Biphasic blood pressure response to neuropeptide Y in anesthetized rats

Potential targets for intervention in radiation-induced heart disease

Radiotherapy of thoracic and chest wall tumors, if all or part of the heart was included in the radiation field, can lead to radiation-induced heart disease (RIHD), a late and potentially severe side effect. RIHD presents clinically several years after irradiation and manifestations include accelerated atherosclerosis, pericardial and myocardial fibrosis, conduction abnormalities, and injury to cardiac valves. The pathogenesis of RIHD is largely unknown, and a treatment is not available. Hence, ongoing pre-clinical studies aim to elucidate molecular and cellular mechanisms of RIHD. Here, an overview of recent pre-clinical studies is given, and based on the results of these studies, potential targets for intervention in RIHD are discussed.

Preclinical research into basic mechanisms of radiation-induced heart disease

Radiation-induced heart disease (RIHD) is a potentially severe side effect of radiotherapy of thoracic and chest wall tumors if all or part of the heart was included in the radiation field. RIHD presents clinically several years after irradiation and manifestations include accelerated atherosclerosis, pericardial and myocardial fibrosis, conduction abnormalities, and injury to cardiac valves. There is no method to prevent or reverse these injuries when the heart is exposed to ionizing radiation. This paper presents an overview of recent studies that address the role of microvascular injury, endothelial dysfunction, mast cells, and the renin angiotensin system in animal models of cardiac radiation injury. These insights into the basic mechanisms of RIHD may lead to the identification of targets for intervention in this late radiotherapy side effect.

Immunohistochemical localization of the neuropeptide Y Y1 receptor in rat central nervous system

The diverse effects of neuropeptide Y (NPY) are mediated through interaction with G-protein coupled receptors. Pharmacological analysis suggests the Y1 receptor mediates several of NPY's central and peripheral actions. We sought to determine the distribution of Y1 protein throughout the rat central nervous system by means of indirect immunofluorescence using the tyramide signal amplification method and a novel, amino terminally-directed Y1 antisera. This antisera was verified as specific for Y1 by solution-phase competition ELISA, Western blot and in situ blocking experiments. High concentrations of Y1 immunoreactivity were found in the claustrum, piriform cortex (superficial layer), arcuate hypothalamic nucleus, interpeduncular nucleus, paratrigeminal nucleus, and lamina II of the spinal trigeminal nucleus and entire spinal cord. Moderate levels of Y1 immunoreactivity were found the in the main olfactory bulb, dorsomedial part of suprachiasmatic nucleus, paraventricular hypothalamic nucleus, ventral nucleus of lateral lemniscus, pontine nuclei, mesencephalic trigeminal nucleus, external cuneate nucleus, area postrema, and nucleus tractus solitarius. Low levels of Y1 immunostaining were distributed widely throughout layers II-III of the cerebral cortex (i.e., orbital, cingulate, frontal, parietal, insular, and temporal regions), nucleus accumbens core, amygdalohippocampal and amygdalopiriform areas, dentate gyrus, CA1 and CA2 fields of hippocampus, principal and oral divisions of the spinal trigeminal nucleus, islands of Calleja and presubiculum. These findings are discussed with reference to previously reported receptor autoradiography, immunohistochemistry and mRNA analyses to further support the role of Y1 in NPY-mediated biology.

Neuropeptide Y1- and Y2-receptor-mediated cardiovascular effects in the anesthetized guinea pig, rat, and rabbit

Neuropeptide Y (NPY) causes vasoconstriction through Y1-receptors and inhibits vagal bradycardia through presynaptic Y2-receptors. These effects of NPY were investigated in anesthetized guinea pigs, rats, and rabbits to find the most suitable species for evaluation of Y1- and Y2-active agents in vivo. The increase in blood pressure (through Y1) of lower doses of NPY was similar in the three species (ED50, 0.9 +/- 0.13, 0.8 +/- 0.39, and 0.6 +/- 0.09 nmol/kg, respectively), but higher doses had depressor effects in four of six rats. Vagal bradycardia, induced by electrical stimulation of the right cervical vagus nerve, was inhibited by NPY in the guinea pig and in the rat (ED35, 3.5 +/- 0.46 and 11.2 +/- 1.79 nmol/kg, respectively; p < 0.05) but not in the rabbit. In the guinea pig, the Y2-receptor-preferring fragment NPY(3-36) and the selective Y1-receptor antagonist H 409/22 were used to confirm that the increase in blood pressure was mediated solely through the Y1-receptor and the vagal inhibition solely through the Y2-receptor. Aside from the cardiovascular effects, NPY caused a decrease in the body temperature and inhibited vagal bronchoconstriction in this species. Considering that NPY may cause depressor effects in the rat and has no effect on the vagal bradycardia in the rabbit, the guinea pig is preferable to both these species for assessment of Y1- and Y2-receptor-active agents in vivo.

