Dual effect of bombesin and gastrin releasing peptide on gastric emptying in conscious cats

The effect of bombesin (BBS) and gastrin releasing peptide (GRP) on gastric emptying was studied in conscious cats. This effect was measured simultaneously with antral motility. Acid and pepsin secretions as well as blood hormonal peptide release were additionally measured. A dual effect was observed. First, BBS and GRP slowed gastric emptying of liquids, while antral motility was decreased, then after 60 minutes of continuous intravenous infusion, antral motility returned to basal values and gastric emptying effect reversed. The mechanism of this peculiar action is independent of gastrin, pancreatic polypeptide, somatostatin and motilin release and most probably connected with a cholinergic stimulation induced by the peptides, the late predominance of which counterbalances the inhibitory effect of bombesin-like peptides on antral motility.     

Functional and anatomical relationships between antral gastrin cells and gastrin-releasing peptide neurons

The present studies were directed to examine the effect of gastrin-releasing peptide (GRP) on beta-adrenergic stimulated gastrin release by cultured rat antral mucosa and to assess the anatomical relationship between gastrin cells and GRP nerves in rat and human antrum. Peptide-containing cells were identified by application of an avidin-biotin-peroxidase immunocytochemical double staining method utilizing antibodies to GRP and gastrin prepared in rabbits. Rat antral mucosa was cultured for 60 min and gastrin released into the culture medium was measured by radioimmunoassay. Inclusion of antibodies to GRP in culture medium did not affect carbachol-stimulated gastrin release, whereas isoproterenol-stimulated gastrin release into the medium was inhibited significantly by addition of GRP antiserum to the culture medium. GRP-containing neurons and axonal fibers were stained immunocytochemically with diaminobenzidine (reddish-brown specific staining) and were located in the lamina propria adjacent to and surrounding the main lobules of antral glands. After double staining utilizing 4-Cl-1-Naphthol as substrate, blue stained gastrin-containing cells were identified in the middle and deeper regions of antral glands in close proximity to GRP neuronal elements. These studies suggest that beta-adrenergic, but not cholinergic, stimulation of gastrin release is mediated, at least in part, through GRP. They also demonstrate intimate anatomical, as well as functional, relationships between gastrin cells and GRP-containing neurons.     

Motor effects of gastrin releasing peptide (GRP) and bombesin in the canine stomach and small intestine

Close intraarterial injections of synthetic porcine gastrin releasing peptide (GRP) or bombesin stimulated contractions in the stomach and inhibited ongoing contractile activity in the small intestine of anaesthetized dogs. Contractile activity of the circular muscle was recorded by serosal strain gauges and phasic activity when desired was elicited by local field stimulation or intraarterial motilin injections. In the stomach (corpus and antrum) following tetrodotoxin blockade of field-stimulated contractions, the contractile response to either peptide was not present, suggesting that stimulation of receptors on nerves initiated contractions in the stomach. Similarly, in the small intestine, the inhibitory response was eliminated by tetrodotoxin suggesting a neural receptor. Pre-treatment with reserpine did not alter the inhibitory response, either in the presence or absence of atropine, therefore, adrenergic inhibitory mechanisms did not appear to be involved. The concentration of bombesin producing 50% inhibition of field stimulation (ED50) was increased following treatment with the putative M1 muscarinic antagonist, pirenzipine suggesting activation of M1 cholinergic inhibitory receptors by bombesin. After blockade by atropine of field-stimulated contractions and the contractile response to intraarterial acetylcholine, the ED50 for bombesin inhibition of motilin contractions was increased. After muscarinic blockade, the residual inhibitory response of GRP/bombesin may involve activation of a neural non-cholinergic non-adrenergic inhibitory mechanism. These results suggest that GRP and bombesin act to alter motility in the dog in vivo by affecting neural activity.     

