Isolation and characterization of chicken hypothalamic luteinizing hormone-releasing hormone

A peptide having gonadotropin-releasing activity was isolated in a yield of 2.5 μg from an extract of 2,000 chicken hypothalami. The biopotency was monitored using rat anterior pituitary cell culture system. The peptide differs from mammalian Luteinizing Hormone-Releasing Hormone (LH-RH) in its behavior during chromatographic separation (ionexchange and high performance liquid chromatography) and in its reaction towards anti-LH-RH antiserum directed against the C-terminal region of the LH-RH molecule. The peptide (chicken LH-RH) stimulates secretion of both LH and FSH from rat anterior pituitary cells. The biological potency of this peptide was about 4 % of that of the authentic decapeptide estimated in the rat anterior pituitary system. The amino acid composition is (Ser, Pro, Glx₂, Gly₂, Leu, Tyr, His, Trp), which differs from mammalian LH-RH only in that one Arg residue is replaced by a Glx residue. Based on the behavior on CM cellulose chromatography and the reaction towards anti-LH-RH antiserum, one possible structural candidate for this peptide (chicken LH-RH) is [Gln⁸]-LH-RH.     

Substrate specificity of peptidases catalyzing LH-RH degradation in hypothalamus, liver and heart of rat]

Degradation of [125I]-LH-RH by peptidases of hypothalamus, liver and heart of the rat and the effects of LH-RH, LH-RH antagonist D-Phe2-Phe3-D-Phe6-LH-RH, LH-RH5-10, oxytocin, bradikinin, thyrotrophin-releasing hormone, melanocyte-inhibiting factor, luteinizing, follicle-stimulating, lactogenic and growth hormones were studied. It was shown that the degradation was inhibited with maximal efficiency by non-labelled LH-RH (Ki = 1,7--2,0 . 10(-6) M). This observation is indicative of peptidase specificity for LH-RH. It is assumed that specific peptidases of liver and heart are involved in the reglation of LH-RH concentration in these organs.     

Synthetic glucagon antagonists and partial agonists.

This paper reports the synthesis and the biological activities of six new glucagon analogues. In these compounds N-terminal modifications of the glucagon sequence were made, in most cases combined with changes in the C-terminal region which had been shown previously to enhance receptor affinity. The design of these analogues was based on [Lys17,18,Glu21]glucagon,1 a superagonist, which binds five times better than glucagon to the glucagon receptor, and on the potent glucagon antagonist [D-Phe4,Tyr5,Arg12]glucagon, which does not stimulate adenylate cyclase system even at very high concentrations. The N-terminal modifications involved substitution of His1 by the unnatural conformationally constrained residue, 4,5,6,7-tetrahydro-1H-imidazo[c]pyridine-6-carboxylic acid (Tip) and by desaminohistidine (dHis). In addition we prepared two analogues (6 and 7), in which we deleted the Phe6 residue, which was suggested to be part of a hydrophobic patch and involved in receptor binding. The following compounds were synthesized: [Tip1, Lys17,18,Glu21]glucagon (2); [Tip1,D-Phe4,Tyr5,Arg12,Lys17,18,Glu21]glucagon (3); [dHis1,D-Phe4,Tyr5,Arg12,Lys17,18,Glu21]glucagon (4); [dHis1,Asp3,D-Phe4,Tyr5,Arg12,Lys17,18,Glu21+ ++]glucagon (5); des-Phe6-[Tip1,D-Phe4,Tyr5,Arg12,Glu21]glucagon (6); des-Phe6-[Asp3,D-Phe4,Tyr5,Arg12,Glu21]glucagon (7). The binding potencies of these new analogues relative to glucagon (= 100) are 3.2 (2), 2.9 (3), 10.0 (4), 1.0 (5), 8.5 (6), and 1.7 (7). Analogue 2 is a partial agonist (maximum stimulation of adenylate cyclase (AC) approximately 15% and a potency 8.9% that of glucagon, while the remaining compounds 3-7 are antagonists unable to activate the AC system even at concentrations as high as 10(-5) M. In addition, in competition experiments, analogues 3-7 caused a right-shift of the glucagon stimulated adenylate cyclase dose-response curve.(ABSTRACT TRUNCATED AT 250 WORDS)     

