Diverse effects of phytohaemagglutinin on gastrointestinal secretions in rats.

Kidney bean lectin phytohaemagglutinin (PHA) is known for its binding capacity to the small intestinal surface inducing marked hyperplasia and hypertrophy and an increased pancreatic function. Recent observations indicate that PHA is able to attach to gastric mucosal and parietal cells. Therefore, we compared the effects of PHA on gastric acid secretion, and pancreatic amylase secretion in rats. To study gastric secretion in conscious animals, rats were surgically prepared with chronic stainless steel gastric cannula and with indwelling polyethylene jugular vein catheter. Acid secretion was determined by titration of the collected gastric juice to pH 7.0. Similar studies were performed to investigate the effect of PHA on pancreatic enzyme secretion in conscious rats supplied with pancreatic cannula. Pancreatic enzyme secretion was also studied in rats anesthetized with either halothane or urethane. In conscious rats PHA significantly inhibited basal acid secretion when compared to vehicle-treated controls. The effect was dose-dependent and reversible. On the other hand, given in the same doses as in the acid-secretory studies, PHA stimulated pancreatic amylase secretion in rats prepared with chronic pancreatic cannula. This effect was blocked by devazepide, a CCK-A receptor antagonist. In halothane-anesthetized rats PHA administration increased pancreatic amylase secretion, too. During urethane anesthesia, however, the stimulatory effect of PHA was not observed. These results provide evidence that intragastric PHA treatment induces opposite effects on gastric acid secretion and pancreatic enzyme secretion: it is a potent inhibitor of acid output, and a stimulator of pancreatic enzyme discharge. Our data also show that the stimulatory effect of PHA on pancreatic enzyme secretion can be blocked by urethane, an anaesthetic that is known to turn off the negative pancreatic feedback control of pancreatic function in rats.     

The effect of secretin on acid and pepsin secretion and gastrin release in the totally isolated vascularly perfused rat stomach

The effect of secretin on acid and pepsin secretion and gastrin release in the totally isolated vascularly perfused rat stomach was studied. With the phosphodiesterase inhibitor isobutyl methylxanthine (IMX) added to the vascular perfusate, baseline acid secretion was 4.7 +/- 1.1 (mean +/- S.E.M.) mumol/h and baseline pepsin output 1147 +/- 223 micrograms/h. Secretin significantly inhibited acid output to a minimum of 1.4 +/- 0.2 mumol/h at a concentration of 25 pM in the vascular perfusate (P less than 0.01). Pepsin output was not significantly different from baseline at any of the secretin doses tested. Threshold secretin concentration for acid inhibition was 5 pM. IMX stimulated gastrin output from 48 +/- 9 pM in the basal state to 95 +/- 13 pM after IMX (P less than 0.01). Secretin inhibited gastrin release only at the maximal dose of 625 pM, when gastrin concentration in the venous effluent decreased from 93 +/- 19 to 68 +/- 19 pM after secretin. Thus, in the totally isolated vascularly perfused rat stomach secretin in physiological concentrations inhibits acid secretion by a direct action on the acid secretory process and not via gastrin inhibition. The study also suggests that gastrin release at least in part is mediated via increased intracellular cAMP.     

雨蛙肽中枢促胃酸分泌作用机制的初步分析

利用特异的受体阻断剂能够拮抗相应的受体激动剂的效应的原理,分析雨蛙肽中枢促胃酸分泌作用的受体机制。向大鼠侧脑室内注射微量雨蛙肽(67ng/鼠),可引起急性灌流大鼠胃酸分泌明显增加。预先向大鼠侧脑室内注射肾上腺素受体阻断剂酚妥拉明或心得安,20min后再向侧脑室内注射雨蛙肽,预处理对雨蛙肽的促胃酸分泌作用影响不大。但事先向侧脑室内注射乙酰胆碱受体阻断剂阿托品或胆囊收缩素(CCK)受体阻断剂二丁酰环化-磷酸鸟苷(Bt_2 cGMP)则可有效地阻断雨蛙肽的作用。以上结果提示,脑内雨蛙肽促胃酸分泌机制中,可能有 CCK 受体和胆碱能受体参与,而与肾上腺素能系统关系不大。     