Effect of porcine gastrin releasing peptide on gastric secretion and motility and the release of hormonal peptides in conscious cats

The effect of porcine gastrin releasing peptide (GRP) was compared to those of bombesin (BBS) and pentagastrin (PG) in conscious cats. GRP and BBS augmented acid and pepsin secretions, as well as antral motility with an early effect comparable to that produced by pentagastrin with an elevation of low amplitude contractions and a diminution of high amplitude contractions. BBS and GRP increased plasma gastrin and pancreatic polypeptide (PP) levels and decreased motilin levels measured by a C terminus-directed antiserum. In all cases, BBS and GRP displayed parallel dose-response curves. PG showed slight differences in the slopes of the dose-response curves except for acid secretion stimulation where no difference was noted (PG was the most effective) and for pepsin stimulation where the difference was large (PG was much less effective). According to the different targets studied, BBS was 4 to 9 times more potent than GRP, 6 to 200 times more than PG. Gastrin release, elicited by the lowest ED50 of both BBS and GRP, should be considered as their primary effect in the cat.     

Neural, hormonal, and paracrine regulation of gastrin and acid secretion.

Physiological stimuli from inside and outside the stomach coverage on gastric effector neurons that are the primary regulators of acid secretion. The effector neurons comprise cholinergic neurons and two types of non-cholinergic neurons: bombesin/GRP and VIP neurons. The neurons act directly on target cells or indirectly by regulating release of the hormone, gastrin, the stimulatory paracrine amine, histamine, and the inhibitory paracrine peptide, somatostatin. In the antrum, cholinergic and bombesin/GRP neurons activated by intraluminal proteins stimulate gastrin secretion directly and, in the case of cholinergic neurons, indirectly by eliminating the inhibitory influence of somatostatin (disinhibition). In turn, gastrin acts on adjacent somatostatin cells to restore the secretion of somatostatin. The dual paracrine circuit activated by antral neurons determines the magnitude of gastrin secretion. Low-level distention of the antrum activates, preferentially, VIP neurons that stimulate somatostatin secretion and thus inhibit gastrin secretion. Higher levels of distention activate predominantly cholinergic neurons that suppress antral somatostatin secretion and thus stimulate gastrin secretion. In the fundus, cholinergic neurons activated by distention or proteins stimulate acid secretion directly and indirectly by eliminating the inhibitory influence of somatostatin. The same stimuli activate bombesin/GRP and VIP neurons that stimulate somatostatin secretion and thus attenuate acid secretion. In addition, gastrin and fundic somatostatin influence acid secretion directly and indirectly by regulating histamine release. Acid in the lumen stimulates somatostatin secretion, which attenuates acid secretion in the fundus and gastrin secretion in the antrum.     

Molecular cloning and sequence analysis of cDNA coding for canine gastrin

We have isolated and sequenced cDNA clones encoding for preprogastrin from a canine antral cDNA library. Comparison of this sequence with those of porcine, human, and rat gastrin reveals extensive (83%) homology in the gastrin coding region as well as short regions of conserved nucleotides in the noncoding regions. The canine sequence encodes a preprogastrin of 104 amino acids which consists of a signal peptide, a 37-amino acid prosegment, and a 34-amino acid gastrin sequence, followed by a glycine (the amide donor), and flanked by pairs of arginine residues.     

The role of vagal integrity in gastrin releasing peptide stimulated gastroenteropancreatic hormone release and gastric acid secretion

The role of the vagus nerve in the control of gastrin releasing peptide (GRP) stimulated gastroenteropancreatic hormone release and gastric acid secretion was investigated in four conscious gastric fistula dogs using a technique of bilateral cryogenic vagal blockade. A 90-min infusion of GRP at a dose of 400 pmol X kg-1. h-1 produced significant elevations in plasma levels of gastrin, motilin, GIP, enteroglucagon, insulin, pancreatic glucagon, pancreatic polypeptide and VIP. Vagal blockade reversibly inhibited the rise of plasma PP and significantly blunted the elevation of plasma VIP. However, the GRP stimulated response of the other hormones investigated was not modified by vagal blockade. Similarly, the substantial secretion of gastric acid observed with GRP was not influenced by vagal blockade. Thus GRP acts predominantly via mechanisms which are independent of vagal integrity, findings that are in support of a major role for the local neuromodulation of hormone release and gastric acid secretion.     

