Actions of galanin fragments on rat, guinea-pig, and canine intestinal motility

A Review of Single-Nucleotide Polymorphisms in Orexigenic Neuropeptides Targeting G Protein-Coupled Receptors

Many physiological pathways are involved in appetite, food intake, and the maintenance of energy homeostasis. In particular, neuropeptides within the central nervous system have been demonstrated to be critical signaling molecules for modulating appetite. Both anorexigenic (appetite-decreasing) and orexigenic (appetite-stimulating) neuropeptides have been described. The biological effects of these neuropeptides can be observed following central administration in animal models. This review focuses on single nucleotide polymorphisms (SNPs) in six orexigenic neuropeptides: agouti-related protein (AGRP), galanin, melanin concentrating hormone (MCH), neuropeptide Y (NPY), orexin A, and orexin B. Following a brief summary of the neuropeptides and their orexigenic activities, reports associating SNPs within the orexigenic neuropeptides to energy homeostasis, food intake, obesity, and BMI in humans are reviewed. Additionally, the NIH tool Variation Viewer was utilized to identify missense SNPs within the mature, biologically active neuropeptide sequences. For SNPs found through Variation Viewer, a concise discussion on relevant pharmacological structure-activity relationship studies for select SNPs is included. This review is meant to update reported orexigenic neuropeptide SNPs and demonstrate the potential utility of genomic sequence databases for finding SNPs that may result in altered receptor signaling for neuropeptide pathways associated with appetite.

Galanin decreases spontaneous resting contractions and potentiates acetyl choline-induced contractions of goldfish gut

Galanin (GAL) is a 29 amino acid peptide, first identified from the porcine intestine and widely distributed within the brain and peripheral tissues. Among GAL biological functions, its role as a potent appetite-stimulating peptide is probably the most studied. With galanin's established role in the modulation of food intake in fish, this study aims to evaluate the effects of GAL on the intestinal motility of the goldfish, Carassius auratus, using an organ bath system. Our results found that application of GAL to the organ bath causes a significant concentration-dependent decrease in the amplitude of spontaneous contractions of goldfish gut. Preincubations of intestinal strips with acetylcholine (ACh) and GAL showed that GAL increases the force of ACh-induced contractions of the goldfish gut. These results provide the first evidence for a role of GAL in gut motility in goldfish. This also suggests a crosstalk between the effects of GAL and ACh in such functions, thus pointing to a putative joint role between the two molecules. These findings offer novel information that strengthens the role of the galaninergic system in fish feeding.

Galanin and its receptors: a novel strategy for appetite control and obesity therapy

The rapid increase in the prevalence of overweight and obesity is becoming an important health problem. Overweight and obesity may cause several metabolic complications, including type 2 diabetes mellitus, hyperlipidemia, high cholesterol, coronary artery disease as well as hypertension. Prevention and treatment of obesity will benefit the treatment of these related diseases. Current strategies for treatment of obesity are not adequately effective and are frequently companied with many side effects. Thus, new ways to treat obesity are urgently needed. Galanin is undoubtedly involved in the regulation of food intake and body weight. The aim of this review is to provide up-to-date knowledge concerning the roles of central and peripheral galanin as well as its receptors in the regulation of metabolism, obesity and appetite. We also highlight the mechanisms of galanin and its receptors in experimental obesity, trying to establish a novel anti-obesity strategy.

Microarray analysis of high-glucose diet-induced changes in mRNA expression in jejunums of C57BL/6J mice reveals impairment in digestion, absorption

Long term intake of high-glucose diet (HGD) may induce many diseases such as dyslipidemia, fatty liver and diabetes disease. Most of the research for molecular mechanisms of the association between HGD and the above diseases focus on the metabolism of glucose and lipid. However, there are few studies on molecular mechanism of the effect of HGD on digestion and absorption. We used HGD (containing 20% glucose) to feed C57BL/6J mice for 4 weeks, detected the expressions of 13,098 genes in jejunums of C57BL/6J mice with DNA microarray. Microarray analysis showed the expression of genes related to digestive enzyme, gastrointestinal peptide and nutrient transporters were significantly changed, which indicated that HGD induced the suppression of digestive enzyme gene expression, attenuation of alimentary tract movement and nutrient transportation. In one word, the microarray analysis suggested that HGD impaired the function of digestion and absorption in jejunum of C57BL/6J mice. We validated our microarray findings by conducting real-time RT-PCR assays on selected genes and detecting the activities of disaccharidases such as lactase, maltase and sucrase in jejunum of C57BL/6J mice.

The contractile effects of several substituted short analogues of porcine galanin in isolated rat jejunal and colonic smooth muscle strips

The activity of short porcine galanin (Gal) analogues was tested in vitro using rat jejunal and colonic smooth muscle strips. Peptides evoked concentration-dependent tissue contractions yielding typical response curves in concentration range from 0.3 nM to 300 microM, with a characteristic fall-down effect at the supramaximal concentrations. Gal(1-15) was less potent than Gal(1-29). Furthermore, [D-Trp(2)]Gal(1-15), [endo-Trp(2),Cle(4)]Gal(1-15), [D-Leu(4)]Gal(1-15), [des-Leu(4)]Gal(1-15), [Hse(6)]Gal(1-15), [Dab(14)]Gal(1-15), [Dpr(14)]Gal(1-15) or [Arg(14)]Gal(1-15) showed a considerable decrease in potency compared to Gal(1-15) in jejunal and/or colonic smooth muscle cells. Functional evidence confirmed that the integrity of both N- and C-terminals must be preserved in order to preserve a full excitatory myogenic potential of the peptide in rat jejunum and colon. Besides, amino acids located in positions 2, 4, 6 and 14 play a crucial role in recognition and activation of molecular domains responsible for Gal action in the intestinal smooth muscle.

Galanin inhibits gastric acid secretion through a somatostatin-independent mechanism in mice

The role of somatostatin in galanin-induced inhibition of gastric acid secretion in urethane-anesthetized mice was investigated by using immunoneutralization of endogenous somatostatin and somatostatin receptor type 2 (SSTR2) knockout mice. Intravenous galanin (10 and 20 microg/kg/h) inhibited pentagastrin-stimulated gastric acid secretion by 47 and 33%, respectively. Somatostatin antibody injected i.v. increased acid secretion by 3.5-fold over basal levels but did not modify the antisecretory effects of galanin. Urethane-anesthetized SSTR2 knockout mice had a basal secretion 14-fold higher than wild-type animals, that was inhibited by galanin (10 and 20 microg/kg/h) by 49 and 31% respectively. In mice galanin inhibits gastric acid secretion through a somatostatin-independent mechanism.

