In vivo action of bombesin on exocrine pancreatic secretion in the rat: independent of cholecystokinin and cholinergic mediation

This study evaluates the effect of bombesin on pancreatic enzyme secretion in the rat and determines whether the stimulatory action of bombesin is mediated through the release of cholecystokinin (CCK) or via a cholinergic pathway. We performed in vivo experiments on conscious rats prepared with cannulae inserted in the pancreatic duct, in the external jugular vein, and in the duodenum. Intravenous infusion of bombesin stimulated pancreatic protein output in a dose-dependent fashion. Bombesin infused at 5 micrograms/kg/h stimulated pancreatic protein secretion from a basal of 12 +/- 5 to 42 +/- 10 mg/h. Infusion of proglumide (400 mg/kg/h) did not affect the stimulatory effect of bombesin on pancreatic protein secretion (38 +/- 5 mg/h). In contrast, infusion of proglumide abolished the pancreatic protein output elicited by intravenous infusion of CCK8 (500 ng/kg/h). This suggests that bombesin does not act through CCK to mediate exocrine pancreatic secretion. In separate studies we intravenously infused rats with atropine (100 micrograms/kg/h) prior to infusion with bombesin. Administration of atropine slightly decreased secretory volume but did not affect the action of bombesin. Combined administration of atropine and proglumide also did not affect pancreatic protein output stimulated by bombesin. Since infusion of neither proglumide nor atropine inhibited the stimulatory action of bombesin, the action of bombesin in the rat is probably direct and not through the release of CCK or via a cholinergic pathway.     

Effect of atropine on intestinal phase of pancreatic secretion in man

The effect of atropine on prestimulatory and Lundh-meal-stimulated pancreatic secretion and on plasma cholecystokinin (CCK) levels has been studied in 20 human volunteers. Prestimulatory secretion was lowered by infusion of atropine. From 10 to 30 min after ingestion of the Lundh meal, atropine had no effect on secretion. From 30 to 120 min, the stimulated enzyme secretion was reduced by 90% during infusion of atropine. Plasma CCK levels were not altered by atropine. Similar results were obtained when the test meal was instilled into the duodenum to exclude a delay of gastric emptying caused by atropine. These data show that cholinergic blockade does not interfere with CCK-mediated stimulation of pancreatic secretion during the first 30 min after ingestion of a meal, and that afterwards the intestinal phase is mainly under cholinergic control.     

Role of secretin and CCK in the stimulation of pancreatic secretion in conscious dogs. Effects of atropine and somatostatin

The role of gut hormones, such as secretin and CCK, in the stimulation of pancreatic secretion by duodenal HCl or oleate and by meat feeding has been studied in conscious dogs before and after pretreatment with atropine and somatostatin. Plasma hormones were measured by specific and sensitive radioimmunoassays. Duodenal perfusion with HCl and oleate stimulated dose-dependently pancreatic HCO3 and protein secretion and raised plasma levels of secretin and CCK, respectively. Atropine reduced significantly both HCO3 and protein secretion but did not affect plasma secretin and CCK levels in these studies. Both exocrine pancreatic secretion and plasma secretin and CCK levels were suppressed by somatostatin. Meat feeding caused a marked pancreatic HCO3 and protein secretion accompanied by a significant increase in plasma secretin and CCK which seem to play an important role in the postprandial pancreatic stimulation. Both atropine and somatostatin reduced the pancreatic secretion induced by exogenous hormones but only somatostatin, but not atropine, significantly decreased plasma secretin and CCK responses to intestinal stimulants. We conclude that both atropine and somatostatin reduce the pancreatic responses to duodenal HCl or oleate or to meat feeding but only somatostatin is capable of suppressing the release of secretin and CCK.     