Gastrin secretion by ovine antral mucosa in vitro

The effect on gastrin and somatostatin release in sheep of stimulatory and inhibitory peptides and pharmacological agents was investigated using an in vitro preparation of ovine antral mucosa. Carbachol stimulated gastrin release in a dose-dependent manner but had no effect on somatostatin release. As atropine blocked the effect of carbachol, cholinergic agonists appear to stimulate gastrin secretion directly through muscarinic receptors on the G-cell and not by inhibition of somatostatin secretion. Both vasoactive-intestinal peptide (VIP) and gastric-inhibitory peptide (GIP) increased somatostatin release but did not inhibit basal gastrin secretion, although VIP was effective in reducing the gastrin response to Gastrin-releasing peptide (GRP). Porcine and human GRP were stimulatory to gastrin secretion in high doses but bombesin was without effect. The relative insensitivity to GRP (not of ovine origin) previously reported from intact sheep may be caused either by a high basal release of somatostatin or by the ovine GRP receptor or peptide differing from those of other mammalian species.     

Somatostatin inhibition of gastrin gene expression: involvement of pertussis toxin-sensitive and -insensitive pathways.

These studies were performed to determine the intracellular pathways involved in regulating gastrin gene expression. The inclusion of 10(-4) M forskolin or 10(-4) M dibutyryl cyclic AMP (DBcAMP) in incubation medium containing dog antral mucosa resulted in 249% and 323% increases, respectively, in gastrin mRNA levels. The stimulatory effects of forskolin and DBcAMP were both inhibited significantly by 10(-6) M somatostatin. Preincubation of antral mucosa with pertussis toxin nearly abolished the inhibitory effects of somatostatin on gastrin mRNA stimulated by forskolin, but had no effect following DBcAMP. To examine whether calcium-dependent pathways might be involved in regulating gastrin gene expression, antral mucosa was incubated with increasing concentrations of calcium or the ionophore ionomycin. Both agents produced only modest increases in gastrin mRNA, which were abolished by the addition of somatostatin to the incubation medium. These studies indicate that somatostatin appears to inhibit gastrin gene expression through mechanisms involving both pertussis toxin-sensitive and -insensitive pathways.     

Inhibition of bombesin-stimulated gastrin release from isolated canine G cells by bombesin antagonists

This study investigated the effects of two putative bombesin antagonists, [D-Arg1,D-Pro2,D-Trp7,9,Leu11]substance P and [Leu13-psi-CH2NH-Leu14]bombesin, on bombesin-stimulated gastrin release from isolated canine G cells following short-term culture. Canine antral tissue was dispersed by sequential collagenase and EDTA treatment, and counterflow elutriation was used to enrich for G cells. Plates were seeded with 2 x 10(6) cells/mL in each well and cultured for 2 days prior to testing. Gastrin-containing and somatostatin-containing cells were identified by immunocytochemistry using the biotin-avidin-peroxidase method and accounted for 8.5 and 1%, respectively, of adhered cells. Basal gastrin secretion was 1.91 +/- 0.48% of total cell content. After a 2-h incubation period, bombesin (0.01-100 pM) stimulated gastrin release in a concentration-dependent fashion. The substance P analog, at a concentration of 1 microM, modestly inhibited bombesin-stimulated gastrin release from canine G cells. This analog also produced weak stimulation of basal gastrin release. In contrast, the bombesin analog, at a concentration of 1 microM, did not affect basal gastrin secretion. The bombesin analog completely blocked bombesin-stimulated gastrin release from 0.01 to 1 pM and produced greater than 50% inhibition at higher doses. The ability of the bombesin analog to directly inhibit bombesin-stimulated gastrin release from cultured canine G cells underscores its usefulness in studies involving the role of bombesin and its mammalian counterpart, gastrin-releasing peptide, in the control of gastrin cell function.     

