Javier Sueiras-Diaz

Super-active analogs of growth hormone-releasing factor (1–29)-amide

Human pancreatic growth hormone releasing factor (1-29)-amide [hpGRF (1-29)-NH2] and the following analogs: [D-Tyr-1]-hpGRF(1-29)-NH2, [D-Ala-2]-hpGRF(1-29)-NH2, [D-Asp-3]-hpGRF(1-29)-NH2, and [N-Ac-Tyr-1]-hpGRF (1-29)-NH2 were synthesized using solid phase methodology and tested for their ability to stimulate growth hormone (GH) secretion in the rat and the pig in vivo. [D-Ala-2]-hpGRF (1-29)-NH2 was approximately 50 times more potent than the parent molecule in eliciting GH secretion in the rat. The other analogs were less active, but all were more potent than the 1-29 amide in the rat. [D-Tyr-1]-hpGRF(1-29)-NH2 was 10 times more potent, [D-Asp-3]-hpGRF(1-29)-NH2 7 times more potent, and the acetylated molecule approximately 12 times more potent than hpGRF(1-29)-NH2.

Somatostatin antagonist analog increases GH, insulin, and glucagon release in the rat

We have utilized the relative structural simplicity of several short, cyclic, highly active somatostatin analogs in the search for competitive antagonists of somatostatin. During an attempted synthesis of cyclo(7-aminoheptanoyl-Phe-D-Trp-Lys-Thr), catalytic hydrogenation of the protected peptide intermediate unexpectedly gave cyclo [7-aminoheptanoyl-Phe-D-Trp-Lys-Thr(Bzl)] in which the benzyl protecting group on Thr could not be removed even upon prolonged treatment under standard conditions. Injection of this new peptide into the rat completely blocked the inhibitory effects of exogenous somatostatin on GH, insulin, and glucagon release. Indeed, in fasted rats, basal hepatic portal insulin and glucagon levels were significantly increased after analog treatment. Plasma GH levels in Nembutal-anesthetized and stimulated rats were also increased after injection of the analog. These results provide strong evidence that endogenous somatostatin exerts local tonic control of pituitary and pancreatic secretions. The availability of a somatostatin anatagonist should be of considerable value in elucidating the roles of somatostatin in these and many other physiological processes.

Corticotropin Releasing Factor (CRF): Immunocytochemical localization and Radioimmunoassay (RIA)

Abstract Recent isolation, structural identification, and synthesis of ovine CRF has made possible the generation of specific antibodies against this hypothalamic peptide. Two fragments of the amino acid sequence corresponding to ovine CRF (CRF 37-41 and CRF 22-41), as well as the full sequence of 41 residues (CRF 1-41), synthesized in our laboratories by solid-phase methods, were coupled to bovine serum albumin (BSA) with glutaraldehyde. New Zealand white rabbits were immunized with the emulsified mixtures of peptide-BSA conjugates and Freunds adjuvant as immunogens. The specificity of the generated antibodies was studied by agar-gel diffusion, absorption tests in the immunohistochemical system, and with the aid of displacement curves in RIA. 125 I-Tyr(35)-CRF 36-41 and 125 I-Tyr(0)-CRF 1-41 were used as radioligands in the RIA. The minimum detectable dose was 20 pg. The linearity observed in RIA for immunoreactive CRF in extracts of rat hypothalami, together with the immunocytochemical findings in the rat brain, indicate the presence of substance(s) immunologically indistinguishable from CRF. Immunohistochemistry with the peroxidase-antiperoxidase (PAP) technique detected the following CRF-immunoreactive structures in vibratome sections of hypothalami of colchicine-treated rats: CRF-containing cell bodies were observed mainly in smaller neurons of the paraventricular nucleus. CRF-positive nerve fibers and/or terminals were present in the external zone of the median eminence, with some immunoreactive CRF also present in the internal zone. The CRF-positive terminals were localized in the central regions of the median eminence. These morphological data reinforce the view that this polypeptide plays a physiological role in the control of ACTH release.

Synthesis and biological properties of ovine corticotropin-releasing factor (CRF)

The 41-residue sequence of recently identified ovine corticotropin-releasing factor (CRF) was assembled on a benzhydrylamine resin support. Deprotection and cleavage from the resin were accomplished by HF treatment. The crude peptide was purified by gel filtration and reverse-phase, medium pressure, followed by high-performance liquid chromatography (HPLC). In addition to the usual criteria, the homogeneity of the final material, obtained in 7% yield, was assessed by the isolation and examination of cyanogen bromide cleavage and tryptic digestion fragments by HPLC and amino acid analysis. The synthetic 41 amino acid CRF stimulated the release of corticotropin (ACTH) in three in vitro systems: isolated rat pituitary quarters, monolayer cultures of dispersed pituitary cells, and superfused pituitary cells on a column, the responses being related to the log-dose of CRF in the range of 0.05-125 ng/ml. The synthetic peptide also augmented in vivo release of ACTH in rats pretreated with chlorpromazine, morphine, and Nembutal, as assessed by the measurement of serum corticosterone. The data indicates chemical purity and high biological activity of synthetic material.

