Pulsatile perfusion and cardiomyocyte viability in a solid three-dimensional matrix.

BACKGROUND: The manufacture of full thickness three-dimensional myocardial grafts by means of tissue engineering is limited by the impeded cellular viability in unperfused in vitro systems. We introduce a novel concept of pulsatile tissue culture perfusion to promote ubiquitous cellular viability and metabolism. METHODS: In a novel bioreactor we established pulsatile flow through the embedded three-dimensional tissue culture. Fibrin glue served as the ground matrix wherein neonatal rat cardiomyocytes were inoculated. Fluor-Deoxy-Glucose-Positron-Emission-Tomography (FDG-PET) and life/dead assays were employed for comparative studies of glucose uptake resp. cell viability. RESULTS: A solid 8 mm thick structure resulted. Cellular viability significantly increased in the perfused chambers. We observed centripetal migration of the embedded cardiomyocytes to the site of the core vessel. However, cellular viability was high in the periphery of the tissue block too. FDG-PET revealed enhanced metabolic activity in perfused chambers. CONCLUSIONS: The present concept is highly effective in enhancing cellular viability and metabolism in a three-dimensional tissue culture environment. It could be utilized for various co-culture systems and the generation of viable tissue grafts.

Clinically established hemostatic scaffold (tissue fleece) as biomatrix in tissue- and organ-engineering research.

Various types of three-dimensional matrices have been used as basic scaffolds in myocardial tissue engineering. Many of those are limited by insufficient mechanical function, availability, or biocompatibility. We present a clinically established collagen scaffold for the development of bioartificial myocardial tissue. Neonatal rat cardiomyocytes were seeded into Tissue Fleece (Baxter Deutschland, Heidelberg, Germany). Histological and ultrastructural examinations were performed by DAPI and DiOC(18) staining and electron microscopy, respectively. Force measurements from the spontaneously beating construct were obtained. The constructs were stimulated with agents such as adrenalin and calcium, and by stretching. Passive stretch curves were obtained. Spontaneous contractions of solid bioartificial myocardial tissue (BMT), 20 x 15 x 2 mm, resulted. Contractions continued to week 12 (40% of BMTs) in culture. Histology revealed intercellular and also cell-fibril junctions. Elasticity was similar to that of native rat myocardium. Contractile force increased after topical administration of Ca(2+) and adrenaline. Stretch led to the highest levels of contractile force. In summary, bioartificial myocardial tissue with significant in vitro longevity, spontaneous contractility, and homogeneous cell distribution was produced using Tissue Fleece. Tissue Fleece constitutes an effective scaffold to engineer solid organ structures, which could be used for repair of congenital defects or replacement of diseased tissue.

Carboxyfluorescein diacetate succinimidyl ester facilitates cell tracing and colocalization studies in bioartificial organ engineering.

BACKGROUND: We demonstrate a method that includes colocalization studies to analyze cell suspensions after isolation and to characterize 3-dimensional grafts consisting of cells and matrix in vitro and in vivo. MATERIALS AND METHODS: Neonatal rat cardiomyocytes were labelled by CFDA-SE after harvest. Cells in the isolated cell suspension, the embodied cells in the seeded scaffolds were characterized measuring features such as viability and distribution of the cell types. RESULTS: Selective cell count revealed high yields of viable cardiomyocytes. After seeding cells in collagen matrix, viability of the cells decreased gradually in the time process in vitro. Histology of implanted bioartificial myocardial tissue detected viable cardiomyocytes within the graft. CONCLUSION: Using colocalization histology we could label and track cells within the bioartificial myocardial tissue graft in vitro and post implant and assess viability and distribution.

In vitro engineering of heart muscle: artificial myocardial tissue.