Role of NPY Y1 receptors in cardiovascular control in the conscious rabbit

Prejunctional neuropeptide Y (NPY) Y1 receptors on cardiac sympathetic neurons mediate transient inhibition of chronotropic responses in rabbit isolated right atria. The function of these receptors remains speculative. We investigated a possible functional role for these receptors in modulation of the baroreceptor-heart rate (HR) reflex in the conscious rabbit. Mean arterial pressure (MAP) responses to a range of doses of the Y1 receptor agonist [Leu31,Pro34]NPY (1-8 microg/kg, i.v.) were constructed in ganglion-blocked rabbits. After administration of the selective Y1 receptor antagonist GR231118(150 microg/kg, i.v.), two-point [Leu31,Pro34]NPY dose-pressor responses were assessed. Linear regression analysis of the relation between the shift in the [Leu31,Pro34]NPY dose-pressor response lines against time was used as an estimate of the functional half-life of GR231118. GR231118 shifted the two-point [Leu31,Pro34]NPY dose-pressor response relation by 10- to 30-fold. A single estimate of the functional half-life of a bolus dose of GR231118 was 25 +/- 2 min. This determination allowed a steady-state Y1-receptor blockade to be established by a bolus and infusion. In a separate group of rabbits, the baroreceptor-HR reflex was assessed before and 30 min after administration of GR231118 (150 microg/kg bolus, then 150 microg/ kg/h, i.v.). GR231118 caused an initial transient pressor response and bradycardia, followed by a depressor response and a more sustained tachycardia. Infusion of GR231118 had no effect on the baroreceptor-HR reflex. Prejunctional Y1 receptors appear not to mediate a tonic inhibition of cardiac sympathetic neurotransmission in the conscious rabbit during physiological manipulations in MAP. However, activation of postjunctional Y1 receptors by neuronal or circulating NPY may be important in maintenance of vascular tone in the conscious rabbit.

Vascular neuropeptide Y Y1-receptors in the rat kidney: vasoconstrictor effects and expression of Y1-receptor mRNA

Neuropeptide Y (NPY) -receptor subtypes were studied in the rat kidney in vivo by systemic administration of NPY, the two agonists [Leu(31), Pro(34)]NPY (Y1-receptor agonist) and NPY (13-36) (Y2-receptor agonist), or the Y1-receptor antagonist BIBP 3226. Effects on mean arterial blood pressure (MAP) and renal arterial blood flow were recorded. The Y1-receptor agonist evoked a dose-dependent increase in MAP concomitantly with a reduction in renal blood flow. At the largest dose administered (1.42 pmol/g), the Y1-agonist [Leu(31), Pro(34)] NPY increased MAP by 20 +/- 6 mmHg and reduced the renal vascular conductance by more than 50%. The same dose of the Y2-agonist NPY (13-36) did not evoke any clear-cut effects on the renal blood flow or MAP. Furthermore, administration of the Y1-receptor antagonist BIBP 3226 reduced the NPY-induced renal vasoconstriction, but did not affect the response to angiotensin II or phenylephrine. The effects evoked by 0.71 pmol/g NPY were almost abolished by 3 mg/kg BIBP 3226. In situ hybridization histochemistry was used to study the expression of Y1-receptor mRNA in the developing rat kidney. The levels of Y1-receptor mRNA expression in the vascular smooth muscle of the rat kidney varied at different ages, with low levels at postnatal day 10 and high levels at 20 days and again low levels at 40 days. In summary, the present study show a maturation-specific expression pattern of NPY Y1-receptor mRNA as well as functional effects of vascular NPY receptors of the Y1-subtype in the rat kidney.