Distribution of galanin receptor 1 immunoreactivity in the rat stomach and small intestine

Galanin affects gastrointestinal functions by activating different G protein-coupled receptors. Here, we identified the sites of expression of the galanin receptor 1 (GAL-R1) subtype in the rat stomach and small intestine by using immunohistochemistry with an antibody raised to the third intracellular loop of rat GAL-R1 (GAL-R1(Y225-238)) and confocal microscopy. Antibody specificity was confirmed by (1) the detection of a band at approximately 70 kDa in Western blot of membranes from GAL-R1 transfected cells, (2) the cell surface staining of GAL-R1 transfected cells, which was not detected in control cells, and (3) the abolition of Western signal and tissue immunostaining by preadsorbing the antibody with the peptide used for immunization. GAL-R1 immunoreactivity was localized to the cell surface of enterochromaffin-like cells, and of myenteric and submucous neurons, and to fibers distributed to the plexuses, interconnecting strands, muscle layers, vasculature, and mucosa. A dense network of GAL-R1 immunoreactivity was observed in the deep muscular plexus in very close association with interstitial cells of Cajal visualized by c-kit immunostaining. In the ileum, 81.6% of GAL-R1 myenteric neurons and 70.7% of GAL-R1 submucosal neurons were substance P immunoreactive. Vasoactive intestinal polypeptide immunoreactivity was found in 48.3% of GAL-R1 submucosal neurons, but not in GAL-R1 myenteric neurons. These findings support the hypothesis that GAL-R1 mediates galanin actions on gastrointestinal motility and secretion by modulating the release of other neurotransmitters and contributes to galanin-induced inhibition of gastric acid secretion by means of the suppression of endogenous histamine release.

Increased potency of some substituted short peptide analogues in comparison to galanin(1-15)-NH(2)in rat fundus strips

The activity of short porcine galanin (Gal) analogues was tested in vitro using rat gastric fundus strips. The peptides contracted longitudinal smooth muscle in a concentration-dependent manner with the following order of potency: Gal(1-29) >[Cit(14)]Gal(1- 15) >[Asp(14)]Gal(1- 15) >[Dab(14)]Gal(1- 15) >[Nle(14)] Gal(1-15) >[Dpr(14)]Gal(1- 15) >[Arg(14)]Gal(1- 15) >[Orn(14)]Gal(1- 15) >Gal(1-15). Only in the case of two peptides, namely [Cit(14)]Gal(1-15) and [Dab(14)]Gal(1-15) did the values of Hill coefficients, estimated from the appropriate concentration-contraction curves, differ significantly from unity. Our results indicate that both N- and C-terminals of Gal molecule contribute towards the affinity and activity of Gal in rat gastric smooth muscle cell receptors, indicating that their integrity is essential for its full excitatory myogenic action. The substitution of histidine with citruline, aspartic acid, norleucine or diaminobutyric acid in position 14 of the amino acid chain led to a considerable increase in potency, suggesting that amino acids located at this position might play a crucial role where the strength of short analogues is concerned.

Monoclonal antibody to rat galanin: production, characterization, and in vivo immunoneutralization activity

A monoclonal antibody (MAb) to galanin was prepared by cell fusion of myeloma Fox-NY and spleen cells from Robertsonian mice immunized with rat galanin. Hybridomas producing high-affinity antibodies were cloned in pristine-primed Balb/c mice. The antibody was purified by affinity chromatography and concentrated to 12 mg IgG/mL by dialysis. Immunoreactivity of the antibody was screened by radioimmunoassay. Ascites fluid contained approximately 10 mg/mL IgG that belong to the subclass of IgG2a as determined by enzyme-linked immunoadsorbent assay (ELISA). The titer of this IgG2a antibody entitled #G65G was 1:10,000 and the ID50 for rat galanin was 1000 fmol/mL as determined by liquid phase radioimmunoassay. Immunohistochemistry showed that this galanin MAb stains densed, beaded processes distributed to the enteric plexuses, where they appear to encircle neuronal cell bodies, to the muscle layer, where they are particularly abundant in the circular muscle layer and in the deep muscular layer, and to the mucosa. In vivo capacity of immunoneutralization by this antibody was tested in male Sprague-Dawley rats fasted for 24 h and anesthetized with urethane. Systemic injection of protein A purified galanin antibody (6 mg/rat) decreased by 70% of the inhibitory effect of intravenous galanin (2 nmol/kg/h i.v.) on gastric acid secretion induced by intracisternal TRH analog. These results show that galanin antibody #G65G is useful for in vivo immunoneutralization of galanin effects and is a valuable tool for immunohistochemical localization of galanin in gastrointestinal tissues.

Electrophysiological evidence for a hyperpolarizing, galanin (1-15)-selective receptor on hippocampal CA3 pyramidal neurons

The effects of the 29-amino acid neuropeptide galanin [GAL (1-29)], GAL(1-15), GAL(1-16), and the GAL subtype 2 receptor agonist D-tryptophan(2)-GAL(1-29) were studied in the dorsal hippocampus in vitro with intracellular recording techniques. GAL(1-15) induced, in the presence of tetrodotoxin, a dose-dependent hyperpolarization in hippocampal CA3 neurons. Most of the GAL(1-15)-sensitive neurons did not respond to GAL(1-29), GAL(1-16), or D-tryptophan(2)-GAL(1-29). These results indicate the presence of a distinct, yet-to-be cloned GAL(1-15)-selective receptor on CA3 neurons in the dorsal hippocampus.