Gastrin-releasing peptide: neuronal distribution and spatial relation to endocrine cells in the human upper gut

By using immunocytochemical techniques, we have studied the distribution of gastrin releasing peptide (GRP)-containing neurons as well as the spatial relationship between these neurons and the endocrine cells in the human stomach and duodenum. Moderate numbers of immunoreactive fibers were distributed in the smooth muscle and submucosa of the stomach; they were more rare in the duodenal wall. Numerous GRP-containing nerve fibers were found in the oxyntic mucosa, the antral mucosa harboured only few GRP immunoreactive nerve fibers. The mucosa of the proximal duodenum was found to be virtually devoid of such fibers. Only occasionally did we observe signs of a direct contact between GRP-containing nerve fibers and gastrin and somatostatin cells in the antral mucosa. In the oxyntic mucosa GRP-containing nerve fibers sometimes seemed to contact endocrine cells, including somatostatin cells as well as individual parietal cells. In conclusion, although GRP-containing nerve fibers were quite numerous in the wall of the human upper gastro-intestinal (GI)-tract, we observed a lack of intimate spatial relationship between these fibers and endocrine cells in the antral mucosa, suggesting additive mechanisms to a direct innervation of gastrin cells and somatostatin cells by GRP nerve fibers explaining the physiological effects on hormonal release.     

胃动素和胃泌素引起大鼠胃窦平滑肌细胞收缩的信号转导通路

应用大鼠游离胃窦平滑肌细胞,观察胃动素和胃泌素对胃窦平滑肌细胞收缩作用的胞内信号转导通路。结果显示：⑴胃动素和胃泌素对胃窦平滑肌细胞均有收缩作用;⑵Ｇａｉ－３抗体可抑制胃动素和胃泌素加强胃窦平滑肌细胞的收缩,胃动素、胃泌明显增加Ｇａｉ－３抗体与「＾３５Ｓ」ＣＴＰγＳ的结合;⑶磷脂酶抑制剂Ｕ－７３１２２、三磷酸肌醇受体拮抗剂肝素可抑制胃坳素和胃泌素引起的胃窦平滑肌细胞的收缩。结果表明：胃坳素和胃泌表     

Effect of porcine gastrin releasing peptide on anterior pituitary hormone release

The effect of porcine gastrin releasing peptide (GRP), a heptacosapeptide with potent gastrin releasing activity which has recently been isolated from porcine non-antral gastric tissue, on pituitary function was investigated in the rat. Graded doses of synthetic porcine GRP were injected intravenously and the animals were killed at various intervals after injection. Growth hormones, LH, FSH, and TSH were measured in serum by specific radioimmunoassays. GRP had no significant effect on growth hormone or FSH serum concentrations at any dose or sampling time studied. In contrast, the heptacosapeptide significantly stimulated LH and suppressed TSH secretion in a dose-related fashion. Since there are striking structural similarities between GRP and bombesin, a tetradecapeptide from amphibian skin which shows amino acid homology with the C-terminal region of GRP, GRP may be the mammalian counterpart of bombesin.     

Evidence that bombesin releases extragastric gastrin in man

Bombesin-induced gastrin release from extragastric sources has been investigated in two groups of patients without gastric antrum: 11 patients with total gastrectomy and 11 patients with subtotal (Billroth II) gastrectomy. A 30-min bombesin infusion (5 ng . kg-1 . min-1) caused a prompt significant gastrin increase (P less than 0.05) in both groups of patients. The gastrin response to bombesin was significantly (P less than 0.005) lower in patients without antral tissue than in the control group (n = 7). The individual peak gastrin responses, in totally (TG) and subtotally (SG) gastrectomized patients, were significantly over basal levels (TG: peak 100.3 +/- 12 vs. basal 62.8 +/- 9.1, P less than 0.005; SG: peak 96.9 +/- 9.4 vs. basal 72.4 +/- 6.8, P less than 0.001; pg/ml, mean +/- S.E.M.). These data indicate that bombesin acts not only on antral G cells, but on all gastrin cells in the gastrointestinal tract.     