Evidence that chicken hypothalamic luteinizing hormone-releasing hormone is [Gln8]-LH-RH

As previously reported, chicken LH-RH has been purified in a yield of ca. 2.5 micrograms from 2,000 chicken hypothalmi, and we have estimated its chemical structure to be [Gln8]-LH-RH (1). Based on our previous observation (1), [Gln8]-LH-RH and [Glu8]-LH-RH have been synthesized by the solution method for the purpose of the structural confirmation. Synthetic [Gln8]-LH-RH was confirmed to be identical to natural chicken LH-RH on a HPLC system. For further structural confirmation, chymotryptic and thermolytic peptides from synthetic [Gln8]-LH-RH and natural chicken LH-RH were also identified. Thus, these studies support the view that chicken LH-RH has the following structure; pGlu-His-Trp-Ser-Tyr-Gly-Leu-Gln-Pro-Gly-NH2, [Gln8]-LH-RH. The gonadotropin releasing potency of synthetic [Gln8]-LH-RH was also in a good agreement with that of natural preparation.     

Parellel inhibition of LH-RH-induced cyclic AMP accumulation and LH and FSH release by LH-RH antagonists in vitro.

The relative potencies of seven antagonists of LH-RH to inhibit LH-RH-induced cyclic AMP accumulation and LH and FSH release were measured using rat hemipituitaries in vitro. At appropriate concentrations, [Des-His2, D-Ala6] LH-RH, [Des-His2, D-Ala6, des-Gly-NH210] LH-RH ethylamide, [Des-His2, D-Leu6] LH-RH, [D-Phe2] LH-RH, [Des-His2, Des-Gly-NH210] LH-RH propylamide, [D-Phe2, D-Leu6] LH-RH and [D-Phe2, D-Phe6] LH-RH led to parallel inhibition of cyclic AMP accumulation and LH and FSH release. [D-Phe2, D-Leu6] LH-RH and [D-Phe2, D-Phe6] LH-RH can inhibit 50% of LH-RH action at molar ratios of 100 and 30, respectively. These findings of parallel changes of cyclic AMP levels and LH and FSH release add strong support to the already obtained evidence for a mediator role of the adenylate cyclase system in the action of LH-RH in the anterior pituitary gland.     

Synthesis and biological properties of (Leu-6)-LH-RH and (D-Leu-6,desGly-NH210)-LH-RH ethylamide

[Leu⁶,desGly-NH₂¹⁰]-LH-RH ethylamide and [Leu⁶]-LH-RH, two analogs of LH-RH, were prepared by the solid phase method. LH- and FSH-releasing activity of these peptides was assayed against LH-RH by subcutaneous administration in immature male rats. When the integrated levels of LH and FSH over a 6 hr period after the injection were used as parameter of the LH- and FSH-releasing activities, the [Leu⁶]-LH-RH showed LH-releasing activity of 9 times and FSH-releasing activity of 5 times greater than that of LH-RH. [Leu⁶,desGly-NH₂¹⁰]-LH-RH ethylamide showed LH- and FSH-releasing activities of 53.6 and 14.5 times greater, respectively, than that of LH-RH.     

Antitumor effects of analogs of LH-RH and somatostatin: Experimental and clinical studies

