Biological effects and receptor binding affinities of new pseudononapeptide bombesin/GRP receptor antagonists with N-terminal d-Trp or d-Tpi

In an attempt to produce more powerful (effective) bombesin/GRP receptor antagonists, the d forms of Trp or Trp analog (Tpi) were introduced at position 6 in two pseudononapeptides, Leu¹³Ψ (CH₂NH)Leu¹⁴-bombesin(6-14) and Leu¹³Ψ(CH₂NH)Phe¹⁴ -bombesin (6-14). These antagonists were tested for their ability to inhibit basal and gastrin releasing peptide (GRP) (14-27)-induced amylase release from rat pancreatic acini in a superfusion assay. They were also assessed for the inhibition of ¹²⁵I-Tyr⁴ -bombesin binding to Swiss 3T3 and small cell lung carcinoma cell line H-345 and the mitogenic response of Swiss 3T3 cells induced by GRP(14-27). The peptides, when given alone, did not stimulate amylase secretion, but were able to inhibit gastrin releasing peptide (14-27)-induced amylase release. All of the antagonists showed strong binding affinities for Swiss 3T3 and H-345 cells and suppressed the GRP(14-27)-induced increase of [³H]thymidine incorporation into DNA of Swiss 3T3 cells at nanomolar concentrations. Antagonist d -Tpi⁶,Leu¹³Ψ (CH₂NH)Leu¹⁴-bombesin (6-14)(RC-3095) was slightly more potent in these assays than d -Trp⁶,Leu¹³Ψ (CH₂NH)Leu¹⁴-bombesin (6-14)(RC-3125). Nevertheless, d -Trp⁶ Leu¹³Ψ (CH₂NH)Phe¹⁴-bombesin (6-14) showed the highest binding affinity for Swiss 3T3 and H345 cells and it was the most potent inhibitor of GRP(14-27)-induced amylase secretion. This antagonist RC-3420 was particularly effective in inhibiting the growth of Swiss 3T3 cells, exhibiting an IC₅₀ value less than 1 nm . Our work indicated that the substitution of d -Trp and d -Tpi at position 6 of the pseudononapeptide bombesin analogs (Ψ^13-14), in which the Met¹⁴ residue is replaced by Leu or Phe, results in potent bombesin/GRP antagonists with improved in vivo activity.     

Development of a radioimmunoassay for a pseudononapeptide bombesin/GRP antagonist with antitumor activity

Bombesin-like and GRP-like peptides may act as autocrine growth factors in the proliferation of some cancers. A pseudononapeptide bombesin antagonist, [d -Tpi⁶,Leu¹³φ(CH₂NH)-Le¹⁴]bombesin(6–14), and related analogs synthesized in our laboratory significantly inhibit tumor growth in various cancer models. A radioimmunoassay (RIA), suitable for determination of RC-3095 and its congeners in unextracted serum, was developed in order to facilitate further experimental and clinical evaluation of this bombesin/GKP receptor antagonist for the treatment of various tumors. Antibodies were generated against RC-3095 and Des-Tpi¹-RC-3095, conjugated to bovine serum albumin with glutaraldehyde. Antiserum JH-631b was selected for further experiments based on the antibody characterization. At an antiserum dilution of 1:189000, this antibody bound approximately 50% of 7 fmol of added radiolabeled Tyr¹-RC-3095. The antibody cross-reacted with C-terminal fragments of RC-3095. Fragments without the C-terminus and naturally existing peptides of the bombesin family or structurally unrelated peptides did not cross-react. The minimum detectable dose of RC-3095 was 0.4 pg/tube. Intra- and interassay coefficients of variation ranged from 3.2 to 4.4% and from 5.6 to 12.8%, respectively. The RIA is suitable for direct determination of RC-3095 in serum. The RIA should be of value for monitoring levels of this analog in serum during long-term therapy. © Munksgaard 1995.     