Validation of the antral mucosal/submucosal sleeve preparation: studies of gastrin and acetylcholine release in response to luminal stimulation.

In the present study we developed an experimental model for direct assessment of antral endocrine cell and cholinergic neural responses to luminal stimulation. A sleeve of antral mucosal/submucosal tissue was prepared from rat antrum, mounted in perfusion chamber, and perfused in both luminal and submucosal compartments. Morphological and functional integrity of the antral sleeve were confirmed by histological examination and measurement of protein synthesis. Antral gastrin release was assessed in response to luminal stimulation with acid, peptone and distension. Luminal acid (pH3) inhibited basal gastrin release by -70.4% and luminal peptone stimulated gastrin release to 210% above control (p < 0.02). Distention of the antral sleeve by hydrostatic pressure (3-25cm H2O) caused stepwise and significant increase in gastrin release that was reversible. 3H-acetylcholine was stimulated significantly by KCl (56mM) to values twice control. In summary, these results establish the integrity and responsiveness of the antral sleeve to pharmacological and luminal stimulation. The antral sleeve may be a useful model in assessing antral function in response to luminal stimulation.     

Expression and post-translational processing of gastrin in heterologous endocrine cells

The biosynthesis of gastrin involves a complex series of post-translational processing reactions that result in the formation of a biologically active secretory product. To study the mechanisms for two specific reactions in gastrin processing, namely dibasic cleavage and amidation, we infected AtT-20, GH3, and Rin5-f cells with the retroviral expression vector, pZip-NeoSV(X), containing human gastrin cDNA. We detected gastrin and its glycine extended post-translational processing intermediates (G-gly) in the media and cell extracts of successfully infected cells. Characterization of the molecular forms of gastrin in these cell lines revealed that GH3 and Rin5-f processed gastrin in a manner similar to antral G-cells but the cleavage of the Lys74-Lys75 bond that converts G34 to G17 appeared to be suppressed in AtT-20 cells. Even after conversion of this site to Arg74-Arg75 via site-directed mutagenesis, the At-20 cells synthesized G34 predominantly. All of the infected cells amidated gastrin but the gastrin/G-gly ratio, a reflection of amidation within the cells, was enhanced in GH3 and Rin5-f cells but diminished in AtT-20 cells upon treatment with dexamethasone (10(-4) M) for 3 days. The dibasic cleavage of gastrin was uneffected by dexamethasone. Our data suggest that the activities of post-translational processing reactions responsible for the synthesis of biologically active gastrin exhibit considerable tissue and substrate specificity.     

ACTH-like immunoreactivity in the gastrin cell. Independent changes in gastrin and ACTH-like immunoreactivity during ontogeny.

Rat antral gastrin cells have been shown to contain ACTH-like immunoreactivity. Studies on the ontogeny of the antral gastrin cells reveal that these cells start to store gastrin before they contain detectable quantities of ACTH-like immunoreactivity. At no stage studied were duodenal gastrin cells found to contain ACTH-like peptides. The data indicate that the G cells synthetizes and/or releases the two hormonal peptides independently.     

ACTH-like immunoreactivity in the gastrin cell. Independent changes in gastrin and ACTH-like immunoreactivity during ontogeny

Summary Rat antral gastrin cells have been shown to contain ACTH-like immunoreactivity. Studies on the ontogeny of the antral gastrin cells reveal that these cells start to store gastrin before they contain detectable quantities of ACTH-like immunoreactivity. At no stage studied were duodenal gastrin cells found to contain ACTH-like peptides. The data indicate that the G cells synthetizes and/or releases the two hormonal peptides independently.