Many clinical approaches for the treatment of hormone-sensitive tumors are being developed based on analogs of LH-RH and somatostatin. Inhibition of the pituitary-gonadal axis forms the basis for oncological applications of LH-RH agonists like [ -Trp⁶]-LH-RH and new LH-RH antagonists free of edematogenic effects such as [Ac- -Nal(2)¹- -Phe(4Cl)²- -Pal(3)³, -Cit⁶, -Ala¹⁰]-LH-RH (SB-75). Agonists and antagonists of LH-RH have been used in patients with prostate cancer and might be also beneficial for the treatment of breast cancer and ovarian, endometrial and pancreatic carcinomas. Some of the effects of LH-RH analogs can be due to direct action since LH-RH receptors have been found in these cancers. The use of sustained delivery systems based on microcapsules of PLG, makes the treatment more efficacious. Octaeptide analogs of somatostatin such as -P s-Trp-NH₂ (RC-160) and related analogs were designed specifically for antitumor activity. These somatostatin analogs, by virtue of having a wide spectrum of activities appear to inhibit various tumors through multiple mechanisms. Direct antiproliferative actions of somatostatin analogs appear to be mediated by specific receptors located on tumor cells. High affinity binding sites for RC-160 and related analogs have been found in human pancreatic, prostate, breast and ovarian cancers and brain tumors such as meningiomas. In vivo administration of analog RC-160 inhibits the growth of Dunning R-3327 prostate cancers in rats, MXT mammary tumors in mice and BOP-induced ductal pancreatic cancers in hamsters. Combination of microcapsules of RC-160 with [ -Trp⁶]-LH-RH results in synergistic potentiation of the inhibition of these cancers. Somatostatin analog RC-160 and LH-RH antagonist SB-75 are the object of further experimental studies and clinical trials aimed at the exploration of their inhibitory effects on the processes of malignant growth.     

Synthesis and biological activities of analogs of luteinizing hormone-releasing hormone (LH-RH) substituted in position 1 or 2

Syntheses are described of [Pro¹]-LH-RH, [Orotic acid¹]-LH-RH, [Glu¹]-LH-RH, [Ser²]-LH-RH, [Leu²]-LH-RH, [Gln²]-LH-RH and [Phe²]-LH-RH. The LH-releasing hormone (LH-RH) activity of each of these peptides was compared with that of natural LH-RH $\text{in vivo}$. [Glu¹]-LH-RH and [Phe²]-LH-RH had significant LH-RH activity, while all the other analogs possessed extremely low activities. These findings are briefly discussed in the light of the structure-activity relationship for LH-RH.     

Syntheses and biological evaluation of analogs of luteinizing hormone-releasing hormone (LH-RH) modified in position 2, 3, 4 or 5

Syntheses by the conventional methods as well as the chemical, physical and biological properties are described of the following analogs of the LH-releasing hormone (LH-RH): [Leu³]-LH-RH, [Phe³]-LH-RH, [Trp²] [His³]-LH-RH, Des-Trp³-LH-RH, Des-His²-[Phe⁵]-LH-RH, [Ala⁴]-LH-RH, [Phe⁵]-LH-RH and [Ala⁴] [Phe⁵]-LH-RH. $\text{In vivo}$ assays showed that [Leu³]-LH-RH did not release LH in doses as high as 5 – 25 μg, having less than 0.0008% of LH-RH activity, while [Phe³]-LH-RH had 0.43% of the LH-RH activity of natural LH-RH. The LH-RH activities of [Trp²] [His³]-LH-RH, Des-Trp³-LH-RH and Des-His²-[Phe⁵]-LH-RH were extremely low. On the other hand, [Ala⁴]-LH-RH, [Phe⁵]-LH-RH and [Ala⁴] [Phe⁵]-LH-RH had significant LH-RH activity. The structure-activity relationship of LH-RH is discussed on the basis of these findings.     

Luteinizing hormone-releasing hormone analogs with increased anti-ovulatory activity

A series of LH-RH antagonist analogs has been developed in which inhibitory activities have been increased to a potentially clinically useful level. The new peptides, which are typified by [N-acetyl-D-p-Cl-Phe^1,2, D-Trp³, D-Phe⁶,D-Ala¹⁰]-LH-RH and [N-acetyl-D-Trp^1,3,D-p-Cl-Phe²,D-Phe⁶, D-Ala¹⁰]-LH-RH, most importantly contain new modification to positions 1, 2 and 10, and induce full blockade of ovulation at single doses as low as 10 μg per rat (50 μg/kg). Various ring substituents on D-Trp or D-Phe in position 1 or other D-amino acid replacements in position 10 did not significantly improve anti-ovulatory activity. Incorporation of N-Me-Leu in position 7 was slightly detrimental to activity.     

