The angiotensin type 1 receptor (AT1R) and its octapeptide ligand, angiotensin II (AngII), engage multiple downstream signaling pathways, including those mediated by heterotrimeric guanosine triphosphate-binding proteins (G proteins) and those mediated by β-arrestin. Here, we examined AT1R-mediated Gα(q) and β-arrestin signaling with multiple AngII analogs bearing substitutions at position 8, which is critical for binding to the AT1R and its activation of G proteins. Using assays that discriminated between ligand-promoted recruitment of β-arrestin to the AT1R and its resulting conformational rearrangement, we extend the concept of biased signaling to include the analog's propensity to differentially promote conformational changes in β-arrestin, two responses that were differentially affected by distinct G protein-coupled receptor kinases. The efficacy of AngII analogs in activating extracellular signal-regulated kinases 1 and 2 correlated with the stability of the complexes between β-arrestin and AT1R in endosomes, rather than with the extent of β-arrestin recruitment to the receptor. In vascular smooth muscle cells, the ligand-induced conformational changes in β-arrestin correlated with whether the ligand promoted β-arrestin-dependent migration or proliferation. Our data indicate that biased signaling not only occurs between G protein- and β-arrestin-mediated pathways but also occurred at the level of the AT1R and β-arrestin, such that different AngII analogs selectively engaged distinct β-arrestin conformations, which led to specific signaling events and cell responses.
Abstract-Growth hormone-releasing peptides (GHRPs) are known as potent growth hormone secretagogues whose actions are mediated by the ghrelin receptor, a G protein-coupled receptor cloned from pituitary libraries. Hexarelin, a hexapeptide of the GHRP family, has reported cardiovascular activity. To identify the molecular target mediating this activity, rat cardiac membranes were labeled with a radioactive photoactivatable derivative of hexarelin and purified using lectin affinity chromatography and preparative gel electrophoresis. A binding protein of M r 84 000 was identified. The N-terminal sequence determination of the deglycosylated protein was identical to rat CD36, a multifunctional glycoprotein, which was expressed in cardiomyocytes and microvascular endothelial cells. Activation of CD36 in perfused hearts by hexarelin was shown to elicit an increase in coronary perfusion pressure in a dose-dependent manner. This effect was lacking in hearts from CD36-null mice and hearts from spontaneous hypertensive rats genetically deficient in CD36. The coronary vasoconstrictive response correlated with expression of CD36 as assessed by immunoblotting and covalent binding with hexarelin. These data suggest that CD36 may mediate the coronary vasospasm seen in hypercholesterolemia and atherosclerosis. Key Words: acute coronary syndromes Ⅲ growth hormone-releasing peptides Ⅲ CD36 scavenger receptor G rowth hormone-releasing peptides (GHRPs) belong to a family of small synthetic peptides modeled from Metenkephalin, which exhibit potent and dose-dependent GHreleasing activity and also significant prolactin (PRL)-and corticotropin (ACTH)-releasing effects. 1 These neuroendocrine activities of GHRPs are mediated by the Ghrelin receptor, a specific G protein-coupled receptor 2,3 that has been cloned from mammalian pituitary libraries and its subtypes identified in the pituitary gland, hypothalamus, and extra-hypothalamic brain regions by binding studies. 4 Equilibrium displacement binding assays with GHRPs in different peripheral tissues have shown specific binding sites in the heart, adrenal, ovary, testis, lung, and skeletal muscle. 5,6 Significantly, hexarelin, a hexapeptide member of the GHRPs family has been reported to feature cardiovascular activity. Long-term pretreatment of GH-deficient rats with this peptide provided protective effect on hearts from ischemia/reperfusion damages 7 and prevented alterations of the vascular endothelium-dependent relaxant function. 8 This protective effect was independent of any stimulation of the somatotropic axis, 8,9 suggesting a direct action of hexarelin on specific cardiac receptors. Our initial characterization of a putative cardiac GHRP receptor revealed the existence of a binding site for a photoactivatable derivative of hexarelin with a M r of 84 000 distinct from those identified in the pituitary. 6,10 In the present study, we report the identification of the unique GHRP binding site in the heart as CD36, a multifunctional B-type scavenger receptor. We also demonstrate that t...