Galanin in the lizard oviduct: its distribution and relationships with estrogen, VIP and oviposition

The distribution of neurons containing galanin immunoreactivity (Gal/IR) has been detected in the oviduct of the lizard Podarcis s. sicula during the main phases of its sexual cycle and after 17beta-estradiol treatment. Indirect immunofluorescence technique was applied both to cryostatic sections and whole mount preparations, and Western blot analysis, with an antibody directed against mammalian galanin (Gal), was performed with lizard oviduct extracts. Colocalization of Gal with vasoactive intestinal polypeptide (VIP) was also studied as well as Gal effects on egg deposition. In the quiescent oviduct of non-reproductive females, scanty Gal/IR fibres were found in the uterine-vaginal segment. During the reproductive period a gradual increase of positive nerve fibres and cell bodies were found distally in the lizard oviduct and the vagina revealed a reactive nerve population denser than elsewhere. Gal-IR nerve structures were present either in the musculature or mucosa and in the intermuscular layer they were organized in a nerve network. In the oviduct of non-reproductive females, 17beta-estradiol administration induced a significant increase of neurons containing Gal/IR. This hormone could be involved in the egg laying by means of galanin action and this hypothesis is supported by the induction of premature oviposition in pre-ovulatory females after Gal administration. Western blot analysis validates this peptide as true Gal, recognising one protein band with a molecular weight (3.2 kDa), similar to that of porcine Gal. Double labelling studies showed the co-presence of Gal and VIP in some neurons.

Effect of galanin on isolated strips of smooth muscle from the gastrointestinal tract of chickens

The contractile effects of galanin on isolated longitudinal smooth muscle strips of pre-crop esophagus, proventriculus, duodenum, colon, and cecum of chickens were investigated. Application of galanin (5.0-100.0 nM) evoked strong contractions from the colon and cecum (hindgut), but evoked minimal responses from the pre-crop esophagus, proventriculus, and duodenum (foregut). Previous studies have demonstrated that the central administration of galanin stimulates food consumption in rats. Since galanin-like immunoreactivity is present in the chicken brain, we speculate that the central release of galanin may increase food intake and possibly be involved in a hypothalamic-colonic reflex modulating hindgut motility and generating a defecation. Thus, the results of this study demonstrate the presence of galanin receptors in the chicken gut and suggest a possible link with their functional presence in the hindgut to the chicken central nervous system.

The GalR2 galanin receptor mediates galanin-induced jejunal contraction, but not feeding behavior, in the rat: differentiation of central and peripheral effects of receptor subtype activation

The neuropeptide galanin mediates a diverse array of physiological functions through activation of specific receptors. Roles of the three recently cloned galanin receptors (GalRs) in rat intestinal contraction and food intake were examined using GalR-selective ligands and the results were compared with the pharmacological profiles of defined GalRs. The action profile of these ligands in jejunal contraction resembled only that of GalR2 and only a high level of GalR2 mRNA was detected in the tissue, supporting GalR2 as the receptor mediating jejunal contraction. The action profile for food intake in rats excluded GalR2, GalR3 and the putative pituitary galanin receptor as the 'feeding receptor', suggesting that either GalR1 or an unidentified GalR is responsible for mediating this function.

Inhibition of gastric acid secretion by galanin in rats. Relation to endogenous histamine release

Inhibitory effect of galanin on basal and secretagogs-stimulated gastric acid secretion was investigated in urethane-anesthetized rats. A rat stomach was mounted in an ex-vivo chamber, perfused with saline, and either gastric acid or alkaline secretion was determined by titrating the perfusate. Gastric mucosal blood flow (GMBF) was measured by a laser Doppler flowmeter. Intravenous infusion of galanin dose-dependently inhibited the increase of acid secretion induced by pentagastrin and carbachol but not by histamine, without any influence on the GMBF response. Galanin also reduced basal acid secretion while increasing GMBF, but did not evoke any change in basal gastric alkaline secretion. M15, which is a galanin receptor antagonist in the central nervous system but acts as a full agonist in the gastrointestinal smooth muscle, also suppressed pentagastrin-induced acid secretion, similar to galanin. In addition, pentagastrin increased the release of histamine into the gastric lumen, and this response was significantly inhibited by galanin. These results suggest that the inhibitory effect of galanin on acid secretion is mediated by suppression of endogenous histamine release from enterochromaffin-like cells and that the process may be related to the activation of the same subtype of galanin receptors as in the central nervous system and pancreatic beta-cells.

The effect of galanin and galanin fragments on blood pressure in the Cane toad, Bufo marinus

Galanin has previously been shown to have a slight vasodepressor or no effect on blood pressure in placental mammals, but causes potent increases in blood pressure in several other vertebrate species. In this paper, the part of the galanin molecule responsible for the pressor activity was investigated in the Cane road, Bufo marinus by administration of fragments of galanin into anaesthetised toads and isolated arterial segments in an organ bath. In anaesthetised toads, the order of efficacy was human galanin > porcine galanin > Gal 1-16 > Gal 1-15 > Gal 3-15 > Gal 21-29 = 0. In isolated vessels, the first three peptides were equally effective. When four fragments of human galanin were tested in anaesthetised toads, the order of efficacy was human galanin > Gal 1-15 > Gal 5-20 > Gal 10-25 > Gal 15-30. The substitution of alanine for tryptophan at position 2 or for tyrosine at position 9 abolished the pressor response to the human galanin fragment 1-18 in anaesthetised toads. These results suggest that vascular activity in the toad is retained within the N-terminus and that positions 2 (tryptophan) and 9 (tyrosine) are key amino acids in retention of the vascular activity of galanin.

Human galanin modulates human colonic motility in vitro. Characterization of structural requirements

BACKGROUND

Human galanin (hGal) is a 30-residue non-amidated gut-brain peptide that shows considerable sequence divergence compared with galanin (Gal) forms of other species. Conflicting results have been reported with regard to the structural requirements for its modulatory action on gut motility.

METHODS

We investigated the effect of human and rat Gal and substituted analogues of Gal on the contractility of longitudinal muscle strips of the human colon in vitro.

RESULTS

Both hGal and rGal contracted the preparations in a concentration-dependent and tetrodotoxin-resistant manner without difference in sensitivity. The NH2-terminally truncated peptides hGal (3-30) and rGal (3-29) were inactive, whereas the NH2-terminal fragments, hGal (1-21) and rGal (1-18), remained fully responsive. Single amino acid substitutions at NH2-terminal positions showed divergent results: substitution of Trp2 reduced significantly potency and efficacy, whereas substitutions at positions 1, 3, 4, or 5 did not markedly modify the bioactivity of Gal. Galantide, a high-affinity Gal antagonist in the central nervous system, is a full agonist in human colonic smooth muscle.