Reduction of LH-RH pituitary and estradiol uterine binding sites by a superactive analog of luteinizing hormone-releasing hormone

The ability of the Luteinizing Hormone-Releasing Hormone (LH-RH) analogs to displace LH-RH from its pituitary receptors was evaluated $\text{in}\text{vitro}$. The two superactive analogs tested showed higher potency than the antagonists and LH-RH itself, D-Trp⁶-LH-RH being the most potent. The LH-RH specific binding activity in the pituitary fluctuated throughout the age of the rats. The highest number of LH-RH binding sites were seen on day 35 of age (276 fmol × 10^?2/pit) and an increment was induced by 0.05 μg D-Trp⁶-LH-RH (400 fmol × 10^?2/pit). However, 1 μg D-Trp⁶-LH-RH reduced the binding of LH-RH at all the times studied. In the control animals the number of estradiol binding sites increased on day 42 of age, and 0.05 μg D-Trp⁶-LH-RH augmented them on day 35 of age. On the contrary, 1 μg D-Trp⁶-LH-RH diminished the estradiol uterine receptors at all the times studied. Similar results were obtained in the ovariectomized-hypophysectomized rats on day 35 of age. Our studies demonstrated a biphasic action of D-Trp⁶-LH-RH on LH-RH pituitary receptors and a direct effect on uterus which could be mediated through the uterine estradiol receptors.     

Use of a double-headed peptide substrate to study the specificity of cAMP-dependent protein kinase and posphorylase kinase.

A peptide containing 2 seryl residues, (1)Leu(2)Ser(3)Tyr(4)Arg(5)Aly(6)Tyr(7)Ser(8)Leu, was chemically synthesized and used as a substrate for phosphorylase kinase and cyclic AMP-dependent protein kinase. The sequence, TryArgGlyTyr, makes up a beta turn in the native protein. Phosphorylase kinase was found to phosphorylate specifically seryl residue2 and protein kinase seryl residue7. Km and Vmax values were obtained and compared with natural substrates. The differences in the specificity of the two enzymes might be explained by a different requirement for organized structure. As a working hypothesis, it is suggested the results could be explained if the two enzymes interacted with seryl residues at different sides of a beta turn.     

Inactivation of two hyperactive LH-RH analogues by rat hypothalamic peptidases.

Hyperactive analogues of luteinizing hormone-releasing hormone (LH-RH) are beleived to derive their properties from either increased binding affinity to anterior pituitary receptor sites or through decreased susceptibility to enzymic degradation. To investigate the latter suggestion and to examine the possible sites of hypothalamic peptidases inactivating LH-RH, D-Ser(TBU)6-EA10-LH-RH and D-Leu6-EA10-LH-RH, which are known to have considerably greater activity than LH-RH, were incubated with a hypothalamic supernatant fraction containing active peptidases degrading LH-RH, and their gonadotrophin-releasing ability after incubation with the enzymes was tested in normal, adult male rats; LH-RH was also tested in the same way. From a comparison of the relative losses of biological activity, both the LH-RH analogues treated proved to be more resistant to the hypothalamic peptidases than LH-RH itself; the D-Leu6-EA10-LH-RH retained its gonadotrophin-releasing activity longer than the D-Ser(TUB)6-EA10-LH-RH. These findings indicate that increased activity of the analogues may, in part be due to increased resistance to enzymic inactivation and suggest initial sites of cleavage at the Gly-leu and Pro-Gly NH2 bonds in the LH-RH decapeptide by the hypothalamic enzymes. Studies on the action of peptidases on LH-RH and its analogues may yield useful information in the design of peptidase with increased biological activity.     