Neuropeptide Y family of hormones: receptor subtypes and antagonists

Neuropeptide Y (NPY) is the most abundant peptide present in the mammalian central and peripheral nervous system. NPY exhibits a variety of potent central and peripheral effects including those on feeding, memory, blood pressure, cardiac contractility and intestinal secretions. Classical pharmacological studies have shown that NPY effects are mediated by four different receptor subtypes, Y-1, Y-1-like, Y-2, and Y-3. However, the existence of numerous atypical activities provide strong evidence for the occurrence of additional NPY receptor subtypes. Pharmacological studies have further been facilitated by the recent cloning and expression of Y-1, Y-2, Y-4 (PP-1) and Y-5 receptors. Moreover, the cloned Y-5 receptor has been suggested to be the long awaited Y-1-like receptor involved in feeding. Structure-activity studies have laid a good foundation towards the development of receptor selective compounds, and to date potent Y-1 selective peptide and nonpeptide antagonists have been developed. The need to clone numerous receptor subtypes and to develop receptor selective compounds for physiological and perhaps clinical use is expected to keep NPY research active for many years to come.

Intravenous NPY (27-36)-D decreases cardiac output in conscious Sprague-Dawley rats

Intravenous (IV) administration of NPY (27-36)-D, a substituted carboxyterminal fragment of neuropeptide Y (NPY), decreases mean arterial pressure (MAP) in normo-and hypertensive rats by a mechanism partially involving histamine receptors. The purpose of this study is to further characterize the cardiovascular effects of NPY (27-36)-D. NPY (27-36)-D dose-dependently decreased MAP, cardiac output, and stroke volume without significantly altering peripheral resistance. Myocardial contractility diminished by 151.2 +/- 31.8, 529.6 +/- 182.5, and 495.4 +/- 66.7 mmHg/s2 in rats treated with 300, 500, and 750 nmol/kg NPY (27-36)-D, respectively. Therefore, NPY (27-36)-D modifies MAP, in part, by a reversible negative inotropic effect on the heart.

Structure activity studies of mast cell activation and hypotension induced by neuropeptide Y (NPY), centrally truncated and C-terminal NPY analogues

1. Neuropeptide-induced histamine release is thought to occur via receptor-independent mechanisms, with net charge and lipophilicity being important factors. 2. In this study, the histamine releasing ability of neuropeptide Y (NPY), two C-terminal segments of NPY and 13 centrally truncated NPY analogues was examined. These results were compared with the ability of the peptides to bind to the Y2 receptor in the rabbit kidney membrane model and with their hypotensive actions in the anaesthetized-rat model. 3. All analogues tested, with the exception of [Glu4,25,33,35]-NPY(1-4)-Ahx-(25-36) and [Asp4,25,33,35]NPY(1-4)-Ahx-(25-36) which were devoid of histamine releasing activity, evoked a dose-dependent histamine release but there were marked differences between the peptides. The native peptide was the least active. 4. Histamine release was not linked to the ability of the peptides to displace NPY from Y2 receptors. There was a statistical correlation between the hypotensive effects expressed as ED10 values (mumol kg-1, which induced a blood pressure decrease of 10 mmHg) and the EC25 for histamine release (r = 0.62, P = 0.04), although histamine release may not be the sole determinant of the alterations in blood pressure. 5. There was a strong negative correlation between EC25 for histamine release and net positive charge (r = -0.93, P = 5.7 x 10(-7), i.e. increasing the net positive charge caused greater histamine release. However, there was a 12 fold difference in activity amongst the most positively charged analogues (+5). Helicity did not correlate with histamine releasing ability. 6. In the development of NPY-related drugs the avoidance of compounds with net positive charge is recommended.

Structural requirements for neuropeptide Y in mast cell and G protein activation

Incubation of neuropeptide Y or its C-terminal fragments with rat peritoneal mast cells resulted in a dose-dependent histamine release. Fragment 18-36 of neuropeptide Y was the most biologically active peptide. EC25 value on rat mast cells was 7.2 +/- 2.2 nM. Neuropeptide Y was also able to induce a flare response after intradermal injection in humans. The histamine releasing effects of neuropeptide Y related peptides were greatly inhibited by pretreatment of rat mast cells with pertussis toxin or benzalkonium chloride. Neuropeptide Y and C-terminal related peptides also stimulated the GTPase activity of purified heterotrimeric G proteins in a dose-dependent manner from 1 to 50 microM. Binding studies with [125I]neuropeptide Y were unable to provide evidence for the presence of specific binding sites on the surface of mast cells. The alpha helical conformation of neuropeptide Y fragments was studied by measuring the circular dichroism spectra. Neuropeptide Y-(18-36) was the smallest fragment having a strong helical conformation. Our results demonstrate that neuropeptide Y activates mast cells through a non-specific process leading to G protein activation.