CONCLUSION

The COOH-terminal part of Gal contributes mainly the receptor-binding affinity of the peptide, whereas the NH2-terminal region is essential for biologic activity.

Galanin contracts and relaxes guinea pig and canine intestinal smooth muscle cells through distinct receptors

BACKGROUND/AIMS

Galanin induces a contraction or a relaxation of digestive smooth muscle. Receptors mediating these effects have not been pharmacologically characterized. The aim of the study was to evaluate properties of two specific galanin antagonists M15 and M35 on galanin effects on muscle cells.

METHODS

Isolated muscle cells were obtained separately from circular and longitudinal layers of guinea pig and dog ileums. Contraction was expressed as percentage decrease in cell length from control.

RESULTS

Galanin induced a contraction of cells from guinea pig circular layer (50% effective concentration [EC50], 80 pmol/L) and dog longitudinal layer (EC50, 100 pmol/L). The antagonists inhibited galanin-induced contraction. The most potent was M15 (50% inhibitory concentration [IC50], 80 pmol/L in guinea pig; 90 pmol/L in dog) which was > M35 (IC50, 4 nmol/L in guinea pig; 1 nmol/L in dog). In dog circular layer, galanin inhibited cholecystokinin-induced contraction by relaxing the cells (EC50, 3 pmol/L). The antagonists inhibited this relaxation. The most potent was M35 (IC50, 60 pmol/L) which was > M15 (IC50, 900 pmol/L).

CONCLUSIONS

Galanin antagonists M15 and M35 inhibit the contraction and the relaxation induced by galanin with different potency, suggesting the presence of distinct galanin receptors in gastrointestinal tract that each mediates a specific effect.

Functional effects and ligand binding of chimeric galanin-neuropeptide Y (NPY) peptides on NPY and galanin receptor types

1. The effects and binding characteristics of a series of chimeric galanin-neuropeptide Y (NPY) peptides were examined in various preparations known to contain a predominant population of either Y1 or Y2 receptors for NPY or galanin receptors. 2. NPY suppressed the electrically stimulated twitches of the rat vas deferens (Y2 receptors), while galanin enhanced the electrically stimulated twitches. The galanin-NPY peptides M 32 (galanin(1-13)-NPY(25-36)), M69A (galanin(1-13)-Lys-[epsilon NH-Gly-NPY(4-1)]NPY(25-36)) and M88 (galanin(1-12)-Ala-NPY(25-36)) evoked a concentration-dependent suppression of the electrically stimulated twitches. These chimeric peptides were about equipotent with NPY, while NPY (13-36) was about five times less potent than NPY itself. Also a stochiometric combination of the N- and C-terminal fragments NPY (1-24)NH2 and NPY (25-36) (each at 1 microM) was inactive in vas deferens. M120 (galanin (1-13)-NPY(14-36) (1 microM) did not affect the NPY-mediated suppression of the stimulated twitches. 3. NPY evoked a concentration-dependent contraction in the guinea-pig isolated caval vein (Y1 receptors), while galanin (< or = 1 microM) was inactive. M32, M69A and M88 induced a slight contraction at very high concentrations only (> or = 0.3 M), while M120 was inactive at 1 microM. None of the four chimeric peptides affected the contraction evoked by NPY. 4. Since the number of NPY receptors in the rat vas deferens and guinea-pig caval vein were too low,the affinities of the galanin-NPY peptides for [3H]-NPY binding sites were examined in membranes from rat brain areas known to contain predominant populations of Y1 receptors (cerebral cortex) and Y2 receptors (hippocampus), respectively. The chimeric peptides M32, M69A, M88, M120 and NPY (13-36)all had higher affinities for hippocampal binding sites than for cerebral cortical binding sites. These peptides were 90-440 times less potent than NPY at cerebral cortical binding sites and 15-125 times less potent than NPY at hippocampal binding sites. The most selective chimeric peptide was M32, which had a 20 fold higher affinity for hippocampal than for cerebral cortical binding sites.5. At hypothalamic [125I]-galanin binding sites M32, M88 and M69A were equipotent with galanin,while M120 was about 10 times less potent than galanin. M32, M88 and M69A, like galanin contracted the rat isolated jejunum.6. The N-terminal portion (1-12) of galanin seems to permit a steric conformation of the attached NPY (25-36) part of the chimeric galanin-NPY peptides, which results in a facilitated Y2 but not Y1.receptor recognition and activation. None of the galanin-NPY peptides appeared to act as antagonists at either type of NPY receptor, probably due to their low affinity. Instead, they displayed a very high affinity for hypothalamic galanin receptors and probably act as galanin agonists in the rat jejunum.

Galanin-induced relaxation in gastric smooth muscle cells is mediated by cyclic AMP

Galanin has numerous effects on gastrointestinal motility in different species; however, its cellular basis of action in mediating these effects is unclear. Dispersed gastric smooth muscle cells have been shown to possess high-affinity galanin receptors that increase cAMP and cause relaxation. Recent studies show some smooth muscle relaxants such as VIP cause relaxation by both cAMP-dependent and -independent mechanisms. It is unknown if galanin's cellular basis of relaxation is similar or different from that of VIP. To investigate galanin's relaxant effect and compare it to VIP's effect, dispersed smooth muscle cells from guinea pig stomach were prepared by collagenase digestion. The mean length in resting cells was 110 +/- 2 microns and, with carbachol treatment, contracted to 89 +/- 2 microns. VIP and galanin alone had no effect on cell length, but each caused a dose-dependent inhibition of carbachol-induced contraction and both had an EC50 of 3-7 nM. Galanin (1 microM) and VIP (1 microM) increased cellular cAMP from 118 +/- 10 pmol/10(6) cells in control to 212 +/- 14 and 214 +/- 12 pmol/10(6) cells, respectively. The protein kinase A inhibitor, Rp-cAMPS, at 100 microM, completely inhibited the relaxant effect of an EC50 concentration of galanin (3 nM), but only inhibited that by VIP by 80% (p < 0.05). Adding the nitric oxide inhibitor, L-NNA (NG-nitro-L-arginine), at 100 microM did not alter the length of resting cells or inhibit carbachol-induced contraction. However, L-NNA (100 microM) decreased VIP-induced relaxation by 45%, whereas it had no effect on galanin-induced relaxation.(ABSTRACT TRUNCATED AT 250 WORDS)