Pathogenic importance of pepsin in ischemia/reperfusion-induced gastric injury

We investigated the role of pepsin in the development of ischemia/reperfusion (I/R)-induced gastric lesions in rats. Under urethane anesthesia, the pylorus was ligated, the celiac artery was clamped, and 1 ml of HCl (50-150 mM) was instilled in the stomach. Then, reperfusion was established 15 min later by removing the clamp, and 2 h later the stomach was assessed for gross mucosal damage. Pepstatin (a specific pepsin inhibitor) or pepsin was given i.g. after the pylorus was ligated while cimetidine, omeprazole, or atropine was given s.c. 30 min before the ligation. I/R produced hemorrhagic gastric injury, with a concomitant increase in the amount of pepsin secreted, and the degree of both these responses was dependent on the concentration of HCl. The formation of lesions by IR in the presence of 100 mM HCl was significantly prevented by atropine or bilateral vagotomy, but neither omeprazole nor cimetidine had any effect. Intragastric administration of pepstatin dose-dependently reduced the severity of the I/R-induced gastric lesions, the effect being significant even at 0.1 mg/kg, while that of pepsin markedly aggravated these lesions. The increased pepsin output during I/R was associated with luminal acid loss and significantly inhibited by bilateral vagotomy or pretreatment with atropine but not cimetidine or omeprazole, while pepstatin significantly inhibited the pepsin activity. In conclusion, we suggest that pepsin plays a pivotal role in the pathogenesis of I/R-induced gastric lesions, and pepsin secretion is increased during I/R, the process being associated with acid back-diffusion and mediated through a vagal-cholinergic pathway.     

Control of pepsin secretion by regulatory peptides in the rat stomach: comparison with acid secretion.

Previous studies of the control of pepsin secretion by neurohumoral agents showed some discrepancies between in vitro (isolated cells) and in vivo experiments. In the present work, the effects on pepsin secretion of CCK, pentagastrin, secretin, VIP, neurotensin, histamine, and methacholine were reinvestigated in conscious gastric fistula rats, in comparison to acid secretion. ED50's and doses inducing maximal responses were measured to directly compare the potency and efficacy of these substances. Methacholine was the most efficient (maximal response = 4.5 x basal level, ED50 = 1.3 mumol/kg.h) and CCK the most potent (ED50 = 1.9 nmol/kg.h) stimulant, whereas secretin was a potent (ED50 regulators of pepsin secretion in the rat. Pentagastrin and histamine did not stimulate pepsin output, as found by others with isolated chief cells in vitro. Neurotensin and large doses of VIP marginally inhibited pepsin secretion.     

Potentiation of the gastro-protective effect of sulglicotide in the presence of cimetidine in the rat

The effects of sulglicotide, alone or combined with cimetidine, have been investigated on mucosal lesions induced in rats by pylorus ligation. In the same animals, the measurement of acid and pepsin output and of soluble and barrier mucus has been performed. Dose-dependent sulglicotide prevented the development of mucosal lesions and its protective effect was achieved without significant modifications in gastric acid secretion. The secretion of pepsin and of mucus was markedly inhibited at every dosage of the compound. Neither the damage to gastric mucosa nor the secretion of acid, pepsin and mucus were affected by cimetidine. The combination of the highest doses of both compounds resulted in a synergistic gastro-protective effect, not dependent on a synergistic effect on the reduction in acid secretion.     

Cyclic hexa- and pentapeptide somatostatin analogues with reduced gastric inhibitory activity

