamily of G protein-coupled receptors (GPCRs), with both arrestins and heterotrimeric G proteins. In our system, the ability to define and discriminate distinct, in vitro receptor complexes relies on quantitative differences in the dissociation rate of a fluorescent agonist as well as the guanosine 5'-3-O-(thio)triphosphate (GTP gamma S) sensitivity of the complex, as recently described for FPR-G protein interactions. In the current study, we demonstrate a concentration- and time-dependent reconstitution of liganded, phosphorylated FPR with exogenous arrestin-2 and -3 to form a high agonist affinity, nucleotide-insensitive complex with EC(50) values of 0.5 and 0.9 microm, respectively. In contrast, neither arrestin-2 nor arrestin-3 altered the ligand dissociation kinetics of activated, nonphosphorylated FPR. Moreover, we demonstrated that the addition of G proteins was unable to alter the ligand dissociation kinetics or induce a GTP gamma S-sensitive state of the phosphorylated FPR. The properties of the phosphorylated FPR were entirely reversible upon treatment of the receptor preparation with phosphatase. These results represent to our knowledge the first report of the reconstitution of a detergent-solubilized, phosphorylated GPCR with arrestins and, furthermore, the first demonstration that phosphorylation of a nonvisual GPCR is capable of efficiently blocking G protein binding in the absence of arrestin. The significance of these results with respect to receptor desensitization and internalization are discussed.

Dexras1/AGS-1, a steroid hormone-induced guanosine triphosphate-binding protein, inhibits 3',5'-cyclic adenosine monophosphate-stimulated secretion in AtT-20 corticotroph cells.

Dexras1 is a novel GTP-binding protein that shares structural similarity with the Ras family of small molecular weight GTPases and is strongly and rapidly induced during treatment with dexamethasone. The function of Dexras1 and its contribution to glucocorticoid-dependent signaling in the corticotroph cell are unknown. The present study was undertaken to examine the potential role of Dexras1 in the regulation of peptide hormone secretion in the AtT-20 corticotroph cell line. To determine the effects of Dexras1 expressed independently of glucocorticoid treatment, expression plasmids for wild-type and constitutively active mutant Dexras1 proteins were cotransfected with human GH (hGH), which provides an ectopic marker for the stimulus-coupled secretory pathway. GTP binding properties and the GTP to GDP ratio of wild-type and mutant Dexras1 proteins were examined in transiently transfected AtT-20 and COS-7 cells. Stimulated and constitutive components of secretion were assessed after 2-h incubations with 5 mM 8-Br-cAMP or control. cAMP treatment led to a 2-fold increase in hGH secretion relative to control. Cotransfection of wild-type Dexras1 had no effect on cAMP-stimulated hGH secretion, but a constitutively active mutant, Dexras[A178V], attenuated stimulated secretion by 86% (P < 0.01). A double-mutant containing a deletion of the carboxyl terminus isoprenylation site, Dexras[A178V/C277term], did not inhibit cAMP-stimulated hGH secretion, indicating that the effect is prenylation dependent. These findings suggest that activation of Dexras1 has important functional consequences leading to inhibition of stimulus-secretion coupling in corticotroph cells. Because Dexras1 messenger RNA is strongly and rapidly induced during glucocorticoid treatment, these results raise the possibility that Dexras1 may participate in the signal transduction pathways that govern the rapid regulatory effects of glucocorticoids on peptide hormone secretion in corticotroph cells.

Real-time analysis of G protein-coupled receptor reconstitution in a solubilized system.

Receptor based signaling mechanisms are the primary source of cellular regulation. The superfamily of G protein-coupled receptors is the largest and most ubiquitous of the receptor mediated processes. We describe here the analysis in real-time of the assembly and disassembly of soluble G protein-coupled receptor-G protein complexes. A fluorometric method was utilized to determine the dissociation of a fluorescent ligand from the receptor solubilized in detergent. The ligand dissociation rate differs between a receptor coupled to a G protein and the receptor alone. By observing the sensitivity of the dissociation of a fluorescent ligand to the presence of guanine nucleotide, we have shown a time- and concentration-dependent reconstitution of the N-formyl peptide receptor with endogenous G proteins. Furthermore, after the clearing of endogenous G proteins, purified Galpha subunits premixed with bovine brain Gbetagamma subunits were also able to reconstitute with the solubilized receptors. The solubilized N-formyl peptide receptor and Galpha(i3) protein interacted with an affinity of approximately 10(-6) m with other alpha subunits exhibiting lower affinities (Galpha(i3) > Galpha(i2) > Galpha(i1) Galpha(o)). The N-formyl peptide receptor-G protein interactions were inhibited by peptides corresponding to the Galpha(i) C-terminal regions, by Galpha(i) mAbs, and by a truncated form of arrestin-3. This system should prove useful for the analysis of the specificity of receptor-G protein interactions, as well as for the elucidation and characterization of receptor molecular assemblies and signal transduction complexes.