Galanin induces opposite effects via different intracellular pathways in smooth muscle cells from dog colon

Smooth muscle cells isolated by enzymatic digestion were used to determine the direct effects of galanin on circular and longitudinal muscle layers from dog proximal colon and to investigate the intracellular pathways involved in these effects. Effects of galanin were compared to those observed with other contracting [cholecystokinin octapeptide (CCK8)] and relaxing [vasoactive intestinal peptide (VIP)] agents. In longitudinal cells, galanin and CCK8 induced a contraction that was maximal at 1 nM galanin and 1 nM CCK8 and was 23.9 +/- 4.5% and 23.4 +/- 3.4%, respectively, of the length of resting cells. Incubation of cells in Ca(2+)-free medium or in the presence of nifedipine caused an inhibition of galanin-induced contraction whereas it had no effect on the contraction induced by CCK8. Vasoactive intestinal peptide, forskolin, and 8 bromo cAMP inhibited CCK-induced contraction but failed to inhibit contraction induced by galanin. The contraction induced by galanin was abolished; the CCK-induced contraction was unchanged by pertussis toxin. In circular cells, CCK8 induced a contraction that was maximal at 10 nM and was 24.2 +/- 2.6%. Galanin had no effect by itself. When cells were preincubated (1 min) with galanin (10 fM-1 microM), the CCK8-induced contraction was inhibited, with a maximal effect at 10 nM galanin. Likewise, VIP inhibited the CCK8-induced contraction with a maximal effect at 1 microM. Preincubation of cells with somatostatin, N-ethylmaleimide, and (R)-p-cAMPS inhibited galanin- and VIP-induced relaxation. In conclusion, galanin induces a contraction of longitudinal smooth muscle cells that is dependent on an influx of extracellular calcium and an activation of pertussis toxin G-protein.(ABSTRACT TRUNCATED AT 250 WORDS)

Galanin: structure-dependent effect on pancreatic amylase secretion and jejunal strip contraction

Rat and porcine galanin and their fragments inhibited cholecystokinin-8 (CCK-8)-stimulated amylase secretion with the following activities: rat galanin-(1-29) = porcine galanin-(1-29) = galanin-(1-15) = rat galanin-(3-29) > rat galanin-(2-29) = porcine galanin-(2-29) > galanin-(1-10). Fragments of rat galanin-(9-29) and N alpha-acetyl-galanin-(9-29) were able to inhibit CCK-8-stimulated pancreatic amylase secretion but only at higher dose levels. Porcine galanin-(15-29) and rat galanin-(21-29) were unable to produce significant inhibition. Rat and porcine galanin-(1-29), galanin-(1-15) and rat N alpha-acetyl-galanin-(9-29) also inhibited basal pancreatic amylase secretion. In the rat jejunal strip contraction model, rat galanin-(1-29) and porcine galanin-(1-29) have similar potencies. Galanin-(1-15) and galanin-(1-10) stimulate rat jejunal strip contraction with decreasing potencies. Elimination of Gly1 from the N-terminus of both rat and porcine galanin had no significant effect either on pancreatic amylase secretion or on jejunal strip contraction. The rat galanin-(3-29) and (9-29) are not active in the stimulation of rat jejunal strip contraction. Acetylation of porcine galanin-(9-29) created a peptide that was a powerful stimulator of rat jejunal strip contraction. The present data indicate that N-terminal rat galanin amino acid residues are crucial for rat jejunal strip contraction but are not required for inhibition of pancreatic amylase. These results suggest that the galanin amino acid sequence contains several specific domains, which can be recognized by specific galanin receptor subsets.

Galanin analogues: agonist and antagonist

23 galanin-related peptides were synthesized by solid phase technology or conventional solution method. The purity of the products was carefully assessed by routine analytical criteria. Using these synthetic peptides, we have investigated the effects of galanins and structurally modified galanin peptides on glucose-stimulated insulin release using the isolated perfused rat pancreas, gastrin and somatostatin release using the isolated perfused rat stomach, the neurally-evoked muscle contractions in guinea pig ileum and the C-fiber response in the isolated spinal cord of the new born rat. The results suggest that the galanin amino-terminal 1-15 sequence is crucial for its activity in the above four systems. With the goal of developing a specific antagonist of galanin, synthetic galanin (1-15) analogues [D-Thr6,D-Trp8,9]galanin(1-15)ol, and [D-Trp8,9]galanin(1-15)ol were found to be a potent antagonist for inhibitory effect of galanin on glucose-induced insulin release.

Characterization of a high-affinity galanin receptor in the rat anterior pituitary: absence of biological effect and reduced membrane binding of the antagonist M15 differentiate it from the brain/gut receptor

Structure-activity studies demonstrate that galanin fragments 1-15 and 2-29 are fully active, whereas fragment 3-29 has been reported to be inactive, in a number of different in vivo models. M15, a chimeric peptide comprising galanin 1-13 and substance P5-11, has recently been found to be a potent galanin antagonist. Direct effects of galanin at the level of the pituitary have been defined, yet, paradoxically, a number of studies have been unable to demonstrate galanin binding to an anterior pituitary receptor. Porcine galanin stimulated prolactin release from dispersed rat anterior pituitary cells up to 180% +/- 12% (mean +/- SEM) of control secretion. The addition of a specific galanin antiserum caused a profound inhibition of basal prolactin release, maximal inhibition being 12% +/- 0.5% of control secretion. Addition of M15 produced no effect on basal or galanin-stimulated prolactin release. Galanin fragment 3-29 was fully active when compared to galanin 1-29. Fragments 5-29 and 8-29 stimulated prolactin release to a lesser extent and galanin 1-15, 10-29, and 20-29 had no significant prolactin-releasing activity. Using [mono(125I)iodo-Tyr26]galanin or porcine 125I-labeled Bolton-Hunter [mono(125I)iodo-Lys25]galanin, no anterior pituitary membrane binding was observed. In contrast, 125I-labeled Bolton-Hunter N-terminally labeled galanin allowed characterization of a single high-affinity anterior pituitary galanin receptor with a Kd of 4.4 +/- 0.34 nM and a Bmax of 79 +/- 8.3 fmol/mg of protein. The IC50 for porcine galanin was 0.51 +/- 0.04 nM but for M15 was in excess of 10 microM. Galanin 3-29 fully displaced the label with an IC50 of 0.96 +/- 0.7 nM. The IC50 for galanin 5-29 was 200 nM, whereas 8-29 and 1-15 were > 1 microM. Galanin 10-29 and 20-29 failed to displace the label. These data suggest the presence of a high-affinity pituitary galanin receptor, designated GAL-R2, in which region 3-10 and amino acid 25 are crucial for membrane binding and biological activity, in contrast to the known gut/brain galanin receptor (designated GAL-R1). A number of tissues known to bind or respond to galanin were screened. GAL-R2 would appear to be expressed only in the anterior pituitary and hypothalamus.

