Synthetic analogs of growth hormone-releasing factor with antagonistic activity in vitro

Analogs of human and rat growth hormone-releasing factor (hGRF and rGRF), related to [D-Arg2]hGRF(1-29)NH2, were synthesized by solid phase methodology. Their capacity to inhibit growth hormone secretion stimulated by hGRF(1-44)NH2 was tested on rat anterior pituitary cells in monolayer culture. Among the analogs of hGRF, [D-Arg2,29,Arg30]hGRF(1-30)NH2 showed the highest antagonistic potency of 3.64 relative to [D-Arg2]hGRF(1-29)NH2 = 1. However, the most potent analog synthesized thus far was [N-Ac-His1,D-Arg2,Ala15]rGRF(1-29)NH2, which showed a relative potency of 27.7.     

Synthesis and biological activity of novel C-terminal-extended and biotinylated growth hormone-releasing factor (GRF) analogs.

A series of novel hGRF(1-29)-NH2 analogs were synthesized and biotinylated. The immunological and biological activities of these analogs were then characterized. To distance the biotin moiety from the putative bioactive core, a C-terminal spacer arm consisting of -Gly-Gly-Cys-NH2 (-GGC) was added to hGRF(1-29)-NH2 (hGRF29) and analogs, with subsequent biotinylation performed at the cysteine residue. Neither addition of the C-terminal spacer arm nor biotinylation affected affinity of these analogs for GRF antibody. Relative to hGRF(1-44)-NH2 (hGRF44: potency = 1.0), the biotinylated analogs were equipotent in vitro to their nonbiotinylated, parent compounds: [desNH2Tyr1,D-Ala2,Ala15]hGRF29-GGC-(tpBiocyt in)-NH2 (4.7) = [Ala15]hGRF29-GGC-(tpBiocytin)-NH2 (3.9) greater than hGRF29-GGC-(tpBiocytin)-NH2 (0.8). Based upon cumulative GH release data in vivo (0-60 min postinjection), [desNH2Tyr1,D-Ala2,Ala15]hGRF29-GGC-(tpBiocyt in)-NH2, [Ala15]hGRF29-GGC-(tpBiocytin)-NH2, and hGRF29-GGC-(tpBiocytin)-NH2 displayed 8.6, 5.5, and 0.8 times, respectively, the potency of hGRF44. These in vivo potency values were not significantly different from the corresponding parent compounds (i.e., with or without the C-terminal spacer arm). In summary, biotinylated hGRF analogs have been developed that retain full immunoreactivity and potent bioactivity (in vitro and in vivo), thus permitting their use in GRF receptor isolation, ELISA, and histochemical procedures.     

Response of growth hormone release to human growth hormone-releasing factor and its analogs in the bovine

Responses of growth hormone (GH) release to synthetic human growth hormone-releasing factor (hGRF)-44-NH2 analogs were determined, and the GH-releasing potency based on dose per kg of body weight (bw) was compared with that of hGRF-44-NH2 in female dairy calves. Four- and 12-month-old calves were injected intravenously with 0.25 microgram of hGRF-44-NH2 or its analogs per kg of bw. Blood samples were collected before, and during 180 min after each injection, and plasma GH concentrations were measured by radioimmunoassay. Areas under the GH response curves for 180 min after injection of hGRF-44-NH2 and its analogs were used as an index of the GH-releasing potency of each peptide. The GH-releasing potency of hGRF(1-26)-NH2 was significantly lower than that of hGRF-44-NH2 (P less than 0.05). On the other hand, hGRF(1-29)-NH2 possessed similar potency to hGRF-44-NH2. [D-Tyr1]-hGRF-44-NH2 showed prolonged GH-releasing activity, though its potency was similar to that of hGRF-44-NH2. Also, [D-Ala2]-hGRF(1-29)-NH2 exhibited prolonged GH-releasing activity, and its potency was 2.5 (P less than 0.05) and twice (P less than 0.05) as great as that of hGRF-44-NH2 and hGRF(1-29)-NH2, respectively. These results demonstrate that the N-terminal 29 amino acid residues of hGRF possess the activity site required for full GH release in vivo, and [D-Ala2]-hGRF(1-29)-NH2 has longer and greater activity, on a dose basis, than hGRF-44-NH2 in the calves.     

