Cardiovascular effects of neuropeptide FF antagonists

The neuropeptide FF (NPFF) antagonist desaminotyrosyl-Phe-Leu-Phe-Gln-Pro-Gln-Arg-NH2 dose-dependently reversed NPFF-induced elevation of blood pressure in anesthetized rats after intravenous injection without causing a significant change of blood pressure and heart rate by itself. However, another antagonist dansyl-Pro-Gln-Arg-NH2 produced a significant drop of the mean arterial pressure only at a large dose (10 micromol/kg body weight), but reversal of the NPFF-induced hypertension was modest. Consequently and contrary to the conclusions of a previous study, NPFF antagonists cannot be identified simply by measuring the changes in the hemodynamic parameters upon the injection of the compounds alone and without a subsequent NPFF challenge.     

Insect neuropeptide antagonist. Part II. Synthesis and biological activity of backbone cyclic and precyclic PBAN antagonists.

A new approach for the design and synthesis of pheromone biosynthesis activating neuropeptide (PBAN) agonists and antagonists using the backbone cyclization and cycloscan concepts is described. Two backbone cyclic (BBC) libraries were synthesized: library I (Ser library) was based on the active C-terminal hexapeptide sequence Tyr-Phe-Ser-Pro-Arg-Leu-NH2 of PBAN1-33NH2; whereas library II (D-Phe library) was based on the sequence of the PBAN lead linear antagonist Arg-Tyr-Phe-d-Phe-Pro-Arg-Leu-NH2. In both libraries the Pro residue was replaced by the BBC building unit Nalpha-(omega-aminoalkyl) Gly having various lengths of alkyl chain. The peptides of the two libraries were tested for agonistic and antagonistic activity. Four precyclic peptides based on two of the BBC antagonists were also synthesized; their activity revealed that a negative charge at the N-terminus of the peptide abolished antagonistic activity. We also describe the use of the reagent SiCl3I for selective deprotection of the Boc group from the building unit prior to on-resin amino-end to backbone-nitrogen (AE-BN) cyclization, during solid-phase synthesis with Fmoc chemistry.     

Substance P analogues act as broad-spectrum neuropeptide antagonists

Summary Neuropeptides including bombesin, vasopressin and bradykinin are increasingly implicated in the control of cell proliferation. There is now considerable evidence that the growth of certain common cancers including small cell lung cancer (SCLC) can be stimulated by multiple neuropeptides which act in an autocrine/paracrine fashion. Consequently, the development of broad spectrum neuropeptide, antagonists could be of therapeutic interest. Indeed, certain substance P (SP) analogues including (DArg¹, DPhe⁵, DTrp^7,9, Leu¹¹) SP and (Arg⁶, DTrp^7,9, MePhe⁸)SP (6–11) inhibit the actions of multiple neuropeptides and block the growth of SCLC cells in vitro and in vivo. Moreover, one of these compounds is now in a phase I clinical study and so an understanding of the mechanism of action of these SP analogues is both of fundamental as well as clinical interest. We have found that the SP analogues coordinately and reversibly inhibit the downstream signals which emanate from neuropeptide receptors and competitively block the binding of neuropeptides to their respective receptors. These and other results using novel SP analogues which are reviewed here, suggest that the SP analogues act directly on the neuropeptide receptors to block neuropeptide action.     

Substance P analogues act as broad-spectrum neuropeptide antagonists

Neuropeptides including bombesin, vasopressin and bradykinin are increasingly implicated in the control of cell proliferation. There is now considerable evidence that the growth of certain common cancers including small cell lung cancer (SCLC) can be stimulated by multiple neuropeptides which act in an autocrine/paracrine fashion. Consequently, the development of broad spectrum neuropeptide antagonists could be of therapeutic interest. Indeed, certain substance P (SP) analogues including (DArg¹, DPhe⁵, DTrp^7,9, Leu¹¹)SP and (Arg⁶, DTrp^7,9, MePhe⁸)SP (6–11) inhibit the actions of multiple neuropeptides and block the growth of SCLC cells in vitro and in vivo. Moreover, one of these compounds is now in a phase I clinical study and so an understanding of the mechanism of action of these SP analogues is both of fundamental as well as clinical interest. We have found that the SP analogues coordinately and reversibly inhibit the downstream signals which emanate from neuropeptide receptors and competitively block the binding of neuropeptides to their respective receptors. These and other results using novel SP analogues which are reviewed here, suggest that the SP analogues act directly on the neuropeptide receptors to block neuropeptide action.     