INTRODUCTION: Myocardial infarction followed by heart failure represents one of the major causes of morbidity and mortality, particularly in industrialized countries. Engineering and subsequent transplantation of contractile artificial myocardial tissue and, consequently, the replacement of ischemic and infarcted areas of the heart provides a potential therapeutic alternative to whole organ transplantation. METHODS: Artificial myocardial tissue samples were engineered by seeding neonatal rat cardiomyocytes with a commercially available 3-dimensional collagen matrix. The cellular engraftment within the artificial myocardial tissues was examined microscopically. Force development was analyzed in spontaneously beating artificial myocardial tissues, after stretching, and after pharmacologic stimulation. Moreover, electrocardiograms were recorded. RESULTS: Artificial myocardial tissues showed continuous, rhythmic, and synchronized contractions for up to 13 weeks. Embedded cardiomyocytes were distributed equally within the 3-dimensional matrix. Application of Ca(2+) and epinephrine, as well as electrical stimulation or stretching, resulted in enhanced force development. Electrocardiographic recording was possible on spontaneously beating artificial myocardial tissue samples and revealed physiologic patterns. CONCLUSIONS: Using a clinically well-established collagen matrix, contractile myocardial tissue can be engineered in vitro successfully. Mechanical and biologic properties of artificial myocardial tissue resemble native cardiac tissue. Use of artificial myocardial tissues might be a promising approach to reconstitute degenerated or failing cardiac tissue in many disease states and therefore provide a reasonable alternative to whole organ transplantation.

Synthetic inhibitors of endopeptidase EC 3.4.24.15: potency and stability in vitro and in vivo.

1. The role of the metalloendopeptidase EC 3.4.24.15 (EP 24.15) in peptide metabolism in vivo is unknown, in part reflecting the lack of a stable enzyme inhibitor. The most commonly used inhibitor, N-[1-(R,S)-carboxy-3-phenylpropyl]-Ala-Ala-Tyr-p-aminobenzoate (cFP-AAY-pAB, Ki = 16 nM), although selective in vitro, is rapidly degraded in the circulation to cFP-Ala-Ala, an angiotensin converting enzyme (ACE) inhibitor. This metabolite is thought to be generated by neutral endopeptidase (NEP; EC 3.4.24.11), as the Ala-Tyr bond of cFP-AAY-pAB is cleaved by NEP in vitro. In the present study, we have examined the role of NEP in the metabolism of cFP-AAY-pAB in vivo, and have tested a series of inhibitor analogues, substituted at the second alanine, for both potency and stability relative to the parent compound. 2. Analogues were screened for inhibition of fluorescent substrate cleavage by recombinant rat testes EP 24.15. D-Ala or Asp substitution abolished inhibitory activity, while Val-, Ser- and Leu-substituted analogues retained activity, albeit at a reduced potency. A relative potency order of Ala (1) > Val (0.3) > Ser (0.16) > Leu (0.06) was observed. Resistance to cleavage by NEP was assessed by incubation of the analogues with rabbit kidney membranes. The parent compound was readily degraded, but the analogues were twice (Ser) and greater than 10 fold (Leu and Val) more resistant to cleavage. 3. Metabolism of cFP-AAY-pAB and the Val-substituted analogue was also examined in conscious rabbits. A bolus injection of cFP-AAY-pAB (5 mg kg-1, i.v.) significantly reduced the blood pressure response to angiotensin I, indicating ACE inhibition. Pretreatment with NEP inhibitors, SCH 39370 or phosphoramidon, slowed the loss of cFP-AAY-pAB from the plasma, but did not prevent inhibition of ACE. Injection of 1 mg kg-1 inhibitor resulted in plasma concentrations at 10 s of 23.5 microM (cFP-AAY-pAB) and 18.0 microM (cFP-AVY-pAB), which fell 100 fold over 5 min. Co-injection of 125I-labelled inhibitor revealed that 80-85% of the radioactivity had disappeared from the circulation within 5 min, and h.p.l.c. analysis demonstrated that only 25-30% of the radiolabel remained as intact inhibitor at this time. Both analogues were cleared from the circulation at the same rate, and both inhibitors blunted the pressor response to angiotensin I, indicative of ACE inhibition. 4. These results suggest that both NEP and other clearance/degradation mechanisms severely limit the usefulness of peptide-based inhibitors such as cFP-AAY-pAB. To examine further EP 24.15 function in vivo, more stable inhibitors, preferably non-peptide, must be developed, for which these peptide-based inhibitors may serve as useful molecular templates.

The role of neuropeptide Y (NPY) in the control of LH secretion in the ewe with respect to season, NPY receptor subtype and the site of action in the hypothalamus.