Degradation of growth hormone releasing factor analogs in neutral aqueous solution is related to deamidation of asparagine residues. Replacement of asparagine residues by serine stabilizes

The incubation of a solution of the human growth hormone releasing factor analog, [Leu27] hGRF(1-32)NH2 at pH 7.4 and 37 degrees, resulted in extensive degradation of the sample. The major degradation products were identified as the peptides [beta-Asp8, Leu27] hGRF(1-32)NH2 and [alpha-Asp8, Leu27] hGRF(1-32)NH2, produced by deamidation of the Asn8 residue. When tested as growth hormone (GH) secretagogues in cultured bovine anterior pituitary cells, [beta-Asp8, Leu27] hGRF(1-32)NH2 was estimated to be 400-500 times less potent than the parent Asn8 peptide, while [alpha-Asp8, Leu27] hGRF(1-32)NH2 was calculated to be 25 times less potent than the parent Asn8 peptide. Three additional analogs of [Leu27] hGRF(1-32)NH2 containing either Ser or Asn at positions 8 and 28 were prepared and evaluated for their GH releasing activity and stability in aqueous phosphate buffer (pH 7.4, 37 degrees). Based on disappearance kinetics, [Leu27] hGRF(1-32)NH2 had a half-life of 202 h while the other analogs had the following half-lives: [Leu27, Asn28] hGRF(1-32)NH2 (150 h); [Ser8, Leu27, Asn28] hGRF(1-32)NH2 (746 h); and [Ser8, Leu27] hGRF(1-32)NH2 (1550 h). After 14 days, incubated samples of the Asn8 analogs lost GH releasing potency, while the Ser8 analogs retained full potency. The potential for loss of biological activity brought about by deamidation of other engineered peptides and proteins should be considered in their design.     

Plasma growth hormone, insulin-like growth factor-I, and milk production responses to exogenous human growth hormone-releasing factor analogs in dairy cows

Responses of plasma growth hormone (GH) and insulin-like growth factor-I (IGF-I), and milk production to subcutaneous (sc) injection(s) of two synthetic human growth hormone-releasing factor (hGRF) analogs were studied in dairy cows. Two mg of each hGRF analog dissolved in 5 ml saline per cow were injected into the shoulder area of each experimental animal, and jugular venous blood samples were collected via an indwelling catheter or by venipuncture. Plasma GH and IGF-I concentrations were measured by radioimmunoassay methods. In dry cows, the mean concentration of plasma GH after a single sc injection of hGRF analogs rose to 22.0-28.3 ng/ml at about 5 h from 1.4-1.7 ng/ml at 0 h (just before injection), and returned to the level before injection after 10-12 h. On the other hand, the plasma IGF-I began to increase after a lag of 4-6 h following a single injection of hGRF analogs, and reached maximum values of 71.1-89.4 ng/ml at 20 h from 43.7-46.4 ng/ml at 0 h. The IGF-I concentration at 24 h after a single injection of hGRF analogs was still higher than the value for the dry cows given saline. In lactating cows, the plasma concentration of GH at 2 h after daily sc injections of hGRF analogs during 14 consecutive days (an injection period) was higher than those for the lactating cows which received saline. Also, during the injection period, the concentration of IGF-I was higher in the lactating cows which received hGRF analog injections than in the cows which received saline injections. During the last 7 days of the injection period, the administration of hGRF analogs increased the mean milk yield by 11-19% in comparison with those for the saline injected cows. A positive correlation was observed between the mean plasma IGF-I concentration and the mean milk yield in the lactating cows treated with hGRF analogs throughout the injection and a postinjection (11 consecutive days after cessation of hGRF analog injection) periods. The results demonstrate that a single sc injection of hGRF analogs stimulates both GH release and the circulating level of IGF-I in dry cows, and that daily sc injections of hGRF analogs over 14 days enhance milk production, and plasma GH and IGF-I levels in lactating cows.     