Novel non-peptidic neuropeptide Y Y2 receptor antagonists

Through SAR studies of a piperidinylindoline cinnamide HTS lead, the first potent, non-peptide, low molecular weight selective Neuropeptide Y Y2 (NPY Y2) antagonists have been synthesized. The SAR studies around the piperidinyl, the indolinyl, and the cinnamyl moieties are discussed.     

Conformation of neuropeptide Y receptor antagonists: structural implications in receptor selectivity

Two NPY analogue peptides, BVD10 (Ile-Asn-Pro-Ile-Tyr-Arg-Leu-Arg-Tyr-OMe) and BVD15 (Ile-Asn-Pro-Ile-Tyr-Arg-Leu-Arg-Tyr-NH(2)) were characterized conformationally by NMR, CD and molecular dynamics simulations. The two peptides exhibit different secondary structure characteristics in trifluoroethanol. BVD10 exhibits a structure with two consecutive beta-turns at Asn2-Pro3-Ile4-Tyr5 and Ile4-Tyr5-Arg6-Leu7. BVD15 exhibits a helical type of structure along with a beta-turn at Asn2-Pro3-Ile4-Tyr5. Molecular modeling studies suggested that the C-terminus Tyr9 is oriented in different directions in the two peptides. The difference in the structures of peptides observed may contribute to the Y(1) selectivity of BVD10 relative to BVD15.     

Dihydropyridine neuropeptide Y Y1 receptor antagonists 2. bioisosteric urea replacements

Structure-activity studies around the urea linkage in BMS-193885 (4a) identified the cyanoguanidine moiety as an effective urea replacement in a series of dihydropyridine NPY Y(1) receptor antagonists. In comparison to urea 4a (K(i)=3.3 nM), cyanoguanidine 20 (BMS-205749) displayed similar binding potency at the Y(1) receptor (K(i)=5.1 nM) and full functional antagonism (K(b)=2.6 nM) in SK-N-MC cells. Cyanoguanidine 20 also demonstrated improved permeability properties in Caco-2 cells in comparison to urea 4a (43 vs 19 nm/s).     

Structure-activity relationships of neuropeptide Y Y1 receptor antagonists related to BIBP 3226

Analogues of BIBP 3226, (R)-N(alpha)-diphenylacetyl-N-(4-hydroxybenzyl)argininamide, were synthesized and investigated for Y1 antagonism (Ca2+-assay, HEL cells) and binding on Y1, Y2 and Y5 receptors. Replacing the benzylamino by a tetrahydrobenzazepinyl group preserves most of the Y1 activity. Combination with a N(G)-phenylpropyl arginine and a N(alpha)-p-biphenylylacetyl moiety shifted the NPY receptor selectivity towards Y5.     

Synthesis and SAR of selective small molecule neuropeptide Y Y2 receptor antagonists

Highly potent and selective small molecule neuropeptide Y Y2 receptor antagonists are reported. The systematic SAR exploration of a hit molecule N-(4-ethoxyphenyl)-4-[hydroxy(diphenyl)methyl]piperidine-1-carbothioamide, identified from HTS, led to the discovery of highly potent NPY Y2 antagonists 16 (CYM 9484) and 54 (CYM 9552) with IC(50) values of 19 nM and 12 nM respectively.     

Rationally designed neuropeptide antagonists: A novel approach for generation of environmentally friendly insecticides

We report our approach for the generation of a novel type of putative insecticides based on backbone cyclic peptidomimetic antagonists of insect neuropeptides using pheromone biosynthesis activating neuropeptide (PBAN) as a model. This approach, called the backbone cyclic neuropeptide based antagonist (BBC-NBA), includes the following steps: (i) elucidation of the active sequence of the chosen insect neuropeptide; (ii) disclosure of a lead antagonist based on the sequence found in step (i); (iii) design and synthesis of backbone cyclic peptide libraries (cycloscan) based on the sequence of the lead antagonist; and (iv) design and synthesis of a peptidomimetic prototype insecticide. The BBC-NBA approach was applied to PBAN and led to the discovery of a potent linear lead antagonist and a potent backbone cyclic antagonist devoid of agnoistic activity which inhibited sex pheromone biosynthesis inHeliothis peltigera female moths.     