An angiotensin II (AngII) peptidic analogue in which the third residue (valine) was substituted with the photoreactive p-benzoyl-L-phenylalanine (Bpa) was used to identify ligand-binding sites of the human AT(1) receptor. High-affinity binding of the analogue, (125)I-[Bpa(3)]AngII, to the AT(1) receptor heterologously expressed in COS-7 cells enabled us to efficiently photolabel the receptor. Chemical and enzymatic digestions of the (125)I-[Bpa(3)]AngII-AT(1) complex were performed, and receptor fragments were analyzed in order to define the region of the receptor with which the ligand interacts. Results show that CNBr hydrolysis of the photolabeled receptor gave a glycosylated fragment which, after PNGase-F digestion, migrated as a 11.4 kDa fragment, circumscribing the labeled domain between residues 143-243 of the AT(1) receptor. Digestion of the receptor-ligand complex with Endo Lys-C or trypsin followed by PNGase-F treatment yielded fragments of 7 and 4 kDa, defining the labeling site of (125)I-[Bpa(3)]AngII within residues 168-199 of the AT(1) receptor. Photolabeling of three mutant receptors in which selected residues adjacent to residue 168 were replaced by methionine within the 168-199 fragment (I172M, T175M, and I177M) followed by CNBr cleavage revealed that the bound photoligand (125)I-[Bpa(3)]AngII forms a covalent bond with the side chain of Met(172) of the second extracellular loop of the AT(1) receptor. These data coupled with previously obtained results enable us to propose a model whereby AngII adopts an extended beta-strand conformation when bound to the receptor and would orient itself within the binding domain by having its N-terminal portion interacting with the second extracellular loop and its C-terminus interacting with residues of the seventh transmembrane domain.
The peptide hormone angiotensin II (AngII) binds to the AT 1 (angiotensin type 1) receptor within the transmembrane domains in an extended conformation, and its C-terminal residue interacts with transmembrane domain VII at Phe-293/Asn-294. The molecular environment of this binding pocket remains to be elucidated. The preferential binding of benzophenone photolabels to methionine residues in the target structure has enabled us to design an experimental approach called the methionine proximity assay, which is based on systematic mutagenesis and photolabeling to determine the molecular environment of this binding pocket. The octapeptide hormone angiotensin II (AngII) 1 (Fig. 1A) is the active component of the renin-angiotensin system. Virtually all known physiological effects of AngII are produced through the activation of the hAT 1 receptor, which belongs to the class A rhodopsin-like family of the heptahelical G proteincoupled receptor (GPCR) superfamily (1, 2). Elucidating the stereochemistry of the ligand-receptor interaction is vital for understanding the mechanism of ligand binding, GPCR activation, and, eventually, rational drug design.In the past, much effort was devoted to identifying the domains or individual residues of a given receptor that may interact with its ligand. Most experiments to address ligandreceptor interactions were performed with series of receptor mutants to identify specific residues critical to ligand binding (3-5). It is, however, speculative to deduce precise structures of ligand-receptor interactions through mutagenesis studies alone. More direct approaches have therefore been used to study ligand-receptor interactions. Among these is photoaffinity labeling, which allows covalent incorporation of the ligand within its binding site, presumably at the contact area of the photolabel in the receptor. This ligand-receptor contact can be identified by specific enzymatic or chemical digestion of the labeled receptor (6) or by mass spectrometry (7). The binding pockets within the transmembrane domains of several bioamine receptors have been identified using this kind of approach. The adenosine A 1 receptor (8) and the  2 adrenergic receptor (9, 10) are typical examples. Peptidergic receptors such as hAT 1 and hAT 2 (11, 12), neurokinin receptors (13), and several other receptors from the secretin GPCR family B (14) have been also studied using this approach. We previously identified ligandcontact points within the second extracellular loop (ECL) and the seventh transmembrane domain (TMD) of the hAT 1 receptor (12,15,16). Although photoaffinity labeling has been widely used to study peptidergic GPCR binding pockets, generally only a single contact point between a given ligand and its cognate receptor has been identified. The resulting information does not, however, induce sufficient restrictions to generate credible GPCR structures in the ligand-bound state using homology modeling.Labeling studies using benzophenone residues have identified many ligand-receptor contact points with a surpris...