Effects of secretin and gastric inhibitory polypeptide on human pancreatic growth hormone-releasing factor(1–40)-stimulated growth hormone levels in the rat

Synthetic human pancreatic growth hormone-releasing factor containing 40 amino acids ([hpGRF (1-40)]-OH) significantly stimulated plasma growth hormone (GH) levels in both sodium pentobarbital and urethane anesthetized rats. Synthetic secretin, gastric inhibitory polypeptide (GIP), and glucagon significantly decreased plasma GH levels while synthetic vasoactive intestinal peptide (VIP) had no effect. Secretin and GIP also altered the in vivo plasma GH response to [hpGRF(1-40)]-OH. Whether this effect is the result of an interaction at the pituitary level or is due to an extra-pituitary effect of secretin and GIP awaits further study.

Opposite effects of CRF and ACTH on reserpine-induced hypothermia

The effects of CRF, ACTH 1-24, alpha-MSH, and an ACTH 4-49 analog, at doses of 0, 0.1, 1, and 10 mg/kg, were tested on temperature, ptosis, and sedation in mice pretreated 18 hr previously with reserpine. IP injection of CRF at doses of 1 and 10 mg/kg significantly potentiated the reserpine-induced hypothermia while ACTH 1-24 at the same two doses had the opposite effect of significantly reversing the hypothermia as compared to diluent. The highest dose of alpha-MSH exerted a similar action to that of ACTH 1-24, but none of the doses of the ACTH 4-9 analog changed body temperature. beta-endorphin also failed to cause a reliable effect even though naloxone blocked the action of CRF on body temperature. The results suggest that CRF, like other hypothalamic peptides, can exert extra-pituitary actions after peripheral administration.

Somatostatin Agonists and Antagonists - Peptide Control of Growth Hormone Secretion

Although somatostatin itself has numerous inhibitory activities which individually are of no little therapeutic interest, there are also several types of physiological effects where it might be of even greater basic and medical value to block activity instead. Perhaps principal among these would be an ability to block the inhibitory effects of somatostatin on growth hormone (GH) release. Antibody experiments (1) have clearly shown that basal GH levels are elevated when somatostatin is neutralized. There is also an unwanted negative participation of somatostatin when GH levels are stimulated with the GH-releasing factor, GRF. In fact, one group has actually been able to demonstrate that GRF(1–44) stimulates somatostatin release from hypothalamic cells in culture (2). It should also be mentioned that both GH (3) and somatostatin (4) can alter somatostatin levels. Somatomedin C has also been implicated in the negative feedback regulation of GH, at least partially by stimulating release of somatostatin (5). Given the successes which have been achieved in the development of very potent competitive antagonists of other peptides, notably in our own experience with LH-RH, there appears to be no reason to neglect the development of a somatostatin antagonist any longer.

Synthesis and Pharmacological Characterization of Novel Glucagon-like Peptide-2 (GLP-2) Analogues with Low Systemic Clearance

Glucagon-like peptide-2 receptor agonists have therapeutic potential for the treatment of intestinal diseases. The native hGLP-2, a 33 amino acid gastrointestinal peptide, is not a suitable clinical candidate, due to its very short half-life in humans. In search of GLP-2 receptor agonists with better pharmacokinetic characteristics, a series of GLP-2 analogues containing Gly substitution at position 2, norleucine in position 10, and hydrophobic substitutions in positions 11 and/or 16 was designed and synthesized. In vitro receptor potency at the human GLP-2, selectivity vs the human GLP-1 and GCG receptors, and PK profile in rats were determined for the new analogues. A number of compounds more potent at the hGLP-2R than the native hormone, showing excellent receptor selectivity and very low systemic clearance (CL) were discovered. Analogues 69 ([Gly(2),Nle(10),D-Thi(11),Phe(16)]hGLP-2-(1-30)-NH2), 72 ([Gly(2),Nle(10),D-Phe(11),Leu(16)]hGLP-2-(1-33)-OH), 73 ([Gly(2),Nle(10),D-Phe(11),Leu(16)]hGLP-2-(1-33)-NH2), 81 ([Gly(2),Nle(10),D-Phe(11),Leu(16)]hGLP-2-(1-33)-NHEt), and 85 ([Gly(2),Nle(10),D-Phe(11),Leu(16)]hGLP-2-(1-33)-NH-((CH2)2O)4-(CH2)2-CONH2) displayed the desired profiles (EC50 (hGLP-2R) < 100 pM, CL in rat <0.3 mL/min/kg, selective vs hGLP-1R and hGCGR). Compound 73 (FE 203799) was selected as a candidate for clinical development.