A phase I trial of the bombesin/gastrin-releasing peptide (BN/GRP) antagonist RC3095 in patients with advanced solid malignancies

Summary Bombesin/gastrin-releasing peptides (BN/GRP) were shown to bind selectively to cell surface receptors, stimulating the growth of various types of malignancies in murine and human models. The novel BN/GRP synthetic receptor antagonist, RC-3095, was able to produce long-lasting tumor regressions in murine and human tumor models in vitro and in vivo. Animal toxicology studies showed no detectable organ toxicity apart from local irritation at the injection site. The purpose of this study was to determine the safety and feasibility of the administration of RC-3095 by daily subcutaneous injections in patients with advanced and refractory solid malignancies. Twenty-five patients received RC-3095 once or twice-daily at doses ranging from 8 to 96 ug/kg. Dose was escalated in groups of 3–5 patients per dose level. The only toxicity observed was local discomfort in the injection site at the highest doses. A single dose administration of RC-3095 at the highest dose level (96 ug/kg) was tested in a clearly hypergastrinemic individual with the Zollingen-Ellison syndrome and produced a decrease in plasma gastrin down to 50% of basal levels in 6 h. There was no objective tumor responses in patients included in the study. A short-lasting minor tumor response was observed in a patient with a GRP-expressing progressive medullary carcinoma of the thyroid. Due to problems with the analytical method, plasma pharmacokinetic data was obtained only from two patients included at the highest dose level. In these patients, RC-3095 reached plasma concentrations >100 ng/mL for about 8 h, which were within therapeutic levels on the basis of prior data obtained in mice and rats. The plasma elimination half-life was between 8.6–10.9 h. Due to the occurrence of local toxicity at the injection site, the dose escalation procedure could not be fully evaluated up to a maximum tolerated dose. Thus, a recommended dose of RC-3095 for Phase II trials could not be clearly established. Considering the novelty of its mechanism of action and impressive preclinical anti-tumor activity, further studies exploiting new formulations of RC-3095 for human use, such as slow-release preparations, and analogues with a more favorable pharmacokinetics are warranted.     

Targeting the bombesin/gastrin-releasing peptide receptor to treat sepsis

Sepsis is a complex, multifactorial syndrome that can develop into conditions of different severity, described as septic shock or severe sepsis. In spite of the great progress in understanding the mechanisms involved in the pathogenesis and management of sepsis, only a few therapeutic strategies were able to show a decrease in the mortality from septic shock. Although sepsis consists on a systemic inflammatory response, the anti-inflammatory therapies have failed to improve the outcome of critically ill patients. Here the role of gastrin-releasing peptide in immune processes is reviewed and the data that have prompted the recent patent for GRP receptor antagonists RC-3095 as a therapeutic agent on inflammatory conditions are described.     

Octylonium bromide interacts competitively with the PAF receptor

To clarify the nature of the interaction of octylonium bromide with the PAF receptor, saturation studies of 3H-PAF binding were made in the presence of increasing concentrations of the radioligand (from 0.06 to 7.4 nM) and of octylonium bromide (1 X 10(-8), 5 X 10(-8) and 1 X 10(-7) M) or of a potent PAF antagonist L 652,731 (2.5 X 10(-7) M), or in the absence of competing drugs. Saturation binding data were plotted according to the non-linear fitting analysis and to Scatchard transformation. Both mathematical models indicated that the presence of added drugs decreased the affinity of the complex 3H-PAF/PAF receptors, leaving unaffected the maximum number of PAF binding sites. Receptor parameters in the absence of competitors were: KD = 1.2 nM, Bmax = 950 fmoles 3H-PAF bound/10(8) platelets. Octylonium bromide increased, in a concentration-dependent manner, KD values from 1.5 to 2.1 nM, while Bmax ranged from 910 to 980 fmoles 3H-PAF specifically bound/10(8) platelets. Likewise, L 652,731 did not influence Bmax (980 fmoles) but increased KD (1.9 nM). The binding behaviour of octylonium bromide and L 652,731 indicates that the two compounds inhibit competitively the binding of 3H-PAF to its receptors.     

A synthetic glycopeptide of substance P analogue (SP6-11) with enhanced NK-1 receptor specificity.

A new glycopeptide analogue of substance P (6-11) (SP6-11), namely, N1,6 (beta-D-glucopyranosyl) [Glu6, Pro9]SP6-11, has been synthesized and found to be water soluble. The in vitro biological activity of this glycopeptide was determined for spasmogenic activity in the guinea pig ileum and for potentiation of electrically evoked contractions in the rat vas deferens. Thus, activities on NK-1, NK-2, and NK-3 receptor types have been differentiated by two assays and, in the case of NK-1 and NK-3, receptors in guinea pig ileum (GPI) were assayed using specific pharmacological procedures. The ED50 values for the analogue and reference peptides substance P (SP), neurokinin A(NKA), and neurokinin B (NKB) were determined and potencies relative to SP were calculated. The analogue is three times more potent than the potent NK-1 agonist SP on NK-1 receptors. Moreover, this glycopeptide proved to be as selective for the NK-1 receptor as the specific agonist SPOMe (the methyl ester of substance P).     

