Structure-activity relationship for peptídic growth hormone secretagogues : Structure-activity relationship for peptídic growth hormone secretagogues

His-DTrp-Ala-Trp-DPhe-LysNH2, [His1,Lys6] GHRP, is a new synthetic hexapeptide which specifically elicits a dosage-related release of GH in vitro and in vivo without a concomitant release of LH, FSH, TSH, or PRL and, in limited in vivo studies, insulin or glucagon. Our results indicate that this small peptide has the attributes of a hypophysiotropic hormone. In vitro the minimum and maximum active dosages ranged from 1-10 ng/ml in the pituitary incubate assay. It was active in rats, monkeys, lambs, calves, and under special experimental conditions chicks, indicating its lack of species dependency. It was active when administered iv, sc, or ip to rats. After iv injection, GH levels rose within 2 min, peaked at +10-20 min, and by 2 h usually had returned to normal. It was not possible to directly compare the potencies of [His1,Lys6]GHRP, and the GH-releasing factors GHRF-44 and GHRF-40 after a single sc injection in rats because the time course of the GH response of these peptides was different. The GH response of [His1,Lys6]GHRP was longer in duration than either of these larger peptides. Both SRIF-14 and SRIF-28 inhibited the GH response of the hexapeptide; however, SRIF-28 was about four times more active than SRIF-14 in vitro and 7.5 times more active in vivo. When this small peptide was administered sc once or twice daily to immature rats for 9 or 25 days, the BW gain increased above the control. At the end of the weight gain studies the pituitary remained fully responsive to the peptide. Thus, [His1,Lys6] GHRP may be a valuable peptide for investigating the function of the pituitary somatotrophs and, in addition, it has the potential for increasing BW gain of a variety of normal animals by inducing GH release via a direct pituitary site of action.

Ghrelin, a novel peptide purified from the stomach, is the endogenous ligand of the growth hormone secretagogue receptor. The Ser(3) residue of ghrelin is modified with a lipid n-octanoic acid, a modification necessary for hormonal activity. To clarify the role of acyl modification and to identify the active core of ghrelin, we examined the activities of partially digested ghrelin and synthetic ghrelin derivatives. The activities confirmed that the N-terminal portion is the active core. Moreover, synthetic ghrelin derivatives demonstrated that octanoic acid is not the only modification of the Ser(3) side chain to sustain the activity of ghrelin; other acyl acid modifications maintained activity. Amino acid replacement of Ser(3) indicated that an L-configuration of the third residue is critical for ghrelin activity. In addition, more stable ether or thioether bonds are capable of replacing the octanoyl ester bond in ghrelin, advantageous for the generation of pharmaceuticals with longer stability. Copyright 2001 Academic Press.

The only molecularly identified ghrelin receptor is the growth hormone secretagogue receptor GHSR1a. Its natural ligand, ghrelin, is an acylated peptide whose unacylated counterpart (UAG) is almost inactive at GHSR1a. A truncated, nonfunctional receptor, GHSR1b, derives from the same gene. We have critically evaluated evidence for effects of ghrelin receptor ligands that are not consistent with actions at GHSR1a. Effects of ghrelin are observed in cells or tissues where the expression of GHSR1a is not detectable or after the Ghsr gene has been inactivated. In several, effects of ghrelin are mimicked by UAG, and ghrelin binding is competitively reduced by UAG. Effects in the absence of GHSR1a and sites at which ghrelin and UAG have similar potency suggest the presence of novel nonspecific ghrelin receptors (ghrelin receptor-like receptors [GRLRs]). A third class of receptor, the UAG receptors, at which UAG, but not ghrelin, is an agonist has been proposed. None of the novel receptors, with the exception of the glycoprotein CD36, which accounts for ghrelin action at a limited number of sites, have been identified. GHSR1a and GHSR1b combine with other G protein-coupled receptors to form heterodimers, whose pharmacologies differ from their components. Thus, it is feasible some GRLRs and some UAG receptors are heterodimers. Effects mediated through GRLRs or UAG receptors include adipocyte lipid accumulation, myoblast differentiation, osteoblast proliferation, insulin release, cardioprotection, coronary artery constriction, vascular endothelial cell proliferation, and tumor cell proliferation. The molecular identification and pharmacologic characterization of novel ghrelin receptors are thus important objectives.