Neuropeptide Y1-36 (NPY1-36) acts through Y1 and Y2 receptors while the C-terminal NPY fragments NPY18-36 and N-acetyl[Leu28,31]pNPY24-36 act only through the Y2 receptor. We have investigated the effects of intracerebroventricular (i.c.v.) administration of NPY1-36, NPY18-36 and N-acetyl[Leu28,31]pNPY24-36 on LH secretion in the ovariectomised (OVX) ewe. These peptides were administered into a lateral ventricle (LV) or the third ventricle (3V) of OVX ewes during the non-breeding and breeding seasons. Microinjections of NPY were also made into the preoptic area (POA) during both seasons to investigate the effects of NPY at the level of the GnRH cell bodies. Tamed sheep were fitted with 19 gauge guide tubes into the LV, 3V or the septo-preoptic area (POA). Jugular venous blood samples were taken every 10 min for 3 h. Sheep were then given NPY1-36 (10 micrograms), NPY18-36 (100 micrograms) or saline vehicle into the LV; N-acetyl[Leu28,31]pNPY24-36 (100 micrograms), NPY1-36 (10 micrograms or 100 micrograms), NPY18-36 (10 micrograms or 100 micrograms) or saline vehicle into the 3V, or NPY1-36 (1 microgram, 5 micrograms, 10 micrograms) into the POA. Blood sampling continued for a further 3 h. LH was measured in plasma by radioimmunoassay. LV or 3V injection of 10 micrograms NPY1-36 caused a small but significant (P < 0.025) increase in the interval from the last pre-injection pulse of LH to the first post-injection LH pulse during the breeding season. Other LH pulse parameters were not significantly affected. NPY18-36 did not produce any significant change in LH pulsatility when injected into the LV, and neither peptide had any effect on plasma prolactin or GH levels. There was a significant (P < 0.01) reduction in LH pulse frequency after 3V injection of 10 micrograms and 100 micrograms NPY and 100 micrograms NPY18-36. Pulse amplitude was reduced by 3V administration of the Y2 agonist, N-acetyl[Leu28-31]pNPY24-36 and 100 micrograms NPY18-36. When the amplitude of the first post-injection LH pulse was analysed, 10 micrograms NPY also had a significant (P < 0.05) suppressive effect. During the non-breeding season, 100 micrograms NPY1-36 (but not 10 micrograms) decreased (P < 0.01) LH pulse frequency. LH pulse amplitude was significantly (P < 0.01) decreased by 100 micrograms NPY18-36. Doses of 10 micrograms NPY1-36 and 100 micrograms NPY18-36 had greater inhibitory effects on pulse frequency during the breeding season but the suppressive effect of 100 micrograms NPY was similar between seasons. Microinjections of NPY into the POA decreased (P < 0.01) average plasma LH levels during the non-breeding season at a dose of 10 micrograms but did not significantly affect pulse frequency or amplitude. We conclude that a substantial component of the inhibitory action of NPY on LH secretion in the absence of steroids is mediated by the Y2 receptor. This inhibition is probably exerted by way of a presynaptic action on GnRH terminals in the median eminence as NPY does not modulate the frequency or amplitude of LH pulses at the level of the GnRH cell bodies in the POA.

Synthesis and biological characterization of a series of analogues of omega-conotoxin GVIA.

The 27-residue polypeptide omega-conotoxin GVIA (omega-CgTx), from the venom of the cone shell Conus geographus, blocks N-type neuronal calcium channels. It contains three disulphide bridges. We report here the synthesis and biological characterization of a series of analogues in which one disulphide has been replaced by substitution of appropriate Cys residues with Ser, viz. [Ser1,16]-omega -CgTx, [Ser8,19]-omega-CgTx, [Ser15,26)-omega-CgTx, [Ser16]-omega-CgTx8-27 and [Ser15]-omega-CgTx1-19. All syntheses were conducted manually using either Boc or Fmoc methodology. Deprotected peptides were oxidized to their bridged forms using either aerial oxidation or aqueous dimethyl sulphoxide. Peptides were purified using RP-HPLC, and their purity and identity were checked by RP-HPLC, capillary electrophoresis and mass spectrometry. Inhibition of neuronal N-type calcium channels was assessed as the inhibition of the twitch responses of rat vas deferens stimulated with single electrical pulses at 20 second intervals. None of these analogues was biologically active, suggesting that the disulphides play an important role in maintaining biological activity.

