Study of species specificity in growth hormone-releasing factor (GRF) interaction with vasoactive intestinal peptide (VIP) receptors using GRF and intestinal VIP receptors from rat and human: evidence that Ac-Tyr1hGRF is a competitive VIP antagonist in the rat

In order to determine species specificity in growth hormone-releasing factor (GRF) interaction with vasoactive intestinal polypeptide (VIP) receptors, we have tested rat (r) GRF (with a His1 such as in VIP), human (h) GRF and position 1 substituted analogs of hGRF (Ala1, Ac-Tyr1, His1, Phe1, and Trp1 in the place of Tyr1) for their ability to inhibit 125I-VIP binding and to stimulate adenylate cyclase activity in human and rat intestinal epithelial membranes. We show that rGRF has a much higher affinity than hGRF for both human and rat VIP receptors. In humans, the Ki values for inhibiting 125I-VIP binding are 0.5 (VIP), 26 (rGRF), and 830 nM (hGRF). In rats the values are 0.6 (VIP), 46 (rGRF), and 1100 nM (hGRF). This is due in part to the presence of His1 in rGRF since the analog His1 hGRF has a higher affinity than hGRF in man and rat, i.e., Ki = 320 nM and 460 nM, respectively. Studies of adenylate cyclase stimulation reveal that rGRF and His1 hGRF are full VIP agonists in man and rat, whereas hGRF and its other analogs behave as partial agonists in both species. One of the hGRF analogs tested (Ac-Tyr1hGRF) is of great interest since it inhibits 125I-VIP binding to rat intestinal membranes with a Ki = 430 nM but has a negligible intrinsic activity in stimulating adenylate cyclase activity (about 6% of the efficacy of VIP). This analog does inhibit the VIP-stimulated adenylate cyclase activity in a dose-dependent manner, complete inhibition of the VIP (0.01-1 nM) effect being obtained with 30 microM analog. The Schild plot of the inhibitory effect further indicates competitive antagonism. In contrast, Ac-Tyr1hGRF is a partial VIP agonist in humans (about 20% of the efficacy of VIP). These results evidence the important role of His1 for peptide interaction with VIP receptors and provide the first example of a competitive VIP antagonist.     

Effect of lead on TRH and GRF binding in rat anterior pituitary membranes.

The effect of lead on binding of the hypothalamic peptides thyroid releasing hormone (TRH) and growth hormone releasing factor (GRF) to rat anterior pituitary receptors was examined in this study. Concentrations of lead ranging from 0.01 to 1 microM did not alter [3H]TRH binding; concentrations above 1 microM increased TRH association with pituitary receptors. A previously uncharacterized ligand, [125I]GRF (human 1-44 amide), was used to examine the binding of GRF to anterior pituitary receptors. A high affinity site (GRFH = 18.1%, KH = 11.5 pM) was displaced by human growth hormone releasing factor (hGRF) (1-44)-NH2 or hGRF (1-29)-NH2 but not by rat growth hormone releasing factor (rGRF) (1-29)-NH2. Use of this ligand also revealed a class of low affinity binding sites (GRFL = 81.9%, KL = 0.39 microM) which has not been previously described. The low affinity site could be displaced by hGRF (1-44)-NH2, hGRF (1-29)-NH2 and rGRF (1-29)-NH2. A synthetic growth hormone releasing peptide (GHRP) also interacted with the low affinity GRF binding site. Lead dose-dependently displaced the binding of [125I]GRF to its pituitary receptors. The IC50 of lead for inhibiting [125I]GRF binding was 0.195 mM added lead or 52 pM free lead. These data suggest that one mechanism by which lead may affect pituitary function is through inhibition of receptor binding.     

Pegylated peptides V. Carboxy-terminal PEGylated analogs of growth hormone-releasing factor (GRF) display enhanced duration of biological activity in vivo