Synthesis and in vitro bioactivity of C-terminal deleted analogs of human growth hormone-releasing factor

A series of C-terminal deleted analogs of human growth hormone-releasing factor (hGRF) with either an amidated or a free carboxylic acid C-terminus were synthesized by solid phase methodology. Their capacity to release growth hormone was tested on rat anterior pituitary cells in monolayer culture. A gradual decrease of bioactivity down to 23% relative to hGRF was noted when the C-terminal amino acids were deleted to hGRF (1-34)OH. Further deletions, however, did not decrease the bioactivity because the potencies of the fragments, hGRF(1-31)NH2, (1-30)NH2 and (1-29)NH2 remained at about 50% of that of hGRF. Continual deletion of residues to hGRF(1-23)NH2, (1-22)NH2 and (1-21)NH2 still yielded bioactive fragments with full intrinsic activity despite very low potency. Only with the deletion down to hGRF(1-19)NH2 did the bioactivity completely disappear. Thus, together with the data published in a previous paper (1), the minimal biologically active core of hGRF with full intrinsic activity comprises the fragment (3-21).     

Synthesis and in vitro bioactivity of human growth hormone-releasing factor analogs substituted at position-1

Eight position-1 analogs of the 40-amino acid fragment and two position-1 analogs of human growth hormone-releasing factor were synthesized by solid phase methodology and their capacity to release growth hormone was determined using rat anterior pituitary cells in monolayer culture. Relative to hGRF(1-40)OH, which was arbitrarily assigned a potency value of 1, [D-Tyr1]hGRF(1-40)OH, [Phe1]hGRF(1-40)OH, [Trp1]hGRF(1-40)OH, [His1]hGRF(1-40)OH, [Ala1]hGRF(1-40)OH, [(-Ac)Tyr1]hGRF(1-40)OH, Arg0-hGRF(1-40)OH and Ala0-hGRF(1-40)OH have potencies of 0.022, 0.038, 0.003, 0.351, 0.010, 0.032, 0.002 and 0.007 respectively. Relative to hGRF(1-44)NH2 = 1, [(3-Me)His1]hGRF(1-44)NH2 and [(O-Me)Tyr1]hGRF(1-44)NH2 have potencies of 0.132 and 0.001 respectively. These results demonstrate the prerequisite for an aromatic residue at position-1 for potent biological activity and also suggest that the capacity for hydrogen bond formation with the first residue is required for full receptor-ligand interaction.     

The influence of albumin on vitamin D metabolism in fetal chick osteoblast-like cells

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.     

Plasma growth hormone and somatomedin-C responses to continuous growth hormone-releasing factor infusion in normal adult men

The pituitary growth hormone (GH) responses during a 20-hour iv infusion of saline or human GH-releasing factor (hGRF-44) at 40 micrograms/h, followed by an iv bolus injection of hGRF at 2 micrograms/kg body weight, were studied in four normal adult men. During saline infusion only one or two pulses of plasma GH were observed. However, during hGRF infusion up to eight or ten pulses of GH were measured with an amplitude not different from that obtained during saline infusion. The mean +/- SEM integrated amount of GH secreted was 107 +/- 38.2 ng/ml.h in response to hGRF infusion, which was greater than the value of 25.4 +/- 3.5 ng/ml.h obtained during saline infusion. Plasma somatomedin-C also increased after hGRF infusion, but not after saline. After saline or hGRF infusion most of the subjects still responded to an iv bolus injection of the peptide (2 micrograms/kg). These results indicate that hGRF infusion augments GH secretion by increasing the number, but not the amplitude of GH pulses and that the infusion does not cause the pituitary somatotrophs to lose their capacity and ability to respond to hGRF subsequently.     