Neuropeptide Y: Y1 and Y2 affinities of the complete series of analogues with single D-residue substitutions.

In an effort to gain insight into the bioactive conformation of neuropeptide Y upon interaction with its receptors, all single-point D-amino acid substituted NPY analogues were prepared, and their Y1 and Y2 receptor binding affinities were evaluated using the human neuroblastoma cell lines, SK-N-MC and SK-N-BE2, respectively. Solid-phase synthesis (Boc strategy) followed by preparative HPLC purification produced analogues of high purity that were characterized by RP-HPLC, AAA, LSIMS, CZE, and optical rotation. Of the 37 isomers (a naturally occurring glycine at position 9 was replaced by Ala and D-Ala), Y1 receptor binding was most perturbed by chiral inversion of residues at the C-terminus (residues 20, 27, 29-35, Ki > or = 300 nM). Substitutions at residues 2-5, 28, and 36 had Ki values ranging from 40 to 260 nM. Substitutions at all other positions yielded analogues with affinities ranging from 1.5 to 20 nM. Binding affinities to the Y2 class of receptors all measured in the low or sub-nanomolar concentrations, with the exception of C-terminally modified isomers (residues 30-35). Only [D-Arg33]- and [D-Gln34]NPY displayed no measurable binding affinity to Y2 receptors at the highest concentration tested (1000 nM). Representative analogues were selected on the basis of their binding affinities and position in the sequence for structural analysis using circular dichroism (CD) spectroscopy. Of the nine peptide evaluated ([D-Pro5]-, [Ala9]-, [D-Glu10]-, [D-Asp11]-, [D-Ala18]-, [D-Tyr20]-, [D-Tyr27]-, and [D-Arg33]NPY), only [D-Tyr27]NPY expressed a definitive correlation between loss of binding affinity and disruption of secondary structure by having the propensity to form beta-sheets at the expense of alpha-helical content. It was concluded that although the incorporation of a single D-amino acid within the sequence of NPY may confer a conformational perturbation, the receptor interaction was only affected when certain critical residues were modified, findings that provide a basis for the identification of the binding pharmacophore of NPY.

High-performance liquid chromatography of amino acids, peptides and proteins. CXXVIII. Effect of D-amino acid substitutions on the reversed-phase high-performance liquid chromatography retention behaviour of neuropeptide Y[18-36] analogues.

The reversed-phase high-performance liquid chromatographic (RP-HPLC) gradient elution behaviour of a series of peptides related to Neuropeptide Y (NPY) has been investigated. The peptides studied included NPY, NPY[13-36], NPY[18-36] and a series of 16 analogues of NPY[18-36], each with a single D-amino acid substitution. Chromatographic parameters which relate to the interactive contact area and the binding affinity have been evaluated with two different stationary phase ligands and two organic modifiers. The results demonstrate that D-amino acid substitutions in the sequence region encompassing amino acid residues NPY[27-31] of these NPY[18-36] peptides significantly influence the interactive behaviour of these peptides relative to the unsubstituted NPY[18-36] molecule, while substitutions in the N- and C-terminal regions had little effect. Further, these results indicate that, in hydrophobic environments, NPY[18-36] adopts a significant degree of secondary structure which is severely disrupted by the presence of the D-amino acids in the central portion of the molecule.

Structural requirements for neuropeptide Y18-36-evoked hypotension: a systematic study.