The effects of galanin and galanin fragments on cardiac-vagal action and blood pressure in the anaesthetised cat

Galanin (GAL), 29 amino acid peptide, has previously been shown to inhibit cardiac vagal action, and to cause a fall in systemic blood pressure in anaesthetised cats, at a dose of 6.2 nmol/kg. Here, the biological activity of exogenous GAL fragments was assessed in anaesthetised cats. GAL 1-16 at a dose equimolar with the full GAL 1-29 peptide (6.2 nmol/kg) and at a dose five times the molar dose of GAL 1-29 (31 nmol/kg), was found to be biologically active although the effects were less than that of the full peptide. GAL 1-15 at doses up to 10-times the molar dose of GAL 1-29, however, was not active, suggesting that amino acid 16, isoleucine, is critical for activity. In addition, GAL 15-29 and 21-29 showed no biological activity at doses up to 10-times the molar dose of GAL 1-29. These results suggest that the N-terminal rather than the C-terminal end of the GAL molecule is the one responsible for most of GAL's biological activity in this preparation.

Galanin-like immunoreactivity in extrinsic and intrinsic nerves to the gut of the Atlantic cod, Gadus morhua, and the effect of galanin on the smooth muscle of the gut

The presence of galanin-like immunoreactivity in nerves to the stomach of the Atlantic cod has been investigated by immunohistochemistry. The distribution of ganglion cells showing galanin-like immunoreactivity was compared with the total distribution in nerves and ganglia. Projection studies were made to determine the origin of the galanin neurons. The effect of galanin was studied in smooth muscle strip preparations of the gut wall and arteries. Galanin-like immunoreactive ganglion cells frequently occurred along the vagal branches to the stomach. Most of them projected cranially. Immunoreactive nerve fibers were present in all layers of the gut and around arterial branches on the surface of the stomach. Ligations of the vagus and splanchnic nerves produced accumulations of immunoreactive material on both sides of the ligature. Galanin produced weak contractile effects unaffected by tetrodotoxin on the gut wall and on gut arteries. It is concluded that a population of the ganglion cells along the vagus nerve in the Atlantic cod contains a galanin-like peptide. Some of these cells may be parts of autonomic parasympathetic pathways innervating the gut of the Atlantic cod, having direct excitatory effects on the smooth muscles of the gut wall and gut arteries.

Intracellular pathways triggered by galanin to induce contraction of pig ileum smooth muscle cells

1. In order to determine the intracellular mechanisms by which galanin induces contraction of isolated smooth muscle cells from pig ileum, we examined the effects of external Ca2+, relaxing agents, pertussis toxin and forskolin on the galanin-induced contraction and compared these effects to those observed on the cholecystokinin derivative CCK8-induced contraction. 2. Galanin induced a concentration-dependent cell contraction. The maximal contraction (24.5 +/- 2.1% of the length of resting cells) was observed at 1 nM of galanin. When cells were incubated in the simultaneous presence of concentrations of galanin (10 fM) and CCK8 (1 pM) which were ineffective alone, or galanin (10 fM) and acetylcholine (100 pM), a synergistic action was observed corresponding to a submaximal contraction. 3. Incubation of cells in Ca(2+)-free medium caused a significant decrease in galanin- but not in CCK-induced contraction. Nifedipine, a Ca2+ channel blocker, provoked a concentration-dependent inhibition of galanin-induced contraction while it had no effect on the contraction induced by CCK8. 4. Vasoactive intestinal polypeptide (VIP) and isoprenaline, known to induce cell relaxation through an increase in intracellular cAMP level, inhibited CCK-induced cell contraction at concentrations ranging from 1 pM to 1 microM but failed to inhibit cell contraction induced by galanin. 5. When cells were pre-incubated for 3 h in the presence of 200 ng/ml of pertussis toxin, the contraction induced by galanin was abolished while the CCK-induced contraction remained unchanged. On the contrary, 10 microM forskolin abolished the contraction induced by 10 nM CCK but had no effect on galanin-induced contraction. 6. These results indicate that galanin induces a concentration-dependent contraction of pig ileum smooth muscle by a direct myogenic effect. This effect of galanin involves the activation of a pertussis toxin-sensitive G protein, which results in an influx of Ca2+ into the cell. This intracellular pathway is insensitive to the relaxing effect of cAMP.

Variant forms of galanin isolated from porcine brain

In a peptide concentrate, prepared from acid extracts of porcine brain, several galanin-like immunoreactive peptides were detected and two of these were purified. Characterization of the peptides by sequence analysis, mass spectrometry, and capillary zone electrophoresis identified them as a N-terminally nine residue elongated form of galanin, preprogalanin(24-61) amide, and as an N-terminally four residue truncated form of galanin corresponding to preprogalanin(37-61) amide. The former finding suggests that the removal of the signal peptide in preprogalanin occurs by enzymatic cleavage between glycine-23 and leucine-24. The presence of truncated galanin might refer to a mechanism, where galanin is inactivated by removal of functionally important amino acid residues from the N-terminus.