Hypotensive effects of [D-Tyr27,36, D-Thr32]Neuropeptide Y (27-36)

An analogue of the 10 C-terminal amino acids of neuropeptide Y (NPY) containing three D-isomeric substitutions (27-36-D) has been synthesized and its cardiovascular activity studied in Sprague-Dawley (SD) and spontaneously hypertensive (SHR) rats. Intravenous administration of 1000 nmol/kg 27-36-D decreases MAP in SHR (-59.9 +/- 5.0 mmHg) and SD rats (-44.4 +/- 4.7 mmHg). The hypotension produced by 1000 nmol/kg 27-36-D diminished by 71.2% following pretreatment with the histamine receptor antagonist diphenhydramine, although histamine depletion with compound 48/80 does not significantly alter this hypotension. These data suggest that NPY (27-36)-D produces a profound and sustained hypotension in two strains of rat which is partially attributable to activity at histamine receptors.

Histamine-independent modulation of the neuropeptide Y-induced pressor response by alpha-trinositol in the pithed rat

The modulatory effects of alpha-trinositol (D-myo-inositol-1.2.6- trisphosphate; PP 56) on the systemic arterial blood pressor responses induced by neuropeptide Y, preganglionic nerve stimulation, phenylephrine and vasopressin were studied in pithed rats. Intravenous administration (within 2 min.) of alpha-trinositol reduced the neuropeptide Y-induced increase in mean arterial pressure within a defined dose range without altering the heart rate. The influence of alpha-trinositol on the neuropeptide Y-induced pressor response in the presence of non-selective as well as H1- and H2-selective histamine antagonists (diphenhydramine, mepyramine and cimetidine respectively) were investigated. The maximal increase in mean arterial pressure induced by neuropeptide Y as well as the duration of the pressor response was enhanced after nonselective (diphenhydramine) or H1-selective (mepyramine) histamine blockade. The enhancement of the neuropeptide Y-induced pressor response by the H1 specific antagonist mepyramine was significantly more pronounced compared to the H2-selective agent. The exaggerated increase in mean arterial pressure in response to neuropeptide Y after histamine blockade was inhibited by alpha-trinositol to a similar extent as without such pretreatment. We conclude that neuropeptide Y interacts with histamine in the pithed rat and that this action may partially offset the pressor actions of the peptide. The neuropeptide Y-induced pressor responses may be inhibited by alpha-trinositol within a defined dose range indicating that this non-peptide agent may act as a functional inhibitor to neuropeptide Y in vascular tissue.

Neuropeptide Y and truncated neuropeptide Y analogs evoke histamine release from rat peritoneal mast cells. A direct effect on G proteins?

Several regulatory peptides, including neuropeptide Y, can release histamine from mast cells. In the present study we investigated which parts of the neuropeptide Y molecule are required to evoke the release of histamine from isolated rat peritoneal mast cells. In addition, we examined whether the histamine release evoked by neuropeptide Y (and by compound 48/80) is sensitive to the G protein inhibitors pertussis toxin and benzalkonium chloride. Neuropeptide Y released histamine in a concentration-dependent manner. Also a neuropeptide Y analog with the center part substituted by 8-aminooctanoic acid, [Aoc2-27]neuropeptide Y, and the cyclic form of the C-terminal hexapeptide, cyclic neuropeptide Y-(31-36), released histamine. The three peptides were equally effective and equally potent. Neuropeptide Y-(1-24)NH2 also released histamine, but its efficacy was low. The rank order of potency of the analogs tested did not agree with that of any of the previously known or postulated neuropeptide Y receptors. Pretreatment of mast cells with pertussis toxin or benzalkonium chloride markedly inhibited the histamine release evoked by neuropeptide Y, [Aoc2-27]neuropeptide Y and compound 48/80. In conclusion, most of the histamine-releasing activity of neuropeptide Y resides in the six C-terminal amino acid residues. The release appears to be G protein-dependent and is probably not receptor mediated.