It has been shown that NPY and select C-terminal fragments of NPY that evoke a hypotensive response upon intraarterial administration in the rat also cause mast cell degranulation and histamine release in vitro. Additionally, elevation of plasma histamine levels has been observed concomitant with the hypotensive effect of NPY and various C-terminal fragments. In order to investigate whether the hypotensive response to NPY18-36 is correlated to this observed elevation of histamine in vivo, we sought to characterize the structural requirements for each activity. We conducted a systematic replacement of each amino acid in NPY18-36 by its D-isomer. Additionally, various modifications were made to the N- or C-terminii of NPY18-36. The following rank order of potency was obtained for the hypotensive action of these analogues of NPY18-36 relative to NPY18-36. Only one analogue ([D-Tyr21]NPY18-36) exhibited significantly enhanced potency. Eleven analogues of NPY18-36, ([D-Thr32]-, [D-Arg35]-, [D-Ile31]-, [D-Leu30]-, [D-Tyr27]-, [D-Ser22]-, [D-Tyr36]-, [D-Gln34]-, [D-Asn29]-, [D-Ala23]-, and [D-Arg33]NPY18-36) were equipotent with NPY18-36. Four analogues ([D-His26]-, [D-Ile28]-, and [D-Ala18]NPY18-36 and -NPY18-27) had reduced potency (10-80%) while eight analogues ([D-Arg19]-, [D-Tyr20], [D-Leu24]-, [D-Arg25]-, [Ac-Ala18]-, [Me-Ala18]-, [desamino-Ala18]NPY18-36 and NPY18-36 free acid) failed to produce a significant hypotensive response (less than 10%) at the doses tested. The sensitivity of NPY18-36 to chiral inversion of single residues or other modifications at the N-terminus suggested the presence of a conformationally well defined N-terminal pharmacophore. Additionally, five NPY18-36 analogues were tested for elevation of plasma histamine levels. The rank order of potency ([D-Thr32]NPY18-36 = [D-Tyr21]NPY18-36 much greater than NPY18-36 greater than [D-Ala18]NPY18-36 greater than [Ac-Ala18]NPY18-36) was correlated with each analogue's potency at evoking a hypotensive response. In contrast, NPY1-36 failed to evoke an elevation in plasma histamine levels despite its hypotensive effects. Hence, we conclude that the magnitude of the hypotensive response evoked by an NPY18-36 analogue is primarily a function of its ability to elevate plasma histamine levels. However, the mechanism underlying NPY1-36-evoked hypotension appears to be different.

Neuropeptide Y radio-immunoassay: characterization and application.

1. A sensitive and specific neuropeptide Y (NPY) radio-immunoassay has been developed. This radio-immunoassay does not detect the NPY-related peptides pancreatic polypeptide or peptide YY. NPY extracted from rat plasma using sequential C18 sorbent and affinity chromatography co-eluted with synthetic rat NPY when applied to high pressure liquid chromatography. 2. The procedure of stabilization of platelets followed by high speed centrifugation reduced basal values of NPY by 60%, and this may be consistent with removal of platelets that release NPY. Administration of the cholinesterase inhibitor physostigmine (0.3 mg/kg), intravenously, produced a small but significant increase (39%) from basal concentrations of NPY. 3. NPY concentrations in young (2-3-month-old) Sprague-Dawley and Fisher 944 rats were similar; however, NPY concentrations were significantly increased (55%) in 2-year-old Fisher 944 rats. Similar to plasma concentrations of noradrenaline, NPY levels increase with age.

The antinociceptive effects of spinally administered neuropeptide Y in the rat: systematic studies on structure-activity relationship.

Neuropeptide Y (NPY) is a 36-amino-acid, C-terminal amidated peptide that is found in bulbospinal pathways and can inhibit the release of the primary afferent C-fiber neurotransmitter, substance P. Based on these observations, the present studies examined the possible antinociceptive effects of this peptide and several NPY fragments after intrathecal administration in rats prepared with chronic intrathecal catheters. In the 52 degrees C hot plate test, NPY produced a dose-dependent elevation in the nociceptive threshold with a median effective dose of 1.1 nmol. The ordering of fragments' activity was: NPY greater than NPY16-36 greater than or equal to NPY19-36 greater than or equal to NPY14-36 greater than or equal to NPY18-36 much greater than NPY1-36-OH = NPY18-36-OH = 0. In the paw pressure test, NPY was not active, even at the highest doses examined (median effective dose greater than 20 nmol), whereas the C-terminal fragments retained their potency and produced significant increases in the pressure required to evoke escape (NPY18-36: median effective dose = 18.7 nmol). The rank ordering of activity in the paw pressure test was: NPY19-36 greater than or equal to NPY14-36 greater than or equal to NPY18-36 greater than or equal to NPY16-36 much greater than NPY = NPY18-36-OH = 0. Peptide YY, human pancreatic polypeptide and avian pancreatic polypeptide behave similarly to NPY.(ABSTRACT TRUNCATED AT 250 WORDS)

Distinction of NPY receptors in vitro and in vivo. II. Differential effects of NPY and NPY-(18-36).