In the present study, human growth hormone-releasing factor (hGRF) and analogs were successfully pegylated at the carboxy-terminus using a novel solid- and solution-phase strategy. Following synthesis, these pegylated hGRF analogs were evaluated for in vitro and in vivo biological activity. Specifically, hGRF(1-29)-NH2, [Ala¹⁵-hGRF(1-29)-NH₂, [desNH₂ 2Tyr1, o-Ala2, Ala15-hGRF(1-29)-NH2 and [His1, Val2, Gin8, Ala15, Leu27-hGRF(1-32)-OH were each C-terminally extended using a Gly-Gly-Cys-NH2 spacer (previously demonstrated not to alter intrinsic biological activity), and then monopegylated via coupling to an activated dithiopyridyl-PEG reagent. PEG moieties of 750, 2000, 5000 or 10000 molecular weight (MW) were examined to determine the effect of polymer weight on activity. Initial biological evaluations in vitro revealed that all C-terminally pegylated hGRF analogs retained high growth hormone (GH)-releasing potencies, regardless of the MW of PEG polymer employed. Two of these pegylated hGRF analogs, [desN₂Tyr, D-Ala², Ala¹⁵-hGRF(1-29)-Gly-Gly-Cys(NH₂)-S-Nle- PEG₅₀₀₀ and [His, Val², Gin⁸, Ala¹⁵, Leu²⁷-hGRF(1-32)-Gly-Cys(NH2)-S-Nle-PEG5000, were subsequently evaluated in both pig and mouse models and found to be highly potent (in vivo potency range = 12-55-fold that of native hGRF). Relative to their non-pegylated counterparts, these two pegylated hGRF analogs exhibited enhanced duration of activity. © Munksgaard 1997.     

Solid phase synthesis of human growth hormone-releasing factor analogs containing a bicyclic β-turn dipeptide

Three analogs derived from the N-terminal 29-residue fragment of human growth hormone-releasing factor (hGRF) which contained a bicyclic β-turn dipeptide (BTD) at 7-8,8-9, and 9-10 positions were synthesized by solid phase methodology to ascertain if the β-turns are important for the biological activity of hGRF and also to show the applicability of the BTD unit to solid phase synthesis. All three analogs were obtained in good yield and purity indicating that the BTD unit can be used in the usual condition of solid phase synthesis. The capacity of these analogs to release growth hormone (GH) was tested in an in vitro bioassay using rat anterior pituitary cells. All three BTD-containing analogs showed the same maximal GH secretion with parallel dose-response curves to that of hGRF(1-29)NH₂, except their relative potencies were very low.     

Non-clinical pharmacology and safety evaluation of TH9507, a human growth hormone-releasing factor analogue

TH9507, an analogue of human growth hormone-releasing factor (hGRF1-44NH2) minimally modified by addition of a trans-3-hexenoyl moiety to Tyr1 of the amino acid sequence, was found to be resistant to dipeptidyl aminopeptidase-IV deactivation. Compared to natural hGRF1-44NH2, the modification slowed the in vitro degradation of the peptide in rat, dog and human plasma and prolonged the in vivo plasma elimination kinetics of immunoreactive TH9507. Plasma growth hormone and insulin-like growth factor-1 (IGF-1) markedly increased in pigs, rats and dogs after daily repeat intravenous or subcutaneous injections of TH9507 at doses up to 600 microg/kg. Subchronic toxicity studies in rats and dogs with TH9507 treatment for up to 4 months showed a significant, but not dose-related, increase in body weight gain associated with increased biomarker response. Although TH9507 was well tolerated by both rats and dogs, a more pronounced anabolic effect and more evident (reversible) adverse effects (liver and kidney findings, anaemia, clinical chemistry changes, organ weight effects) were observed in dogs after repeat daily subcutaneous injections, which were attributed to prolonged exposure to supraphysiological levels of growth hormone and/or IGF-1. In both rats and dogs, toxicokinetic evaluations indicated that exposure to immunoreactive TH9507 was dose related after both routes of administration. The apparent elimination t1/2 in dogs ranged from 21 to 45 min. In conclusion, TH9507 is a modified hGRF peptide having enhanced potency and duration of action. The adverse treatment-related effects in dogs appear to be associated with sustained exposure to supraphysiological levels of growth hormone and IGF-1 induced by prolonged TH9507 treatment.     

Degradation of growth hormone releasing factor analogs in neutral aqueous solution is related to deamidation of asparagine residues

The incubation of a solution of the human growth hormone releasing factor analog, [Leu²⁷] hGRF(1-32)NH₂ at pH 7.4 and 37°, resulted in extensive degradation of the sample. The major degradation products were identified as the peptides [β-Asp⁸, Leu²⁷] hGRF(l-32)NH₂ and [α-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, [β-Asp⁸, Leu²⁷] hGRF(l-32)NH₂ was estimated to be 400-500 times less potent than the parent Asn⁸ peptide, while [2-Asp⁸, Leu²⁷] hGRF(l-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°). 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)NH_: (150h); [Ser⁸, Leu²⁷, Asn²⁸] hGRF(l-32)NH₂ (746h); 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.     