A novel neuropeptide Y analog, N-acetyl [Leu28,Leu31]neuropeptide Y-(24-36), with functional specificity for the presynaptic (Y2) receptor

We have carried out functional and in vitro studies on a novel analog of neuropeptide Y which shows selectivity for the prejunctional or neuropeptide Y Y2 receptor. In anaesthetised rats N-acetyl [Leu28,Leu31]neuropeptide Y-(24-36) attenuates cardiac vagal action (a prejunctional or neuropeptide Y Y2 action) and has no significant pressor effects (postjunctional or neuropeptide Y Y1 action). In the human neuroblastoma cell line (SMS-KAN) which expresses and endogenous Y2-like neuropeptide Y receptor, N-acetyl [Leu28,Leu31]neuropeptide Y-(24-36) competes with peptide YY for binding sites with an IC50 of 0.5 +/- 0.1 nM. In contrast in a fibroblast Chinese hamster ovary cell line which expresses the cloned human neuropeptide Y Y1 receptor and is used to study changes in cytosolic calcium evoked by (a neuropeptide Y Y1 effect), N-acetyl [Leu28,Leu31]neuropeptide Y-(24-36) showed no activity even at high concentrations. The steric structure for this novel compound has been determined using proton nuclear magnetic resonance (NMR) spectroscopy and it is consistent with the C-terminal end of published structures of neuropeptide Y. We suggest acetylation and amino acid substitutions stabilise the molecule and allow it to bind only to the neuropeptide Y Y2 receptor.

Subtypes of receptors for neuropeptide Y: implications for the targeting of therapeutics

Neuropeptide Y is a 36 amino acid peptide that was originally discovered in extracts of porcine brain. The peptide has a broad distribution in the central or peripheral nervous system. Receptors for this peptide were originally subdivided into postsynaptic Y-1 receptors and presynaptic Y-2 receptors. The Y-1 receptor has recently been cloned and appears to mediate several effects of NPY including vasoconstriction and an anxiolytic effect in animal models of anxiety. The Y-2 receptor inhibits the release of neurotransmitters in the CNS by the inhibition of the mobilization of intracellular calcium. Additional receptors have been proposed including a Y-3 receptor that recognizes NPY but not the related endocrine peptide, PYY. The functional importance of these newer receptors remains to be established. The absence of useful antagonists has made the study of NPY a challenge for investigators in the field. The potential utility of such molecules is discussed.

Multiple neuropeptide Y receptors are involved in cardiovascular regulation. Peripheral and central mechanisms

1. Neuropeptide Y (NPY) occurs in both the central and peripheral nervous system. In the periphery, NPY coexists with noradrenaline (NA) in perivascular sympathetic fibers. 2. NPY has a vasopressor effect, reflecting direct vasoconstriction of blood vessels and potentiation of the NA-evoked response. NPY also suppresses the release of NA from sympathetic fibers. 3. The post- and pre-junctional NPY receptors are referred to as Y1 and Y2, respectively. They recognize not only NPY but also the homologous gut hormone peptide YY (PYY). 4. The Y1 and Y2 receptors have been characterized in numerous test systems using analogs of NPY/PYY. Already the deletion of the first N-terminal amino acid (NPY 2-36) results in a marked loss of potency at the Y1 receptor. The Y2 receptor is much less dependent upon an intact N-terminus, and a wide range of C-terminal NPY fragments retain quite high potency. 5. Recently, yet another NPY receptor, Y3, that is distinct from Y1 and Y2 in that it recognizes PYY poorly, has been demonstrated in the brainstem and in the periphery. 6. Further attempts to characterize the various receptor types have relied on truncated and substituted analogs of NPY/PYY. Although such studies suggest the existence of at least three types of NPY receptors, the lack of antagonists has represented a problem. 7. Since NPY may regulate cardiovascular functions via peripheral and central receptors its physiological and possibly pathophysiological significance has attracted much attention. 8. The responsiveness to NPY seems to be altered in animal models of hypertension and elevated plasma levels of NPY have been found in patients under various conditions of stress and in primary hypertension. A number of studies have suggested that NPY may be a pathogenetic factor behind primary hypertension. 9. Antagonists for the various NPY receptors would be useful for an analysis of which effects of these peptides are physiologically relevant. It is tempting to predict that both agonists and antagonists of the NPY receptors could be useful as drugs, for instance, in the treatment of primary hypertension.