Investigation of human growth hormone releasing factor in adults

A dose-effect relationship between human growth hormone (GH) releasing factor (hGRF) and GH response was demonstrated for doses ranging from 5 micrograms per subject (minimal active dose) to 40-80 micrograms per subject (minimal dose for maximal effect). Bioactivity of GH released under hGRF was proven in the Nb2 lymphoma cell multiplication assay. Unwanted effects were observed for doses equal to or larger than 150 micrograms. Pharmacokinetic parameters were calculated from the immunoreactive GRF plasma concentrations obtained after intravenous injections of various doses. The half-lives were 6.8 +/- 0.4 min and 43.2 +/- 3 min for distribution and elimination phases, respectively. Subcutaneous administration of hGRF was shown to be effective for promoting GH release, with doses higher than those required by intravenous administration. Intermittent intravenous injection of hGRF, at 3-hour intervals, resulted in a decrease in the magnitude of GH response in normal subjects.     

Human growth hormone-releasing hormone (hGH-RH; hGRF) treatment of four patients with GH deficiency

Four patients with GH deficiency aged 6-14 years old were treated with hGRF for 6 months. Before the treatment maximal plasma GH responses to 50 micrograms iv hGRF administration were 48.6, 12.1, 24.3 and 13.0 ng/ml, respectively. Human GRF was administered at a dosage of 50-100 micrograms twice a day subcutaneously. In two patients, the growth rate was increased from 2.4 and 2.0 cm/year to 8.2 and 9.8 cm/year, respectively. In the other two patients, the growth rate did not change with hGRF treatment. Plasma somatomedin C levels increased in one patient but did not change in the other three. Antibody to hGRF was observed in two patients during the treatment, but the presence of antibody did not affect the growth rate.     

Plasma growth hormone (GH) response to GH-releasing factor (SM-8144) in children of short stature and patients with GH deficiency

Synthetic human GRF (hGRF (1-44) NH2; SM-8144) was administered as an iv bolus to 141 normal children of short stature (NSC), 73 patients with severe idiopathic GH deficiency (IGD; group A), 30 patients with mild idiopathic GH deficiency (IGD; group B), 29 patients with secondary GH deficiency, 3 patients with primary hypothyroidism, 21 patients with Turner's syndrome and 25 patients with various other disease. Their height was below normal for their age and sex, and they were all below 25 years old without obesity. The maximal GH responses (M+SEM) were 39.5 +/- 2.2, 7.2 +/- 0.9, 27.2 +/- 3.7, 5.2 +/- 0.8, 9.7 +/- 4.4, 25.1 +/- 2.8 and 32.3 +/- 4.8 ng/ml, respectively (significance from the NSC, ; p less than 0.05, ; p less than 0.001). The GH responses to hGRF were greater than those elicited by standard pharmacological tests. There was a negative correlation between bone age and peak plasma GH response to hGRF in patients with idiopathic GH deficiency (IGD) but not in normal children (NSC). In twenty-two percent of the patients with IGD in group A the response was above 10 ng/ml and in 57% of the patients with IGD in group B the response was above 20 ng/ml, suggesting that a large percentage of patients with idiopathic GH deficiency lack hypothalamic GRF. The side effect of flushing was observed in 15.2% of all subjects. These results indicate the potential usefulness of hGRF (1-44) NH2 (SM-8144) in inducing GH release from the pituitary.     

Chemical synthesis of human beta-endorphin(1-27) analogs by peptide segment coupling. Leucine and glycine residues bearing thiocarboxyl functions as junctions for peptide segment coupling.