Affinity of human growth hormone-releasing factor (1-29)NH2 analogues for GRF binding sites in rat adenopituitary.

Previous research on growth hormone-releasing factor analogues has used pituitary cell culture assay systems to evaluate in vitro their biological activity. However, binding assay systems in which receptor affinity and peptide stability can be assessed independently have been lacking so far. Since we have recently developed a sensitive GRF binding assay with [125I-Tyr10]hGRF(1-44)NH2, this method was applied to structure-affinity studies as a first step of screening GRF analogues. Acylation of the N-terminus of hGRF(1-29)NH2 generally decreased its affinity (relative affinity to hGRF(1-29)NH2 (RA), 26-85%). Replacement of the C-terminal carboxamide by a free carboxylic function decreased affinity likely by diminishing its proteolytic stability (RA, 57%). Removal of Tyr1, Ser9, Lys12, Val13, Gly15, Gln16, or Lys21 drastically decreased its affinity (RA, less than 3%). Multiple amino acid deletions in the segment 13-21 of hGRF(1-29)NH2 also led to a loss of affinity as did replacing segment 13-15, 16-18, or 19-21 by an octanoyl moiety (RA, less than 1%). Removal of Asn8, Gln24, Asp25, Ile26, Met27, and Ser28 or Arg29 had less effect on GRF receptor affinity (RA, 5-33%). Removal of Met27 or Ser28 only slightly affected hGRF(1-29)NH2 affinity (RA, 62-78%). Altogether, these results indicate that the amino acids contained in the segment 13-21 are more important than those of 24-29 to insure high affinity receptor binding or to maintain an optimal conformation to allow GRF binding.     

Relaxations to oestrogen receptor subtype selective agonists in rat and mouse arteries

It has been recently reported that the oestrogen receptor alpha agonist PPT (4,4',4"-(4-propyl-[1H]-pyrazole-1,3,5-triyl) tris-phenol) is more potent than the oestrogen receptor beta agonist DPN (2,3-bis(4-hydroxyphenyl)-propionitrile) at producing relaxations in rat mesenteric artery. We have investigated the relaxant actions of PPT and DPN in rat and mouse aorta and mesenteric artery. In rat aortic rings contracted with KCl (40 mM), the oestrogen receptor beta agonist DPN produced significantly greater relaxations than the oestrogen receptor alpha agonist PPT. In wild-type (WT) mouse aorta, the same result was found, but in WT mouse mesenteric artery, as in rat mesenteric artery, DPN was significantly less potent than PPT in females but had similar potency to PPT in males. Relaxations to DPN also occurred in aorta from nitric oxide synthase-3-knockout (NOS-3-KO) mice, and in denuded aorta from both mouse and rat. Hence, in the mouse mesenteric artery, as in the rat mesenteric artery, PPT is at least as potent as DPN at producing relaxations; however, DPN was much more potent than PPT in the rat and mouse aorta. Effects of oestrogen receptor subtype selective agonists are tissue dependent. In addition, actions are largely endothelium-independent.     

Solution conformation of Leu27 hGRF(1-32)NH2 and its deamidation products by 2D NMR

The solution structure and helical content of a human growth hormone releasing factor analog, Leu²⁷ hGRF(1–32)NH₂ (hGRF), and its deamidation products Asp⁸ Leu²⁷ hGRF(l-32)NH₂ and isoAsp⁸ Leu²⁷ hGRF(1-32)NH₂, were determined by CD and 2D NMR. Chemical-shift assignments of ¹H NMR resonances were made from DQFCOSY, HOHAHA and NOESY spectra, and qualitative secondary structure was determined from NOESY spectra. 2D NMR studies in aqueous MeOH showed the Asn⁸, Asp⁸ and isoAsp⁸ hGRF analogs to have significant α-helical character. However, the β-linked isoAsp⁸ analog did not retain helical structure in the N-terminal region, most likely because of disruption of the hydrogen bonding pattern upon substitution of the extra methylene into the peptide backbone. The helical content, as determined by CD, was ~ 12% in 0% MeOH for all three peptides, and 77, 72 and 69% in 80% MeOH for the Asn⁸, Asp⁸ and isoAsp⁸ hGRF analogs, respectively. However, 2D NMR solution structure data indicated a decrease in helicity in the N-terminal region for the isoAsp⁸ analog when compared with the other two analogs. In the Asn⁸ and Asp⁸ hGRF analogs, the helix began at Asp³ or Ala⁴, while the isoAsp⁸ analog helix was disrupted until Arg. The higher helicity value for the Asn⁸ peptide over the isoAsp⁸ analog may be associated with reported biological activity, where the in vitro activity decreased from 100 to 4 and < 1% for Asn⁸, Asp⁸ and isoAsp⁸ hGRF, respectively.     