Effects of neuropeptide Y antagonists on food intake in rats: differences with cold-adaptation

Hyperphagia followed both central neuropeptide Y (NPY) administration and the presumed increase of endogenous NPY activity after food deprivation. NPY induced greater hyperphagia in cold-adapted than non-adapted rats; fasting of comparable severity caused similar hyperphagia in the two groups. NPY-receptor-antagonist D-Tyr(27,36), D-Thr32-NPY(27,36) or functional NPY-antagonist D-myo-inositol-1,2,6-trisphosphate attenuated the hyperphagic effect of both NPY and fasting in non-adapted rats. However, while completely preventing the NPY-hyperphagia, they did not influence the fasting-induced hyperphagia in cold-adapted rats. With cold-adaptation the sensitivity to NPY and to its antagonists increases, but the hypothalamic NPY loses from its fundamental role in the regulation of food intake, and the hyperphagia seen in cold-adaptation may need some other explanation.     

Discovery and evaluation of spirocyclic derivatives as antagonists of the neuropeptide Y5 receptor

A novel series of spirocyclic derivatives was synthesized and evaluated as NPY Y5R antagonists for the treatment of obesity. Cis and trans analogs 7a and 8a were equipotent in a Y5R binding assay (K(i)'s ≤ 1 nM) and displayed good stability in human and rat liver microsome preparations. Compound 7a failed to demonstrate weight loss activity in a diet-induced obese (DIO) rat model at unbound drug levels in the brain that exceeded the Y5R K(i) value by 25-fold over a 24-h time-period.     

Centrally administered neuropeptide Y enhances the hypothermia induced by peripheral administration of adrenoceptor antagonists

The distribution of neuropeptide Y in the brain includes extensive coexistence within adrenaline- and noradrenaline-containing neurons and many of its actions are often associated with adrenergic systems. Since neuropeptide Y immunoreactivity is particularly intense in the preoptic area, one of the principal sites for thermoregulation, we have tested the effects of neuropeptide Y on core temperature in normothermic rats, and rats rendered hypothermic by systemic treatment with adrenergic antagonists. In the normothermic rat, intracerebroventricular administration of 1 microgram of neuropeptide Y did not have a significant effect on core temperature. Intraperitoneal treatment with the alpha 1-adrenoceptor antagonist, prazosin, or the beta-adrenoceptor antagonist, propranolol, caused an immediate and significant hypothermia; the intracerebroventricular administration of 1 microgram of neuropeptide Y, 10 minutes after these drugs, strongly potentiated their hypothermic effect. Although intraperitoneal treatment with the alpha 2-adrenoceptor antagonist, idazoxan, had no hypothermic effect per se, the intracerebroventricular administration of NPY 10 minutes after this antagonist led to a significant decrease in core temperature.     

The identification and optimisation of novel and selective diamide neuropeptide Y Y2 receptor antagonists

A novel small molecule NPY Y2 antagonist (3) identified from high throughput screening is described. A subsequent SAR study and optimisation programme based around this molecule is also described, leading to the identification of potent and soluble pyridyl analogue 36.     

Discovery and evaluation of pyrazolo[1,5-a]pyrimidines as neuropeptide Y1 receptor antagonists

A novel series of pyrazolo[1,5-a]pyrimidine derivatives was synthesized and evaluated as NPY Y1R antagonists. High binding affinity and selectivity were achieved with C3 trisubstituted aryl groups and C7 substituted 2-(tetrahydro-2H-pyran-4-ylamino)ethylamine moieties. Efforts to find close analogs with low plasma clearance in the rat and minimal p-glycoprotein efflux in the mouse were unsuccessful. Compound 2f (CP-671906) inhibited NPY-induced increases in blood pressure and food intake after iv and icv administration, respectively, in Sprague-Dawley (SD) rat models. Oral administration of compound 2f resulted in a modest, but statistically significant, reduction in food intake in a Wistar rat model of feeding behavior. Small inhibitions of food intake were also observed in an overnight fasting/refeeding model in SD rats. These data suggest a potential role for Y1R in the regulation of food intake in rodents.     

Design of non-peptide agonists and antagonists at neuropeptide receptors starting from the chemical structure of neuropeptides

Non-peptide small-molecule antagonists for cholecystokinin (CCK)-A and -B receptors, tachykinin NK-1, NK-2 and NK-3 receptors and bombesin BB-1 receptors have been designed and synthesized starting from the chemical structure of the endogenous mammalian neuropeptides cholecystokinin, substance-P and bombesin, respectively. A non-peptide CCK-A agonist, with weak potency but high efficacy, was also identified from the same strategy.     