Antagonism of pre- and postjunctional responses to neuropeptide Y and sympathetic stimulation by D-myo-inositol-1,2,6-trisphosphate in the anaesthetised dog

Pre- and postjunctional responses to nerve released or exogenous neuropeptide Y (NPY) were measured in the anaesthetised dog before and after administration of D-myo-inositol-1,2,6-trisphosphate (PP56) a putative NPY antagonist. The inhibition of the increase in pulse interval evoked by vagal stimulation was used as a measure of prejunctional action of NPY and the magnitude of increase in blood pressure was used as a measure of postjunctional action of NPY (direct action or constrictor potentiating). Elevated plasma levels of PP56 were maintained throughout the course of the experiment. PP56 significantly reversed the inhibitory effect of NPY (nerve released or exogenous) on cardiac vagal action, and significantly inhibited the pressor response to exogenous NPY. PP56 did not affect the pressor response to intravenous phenylephrine, a selective alpha-adrenoceptor agonist. PP56 therefore significantly antagonises both pre- and postjunctional effects of NPY (nerve released and exogenous) and, with respect to its postjunctional antagonism, this action is selective for NPY.

Unmasking the vasoconstrictor response to neuropeptide Y and its interaction with vasodilating agents in vitro

Neuropeptide Y (NPY) is a powerful vasoconstrictor in vivo but is usually much less active on isolated blood vessels. The contractile effect of NPY was examined in the isolated rat femoral artery exposed to various degrees of vasoconstriction. The effects of NPY on the relaxation induced by vasodilator agents was also studied. NPY (< or = 1 microM) had no contractile effect. In vessels pretreated with a low concentration of phenylephrine (0.3-1.0 microM), NPY evoked a concentration-dependent contraction, which was similar in intact and in endothelium-deprived vessels. Other vessels were contracted with phenylephrine (3-10 microM) and relaxed with histamine (0.1 mM). Subsequent addition of NPY elicited a contraction which was much greater than that observed in vessels pretreated with phenylephrine only. The Y1 receptor agonist, [Pro34]NPY, but not the Y2 receptor agonist, NPY 13-36, evoked a concentration-dependent contraction in phenylephrine-pretreated vessels. Acetylcholine (ACh) induced endothelium-dependent relaxation in vessels contracted with phenylephrine. NPY (0.1 microM) induced a rightward shift of the concentration-response curve and a lower maximum relaxation in response to ACh. NPY was without effect on the dilatation evoked by nitroprusside, histamine or forskolin. In conclusion, under appropriate vasoconstrictor and vasodilator influence, NPY can act at Y1 receptors to evoke vasoconstriction in the femoral artery via endothelium-independent mechanisms. In addition, NPY seems to attenuate the endothelium-dependent relaxation induced by ACh. These actions of NPY may contribute to explain the strong vascular effects of the peptide in vivo.

Interstitial cystitis: increased sympathetic innervation and related neuropeptide synthesis

To investigate the possibility of a neural deterioration of the bladder wall in interstitial cystitis, bladder tissue from 10 patients with interstitial cystitis was compared with that from 10 control subjects by means of immunohistochemistry. An enhanced innervation of the bladder in the submucosa and detrusor muscle was found to represent an increase of sympathetic but not cholinergic neurons. In interstitial cystitis the number of neurons positive for vasoactive intestinal polypeptide and neuropeptide Y was higher and carried a larger number of axonal varicosities, whereas the number of neurons positive for substance P and calcitonin-gene-related peptide was not significantly different in both groups. We conclude that interstitial cystitis is associated with increased sympathetic outflow into the bladder and altered metabolism of vasoactive intestinal polypeptide and neuropeptide Y. Since similar changes have been observed in other inflammatory diseases of a presumably autoimmune nature, such as rheumatoid arthritis, Crohn's disease and colitis ulcerosa, the pathophysiology of interstitial cystitis may share common pathways with the latter. Experience in these diseases may facilitate a better understanding of the pathophysiology of interstitial cystitis and suggest new therapeutic concepts.