Pharmacological characteristics of KP-102 (GHRP-2), a potent growth hormone-releasing peptide

KP-102 (D-alanyl-3-(2-naphthyl)-D-alanyl-L-alanyl-L-tryptophyl-D-phenylalanyl-L-lysinamide dihydrochloride, growth hormone-releasing peptide-2, GHRP-2, pralmorelin, CAS 158861-67-7), is a potent synthetic growth hormone (GH) secretagogue. In the present study, the pharmacological characteristics of the GH-releasing property of KP-102 were investigated by means of in vivo and in vitro experiments. In conscious rats, the GH-releasing activity of KP-102 was more potent than that of exogenously injected GH-releasing hormone (GHRH). Under pentobarbital anesthesia in which endogenous somatostatin secretion is known to be decreased, KP-102 and GHRH, both showed an almost equivalent GH-releasing potency, which was also similar to that of KP-102 in conscious rats. Besides, KP-102 showed GH-releasing activity in conscious dogs as well, while GHRH failed to increase serum GH levels in conscious dogs. These findings suggest that the GH-releasing activity of KP-102 was less sensitive to GH suppression by endogenous somatostatin as compared with that of GHRH. The GH-releasing activity of KP-102 was completely absent in hypophysectomized rats, but present in median eminence-lesioned rats in which secreted GH amounts were significantly less than those normal rats, indicating necessity of the median eminence (endogenous GHRH) to exert the full activity of KP-102 in GH stimulation. KP-102 directly stimulated GH secretion from cultured rat anterior pituitary cells, although the GH-releasing potency of KP-102 was significantly weaker than that of GHRH in vitro. In conscious rats, KP-102 stimulated the secretion of both adrenocorticotrophic hormone (ACTH) and corticosterone, but not of prolactin. Three weeks administration of KP-102 showed growth-accelerating effect, a slight increase of body weight and wet weight of some organs in both normal and monosodium glutamate (MSG)-treated rats. These results suggest that KP-102 showed specific GH-releasing activity apart from slight ACTH secretion, and that the GH-releasing activity was stable in comparison with that of exogenously injected GHRH.     

Antinociceptive action of nicotine and its methiodide derivatives in mice and rats.

Three quaternary methiodides of nicotine were prepared and tested for antinociceptive activity in the mouse tail-flick, mouse phenylquinone and rat tail-flick tests. Following peripheral administration, all three methiodides were inactive in the mouse and rat tail-flick procedures, whereas nicotine was active in both tests, which suggested that nicotine was acting centrally. Quaternization of nicotine did not eliminate antinociceptive activity as demonstrated by the intraventricular injection of the methiodides in mice. Nicotine pyrrolidine and bis methiodides were somewhat more potent than nicotine, whereas nicotine pyridine methiodide was considerably less potent than nicotine in the tail-flick procedure. Systemically administered nicotine pyrrolidine methiodine was approximately one-third as active as nicotine in the mouse phenylquinone test; nicotine pyridine methiodide and nicotine bis methiodide were 100 and 300 times less active, respectively. Hexamethonium partially blocked nicotine and nicotine pyrrolidine methiodide, whereas mecamylamine blocked nicotine completely but nicotine pyrrolidine methiodide partially. Nicotine may have both central and peripheral actions in the mouse phenylquinone test, whereas nicotine pyrrolidine methiodide may have both nicotine and non-nicotine like antinociceptive activity. The radiolabelled methiodides were synthesized and their disposition in body tissues studied. The methiodides were found to penetrate brain poorly (plasma-to-brain ratios greater than 20). The methiodides were metabolized to nicotine to a small extent. This metabolism occurred to a greater extent in mice than in rats.     