Structural requirements for galanin inhibition of pentagastrin-stimulated gastric acid secretion in conscious rats

The effects of rat galanin, together with a number of its N- and C-terminal fragments, on pentagastrin-stimulated gastric acid secretion were studied in conscious rats equipped with chronic gastric fistulas. Similarly to its porcine counterpart studied previously, at a dose of 3 nmol/kg per h rat galanin was a potent inhibitor of gastric acid secretion. The N-terminal fragments, rat galanin-(1-10) and -(1-15), retained about 60% of the inhibitory potency of the whole galanin sequence whilst the C-terminal fragments, rat galanin-(2-29), -(3-29) and -(9-29), were unable to produce significant inhibition over comparable dose ranges. Surprisingly, however, simply acetylating the alpha-amino group in position 9 of rat galanin-(9-29) restored almost full gastric acid inhibitory activity in a homologous rat model. We speculate that this could be due to a favorable conformational effect on the C-terminal region produced by alpha-acetylation. These results also suggest that structural features within either the N-terminal or C-terminal regions of rat galanin are able to elicit this particular biological response. One possible explanation for this could be the involvement of more than one rat galanin receptor having different ligand recognition requirements.

Effects of human, rat and porcine galanins on cardiac vagal action and blood pressure in the anaesthetised cat

Galanin (GAL) is distributed in sympathetic nerves in the cat, and exogenous GAL inhibits cardiac vagal action and lowers blood pressure in this species. This study on anaesthetised cats compares the effects on cardiac vagal action and blood pressure of human, rat and porcine GAL. Human GAL has only recently been sequenced. It is of particular interest as it is not C-terminally amidated, unlike porcine and rat GAL. Many regulatory peptides require a C-terminal amide group for their action. However, human GAL showed similar biological activity to the other (amidated) GALs here. Omission of a single amino acid (Ser6) from rat GAL significantly attenuated both cardiovascular actions studied here.

Comparative effects of galanin on isolated smooth muscle cells from ileum in five mammalian species

Effect of galanin and CCK8 were studied on isolated smooth muscle cells obtained from pig, guinea-pig, rat, rabbit and dog ileum circular muscle layer. Galanin as well as CCK8 induced a concentration-dependent contraction of pig, rat, rabbit and guinea-pig ileum smooth muscle cells. Maximal contraction ranged between 23.7 +/- 1.9% and 26.1 +/- 3.1% decrease in cell length from control in the presence of both peptides. This maximal contraction was obtained at 1 nM galanin in pig, rat, rabbit, 1 nM CCK8 in rat, rabbit, guinea-pig, at 10 nM galanin in guinea-pig and 10 nM CCK8 in pig. Concentrations of galanin inducing a half maximal contraction (EC50) ranged between 8 pM and 80 pM in these species. In dog, CCK8 induced a concentration-dependent contraction of ileum smooth muscle cells, with a maximal contraction (24.5 +/- 2.3%) at 1nM and an EC50 of 50 pM while galanin inhibited cell contraction induced by CCK8. The CCK-induced contraction was abolished at 10 nM galanin and 10 nM VIP. Concentrations of galanin and VIP inducing a half-maximal relaxation of contracted cells were 2 pM and 3 pM respectively. It is concluded that galanin may induce cell contraction of pig, guinea-pig, rat and rabbit ileum circular muscle layer and cell relaxation of dog ileum by a direct myogenic effect.

Galanin inhibition of vasoactive intestinal polypeptide release and circular muscle motility in the isolated perfused canine ileum

The role of porcine galanin, infused arterially into isolated perfused canine ileal segments, in modulating the tonically elevated neural release of vasoactive intestinal polypeptide and possible concomitant motor actions dependent on vasoactive intestinal polypeptide modulation was studied. Galanin infusions (9-minute) inhibited vasoactive intestinal polypeptide release in a concentration-dependent manner (maximum during minutes 8-10) irrespective of the absence (quiescence) or presence of phasic circular muscle contractions induced by local electrical field stimulation of nerves. During quiescence, galanin induced phasic contractions in four of five segments beginning in the 8th minute of the infusion. During stimulated contractions, galanin inhibited phasic motor activity within 2 minutes of initiation of the infusion; this inhibition may result from direct smooth previously reported muscle inhibition. Thus galanin may inhibit both neural release of vasoactive intestinal polypeptide and circular muscle motility directly. The delayed period of phasic activity initiated by galanin during quiescence may be related to inhibition of vasoactive intestinal polypeptide release, freeing the muscle from tonic inhibition by vasoactive intestinal polypeptide. Because galanin and vasoactive intestinal polypeptide are colocalized in some enteric nerves, galanin may regulate vasoactive intestinal polypeptide release by negative feedback.

Human galanin: primary structure and identification of two molecular forms

From acid/ethanol extracts of surgical specimens of human large intestine we isolated two peptides, in approximately equal amounts, that reacted with an antiserum against porcine galanin. By amino acid analysis, sequence analysis and mass spectrometry, the larger of the two peptides was found to consist of 30 amino acid residues, the sequence of which was identical to that of porcine galanin except for the following substitutions: Val16, Asn17, Asn26, Thr29 and Ser30. Unlike porcine galanin, the carboxy-terminus was not amidated. The smaller peptide corresponded to the first 19 amino acid residues counted from the N-terminus of the 30 residue peptide (again without amidation). The structural analysis was repeated on another batch of tissue with identical results. By HPLC analysis of extracts of specimens from a further 4 patients, the same peptides were identified. Thus, human galanin includes two peptides of 19 and 30 amino acids that share the sequence of the N-terminal 15 residues with other mammalian galanins, but exhibit characteristic differences in the remaining part of the molecules.

Effects of galanin on the opossum internal anal sphincter: structure-activity relationship

The present study was carried out to investigate the effects of porcine galanin-(1-29), N-terminal fragment galanin-(1-10), C-terminal fragment galanin-(15-29), and the middle fragment galanin-(7-16) on the spontaneous tension of the opossum internal anal sphincter and on the decrease in the resting internal anal sphincter tension in response to neural stimulation by electrical field stimulation. Galanin and galanin-(1-10) caused a concentration-dependent decrease in the resting tension of internal anal sphincter and an augmentation of the percent decrease in the resting tension with electrical field stimulation. Galanin-(15-29), on the other hand, produced an increase in the resting tension of the internal anal sphincter and had no effect on the electrical field stimulation-induced decrease in the resting tension. Galanin-(7-16) produced no significant effect on the internal anal sphincter. The decrease in the internal anal sphincter tension by galanin and galanin-(1-10) was partially antagonized by tetrodotoxin, whereas the increase in the internal anal sphincter tension caused by galanin-(15-29) was not modified by tetrodotoxin. In contrast to its effect in the internal anal sphincter, galanin caused an increase in the resting tension and suppressed a decrease in the lower esophageal sphincter tension in response to electrical field stimulation. From these findings we conclude that (a) galanin exerts an inhibitory effect on the internal anal sphincter by activating galanin receptors both at the intramural inhibitory neurons and at the internal anal sphincter smooth muscle and that the N-terminal portion of galanin may be responsible for these actions; (b) the contractile action of galanin is produced by its action on the smooth muscle; and (c) the actions of galanin on the gastrointestinal tract are tissue specific.