[Gly8]beta hEP(1-27)NH2 and [L-Leu8]beta hEP(1-27)NH2, two analogs of human beta-endorphin, were synthesized by both all-stepwise solid phase synthesis and peptide segment coupling. For the peptide segment coupling method, two thiocarboxyl peptides. Msc-[Gly8]beta hEP(1-8)SH and Msc-[L-Leu8]beta hEP(1-8)SH, were synthesized by standard solid phase method on 4-[alpha-(Boc-Gly-S)benzyl]phenoxyacetamidomethy-resin and 4-[alpha-(Boc-L-Leu-S)benzyl]phenoxyacetamidomethy-resin. These two thiocarboxyl peptides were coupled to H-[Lys(Cit)9,19,24]-beta hEP(9-27)NH2. [Gly8]beta hEP(1-27)NH2 and [L-Leu8]beta hEP(1-27)NH2 were obtained after removal of Msc groups and citraconyl groups from products of the segment coupling reaction. The yields of both [Gly8]beta hEP(1-27)NH2 and [L-Leu8]beta hEP(1-27)NH2 in the segment coupling reaction were approximately 18%. Less than 1% of racemization of Leu-8 occurred during coupling of Msc-[L-Leu8]beta hEP(1-8)SH to H-[Lys(Cit)9,19,24]-beta hEP(9-27)NH2. Results of amino acid composition analysis, analysis by reverse phase high pressure liquid chromatography and receptor binding activity assays of the analogs showed that peptide analogs prepared by segment coupling method and those prepared by all-stepwise solid phase synthesis were identical. Results of receptor binding activity assays suggested that the molecular charge properties of beta-endorphin(1-27) and its analogs influenced the receptor binding activity.     

Amphiphilic growth hormone releasing factor (GRF) analogs: peptide design and biological activity in vivo

The first twenty-nine amino acids of human Growth Hormone Releasing Factor (hGRF) possess a distinct amphiphilic character. This is seen as twisted hydrophobic and hydrophilic bands in the helical net projection. Four amidated analogs were designed by optimizing amphiphilic and helical potentials of the native sequence. These designed analogs, with up to eight-amino acid changes, were tested in sheep via intravenous injection. The growth hormone-stimulating activities of the analogs were significantly higher when compared to bovine Growth Hormone Releasing Factor (bGRF44-NH2). This suggests that the amphiphilic conformation of GRF(1-29) is important to the receptor.     

Evaluation of the biological potency of new agmatine analogs of growth hormone-releasing hormone in the bovine.

Four new growth hormone-releasing hormone (GHRH) analogs with C-terminal agmatine were compared with the parent human GHRH(1-29)NH2 fragment to assess their abilities to increase serum concentrations of growth hormone (GH) in the bovine. The four analogs were: [D-Ala2, Nle27] GHRH(1-28)Agm (JG-73); [desNH2-Tyr1, Ala15, Nle27] GHRH(1-28)Agm (MZ-2-51); [desNH2-Tyr1, Ala15, D-Lys21, Nle27] GHRH(1-28)Agm (MZ-2-75); and [desNH2-Tyr1, D-Lys12,21, Ala15, Nle27] GHRH(1-28)Agm (MZ-2-87). The special characteristic of all four GHRH analogs is that arginine was replaced by agmatine (Agm) in Position 29. Five pregnant Holstein cows received these peptides subcutaneously at the following doses: 0.0156, 0.0625, 0.25, 1, and 4 micrograms/kg body wt. Each cow received each analog-dose combination according to a 5 x 5 Greco-Latin square design repeated for the 5-week treatment. Each cow also received saline vehicle only at the end of the 5-week treatment. Blood samples were collected from 30 min before until 360 min after treatment injection. Total area under the GH response curves for the 6-hr sampling period for each dose of each GHRH analog was compared. There was a linear dose-dependent GH release in response to hGHRH(1-29)NH2 and its four GHRH(1-28)Agm analogs. At the dose of 0.25 micrograms/kg, two GHRH analogs, JG-73 and MZ-2-75, stimulated greater GH release than hGHRH(1-29)NH2 (P less than 0.05). No differences were seen at the two lowest doses, 0.0625 and 0.156 micrograms/kg. When both total area under the GH response curves and GH peak amplitudes for each treatment were averaged for all doses, JG-73 and MZ-2-75 stimulated greater GH release than hGHRH(1-29)NH2 (P less than 0.05). In summary, three GHRH(1-28)Agm analogs, JG-73, MZ-2-75, and MZ-2-51, were found to be 11.8, 11.3, and 6.5 times more potent, respectively, on a weight basis, than hGHRH(1-29)NH2 in stimulating the release of GH in cows.     