Novel hexarelin analogs stimulate feeding in the rat through a mechanism not involving growth hormone release

Growth hormone-releasing peptides (GHRPs) are a class of small peptides that stimulate growth hormone (GH) release in several animal species, including the human. Moreover, GHRPs injected into the brain ventricles stimulate feeding in the rat. The aim of this study was to evaluate the GH-releasing properties of a series of novel GHRP analogs and the possible existence of functional correlations between the GH-releasing activity and the effects on feeding behavior. Two well-known hexapeptides, GHRP-6 and hexarelin, given s.c., dose dependently stimulated both GH release and feeding behavior in satiated rats. However, in a series of tri-, penta- and hexapeptide analogs of hexarelin, some compounds were active either on GH release or on eating behavior. Interestingly, even minor structural modifications resulted in major changes of the pharmacological profile. We conclude that GHRPs have orexigenic properties after systemic administration which are largely independent from the effects they exert on GH release.     

The growth hormone-releasing hormone receptor: desensitisation following short-term agonist exposure

We have investigated the effect of short-term preexposure of growth hormone-releasing hormone (GHRH) on the subsequent response to GHRH in a baby hamster kidney (BHK) cell line expressing the human GHRH receptor and in primary rat pituitary cells. In the BHK cells the receptor was rapidly desensitised in a homologous fashion. Preexposure with agents directly stimulating the cAMP pathway like forskolin and db-cAMP had no effect. In rat pituitary cells we also observed a rapid desensitisation of the GHRH response in an apparently homologous fashion. In both systems the desensitisation was dose-dependent with no change in the potency of the hormone in a subsequent stimulation, only the efficacy was decreased. In the rat pituitary cell, the response measured as growth hormone release was more sensitive to the agonist-induced desensitisation than the cAMP response. No indication of depletion of growth hormone (GH) stores was seen. In rat pituitary cells, contrary to observations in BHK cells, preexposure with both forskolin and db-cAMP desensitised a subsequent growth hormone-releasing hormone stimulation, indicating a heterologous desensitisation. Phorbol-12-myristate 13-acetate (PMA), on the other hand, had no effect. In the baby hamster kidney cells it was demonstrated that the GHRH receptor surface expression decreased following preexposure with GHRH. This phenomenon was observed only in whole cells suggesting a rapid internalisation process. Together, these data indicate that after short-term GHRH preexposure, both in a human and rat system, the following GHRH response is desensitised. In BHK cells this desensitisation is strictly homologous. In rat pituitary cells, on the other hand, the desensitisation is a mixed homologous/ heterologous type.     

Synthesis of human pancreatic growth hormone-releasing factor and two omission analogs by segment-coupling method in aqueous solution

The human growth hormone-releasing factor (GRF) peptides [GlyS¹⁵]-GRF-(1–15) (IV), trifluoroacetyl-GRF-(20–44) (VI), trifluoroacetyl-GRF-(18–44) (VIII), and trifluoroacetyl-GRF-(16–44) (X) were synthesized by the solid-phase method. Each of the peptides was reacted with citraconic anhydride and the trifluoroacetyl group was removed by reaction with 10% hydrazine in water. The citraconylated GRF-(1–15) peptide was coupled to the (20–44), (18–44) or (16–44) peptides by reaction with silver nitrate/N-hydroxysuccinimide to give GRF-(1–15)-(20–44) (XII), GRF-(1–15)-(18–44) (XIII), or GRF-(1–44), respectively. GRF-(1–44) was shown to stimulate the release of rat growth hormone from rat pituitary cells with an ED₅₀= 8.8 times 10^-11 M. Peptides XII and XIII were inactive, either as agonists or as antagonists of the action of GRF-(1–44).     

Species differences in mu- and delta-opioid receptors.

The mu opioid receptor ligand [D-Ala2, NMePhe4, Gly-ol5]enkephalin (DAGO) and delta opioid receptor ligand [D-Pen2,D-Pen5]enkephalin (DPDPE) show similar specificity in competition binding studies in whole brain homogenate in rat and mouse. However, in saturation studies, the density and affinity of DPDPE binding sites were substantially greater in the mouse. There was no difference between the mouse and rat in the density and affinity of DAGO sites. Results from dose-response studies for analgesia using the same ligands administered i.c.v. in both species paralleled the binding studies. DAGO was approximately 2 times more potent in the mouse compared to the rat; while DPDPE was more than 15 times more potent in the mouse. Thus, binding capacity and affinity differences appear to be related to the functional potency of the mu and delta ligands in the two species. These results suggest that the difference in potency of DPDPE between rat and mouse is related to the differences in brain delta opioid receptors.     