The N-terminal 1-16, but not C-terminal 17-29, galanin fragment affects the flexor reflex in rats

The biological activity of two galanin (GAL) fragments, GAL-(1-16) and GAL-(17-29), was tested in vivo by using a spinal nociceptive flexor reflex model in the rat. Intrathecal (i.t.) GAL-(1-16) had a similar biphasic effect on the flexor reflex, with facilitation at lower doses and facilitation followed by depression at higher doses, as the full length peptide GAL-(1-29). GAL-(1-16) also effectively depressed the facilitation of the flexor reflex caused by i.t. substance P (SP) or C-fiber conditioning stimulation (CS) and potentiated the depressive effect of i.t. morphine on the reflex, both actions that have been reported earlier with GAL-(1-29). In contrast, i.t. GAL-(17-29), even at high doses, did not induce changes in the amplitude of the flexor reflex, nor did it interact with the effects of i.t. SP, morphine or C-fiber CS. It is concluded that the N-terminal portion of GAL-(1-29) is critical for the biological activity of the intact peptide in the dorsal horn of the rat spinal cord. The similarity between the effects of GAL-(1-16) and GAL-(1-29) indicates that they probably act on the same GAL receptor.

Structural requirements for galanin action in the guinea-pig ileum

Galanin fragments and galanin analogues were tested on neurally evoked muscle contractions in guinea-pig ileum in vitro. Galanin fragments inhibited the neurally evoked circular muscle contractions with the following order of potency: Galanin(1-29), galanin(2-29), galanin(1-15). In contrast, galanin(3-29), galanin(10-29), galanin(21-29), [D-Trp2]galanin, [Phe2]galanin and [Tyr2]galanin were ineffective. Galanin(1-29), galanin(2-29) and galanin(1-15) did not affect the neurally evoked longitudinal muscle contractions. These results indicate that (1) the two N-terminal amino acid residues of the galanin molecule are essential for the inhibitory action of galanin on neurally-evoked circular muscle contraction and (2) for the full potency also the C-terminal end is required.

Galanin binding sites in rat gastric and jejunal smooth muscle membrane preparations

Receptors for galanin in membranes from the rat gastric and jejunal smooth muscle were studied using [125I] radioiodinated synthetic porcine galanin. Specific binding was time and temperature dependent. At 32 degrees C radioligand was degraded in the presence of smooth muscle membranes in a time-dependent manner. At optimal experimental conditions, the equilibrium binding analyses showed the presence of a single population of high affinity binding sites in both the rat stomach and jejunum (Kd value of 2.77 +/- 0.78 nM and 4.93 +/- 1.74 nM for stomach and jejunal smooth muscle membranes, respectively). The concentration of the high affinity binding sites was 58.19 +/- 11.04 and 32.36 +/- 5.68 fmol/mg protein, for gastric and jejunal preparations, respectively. Specific binding was completely inhibited by 10(-6) M of nonradioactive galanin; was 75% blocked by 1 microM of galanin(9-29); it was 10% blocked by 1 microM of galanin(15-29). Galanin(1-15) at a concentration of 1 microM was ineffective for inhibiting [125I]galanin binding. Deletion of four C-terminal amino acid residues from galanin(9-29) to give galanin(9-25) also resulted in almost complete loss of affinity. Radioiodinated galanin and N-terminally deleted fragments had receptor binding potency in the following order: galanin(1-29) greater than galanin(9-29) greater than galanin(15-29). We conclude that the C-terminal part of the galanin chain is important for the rat gastric and jejunal smooth muscle membrane receptor recognition and binding and that N-terminal amino acid sequences are probably not so important, since galanin(1-15) was not active but galanin(9-29) retained most of the receptor binding activity.

N-terminal galanin-(1-16) fragment is an agonist at the hippocampal galanin receptor

The galanin N-terminal fragment [galanin-(1-16)] has been prepared by solid-phase synthesis and by enzymic cleavage of galanin by endoproteinase Asp-N. This peptide fragment displaced 125I-labeled galanin in receptor autoradiography experiments on rat forebrain and spinal cord and in equilibrium binding experiments from high-affinity binding sites in the ventral hippocampus with an IC50 of approximately 3 nM. In tissue slices of the same brain area, galanin-(1-16), similarly to galanin, inhibited the muscarinic agonist-stimulated breakdown of inositol phospholipids. Upon intracerebroventricular administration, galanin-(1-16) (10 micrograms/15 microliters) also inhibited the scopolamine (0.3 mg/kg, s.c.)-evoked release of acetylcholine, as studied in vivo by microdialysis. Substitution of [L-Trp2] for [D-Trp2] resulted in a 500-fold loss in affinity as compared with galanin-(1-16). It is concluded that, in the ventral hippocampus, the N-terminal galanin fragment [galanin-(1-16)] is recognized by the galanin receptors controlling acetylcholine release and muscarinic agonist-stimulated inositol phospholipid breakdown as a high-affinity agonist and that amino acid residue [Trp2] plays an important role in the receptor-ligand interactions.

Co-existence of galanin and acetylcholine: is galanin involved in memory processes and dementia?

Galanin-like immunoreactivity co-exists with choline acetyltransferase-like immunoreactivity in neurons of the septal-hippocampal and nucleus basalis of Meynert-neocortical pathways. These structures mediate some forms of cognition, and characteristically degenerate in Alzheimer's disease. Biochemical, neurophysiological and behavioral studies indicate that galanin acts as an inhibitory modulator of cholinergic function. In this article, we consider the possibility of a role for galanin in memory processes and dementia.