The gastric inhibitory activity of cyclic hexa- and pentapeptide analogues of somatostatin was investigated in conscious cats with gastric fistulae. Gastric acid and pepsin secretions were stimulated by pentagastrin. Cyclo(Phe-Phe-D-Trp-Lys-Thr-Phe) showed no inhibition of acid secretion at molar doses up to 50-times the ID50 for somatostatin. This peptide inhibited pepsin secretion at the highest dose (50 micrograms kg-1 hr-1), and its potency is approximately 0.005 compared with somatostatin (1.0). Cyclo(Pro-Phe-D-Trp-Lys-Thr-Phe) inhibited acid (approximately 50%) and pepsin (approximately 85%) secretions, but the inhibition was not dose-related being similar with doses of 10 to 50 micrograms kg-1 hr-1. The cyclic pentapeptide, cyclo(7-aminoheptanoyl-Phe-D-Trp-Lys-Thr), was inactive in the dose range studied, with a potency less than 0.01. Cyclo[7-aminoheptanoyl-Phe-D-Trp-Lys-Thr(Bzl)] has been described as a somatostatin antagonist with respect to inhibition of growth hormone, insulin and glucagon release in rats [2]. Up to 60-fold molar excesses of this peptide failed to antagonise the inhibitory activity of somatostatin in the stomach. The results demonstrate that residues outside the central 6-11 region of somatostatin are very important for its gastric activity. The lack of gastric antagonistic activity of the pentapeptide antagonist indicates that these residues are likely to be involved in receptor recognition/binding.     

Gastric secretion and gastrin under progressive doses of somatostatin-14 and -28 administered intraperitoneally to the rat

The actions of progressive doses of intraperitoneally (IP) administered somatostatin-14 (SS-14) and -28 (SS-28) on gastric secretion (acid, pepsin) and mucosal blood flow (MBF) were studied in conscious gastric fistula rats both under basal conditions and under additional administration of pentagastrin. Also, somatostatin-like immunoreactivity was measured in aortal blood in all groups as well as aortal gastrin levels under basal conditions. IP infusion of equimolar doses of SS-14 and SS-28 resulted in an equal and dose-dependent inhibition of basal as well as pentagastrin-stimulated gastric acid secretion. MBF was reduced by either peptide both in the basal and pentagastrin experiments. Under basal conditions pepsin secretion was significantly increased by infusion of SS-14 at the higher doses, by infusion of SS-28 only at the intermediate dose (3.1 nmole kg-1.hr-1). In the pentagastrin experiments, low and intermediate doses of SS-14 tended to lower pepsin outputs but the highest dose of SS-14 stimulated pepsin secretion, whereas SS-28 had no effect on pepsin. Administration of SS-28 inhibited gastrin only at the highest dose (12.3 nmole kg-1.hr-1), and SS-14 had no influence at all on gastrin. After IP infusion of both peptides, plasma SLI rose dose-dependently under basal and stimulated conditions. Gel chromatography indicated an in-vivo conversion of SS-28 to SS-14 or intermediate fragments. It is concluded that SS-14 and SS-28 delivered by IP infusion, inhibit basal and stimulated gastric acid equally in the rat without suppressing gastrin. The mechanism underlying SS-mediated pepsin stimulation is unknown.     

八种脑-肠肽侧脑室内注射对大鼠基础胃酸分泌的影响

用乌拉坦麻醉大鼠作急性实验,采用连续灌流胃并收集流出液的方法,观察向侧脑室内注射微量脑-肠肽对大鼠基础胃酸分泌的影响。实验结果如下:(1)雨蛙肽、八肽胆囊收缩素、促甲状腺素释放激素及四肽胃泌素均使总酸排出量增加;(2)生长抑素、胰多肽、P 物质、胰高血糖素则使总酸排出量减少;(3)上述肽类用侧脑室注射的剂量作肌肉注射,除四肽胃泌素也产生明显的刺激胃酸分泌作用外,对胃酸分泌均无明显影响。以上结果提示,脑内的一些肽类可能以神经递质或调制物的方式,参与中枢对胃酸分泌的调节。     

Inhibition of gastric and pancreatic secretions by cerebroventricular injections of gastrin-releasing peptide and bombesin in rats