A comparative study of the antiinflammatory activity of fentiazac and its major metabolite, p-hydroxy fentiazac

Wy-25,110, the p-OH metabolite of fentiazac was approximately 100 times less potent than fentiazac after oral administration in rat carrageenan edema and 100-130 times less potent as an inhibitor of prostaglandin synthesis by mouse peritoneal macrophages. In addition, Wy-25,110 was one twelfth as active as fentiazac against immunologic-induced inflammation on day 16 in rat adjuvant arthritis. Wy-25,110 was also much less potent than fentiazac when administered intravenously, suggesting that inadequate oral absorption does not account for its lack of potency. Thus it seems unlikely that the p-OH metabolite contributes greatly to the antiinflammatory properties of fentiazac.     

Suppression of hepatocyte apoptosis and induction of DNA synthesis by the rat and mouse hepatocarcinogen diethylhexylphlathate (DEHP) and the mouse hepatocarcinogen 1,4-dichlorobenzene (DCB)

Nongenotoxic rodent hepatocarcinogens do not damage DNA but cause liver tumours in the rat and mouse, associated with the induction of hepatic DNA synthesis. Previously, we have demonstrated that nongenotoxic hepatocarcinogens such as phenobarbitone and the peroxisome proliferator (PP), nafenopin, also suppress rat hepatocyte apoptosis. The nongenotoxic chemicals 1,4-dichlorobenzene (DCB) and the PP, diethylhexyl phthalate (DEHP), both induce high levels of DNA synthesis in rat liver in vivo, but only DEHP is hepatocarcinogenic in this species. Here, we investigate whether the difference in rat carcinogenicity of these two hepatic mitogens may be due to differences in their ability to suppress hepatocyte apoptosis. In rat hepatocytes in vitro, MEHP (the active metabolite of DEHP) induced DNA synthesis 2.5-fold (P = 0.001) and suppressed 10- and 4-fold, respectively both spontaneous (P = 0.0008) and transforming growth factor β1 (TGFβ1)-induced (P = 0.0001) apoptosis. DCB gave a small (1.7-fold) increase in DNA synthesis (P = 0.03) and a small (1.7- to 2-fold) suppression of both spontaneous (P = 0.022) and TGFβ1-induced (P = 0.015) apoptosis. We next analysed the induction of DNA synthesis and the suppression of apoptosis in rat liver in vivo. Both DEHP and DCB were able to induce DNA synthesis although, as seen in vitro, the induction by DCB (4.2-fold; P = 0.023) was less marked than that with DEHP (13.4-fold; P = 0.007). Similarly, DEHP and DCB were both able to suppress rat hepatocyte apoptosis in vivo but the magnitude of the suppression was comparable; apoptosis was reduced to undetectable levels in four out of five animals with DCB and three out of five with DEHP. Since both chemicals suppressed apoptosis and induced DNA synthesis in rat liver but, overall, DCB was less potent, the disparate hepatocarcinogenic potential of these two chemicals could arise from differences in the magnitude of growth perturbation. To test this hypothesis, we repeated the studies in mouse, a species where both DCB and DEHP are hepatocarcinogenic. Both in vitro and in vivo, DCB and DEHP/MEHP were able to suppress apoptosis and induce hepatocyte DNA synthesis in the mouse with comparable potencies. The data support the hypothesis that the carcinogenicity of nongenotoxic hepatocarcinogens is associated strongly with the ability to perturb hepatocyte growth regulation. However, the ability to effect such changes is not unique to nongenotoxic carcinogens and is common to some noncarcinogenic chemicals, such as DCB, suggesting that the growth perturbation may need to exceed a threshold for carcinogenesis. Received: 9 June 1998 / Accepted: 23 September 1998     

Postjunctional inhibition of contractor responses in the mouse vas deferens by rat and human calcitonin gene-related peptides (CGRP).