Stargazin interacts functionally with the AMPA receptor glutamate-binding module

Neuronal AMPA receptors comprise pore forming glutamate receptor (GluR) proteins and auxiliary transmembrane AMPA receptor regulatory (TARP) subunits. TARPs traffic AMPA receptors to synapses and regulate channel gating. Both intracellular and extracellular regions in TARPs regulate AMPA receptors; however, the details for these interactions remain unknown. Here, we employ site-directed mutagenesis to determine functional interactions between GluR1 and the prototypical TARP, stargazin. We find that a point mutation in the glutamate-binding region of GluR1 corresponding to the Lurcher allele of GluRdelta2, abolishes stargazin's effects on receptor trafficking and channel gating. A point mutation that prevents receptor desensitization modulates the effects of stargazin on channel gating but preserves receptor trafficking. These studies identify a functional interaction of stargazin with the extracellular glutamate-binding domain of AMPA receptors.     

Characterisation of an endogenous bombesin receptor in CHO/DG44 cells

Bombesin and its receptors have been shown to have a role regulating circadian rhythms in the hamster suprachiasmatic and dorsal raphe nuclei and have been implicated in the regulation of sleep. We have identified and characterised a bombesin receptor endogenously expressed in a Chinese hamster ovary cell line (CHO/DG44). Using a range of bombesin-like peptides, we demonstrate that this receptor displays bombesin BB2 receptor-like pharmacology. We also show that this receptor signals through inositol-[1,4,5]-trisphosphate and protein kinase C and thus provides a useful model system to aid in the interpretation of hamster suprachiasmatic nucleus studies of mammalian circadian rhythm.     

Short chain bombesin pseudopeptides with potent bombesin receptor antagonist activity in rat and guinea pig pancreatic acinar cells

A series of potent bombesin antagonists based on the reduced C-terminal peptide bond modification which in the past resulted in the first really potent antagonists are compared for effects on bombesin-stimulated amylase release from and binding to rat and guinea pig pancreatic acini. It was found that the original member of this series, [Leu13 psi (CH2NH)Leu14] bombesin, displayed partial agonist activity with 11% efficacy in the rat. More recent analogues of this type which were found previously to be even more potent pure antagonists in the guinea pig pancreas or 3T3 cells, exhibited similarly higher binding affinity for rat acini but displayed even higher residual partial agonist activity in the rat. For instance, [D-Phe6,Leu13 psi (CH2NH)Phe14]bombesin-(6-14) was one of the most potent bombesin antagonists known in the guinea pig and 3T3 cell systems but has 40% partial agonist activity in the rat. Several structural modification strategies were developed to remove rat partial agonist properties with retention of high antagonist potency in all systems tested. The most effective of these was the substitution of a Cl on the aromatic ring of the Phe residue (p-Cl-Phe, Cpa) in position 14 to give [D-Phe6,Leu13 psi (CH2NH)Cpa14]bombesin-(6-14). This had higher binding affinities for both rat and guinea pig pancreatic acini and was a pure antagonist on both cell types. Another effective method was alteration of the stereochemistry of the position 14 amino acid in [D-Phe6,Leu13 psi (CH2ND)D-Phe14]bombesin-(6-14) which had somewhat lowered binding affinities but pure antagonist properties.(ABSTRACT TRUNCATED AT 250 WORDS)     

Progress in the development of potent bombesin receptor antagonists.

Bombesin and the mammalian-related peptides gastrin-releasing peptide (GRP), GRP and neuromedin B have been shown to have numerous actions in the CNS, gastrointestinal tract and on growth. However, the role of the peptides in various physiological processes has remained unclear because of the lack of potent antagonists. Recent in vitro studies have described four different classes of bombesin receptor antagonist, some of which are active in the nanomolar range and in vivo. Robert Jensen and David Coy describe recent insights into peptide structural determinants of biological activity. Evidence from structure-function studies have resulted in identification of some analogues that function as potent antagonists in all systems examined. Furthermore, various subtypes of bombesin receptors can now be differentiated by these various classes of antagonist.     

Synthesis and biological evaluation of novel potent antagonists of the bombesin/gastrin releasing peptide receptor.