It has been suggested that mammalian gastrin-releasing peptide (GRP) and bombesin (BBS) might inhibit gastric secretion by a central nervous system action. The present investigations were intended to define the gastric effect and to look for an effect on the exocrine pancreas. Wistar male rats were provided with a chronic cannula allowing cerebroventricular injections in the 3rd ventricle, and with chronic gastric and/or pancreatic fistulas allowing the collection of gastric and/or pancreatic secretions in conscious animals. Both basal secretions were studied. Gastric secretion was stimulated with a 75 mg/kg s.c. injection of 2-deoxyglucose (2-dGlc). The dose range of bombesin was 0.01–1 μg (6–600 pmol) and GRP was 0.01–10 μg/rat (3.5 pmol to 3.5 nmol). A significant dose related decrease of basal gastric secretion was observed with the two peptides. The gastric acid response to 2-dGlc was inhibited by both peptides in a dose-related fashion and the reduction of gastric acid output mainly resulted from a decrease in the volume of gastric juice. The exocrine pancreatic secretion was also decreased by 30–55% after GRP but the BBS inhibitory effect was poorly dose-related. No significant difference was found after removal of gastric secretion, indicating that most of the pancreatic inhibition was independent of gastric secretion.     

Bombesin microinjected into the dorsal vagal complex inhibits vagally stimulated gastric acid secretion in the rat

Medullary sites of action for bombesin-induced inhibition of gastric acid secretion were investigated in urethane-anesthetized rats with gastric fistula. Unilateral microinjection of bombesin or vehicle into the dorsal vagal complex was performed using a glass micropipet and pressure ejection of 100 nl volume; gastric acid output was measured every 10 min by flushing the stomach. Microinjection of vehicle into the dorsal vagal complex did not alter gastric acid secretion (1.9 +/- mumol/10) from preinjection levels (2.9 +/- 0.8 mumol/10 min). Microinjection of the stable thyrotropin-releasing hormone (TRH) analog, RX 77368, at a 77 pmol dose into the dorsal vagal complex stimulated gastric acid secretion for 100 min with a peak response at 40 min (24.1 +/- 3.2 mumol/10 min). Concomitant microinjection of RX 77368 (77 pmol) with bombesin (0.6-6.2 pmol) into the dorsal vagal complex dose dependently inhibited by 35-86% the gastric acid response to the TRH analog. Bombesin (6.2 pmol) microinjected into the dorsal vagal complex inhibited by 17% pentagastrin infusion-induced stimulation of gastric acid secretion (13.2 +/- 0.8 mumol/10 min) whereas intracisternal injection induced a 69% inhibition of the pentagastrin response. These results demonstrate that the dorsal motor complex is a sensitive site of action for bombesin-induced inhibition of vagally stimulated gastric secretion. However, other medullary sites must be involved in mediating the inhibitory effect of intracisternal bombesin on pentagastrin-stimulated gastric acid secretion.     

Effect of Intragastric Administration of Crude Aqueous Leaf Extract Of Anacardium occidentale on Gastric Acid Secretion in Rats

The effect of an aqueous leaf extract ofAnacardium occidentale on gastric acid secretion was tested in rats. Twenty (20) Wistar albino rats were used for the gastric acid assay experiment. The rats were divided into 2 groups of 10 each. Gastric acid output was determined by continuous perfusion of rat stomach in urethane anesthetized rats. Control gastric acid output was obtained using 0.9% sodium chloride as perfusate and extract induced gastric acid output was obtained by perfusion with 0.1% solution of Anacardium occidentale Intragastric administration of the extract caused significant increase in mean gastric output (P <0.05). Atropine (5μg/100g,) lM and Cimetidine (5mg/100g), IM. significantly inhibited the extract induced gastric acid secretion via muscarinic and histaminic receptors respectively. Our findings showed that the use of the plant extract as a single anti-gastric ulcer therapy may not involve lowering of acid secretions rather it may be due to its anti Helicobacter pylori effect.     

Does motilin control interdigestive pepsin secretion in the dog?