Production of transgenic sheep with growth-regulating genes

Pronuclei of fertilized sheep ova were injected with fusion genes consisting of the mouse metallothionein-I promotor/regulator ligated to either the structural gene for bovine growth hormone (mMTbGH) or to a minigene for human growth hormone-releasing factor (mMThGRF). From a total of 842 sheep ova injected with mMTbGH and transferred into recipient ewes, 47 lambs were born. Two of the lambs were transgenic with mMTbGH, and both had bGH mRNA present in liver, kidney, and gut. In one lamb, plasma growth hormone was as high as 700 ng/ml. From a total of 435 sheep ova injected with mMThGRF and transferred to recipients, 54 lambs were born and 9 fetuses were collected. Nine of the 63 had integrated the mMThGRF gene. One of the nine had high concentrations of immunoassayable hGRF in its plasma and high variable plasma concentrations of ovine growth hormone. The lamb that expressed the hGRF gene did not release GH in response to an hGRF challenge. Four of five fetal offspring of a nonexpressing mMThGRF transgenic ram also contained the mMThGRF gene and, like the sire, failed to express the gene as determined by either liver hGRF mRNA or by plasma hGRF. Growth of the single transgenic lamb expressing hGRF was similar to control lambs. These studies demonstrate efficient introduction of genes into the sheep genome and indicate that transgenes are expressed and heritable.     

Synthesis and biological evaluation of mouse growth hormone-releasing factor

The recently described mouse growth hormone-releasing factor (mGRF) was synthesized by the solid phase procedure, purified by 2 stages of preparative high performance liquid chromatography and fully characterized. The biologic activity of the 42-amino acid peptide (H-His-Val-Asp-Ala-Ile-Phe- Thr-Thr-Asn-Tyr- Arg-Lys-Leu-Leu-Ser-Gln-Leu-Tyr-Ala-Arg-Lys-Val-Ile-Gln-Asp-Ile-Met-Asn- Lys- Gln-Gly-Glu-Arg-Ile- Gln-Glu-Gln-Arg-Ala-Arg-Leu-Ser-OH) was assessed in primary cultures of both mouse and rat anterior pituitary cells and compared to synthetic rat (rGRF) and human (hGRF) growth hormone-releasing factors. mGRF was equipotent to rGRF in mouse somatotrophs but slightly less potent in rat somatotrophs, while hGRF was 3-5 times less potent in both rodent species.     

Somatostatin pretreatment facilitates GRF-induced GH release and increase in free calcium in pituitary cells

Somatostatin pretreatment sensitizes rat anterior pituitary to hGRF stimulation in vitro. The pretreatment (1 nM for 10 min) facilitated GH release response of dispersed rat anterior pituitary cells to hGRF (1 nM for 3 min) 2.04-fold in a perifusion system. The effect lasted even 20 min after the pretreatment. SRIF pretreatment decreased cAMP content in the cells after hGRF stimulation to 61% of the control value. When hGRF was replaced by 1 mM DBcAMP and 15 mM KCl, the pretreatment increased GH secretion 1.69- and 1.67-fold respectively. SRIF pretreatment (1 nM for 10 min) caused a larger increase in (Ca2+)i by hGRF than that of control. The effect of SRIF pretreatment facilitates GRF-induced increase in GH secretion probably through the stimulation of increase in (Ca2+)i.     