Effect of neuropeptide S receptor antagonists and partial agonists on palatable food consumption in the rat

Neuropeptide S (NPS) is the endogenous ligand for the previously orphan G-protein-coupled-receptor, now termed NPS receptor (NPSR). NPS has both anxiolytic and pro-arousal properties and decreases food intake. In this work we use a rat model of palatable food intake to test in vivo different analogs of human NPS developed in our laboratories and characterized in previous in vitro experiments as partial agonists ([Ala³]NPS and [Aib⁵]NPS), or antagonists ([d-Cys(^tBu)⁵]NPS and [^tBu-d-Gly⁵]NPS). Our results confirmed that intracerebroventricular (ICV) injection of NPS (1 nmol) decreases standard chow intake in food restricted rats as well as in freely feeding animals fed with standard or palatable food diets. [Aib⁵]NPS (30 and 60 nmol), like NPS, reduced palatable food intake, thus confirming in vivo its ability to activate NPSR. [Ala³]NPS (60 nmol) did not affect palatable food intake per se but blocked the anorectic effect of NPS, thus suggesting its ability to function as an antagonist in this model. Finally, [d-Cys(^tBu)⁵]NPS (20-60 nmol) and [^tBu-d-Gly⁵]NPS (10-30 nmol), described in previous in vitro studies as pure NPSR antagonists, did not affect palatable food intake when given alone, but fully blocked the anorectic effect of NPS. These results provide an important characterization of the pharmacological properties of these NPS analogs in vivo. Of particular relevance are the data showing that [d-Cys(^tBu)⁵]NPS and [^tBu-d-Gly⁵]NPS behave as pure antagonists at NPSR regulating food intake, indicating that these molecules are suitable tools for further investigation of the physiopharmacology of the NPS/NPSR system.     

Design of non-peptide agonists and antagonists at neuropeptide receptors starting from the chemical structure of neuropeptides

Summary Non-peptide small-molecule antagonists for cholecystokinin (CCK)-A and-B receptors, tachykinin NK-1, NK-2 and NK-3 receptors and bombesin BB-1 receptors have been designed and synthesized starting from the chemical structure of the endogenous mammalian neuropeptides cholecystokinin, substance-P and bombesin, respectively. A non-peptide CCK-A agonist, with weak potency but high efficacy, was also identified from the same strategy.     

Dimeric argininamide-type neuropeptide Y receptor antagonists: Chiral discrimination between Y1 and Y4 receptors

The structurally related peptides neuropeptide Y (NPY), peptide YY (PYY) and pancreatic polypeptide (PP) are endogenous agonists of the NPY receptor (YR) family, which in humans comprises four functionally expressed subtypes, designated Y₁R, Y₂R, Y₄R and Y₅R. Nonpeptide antagonists with high affinity and selectivity have been described for the Y₁R, Y₂R and Y₅R, but such compounds are still lacking for the Y₄R. In this work, the structures of the high affinity selective (R)-argininamide-type Y₁R antagonists BIBP3226 and BIBO3304 were linked via the guanidine or urea moieties to give homo-dimeric argininamides with linker lengths ranging from 31 to 41 atoms. Interestingly, the twin compounds proved to be by far less selective for the Y₁R than the R-configured monovalent parent compounds. The decrease in selectivity ratio was most pronounced for Y₁R versus Y₄R subtype, resulting in comparable affinities of bivalent ligands for Y₁R and Y₄R (e.g. UR-MK177 ((R,R)-49): K_i = 230 nM (Y₁R) and 290 nM (Y₄R)). With a K_i value of 130 nM and a K_b value of 20 nM, UR-MK188 ((R,R)-51) was superior to all Y₄R antagonists known to date. The S,S-configured optical antipodes of UR-MK177 and UR-MK188 (UR-MEK381 ((S,S)-49) and UR-MEK388 ((S,S)-51)) were synthesized to investigate the stereochemical discrimination by the different receptor subtypes. Whereas preference for R,R-configured argininamides was characteristic of the Y₁R, stereochemical discrimination by the Y₄R was not observed. This may pave the way to selective Y₄R antagonists.     

The identification of a series of novel, soluble non-peptidic neuropeptide Y Y2 receptor antagonists

The identification and subsequent optimisation of a selective non-peptidic NPY Y2 antagonist series is described. This led to the development of amine 2, a selective, soluble NPY Y2 receptor antagonist with enhanced CNS exposure.