Design and synthesis of glucagon partial agonists and antagonists

The hyperglycemia and ketosis of diabetes mellitus are generally associated with elevated levels of glucagon in the blood. This suggests that glucagon is a contributing factor in the metabolic abnormalities of diabetes mellitus. A glucagon-receptor antagonist might provide important evidence for glucagons's role in this disease. In this work we describe how we combined structural modifications that led to glucagon analogues with partial agonist activity to give glucagon analogues that can act as competitive antagonists of glucagon-stimulated adenylate cyclase activity. Using solid-phase synthesis methodology and preparative reverse-phase high-performance liquid chromatography, we synthesized the following seven glucagon analogues and obtained them in high purity: [D-Phe4,Tyr5,Arg12]glucagon (2); [D-Phe4,Tyr5,Lys17,18]glucagon (3); [Phe1,Glu3,Lys17,18]glucagon (4); [Glu3,Val5,Lys17,18]glucagon (5); [Asp3,D-Phe4,Ser5,Lys17,18]glucagon (6); I4-[Asp3,D-Phe4,Ser5,Lys17,18]glucagon (7); [Pro3]glucagon (8). Purity was assessed by enzymatic total hydrolysis, by chymotryptic peptide mapping, and by reverse-phase high-performance liquid chromatography. The new analogues were tested for specific binding, for their effect on the adenylate cyclase activity in rat liver membranes, and for their effect on the blood glucose levels in normal rats relative to glucagon. Analogues showing no adenylate cyclase activity were examined for their ability to act as antagonists by displacing glucagon-stimulated adenylate cyclase dose-response curves to the right (higher concentrations). The binding potencies of the new analogues relative to glucagon (= 100) were respectively 1.0 (2), 1.3 (3), 3.8 (4), 0.4 (5), 1.3 (6), 5.3 (7), and 3 (8). Glucagon analogues 3-5 and 8 were all weak partial agonists with EC50 values of 500 (3), 250 (4), 1600 (5), and 395 nM (8), respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Binding capacity of luteinizing hormone-releasing hormone and its analogues for pituitary receptor sites.

Competition for luteinizing hormone-releasing hormone (LH-RH) receptor sites by the inhibitory analog [D-Phe², D-Trp³, D-Phe⁶]-LH-RH and by the superactive stimulatory analog [D-Trp⁶]-LH-RH was observed in adenohypophysial homogenates incubated at 4°C. Competition for LH-RH binding sites was less evident with adenohypophysial plasma membranes. The binding affinities of these analogues to LH-RH pituitary receptors can explain at least in part their respective action in blocking ovulation and in inducing a greater release of luteinizing hormone and follicle stimulating hormone than the parent hormone.     

Analogues of luteinizing hormone-releasing hormone (LH-RH) containing dehydroalanine in 6th position

(Phe5, delta Ala6)-LH-RH and des-Gly10(Phe5, delta Ala6)-LH-RH ethylamide, two analogues of luteinizing hormone-releasing hormone (LH-RH), have been synthesised using fragment condensation approach in solution phase with minimum protection of the side chains. The presence of dehydroalanine in peptide fragments was confirmed by 1H n.m.r. and chemical analysis. Both the analogues were found to be inactive in comparison to LH-RH, indicating that alpha,beta-dehydrogenation of alanine in 6th position is not tolerated and suggesting that flexibility at this position may be crucial for the retention of biological activity.     

Comparative structure-activity studies on mammalian [Arg8] LH-RH and chicken [Gln8] LH-RH by fluorimetric titration

Fluorimetric titrations of mammalian [Arg8] LH-RH, chicken [Gln8] LH-RH and an analogue [Lys8] LH-RH revealed pK values of 5.80, 6.22 and 6.01 for His2, and 9.65, 9.88 and 9.88 for Tyr5. The titration ranges for His2 were 1.72, 2.03 and 1.71 while the range for Tyr5 was rather similar (approximately 1.7) for all three peptides. Biological activity and receptor binding in the mammalian system for chicken LH-RH was 1% relative to mammalian LH-RH while [Lys8] LH-RH had a relative activity of approximately 10%. In contrast, mammalian and chicken LH-RH were equipotent in stimulating LH release from chicken pituitary cells. The results indicate differences in the receptors related to the conformations of LH-RH and position 8-substituted analogues.     

LH-releasing activity of potent LH-RH analogs in vitro

The LH-releasing activity of eight superactive analogs of LH-RH was measured in pituitary cells in primary culture. Introduction of the C-terminal ethylamide modification into [D-Ala⁶]- and [D-Leu⁶]-LH-RH (two peptides already 3 times more active than LH-RH) increases their activities 10-fold. [D-Phe⁶]- and [D-Trp⁶]-LH-RH are 90 and 100 times more active than LH-RH, respectively. The ethylamide derivatives of these two compounds are however approximately six times less active than the parent peptides.     