Activation of G protein-coupled receptors by agonists involves significant movement of transmembrane domains (TM) following binding of agonist. The underlying structural mechanism by which receptor activation takes place is largely unknown but can be inferred by detecting variability within the environment of the ligand-binding pocket, which constitutes a water-accessible crevice surrounded by the seven TM helices. Using the substituted cysteine accessibility method, we initially identified those residues within the seventh transmembrane domain (TM7) of wild type angiotensin II type 1 (AT 1 ) receptor that contribute to forming the binding site pocket. We have substituted successively TM7 residues ranging from Ile 276 to Tyr 302 to cysteine. Treatment of A277C, V280C, T282C, A283C, I286C, A291C, and F301C mutant receptors with the charged sulfhydryl-specific alkylating agent MTSEA significantly inhibited ligand binding, which suggests that these residues orient themselves within the water-accessible binding pocket of the AT 1 receptor. Interestingly, this pattern of acquired MTSEA sensitivity was greatly reduced for TM7 reporter cysteines engineered in a constitutively active mutant of the AT 1 receptor. Our data suggest that upon activation, TM7 of the AT 1 receptor goes through a pattern of helical movements that results in its distancing from the binding pocket per se. These studies support accumulating evidence whereby elements of TM7 of class A GPCRs promote activation of the receptor through structural rearrangements.
Hexarelin, a synthetic hexapeptide of the growth hormone-releasing peptide (GHRP) family with strong growth hormone (GH)-releasing activity, features protecting activity against postischemic ventricular dysfunction in hearts from GH-deficient and senescent rats. To document whether hexarelin action is mediated through specific cardiac receptors, perfusion of Langendorff rat hearts with hexarelin and binding studies were carried out. In the Langendorff rat heart system, hexarelin induced a dose-dependent increase in coronary perfusion pressure. Nifedipine, chelerythrine, and bisindolylmaleimide partially inhibited the vasoconstriction induced by hexarelin, suggesting that this effect was mediated at least in part by L-type Ca(2+) channels and protein kinase C. In contrast, diclofenac and 1-(7-carboxyheptyl)imidazole were without effect, suggesting that prostaglandins and thromboxanes were not involved in the coronary vasoconstriction induced by hexarelin. To characterize the hexarelin binding sites in the rat heart, [(125)I]Tyr-Bpa-Ala-hexarelin was used as photoactivatable radioligand in saturation and competitive binding studies. We specifically labeled a hexarelin receptor with an M(r) of 84 000 in rat cardiac membranes. Saturation binding curves revealed a single class of binding sites with a K(d) of 14.5 nmol/L and a density of 91 fmol/mg of protein. Competition binding studies gave an IC(50) of 2.9 micromol/L for hexarelin; MK-0677 and EP51389, both potent GH secretagogues, did not displace the binding of the photoactivatable derivative from rat cardiac membranes. Interestingly, both compounds were devoid of any vasoconstrictive activity. These results suggest the existence of a new class of hexarelin receptor in the heart, whose role in the regulation of the coronary vascular tone is yet to be determined.
We designed and synthesized a novel contrast agent (CA) to image the activity of matrix metalloproteinase-2 (MMP-2) in a tumor, noninvasively using magnetic resonance imaging (MRI). We exploited the concept of solubility-switchable CAs in the design of a protease-modulated CA (PCA), referred to as PCA2-switch. This PCA contains a paramagnetic gadolinium chelate (Gd-DOTA), which was attached to the N-terminus of a MMP-2 cleavable peptide sequence via a hydrophobic chain. The aqueous solubility of the CA depends on the presence of a polyethylene glycol chain (PEG) on the C-terminus of the peptide. Upon proteolytic cleavage of the peptide by MMP-2, the PEG chain is detached from the CA, which becomes less water soluble. This compound and control compounds were successfully tested in an animal model bearing two tumors with different levels of MMP-2 activity.
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