GI side-effects of a possible therapeutic GRF analogue in monkeys are likely due to VIP receptor agonist activity.

Growth hormone (GH) is used or is being evaluated for efficacy in treatment of short stature, aspects of aging, cardiac disorders, Crohn's disease, and short bowel syndrome. Therefore, we synthesized several stable growth hormone-releasing factor (GRF) analogues that could be therapeutically useful. One potent analog, [D-Ala(2),Aib(8, 18,)Ala(9, 15, 16, 22, 24-26,)Gab(27)]hGRF(1-27)NH(2) (GRF-6), with prolonged infusion caused severe diarrhea in monkeys; however, it had no side-effects in rats. Because GRF has similarity to VIP/PACAP and VIPomas cause diarrhea, this study investigated the ability of this and other GRF analogues to interact with the VIP/PACAP receptors. Rat VPAC(1)-R (rVPAC(1)-R), human VPAC(1)-R (hVPAC(1)-R), rVPAC(2)-R and hVPAC(2)-R stably transfected CHO and PANC 1 cells were made and T47D breast cancer cells containing native human VPAC(1)-R and AR4-2J cells containing PAC(1)-R were used. hGRF(1-29)NH(2) had low affinity for both rVPAC(1)-R and rVPAC(2)-R while VIP had a high affinity for both receptors. GRF-6 had a low affinity for both rVPAC(1)-R and rVPAC(2)-R and very low affinity for the rPAC(1)-R. VIP had a high affinity, whereas hGRF(1-29)NH(2) had a low affinity for both hVPAC(1)-R and hVPAC(2)-R. In contrast GRF-6, while having a low affinity for hVPAC(2)-R, had relatively higher affinity for the hVPAC(1)-R. In guinea pig pancreatic acini, all GRF analogues were full agonists at the VPAC(1)-R causing enzyme secretion. These results demonstrate that in contrast to native hGRF(1-29)NH(2,) GRF-6 has a relatively high affinity for the human VPAC(1)-R but not for the human VPAC(2)-R, rat VPAC(1)-R, rat VPAC(2)-R or rat PAC(1)-R. These results suggest that the substituted GRF analog, GRF-6, likely causes the diarrheal side-effects in monkeys by interacting with the VPAC(1)-R. Furthermore, they demonstrate significant species differences can exist for possible therapeutic peptide agonists of the VIP/PACAP/GRF receptor family and that it is essential that receptor affinity assessments be performed in human cells or from a closely related species.     

Effects of gonadotropin-releasing hormone on growth hormone secretion and gene expression in common carp pituitary

Using radioimmuno- and ribonuclease protection assays, we examined the effects of gonadotropin-releasing hormone and its analogs on the growth hormone mRNA level and growth hormone secretion in common carp (Cyprinus carpio) pituitary fragments with static incubation. After a 24 h treatment, sGnRH ([Trp(7),Leu(8)]-LHRH) and sGnRH-A ([D-Arg(6),Pro(9)]-LHRH) (0.1 nM-1 microM) elevated the GH mRNA level and stimulated the GH secretion in a dose-dependent manner, with a higher potency for sGnRH-A. In a time-course experiment, the function of sGnRH and sGnRH-A (10 nM) on GH secretion was observed after 6 h incubation, while no action on the GH mRNA level were noted until 12 h after treatment. Comparing mammalian GnRH, avian GnRH and piscine GnRH, sGnRH and sGnRH-A showed the highest potency in increasing GH mRNA level and GH-release, followed by cGnRH-II ([His(5),Tyr(8)]-LHRH), and finally LHRH and LHRH-A([D-Trp(6), Pro(9)]-LHRH). These findings, taken together, suggest that GnRH not only can influence GH release, but also play a role in the regulation of GH synthesis.