Metabolism of bradykinin analogs by angiotensin I converting enzyme and carboxypeptidase N.

Bradykinin (BK) analogs such as Lys-Lys-BK, des-Arg9-BK and [Leu8]des-Arg9-BK were poor substrates for angiotensin I converting enzyme (ACE), and analogs containing D-Phe7 residues, or a pseudopeptide C-terminal bond, were completely resistant. However, many of these analogs were metabolized by carboxypeptidase N (CPN) including Lys-Lys-BK, [Tyr8(OMe)]BK and D-Phe7-containing analogs, with Km and Vmax values comparable to those for BK. The only analogs completely resistant to both ACE and CPN were the B2 agonist [Phe8 psi(CH2NH)Arg9]BK, the B2 agonist D-Arg[Hyp3,D-Phe7,Phe8 psi(CH2NH)Arg9]BK, and the B1 agonist [D-Phe8]des-Arg9-BK. These data indicate an important role for plasma CPN and vascular CPN-like activity in the metabolism of the widely used ACE-resistant/D-Phe7-containing antagonists of B2 kinin receptors.     

Different structural requirements for melanin-concentrating hormone (MCH) interacting with rat MCH-R1 (SLC-1) and mouse B16 cell MCH-R

Melanin-concentrating hormone (MCH) is a neuropeptide occurring in all vertebrates and some invertebrates and is now known to stimulate pigment aggregation in teleost melanophores and food-intake in mammals. Whereas the two MCH receptor subtypes hitherto cloned, MCH-R1 and MCH-R2, are thought to mediate mainly the central effects of MCH, the MCH-R on pigment cells has not yet been identified, although in some studies MCH-R1 was reported to be expressed by human melanocytes and melanoma cells. Here we present data of a structure-activity study in which 12 MCH peptides were tested on rat MCH-R1 and mouse B16 melanoma cell MCH-R, by comparing receptor binding affinities and biological activities. For receptor binding analysis with HEK-293 cells expressing rat MCH-R1 (SLC-1), the radioligand was [125I]-[Tyr13]-MCH with the natural sequence. For B16 cells (F1 and G4F sublines) expressing B16 MCH-R, the analog [125I]-[D-Phe13, Tyr19]-MCH served as radioligand. The bioassay used for MCH-R1 was intracellular Ca2+ mobilization quantified with the FLIPR instrument, whereas for B16 MCH-R the signal determined was MAP kinase activation. Our data show that some of the peptides displayed a similar relative increase or decrease of potency in both cell types tested. For example, linear MCH with Ser residues at positions 7 and 16 was almost inactive whereas a slight increase in side-chain hydrophilicity at residues 4 and 8, or truncation of MCH at the N-terminus by two residues hardly changed binding affinity or bioactivity. On the other hand, salmonic MCH which also lacks the first two residues of the mammalian sequence but in addition has different residues at positions 4, 5, 9, and 18 exhibited a 5- to 10-fold lower binding activity than MCH in both cell systems. A striking difference in ligand recognition between MCH-R1 and B16 MCH-R was however observed with modifications at position 13 of MCH: whereas L-Phe13 in [Phe13, Tyr19]-MCH was well tolerated by both MCH-R1 and B16 MCH-R, change of configuration to D-Phe13 in [D-Phe13, Tyr19]-MCH or [D-Phe13]-MCH led to a complete loss of biological activity and to a 5- to 10-fold lower binding activity with MCH-R1. By contrast, the D-Phe13 residue increased the affinity of [D-Phe13, Tyr19]-MCH to B16 MCH-R about 10-fold and elicited MAP kinase activation as observed with [Phe13, Tyr19]-MCH or MCH. These data demonstrate that ligand recognition by B16 MCH-R differs from that of MCH-R1 in several respects, indicating that the B16 MCH-R represents an MCH-R subtype different from MCH-R1.