Characterization of vascular neuropeptide Y receptors

1. In the present study we compared neuropeptide Y (NPY) and NPY-related analogues for their ability to activate or bind to vascular NPY receptors in four experimental set-ups. Previous results have suggested the existence of different receptor subtypes, Y1 receptors requiring full-length NPY (1-36) or [Pro34]-NPY, and Y2 receptors recognizing also N-terminally truncated forms of NPY but not [Pro34]-NPY. 2. NPY 1-36 and [Pro34]-NPY dose-dependently increased arterial pressure in the anaesthetized rat with a similar magnitude and potency. NPY 2-36 was much less potent than NPY 1-36. NPY 4-36 and NPY 11-36 were inactive even at a dose as high as 10 nmol kg-1. 3. NPY 1-36, [Pro34]-NPY, NPY 2-36 and NPY 5-36 concentration-dependently increased the coronary resistance in the Langendorff preparation of the rat. NPY 1-36 and [Pro34]-NPY were equipotent, while NPY 2-36 and NPY 5-36 were about 7 and 20 times less potent. At 0.3 microM, NPY 11-36, NPY 20-36 and NPY 22-36 induced a slight contraction while NPY 23-36 was inactive. 4. NPY 1-36, [Pro34]-NPY, NPY 2-36, NPY 4-36, NPY 5-36 and NPY 11-36 evoked concentration-dependent contractions in the isolated inferior caval vein of the rat and guinea-pig. [Pro34]-NPY was more potent than NPY 1-36. NPY 2-36 was equipotent with NPY 1-36, while NPY 4-36, NPY 5-36 and NPY 11-36 were approximately 30 times less potent.5. [Pro34]-NPY was equipotent with NPY 1-36 in displacing the '25I-labelled gut hormone peptide([1251]-PYY) from rat aortic smooth muscle cells, while NPY 2-36 and shorter forms of NPY were much less potent or inactive.6. In caval vein smooth muscle cells of the rat, the displacement pattern was more complex than in aortic smooth muscle cells, in that both [Pro34]-NPY and NPY 13-36 effectively displaced the radioligand,albeit none of them completely.7. In conclusion, the NPY-evoked pressor response in the whole rat and coronary vessels seems to be mediated by vascular Y1 receptors and the binding characteristics of the NPY-related peptides in the aortic smooth muscle cells correspond to a population of such receptors. In the caval vein, the profile of the bioactivity and the binding affinity of the NPY-related peptides suggest a mixed population of Y1/Y2 receptors.

Neuropeptide Y, peptide YY and C-terminal fragments release histamine from rat peritoneal mast cells

1. Neuropeptide Y (NPY) and peptide YY (PYY) seem to act on at least two receptor subtypes, Y1 and Y2. The Y1-receptor requires the whole C-terminally amidated NPY/PYY molecule whereas the Y2-receptor in addition recognizes C-terminal fragments of the two peptides. The present study was designed to elucidate whether NPY and related peptides were able to release histamine from isolated peritoneal mast cells of the rat. 2. NPY, NPY 15-36, NPY 22-36, NPY 26-36 and desamido-NPY evoked a concentration-dependent release of mast-cell histamine. The pEC15 values for NPY 15-36 and NPY 22-36 were higher, while the pEC15 value for NPY 26-36 was lower than that for NPY. At the highest concentration tested (0.1 mM), NPY and its C-terminal fragments released between 30 and 40% of the total histamine content. At the same concentration desamido-NPY released about 20%. 3. PYY and PYY 15-36 also evoked a concentration-dependent release of mast-cell histamine. PYY was more effective than PYY 15-36 since, at 0.1 mM, PYY released about 33%, while PYY 15-36 released about 15% of the total histamine content. Pancreatic polypeptide (PP) and the Y1-receptor-selective agonist [Pro34]NPY were virtually inactive. 4. The effect profile of the NPY/PYY-related peptides suggests that they act on the mast cells by a mechanism that does not involve either of the receptor subtypes hitherto described. The kinetics of the NPY-evoked histamine release may suggest that positively charged amino acid residues of NPY/PYY release mast-cell histamine by a non-receptor mechanism, as has been suggested for substance P and other basic peptides.

C-terminal neuropeptide Y fragments are mast cell-dependent vasodepressor agents

Neuropeptide Y (NPY) is a well-established vasopressor agent present in sympathetic perivascular nerves. Recently, it was found that high doses of the peptide cause a biphasic pressor-depressor response upon intravenous administration. We now report that C-terminal NPY fragments (NPY-(18-36) and NPY-(22-36] given intravenously to conscious or pithed (areflexive) male Sprague-Dawley rats mimic the depressor component of the NPY-(1-36) response while displaying very low pressor activity. Additionally, we have found that the depressor component is blocked by the histamine H1-antagonist, mepyramine. Since the fragment, NPY-(22-36), was equipotent with NPY in inducing histamine release from isolated peritoneal mast cells, we conclude that short C-terminal NPY fragments, like NPY itself, act on mast cells to initiate histamine-mediated cardiovascular actions. Such actions may conceivably be accounted for by the abundance of positively charged amino acid residues in the C-terminus. Moreover, these fragments have little affinity for vascular NPY receptors, as indicated by their poor ability to displace iodinated NPY or peptide YY (PYY) from specific binding sites on vascular smooth muscle cells derived from rat aorta. In conclusion, we propose that short C-terminal NPY fragments, which contain several positively charged amino acid residues, retain the ability of NPY to release histamine from rat mast cells while being essentially devoid of direct vascular motor activity.