We have studied the hemodynamic effects of neuropeptide Y (NPY) and its COOH-terminal fragment NPY-(18-36) in conscious rats. Intra-arterial injection of NPY rapidly elevated systemic vascular resistance (SVR), which remained high for greater than 30 min. Cardiac output (CO) decreased, and it remained low for greater than 30 min. Accordingly, blood pressure rose only transiently and returned to base-line values within 5 min. The reduction of CO could be attributed to a decreased stroke volume with an only marginal reduction of heart rate. Thus a direct cardiodepressive effect of NPY rather than baroreflex activation appears to be the major cause of the reduced CO. In vitro experiments excluded the possibility that NPY has direct negative inotropic effects and suggest that its cardiodepressive action is caused by coronary vasoconstriction or by presynaptic inhibition of norepinephrine release. Intra-arterial injections of NPY-(18-36) caused different hemodynamic effects. NPY-(18-36) decreased CO in a manner similar to that seen with NPY but initially did not elevate SVR, resulting overall in a reduced blood pressure. Only later, when blood pressure was reduced, was an elevation of SVR observed, which could be associated with increased plasma levels of catecholamines, angiotensin II, vasopressin, and NPY. Thus NPY-(18-36) mimics the cardiac effects of NPY but does not elicit its vascular effects. As NPY-(18-36) discriminates between NPY receptor subtypes in vitro, we conclude that the cardiac and vascular effects of NPY are mediated by distinct receptor subtypes.

Distinction of NPY receptors in vitro and in vivo. I. NPY-(18-36) discriminates NPY receptor subtypes in vitro.

We studied the possibility of multiple neuropeptide Y (NPY) receptor subtypes. NPY-stimulated Ca2+ mobilization in human erythroleukemia (HEL) cells was used to screen a number of NPY analogues. The potencies of three of these analogues [peptide YY (PYY), [D-Tyr-36]NPY, and NPY-(18-36)] were compared with that of NPY in the following model systems: Ca2+ mobilization and inhibition of adenosine 3',5'-cyclic monophosphate accumulation in HEL cells, potentiation of vasoconstriction in the isolated rabbit ear artery, reduction of cutaneous microvascular perfusion in the rat digit, and inhibition of [3H]serotonin release in rat brain. In each of the five models, PYY was a full agonist that exhibited a similar or slightly higher potency than NPY, whereas [D-Tyr-36]NPY and NPY-(18-36) were partial agonists with lower potencies: NPY-(18-36) had a lower potency and efficacy than [D-Tyr-36]NPY in HEL cells and the rabbit ear artery, but was more effective than [D-Tyr-36]NPY for constricting cutaneous microvasculature and inhibiting serotonin release. Because of its weak partial agonism, we also tested NPY-(18-36) as an antagonist of NPY-stimulated Ca2+ mobilization in HEL cells. NPY-(18-36) shifted the NPY concentration-response curve to the right with a KB affinity value of 297 nM. In summary, [D-Tyr-36]NPY and NPY-(18-36) are partial agonists, the relative potency of which varies between systems. These data demonstrate the presence of multiple NPY receptor subtypes. We propose a modified classification scheme of NPY receptor subtypes.

Preparative-scale synthesis and reversed-phase purification of a gonadotropin-releasing hormone antagonist.

The preparation of "Nal-Glu" antagonist (Ac-D-Nal-D-Cpa-D-Pal-Ser-Arg- D-2-amino-5-oxo-5-(4-methoxyphenyl)pentanoic acid-Leu-Arg-Pro-D-Ala-NH2) was accomplished in two steps: (i) preparation of [Ac-D-Nal1, D-Cpa2, D-Pal3, Arg5, D-Glu6, D-Ala10]-GnRH via standard solid-phase synthetic techniques and (ii) acylation of anisole (Friedel-Crafts) by the glutamic acid residue in position 6. The preparative-scale, reversed-phase high-performance liquid chromatographic (HPLC) purification of the crude "Nal-Glu" antagonist employs first a triethylammonium phosphate (TEAP) (pH 2.25)-acetonitrile solvent system, followed by an HPLC-based desalting procedure, yielding the acetate salt of the peptide. This repetitive process of purification in TEAP-acetonitrile, followed by counter-ion exchange with 0.5% acetic acid-acetonitrile is highly reproducible and allows large amounts of a given peptide to be purified efficiently in a batchwise fashion. The procedure described for the synthesis, purification and characterization of the "Nal-Glu" antagonist is presented as a model for the multi-gram synthesis and purification of peptides to be used in clinical investigations.