This paper reports the synthesis and antagonist activity of 20 C-terminal analogues of gastrin releasing peptide (GRP). The ability of each analogue to inhibit bombesin (BN) stimulated amylase release from rat pancreatic acini was determined, and those showing antagonist activity were further evaluated for their ability to inhibit BN-stimulated [3H]thymidine uptake in serum-starved 3T3 cells. The assays also included two known peptide antagonists, C (Leu14,psi 13,14]BN) and H (N-pivaloyl-GRP20-25-(R)-2-methyl-4-nonylamide) as positive controls. On the basis of these assays we suggest that a des-Met27,Leu26-psi[CH2NHCOCH3]GRP C-terminal octapeptide imparts antagonist activity. The two most active compounds are peptides 14 ([D-Phe19,Leu26-psi(CH2NHCOCH3)]GRP19-26) and 18 ([D-Phe19,Gln20,Leu26-psi(CH2NHCOCH3)]GRP19++ +-26). In their ability to inhibit BN-stimulated [3H]thymidine uptake, the IC50 of peptides C, H, 14, and 18 were 43.2, 31.2, 2.7, and 32.5 nM, respectively. In conclusion, the novel C-terminal psi[CH2NHCOCH3] bond promises to be a useful peptide backbone modification for imparting antagonism in GRP/BN analogues.     

Fitting a xenobiotic receptor into cell homeostasis: how the dioxin receptor interacts with TGFbeta signaling

As our knowledge on the mechanisms that control cell function increases, more complex signaling pathways and quite intricate cross-talks among regulatory proteins are discovered. Establishing accurate interactions between cellular networks is essential for a healthy cell and different alterations in signaling are known to underline human disease. Transforming growth factor beta (TGFbeta) is an extracellular cytokine that regulates such critical cellular responses as proliferation, apoptosis, differentiation, angiogenesis and migration, and it is assumed that the latency-associated protein LTBP-1 plays a relevant role in TGFbeta targeting and activation in the extracellular matrix (ECM). The dioxin receptor (AhR) is a unique intracellular protein long studied because of its critical role in xenobiotic-induced toxicity and carcinogenesis. Yet, a large set of studies performed in cellular systems and in vivo animal models have suggested important xenobiotic-independent functions for AhR in cell proliferation, differentiation and migration and in tissue homeostasis. Remarkably, AhR activity converges with TGFbeta-dependent signaling through LTBP-1 since cells lacking AhR expression have phenotypic alterations that can be explained, at least in part, by the coordinated regulation of both proteins. Here, we will discuss the existence of functional interactions between AhR and TGFbeta signaling. We will focus on regulatory and functional aspects by analyzing how AhR status determines TGFbeta activity and by proposing a mechanism through which LTBP-1, a novel AhR target gene, mediates such effects. We will integrate ECM proteases in the AhR-LTBP-1-TGFbeta axis and suggest a model that could help explain some in vivo phenotypes associated to AhR deficiency.     

Disposition of a synthetic analogue of lipid A (E5564) in rats

1. E5564, a lipid A analogue that potently antagonises lipopolysaccharide, is being developed to treat sepsis caused by Gram-negative bacterial infections. The pharmacokinetic profile of E5564 is independent of dose between 0.1 and 1?mg kg ? 1. The distribution volume of E5564 is slightly larger than the total plasma volume, and the terminal elimination half-life is about 5?h. 2. Following 14 C-E5564 administration (0.5?mg kg ? 1), radioactivity rapidly accumulates in the liver and spleen. The half-life of E5564 in the liver is 5.1?h, which is similar to that in the plasma. At 48 weeks after dosing, 35.27% of the administered radioactivity was still present in the liver. Cumulative urinary and faecal excretion of radioactivity for up to 48 weeks after administration were 3.86 and 67.17% of the dose, respectively. 3. The results of mass spectroscopy and nuclear magnetic resonance analysis reveal that the main hepatic metabolite is di-dephosphorylated E5564. The half-life of di-dephosphorylated E5564 in the liver is 87.4 days, which is similar to that for the hepatic radioactivity. 4. The results indicate that E5564 is rapidly taken up by the liver, is metabolized via dephosphorylation pathways to form dephosphorylated E5564 and is mainly excreted in the faeces.     