Pepsin output in the Heidenhain pouch, plasma motilin concentration, and contractile activity in the pouch and the main stomach were investigated in five dogs. During the interdigestive state, the pepsin output was significantly increased with a cyclic increase in contractile activity in both the pouch and main stomach at approximately 100-min intervals. The plasma immunoreactive motilin (IRM) concentration fluctuated during the interdigestive state, and, peaks of IRM concentration coincided with the maximum pepsin secretory activity. Exogenous administration of motilin (0.5 micrograms/kg-hr) increased contractile activity in the main stomach and pouch quite similar to the natural interdigestive migrating contractions (IMC), and increased pepsin output significantly. Atropine pre-treatment suppressed the naturally-occurring and motilin-induced pepsin output and contractions in the pouch. It is concluded that pepsin output and contractions in the Heidenhain pouch increase in close association with the IMC in the main stomach during the interdigestive state and these cyclic motor and secretory events in the vagally denervated fundic pouch are most likely regulated by motilin through the intramural cholinergic pathway.     

Effects of ethanol on gastric acid secretion and gastric mucosal cyclic AMP in the rat.

The effect of ethanol on the secretion of gastric acid and the content of cyclic AMP of the gastric mucosa was studied in rats. Intravenously, ethanol (10 to 800 mg/kg) had no effect on the output of acid. Upon local application into the stomach, ethanol (1 to 10%) caused a concentration-dependent inhibition of the output of gastric acid. The effect was evident within 5 min. At the concentration of 1 %,ethanol decreased the rate of acid secretion maximally by about 30%. At the concentration of 3 %, the maximal inhibition was about 70 %. At the concentration of 10 %, ethanol caused a total cessation of the output of acid within 20 to 60 min.Five and 25 min after the administration of 10 % ethanol into the stomach, the gastric mucosal content of cyclic AMP was decreased by approximately 50 %. Also in vitro, the mucosal content of cyclic AMP was decreased by ethanol within 5 min. The decrease was about 30 % with 2.5 % ethanol, approximately 60 % with 10 % ethanol, and approximately 45 % with 20 % ethanol. Alcohol inhibited the activity of the cyclic AMP phosphodiesterase of the gastric mucosa in a competitive manner. The K_i-value was 0.16 M which would correspond to an alcohol concentration of 9.1 % (v/v). Ethanol caused a concentration-dependent inhibition of the activity of the gastric mucosal adenyl cyclase. By 0.166 M (9.4 %) alcohol the inhibition was nearly 100 %.It is concluded that the ethanol-induced decrease of cyclic AMP in the gastric mucosa is due to a decreased formation of the nucleotide. The accompanying inhibition of the output of acid by ethanol is consistent with the view that cyclic AMP is an intracellular regulator of the gastric acid secretion. In view of the role of cyclic AMP in the control of the integrity of the cells, it is suggested that the ethanol-induced damage of gastric mucosa might also be, at least partly, due to the decreased mucosal content of cyclic AMP.     

Influence of amino acids on gastric emptying in young pigs.

The effects of amino acids on gastric emptying and secretion were studied in four young conscious pigs provided with a chronic gastric cannula. A basal test meal of 500 ml containing 10 g citrus pectin, 17.5 g sucrose, 100 mg phenol red alone or with glycine, L- or DL-tryptophan, DL-methionine or L-glutamic acid was poured into the stomach and recovered 20 min later. Glycine at concentrations of 26.7--106.8 mM/l did significantly affect gastric emptying, although at the highest concentration gastric emptying appeared to slow down. L-lysine (41.0 mM/l), DL-methionine (40.3 mM/l or L-tryptophan (29.4 mM/l did not significantly affect the rate of stomach emptying; L-tryptophan increased the amount of Cl- and H+ secreted as compared with the basal diet alone. The effects of addition of the essential amino acids, L-lysine and DL-methionine, were compared with those of the nonessential glycine and L-glutamic acid. There was no significant difference in the rate of gastric emptying or secretion between them. The L and DL isomers of lysine and trypotphan were not found to differ significantly in their effects on gastric emptying and secretion.     