The effects of rat and human alpha-calcitonin gene-related peptide (CGRP) were compared in the mouse and rabbit isolated vas deferens preparation contracted by either field stimulation or acetylcholine. The peptides were about equipotent at inhibiting twitch responses of the mouse vas deferens to field stimulation at 0.2 Hz (IC50 12 +/- 4 nM and 15 +/- 3 nM, rat and human alpha-CGRP respectively). Rat alpha-CGRP was less potent at inhibiting responses to 10 Hz than to either 0.2 Hz or 1.0 Hz stimulation. The potency of rat alpha-CGRP at 1.0 Hz was unaltered by halving the calcium concentration of the Krebs solution. The inhibitory effect of human alpha-CGRP was not antagonized by either propranolol (300 nM) or idazoxan (300 nM), although in the same tissues these latter two drugs reduced responses to isoprenaline and clonidine respectively. Rat alpha-CGRP (100 nM) and human alpha-CGRP (1.0 microM) did not alter the uptake of [3H]-noradrenaline (30 nM) into mice isolated vasa deferentia. Rat alpha-CGRP (3-100 nM) did not alter the fractional release per pulse (1.0 Hz, 100 pulses) of tritium from vasa preloaded with [3H]-noradrenaline, although at the same time the peptide inhibited responses of the smooth muscle to field stimulation. Rat and human alpha-CGRP were equipotent at inhibiting contractions of the mouse vas deferens evoked by acetylcholine although the peptides were less potent than against twitch responses. In the rabbit vas deferens neither rat nor human alpha-CGRP (3 nM-1 microM) inhibited either twitch responses or acetylcholine contractions.(ABSTRACT TRUNCATED AT 250 WORDS)     

The cholinergic pharmacology of tetrahydroaminoacridine in vivo and in vitro.

1. The effect of tetrahydroaminoacridine (THA) on cholinergically mediated behaviour in the rat and mouse has been investigated. In addition the actions of this compound on cholinesterase activity and on muscarinic and nicotinic receptors has also been examined. 2. Administration of THA (5-20 mg kg-1, i.p.) produced a dose-dependent increase in tremor, hypothermia and salivation in both rats and mice. A similar profile of activity was seen following physostigmine (0.1-0.6 mg kg-1) administration. 3. THA was approximately fifty fold less potent than physostigmine in inducing behavioural change but its effects persisted for over twice as long as those of physostigmine. For example THA-induced hypothermia was still present at 4 h in the mouse and 8 h in the rat. 4. In vitro THA was a potent non-competitive inhibitor of rat brain cholinesterase (IC50: 57 +/- 6 nM) and bovine erythrocyte acetylcholinesterase (IC50: 50 +/- 10 nM) but was a more potent inhibitor of horse serum butyrylcholinesterase (IC50: 7.2 +/- 1.4 nM). 5. Radioligand binding studies indicated that THA binds non-selectively but with moderate potency to both M1 (Ki: 600 nM) and M2 (Ki: 880 nM) muscarinic receptors. THA also interacted with the allosteric site present on cardiac M2 receptors. 6. It is concluded that THA is a reversible non-competitive inhibitor of cholinesterase with a long half life (compared with physostigmine). It also may antagonize muscarinic receptors at high doses. The long half life may account for its reported efficacy in the treatment of Alzheimer's disease.     

The relative potency of enkephalins and beta-endorphin in guinea-pig ileum, mouse vas deferens and rat vas deferens after the administration of peptidase inhibitors

Previous studies have shown that three distinct enzymes, amastatin-sensitive aminopeptidase, captopril-sensitive peptidyl dipeptidase A, and phosphoramidon-sensitive endopeptidase-24.11, played a critical role in the inactivation of enkephalins in isolated preparations. In the present study, therefore, the rank order of the potency of three endogenous opioid peptides, [Met5]-enkephalin, [Leu5]-enkephalin, and beta-endorphin, in three isolated preparations, guinea-pig ileum, mouse vas deferens, and rat vas deferens, was estimated in the presence of the mixture of three peptidase inhibitors, amastatin, captopril, and phosphoramidon. [Met5]-Enkephalin was approximately three-fold more potent than [Leu5]-enkephalin and four-fold more potent than beta-endorphin in guinea-pig ileum in which three opioid peptides were indicated to act on mu-receptors. Additionally, [Met5]-enkephalin was slightly but significantly more potent than [Leu5]-enkephalin and approximately twenty-fold more potent than beta-endorphin at delta-receptor sites in mouse vas deferens. Moreover, [Met5]-enkephalin was approximately three-fold more potent than [Leu5]-enkephalin, but sixty-fold less potent than beta-endorphin in rat vas deferens in which the opioid-receptor type interacting with enkephalins could not be determined. In conclusion, the well-known rank order of the potency of three endogenous opioid peptides was shown to be altered in both guinea-pig ileum and mouse vas deferens but not in rat vas deferens by the pretreatment of the preparations with the mixture of three peptidase inhibitors.