Disposition of a synthetic analogue of lipid A (E5564) in rats

1. E5564, a lipid A analogue that potently antagonises lipopolysaccharide, is being developed to treat sepsis caused by Gram-negative bacterial infections. The pharmacokinetic profile of E5564 is independent of dose between 0.1 and 1 mg kg(-1). The distribution volume of E5564 is slightly larger than the total plasma volume, and the terminal elimination half-life is about 5 h. 2. Following (14)C-E5564 administration (0.5 mg kg(-1)), radioactivity rapidly accumulates in the liver and spleen. The half-life of E5564 in the liver is 5.1 h, which is similar to that in the plasma. At 48 weeks after dosing, 35.27% of the administered radioactivity was still present in the liver. Cumulative urinary and faecal excretion of radioactivity for up to 48 weeks after administration were 3.86 and 67.17% of the dose, respectively. 3. The results of mass spectroscopy and nuclear magnetic resonance analysis reveal that the main hepatic metabolite is di-dephosphorylated E5564. The half-life of di-dephosphorylated E5564 in the liver is 87.4 days, which is similar to that for the hepatic radioactivity. 4. The results indicate that E5564 is rapidly taken up by the liver, is metabolized via dephosphorylation pathways to form dephosphorylated E5564 and is mainly excreted in the faeces.     

Bombesin-induced anorexia requires central bombesin receptor activation: independence from interaction with central catecholaminergic systems

Intraperitoneal (IP) administration of bombesin (BBS; 2.5–20 µg/kg) induced a dose-dependent inhibition of food intake. The effect was decreased by intraventricular (ICV) administration of bombesin receptor antagonist [Leu¹⁴- (CH₂ NH)-Leu¹³] (3 µg/rat) but not by the D₁ antagonist SCH 23390, the D₂ antagonists sulpiride and pimozide, the dopamine antagonist cis-flupentixol, adrenoceptor blockers phenoxybenzamine or propranolol and serotonergic antagonist methergoline. It is concluded that BBS-induced suppression of feeding may be mediated through central BBS receptors, and is independent of interaction with brain catecholaminergic system.     

Function of non-visual arrestins in signaling and endocytosis of the gastrin-releasing peptide receptor (GRP receptor)

Little is known about the role of arrestins in gastrointestinal hormone/neurotransmitter receptor endocytosis. With other G protein-coupled receptors, arrestins induce G protein-uncoupling and receptor endocytosis. In this study, we used arrestin wild-type and dominant-negative mutant constructs to analyze the arrestin dependence of endocytosis and desensitization of the gastrin-releasing peptide receptor (GRP-R). Co-expression of the GRP-R with wild-type arrestin2 and arrestin3 increased not only GRP-R endocytosis but also GRP-R desensitization in arrestin-overexpressing cells. Co-expression of the dominant-negative mutants V53D-arrestin2 or V54D-arrestin3 reduced GRP-R endocytosis. Notably, different trafficking routes for agonist-activated GRP-R-arrestin2 and GRP-R-arrestin3 complexes were found. Arrestin3 internalizes with GRP-R to intracellular vesicles, arrestin2 splits from the GRP-R and localizes to the cell membrane. Also, the recycling pathway of the GRP-R was different if co-expressed with arrestin2 or arrestin3. Using different GRP-R mutants, the C-terminus and the 2nd intracellular loop of the GRP-R were found to be important for the GRP-R-arrestin interaction and for the difference in GRP receptor trafficking with the two arrestin subtypes. Our results show that both non-visual arrestins play an important role in GRP-R internalization and desensitization.     

Indobufen interacts with the sulphonylurea, glipizide, but not with the beta-adrenergic receptor antagonists, propranolol and atenolol

This study assessed the possible interactions of the cyclooxygenase inhibitor indobufen with one sulphonylurea, glipizide, and with two beta-adrenoceptor antagonists, one of which is extensively metabolised already in the first passage through the liver (propranolol) while the other essentially escapes biotransformation (atenolol). Indobufen was first given as a single 200 mg dose and then for a 5 day period in a dosage of 200 mg twice daily, to six healthy volunteers. Glipizide (5 mg), propranolol (80 mg) and atenolol (100 mg) were given as single doses before and during indobufen medication. The drug concentrations were measured by selective and sensitive h.p.l.c. methods. The findings suggest that the lipophilic acid indobufen can inhibit the metabolic inactivation of another lipophilic acid, glipizide, but does not interfere with the disposal of the two basic drugs, propranolol and atenolol. The increased glipizide concentrations following indobufen were associated with an enhanced blood glucose reduction. Hence, this interaction may be clinically relevant.