The cardiovascular actions of centrally administered neuropeptide Y.

The cardiovascular actions of intracerebroventricular (i.c.v.) administration of neuropeptide Y (NPY) were examined in conscious, unrestrained rats. A prolonged decrease in heart rate (HR) and a fall in mean arterial pressure (MAP) were obtained following i.c.v. administration of NPY (1 and 10 micrograms). Passive immunization with an antiserum directed against NPY confirmed that the slowing of HR following i.c.v. administration of NPY was mediated via a central nervous mechanism and not from leakage of NPY out of the brain. Administration of NPY into different brain parenchymal regions identified a putative site of action in the rostral region of the solitary tract. The mechanism of the decrease in HR caused by centrally administered NPY was investigated by i.c.v. administration of NPY to animals that were pretreated with agents that altered autonomic tone. Administration of NPY to atropine-treated animals produced a reversal of the atropine-induced tachycardia, suggesting that the NPY-induced decrease in HR was not due to augmented vagal tone. However, administration of NPY to animals pretreated with propranolol did not significantly lower HR below that obtained with propranolol alone. These data suggest that i.c.v. administration of NPY may cause a decrease in cardiac sympathetic outflow. The effects of centrally administered NPY on baroreflex function were studied. The changes in HR caused by NPY did not significantly alter baroreflex set-point or gain. These studies provide evidence that NPY acted within a brainstem region to decrease sympathetic nervous outflow, resulting in a decrease in HR and MAP.

Synthesis and hypertensive activity of neuropeptide Y fragments and analogues with modified N- or C-termini or D-substitutions.

Porcine neuropeptide Y (NPY), NPY fragments, and analogues with D-Xaan, Ala9, D-Ala9, and Met17 substitutions or modifications to the C- or N-termini were synthesized. The synthesis and purification of these peptides was achieved by using routine laboratory strategies and techniques. The ability of these peptides to alter mean arterial pressure (MAP) and heart rate (HR) in conscious rats was monitored for 15 min following intraarterial administration. Potencies and efficacies of these peptides relative to NPY were determined by comparison of dose-response curves. Administration of 40 micrograms/kg NPY resulted in a rapid, though short-lived, rise in mean arterial pressure from a basal value of 107.0 +/- 2.6 to 157 +/- 5.5 mmHg (means +/- sem, n = 13). The ED50 (+/- SE) for this response was 3.04 +/- 0.88 micrograms/kg. Peptide YY (PYY) elicited a response that was similar in magnitude but with an ED50 (+/- SE, n = 3) of 0.76 +/- 0.24 micrograms/kg while porcine pancreatic polypeptide (pPP) was inactive when tested at 40 micrograms/kg (n = 4). Relative potencies for [Ac-Tyr1]NPY, [Ac-D-Tyr1]NPY, [des-amino-Tyr1] NPY, and [Me-Tyr1]NPY ranged from 1.1 to 2.2. Potencies relative to NPY for D-substitutions at positions 2-6 and 8-13 inclusive ranged from 0.1 to 1.0. Analogues with D-substitutions at positions 1-3 exhibited an extended duration of action. Analogues with D-substitutions at positions 33-35 inclusive were inactive at 40 micrograms/kg, and [D-Tyr36]NPY was 10-fold less potent than NPY, suggesting that the integrity of the C-terminal region is critical to the overall biological action of NPY. This conclusion is supported by studies with C- and N-terminal deletion peptides. NPY2-36 showed full intrinsic activity at 40 micrograms/kg and retains 40% of the hypertensive potency of NPY. There was a sequential decrease in efficacy upon further N-terminal deletion. In contrast to the finding with NPY2-36, modification of the C-terminus either from the native carboxamide to the free carboxylic acid or by deletion of the C-terminal residue resulted in analogues which were inactive at 40 micrograms/kg. These data indicate that an essentially full-length, C-terminally amidated NPY structure is required for the hypertensive activity observed in conscious rats upon intraarterial administration of NPY and NPY analogues.