Receptors for neuropeptide Y: multiple subtypes and multiple second messengers

Neuropeptide Y (NPY) can elicit numerous physiological responses by activating specific pre- and postsynaptic receptors. Different orders of potency for agonists in various model systems suggest that there are multiple subtypes of NPY receptors, described here by Martin Michel, but their pharmacological definition remains tentative, awaiting development of specific antagonists and receptor cloning studies. The coupling of NPY receptors to various signal transduction mechanisms is also reviewed, including inhibition of adenylyl cyclase and stimulation or inhibition of increases in intracellular Ca2+, but a link between individual NPY receptor subtypes and specific signal transduction pathways has not been established.

N-alpha-biotinylated-neuropeptide Y analogs: syntheses, cardiovascular properties, and application to cardiac NPY receptor visualization

Two monobiotinylated analogs of neuropeptide Y (NPY) were synthesized by coupling the N-hydroxysuccinimidyl esters of biotin and (6-biotinylamido)-hexanoic acid, respectively, to the free alpha-NH2 group of the side chain protected NPY peptide resin. Crude peptides obtained by HF cleavage were purified by RPLC and their integrities were confirmed by amino acid and mass spectral analysis. As with NPY, both biotinylated analogs inhibited 125I-NPY binding and adenylate cyclase activity of rat cardiac ventricular membranes in a dose-dependent manner. N-alpha-[(6-biotinylamido)-hexanoyl]-NPY exhibited potencies comparable to that of NPY whereas N-alpha-biotinyl-NPY was slightly less potent. In the in vivo experiments, however, both the biotinylated analogs exhibited responses comparable to NPY in increasing arterial blood pressure and decreasing heart rate in anesthetized rats. The responses of the biotinyl analogs were longer lasting than those of NPY. Histochemical studies revealed that N-alpha-[(6-biotinylamido)-hexanoyl]-NPY could label the NPY receptors in rat cardiac ventricular tissues. This labeling was specific since intact NPY inhibited the staining. These studies show that biotinyl-NPY analogs exhibit biological potencies comparable to intact NPY and can therefore be used to further probe the NPY-receptor interaction.

Neuropeptide Y receptor subtypes, Y1 and Y2

Heterogeneity among NPY (and PYY) receptors was first proposed on the basis of studies on sympathetic neuroeffector junctions, where NPY (and PYY) can exert three types of action: 1) a direct (e.g., vasoconstrictor) response; 2) a postjunctional potentiating effect on NE-evoked vasoconstriction; and 3) a prejunctional suppression of stimulated NE release; the two latter phenomena are probably reciprocal, since NE affect NPY mechanisms similarly. It was found that amidated C-terminal NPY (or PYY) fragments, e.g., NPY 13-36, could stimulate selectively prejunctional NPY/PYY receptors, which were termed Y2-receptors. Consequently, the postjunctional receptors which were activated poorly by NPY/PYY fragments, were termed Y1-receptors. Later work has indicated that the Y2-receptor may occur postjunctionally in selected sympathetic effector systems. The central nervous system appears to contain a mixture of Y1- and Y2-receptors as indicated by functional as well as binding studies. For instance, NPY and NPY 13-36 produced diametrically opposite effects on behavioral activity, indicating the action of the parent peptide on two distinct receptors. Cell lines, most importantly neuroblastomas, with exclusive populations of Y1- or Y2-receptors, have been characterized by binding and second messenger studies. In this work, selective agonists for the two receptor subtypes were used. Work of many investigators has formed the basis for subclassifying NPY/PYY effects being mediated by either Y1- or Y2-receptors. A preliminary subclassification based on effects of NPY, PYY, fragments and/or analogs is provided in Table 6. It is, however, to be expected that further receptor heterogeneity will be revealed in the future. It is argued that mast cells possess atypical NPY/PYY receptors. The histamine release associated with stimulation of the latter receptors may, at least in part, underlie the capacity of NPY as well as of short C-terminal fragments to reduce blood pressure. Fragments, such as NPY 22-36, appear to be relatively selective vasodepressor agents because of their weak vasopressor properties.(ABSTRACT TRUNCATED AT 400 WORDS)