Intragastric pH regulates conversion from net acid to net alkaline secretion by the rat stomach

Our previous report showed gastric mucosal surface pH was determined by alkali secretion at intragastric luminal pH 3 but by acid secretion at intragastric pH 5. Here, we question whether regulation of mucosal surface pH is due to the effect of luminal pH on net acid/base secretions of the whole stomach. Anesthetized rats with a gastric cannula were used, the stomach lumen was perfused with weakly buffered saline, and gastric secretion was detected in the gastric effluent with 1) a flow-through pH electrode and 2) a fluorescent pH-sensitive dye (Cl-NERF). During pH 5 luminal perfusion, both pH sensors reported the gastric effluent was acidic (pH 4.79). After perfusion was stopped transiently (stop-flow), net acid accumulation was observed in the effluent when perfusion was restarted (peak change to pH 4.1-4.3). During pH 3 luminal perfusion, both pH sensors reported gastric effluent was close to perfusate pH (3.0-3.1), but net alkali accumulation was detected at both pH sensors after stop-flow (peak pH 3.3). Buffering capacity of gastric effluents was used to calculate net acid/alkaline secretions. Omeprazole blocked acid secretion during pH 5 perfusion and amplified net alkali secretion during pH 3 perfusion. Pentagastrin elicited net acid secretion under both luminal pH conditions, an effect antagonized by somatostatin. We conclude that in the basal condition, the rat stomach was acid secretory at luminal pH 5 but alkaline secretory at luminal pH 3.     

Gastric effects of thyrotropin-releasing hormone microinjected into the dorsal vagal nucleus in cats

We investigated the gastric acid secretory and motility responses to microinjection of thyrotropin-releasing hormone (TRH) into the dorsal motor nucleus of the vagus (DMV) in anesthetized cats. Gastric acid output was collected every 15 min through a gastric cannula after saline flush and titrated to pH 7.0. Antral and corpus contractions were continuously recorded by extraluminal force transducers. TRH dissolved in 200 nl of saline and microinjected unilaterally into the DMV induced a dose-dependent (50-200 ng) increase in gastric acid secretion. The acid secretory response began in the first 15 min collection and lasted 45 min. TRH frequently increased the force of contractions of the antrum and corpus within one minute of microinjection. The minimal effective dose for eliciting increased motility was lower than for inducing acid secretion. These results demonstrate that TRH acts in the DMV of cats to stimulate gastric acid secretion and contractions.     

Correlation of gastric mucosal damage with sialic acid profile in rats: effect of hydrochloric acid, pepsin and hypertonic saline

Sialic acids occupy terminal positions on gastric mucus glycoprotein where they contribute to the high viscosity of mucin. Desialylation of mucus may lead to degradation of the mucus and eventually to the breakdown of the gastric mucus barrier. The effect of a variety of damaging agents (0.1 M HCl, 2 mg ml(-1) pepsin and 2 M NaCl) on sialic acid profile was determined in pylorus-ligated rats. The relationship between sialic acid, galactose, pyruvate and the extent of gastric mucosal damage were studied. Instillation of pepsin significantly increased total sialic acid, galactose and macroscopic mucosal lesions in the stomach. Instillation of 0.1 M HCl reduced the total sialic acid but this decrease was not significant. Acidity led to a significant increase in the amount of free sialic acid in the gastric instillates and the macroscopic lesions induced by acid was not significantly different from the control animals (0.15 M NaCl). 2 M NaCl induced the macroscopic lesions in the stomach and also free sialic acid in the instillates. Pepsin potentiates the action of 2 M NaCl. In all the agents examined with the exception of acid, it was observed that an increase in free sialic acid and galactose was accompanied by gastric mucosal erosion and elevation of pyruvate concentration. It is concluded that gastric acidity alone is not inherently damaging and that resistance of gastric mucosa to destructive agents may be dependent on the integrity of the sialic acids.     

Peptide histidine valine-42 stimulates gastric acid secretion in man

The effect of peptide histidine valine-42 (PHV-42) on gastric acid secretion was studied in man. PHV-42 was infused into 5 healthy volunteers at a dose of 10 pmol/kg/min. This dose caused a significant stimulation of basal gastric acid and potassium output. there were no significant changes in circulating gastrin throughout the infusion. In 2 subjects with a background of submaximal pentagastrin stimulation, PHV-42 infusion at the same dose did not alter acid secretion in either subject. The previous observation that PHV-42 is found particularly in the stomach and the new finding that it stimulates basal gastric secretion suggest the possibility that PHV-42 could have a role in local control of acid secretion.