Atropine enhances food-stimulated CCK secretion in the rat

The effect of atropine on plasma cholecystokinin (CCK) and pancreatic secretion during intraintestinal infusion of a conventional defined formula liquid diet (Ensure HN, Ross Laboratories, 1.06 kcal/ml) was studied in conscious rats. Rats were prepared with cannulae draining bile and pancreatic juice, which were returned to the duodenum at all times. Pancreatic secretion was monitored during intraduodenal infusion of 0.15 M NaCl for 2 h followed by Ensure HN, both infused at 4.62 ml/h. Rats were infused i.p. with atropine (500 micrograms/kg/h) or vehicle throughout the experiment, beginning 1 h before monitoring of basal pancreatic secretion. Basal and 15 min postprandial plasma CCK concentrations were determined by bioassay. Atropine inhibited basal pancreatic protein secretion by approximately 60%. However, protein secretion during infusion of the diet was not decreased by atropine, due to a larger incremental pancreatic protein secretory response in atropine-treated rats. Plasma CCK 15 min after beginning the diet infusion was significantly increased by atropine (8.09 +/- 1.77 pM in atropine-treated rats versus 3.14 +/- 0.64 pM in controls). The results indicate that rats compensate for loss of cholinergic input to the pancreas by increasing CCK release in response to a meal. This is hypothesized to occur by virtue of reduced feedback inhibition of CCK release due to anticholinergic reduction of basal levels of intestinal protease activity.     

Comparison of loxiglumide, a cholecystokinin receptor antagonist, and atropine on hormonal and meal-stimulated pancreatic secretion in man

The effects of loxiglumide, a potent cholecystokinin (CCK)-receptor antagonist, and atropine, a muscarinic receptor blocker, on exocrine pancreatic secretion stimulated by hormones (secretin plus CCK) and a Lundh test meal were studied in healthy young volunteers. Loxiglumide infused intravenously in gradually increasing doses (2-16 mumol/kg-h) caused a dose-dependent inhibition of pancreatic enzyme secretion induced by intravenous infusion of a constant dose of secretin (82 pmol/kg-h) plus CCK-8 (85 pmol/kg-h) but had relatively smaller influence on duodenal volume flow and bicarbonate output. Atropine (20 nmol/kg) also caused a significant reduction in pancreatic enzyme secretion but failed to affect the volume flow or bicarbonate secretion induced by secretin plus CCK, possibly owing to the high doses of secretin and CCK used in these tests. Both loxiglumide and atropine inhibited the pancreatic enzyme response to a Lundh meal, but atropine was more effective in the early phase and loxiglumide in the late phase of the postprandial secretion. Neither loxiglumide nor atropine affected the plasma gastrin and CCK levels, but both antagonists reduced plasma pancreatic polypeptide responses to the Lundh meal. We conclude that 1) loxiglumide results in a relatively stronger suppression of the pancreatic enzyme than aqueous-alkaline secretion induced by secretin plus CCK, whereas atropine inhibits only enzyme secretion; and 2) both loxiglumide and atropine suppress the pancreatic enzyme responses to the meal stimulation without affecting the postprandial plasma gastrin and CCK responses.     

Trypsin suppression of pancreatic enzyme secretion. Differential effect on cholecystokinin release and the enteropancreatic reflex

We have recently demonstrated that intraduodenal perfusion of trypsin inhibits phenylalanine-stimulated pancreatic enzyme secretion by suppression of release of cholecystokinin (CCK). It is not known whether trypsin in the duodenum inhibits pancreatic secretion stimulated by a cholinergic mechanism. To investigate this question gastrointestinal intubation and perfusion were performed in 12 healthy subjects. Volume and osmoreceptors in the duodenum, which are known to elicit pancreatic secretion through cholinergic pathways, were stimulated by infusing increasing volumes (1.0, 2.5, and 5.0 ml/min) of normal saline or increasing osmolality (300, 400, 500 mosmol) of NaCl solution. Increasing the rates of intraduodenal perfusion of normal saline or increasing the osmolality of the duodenal perfusates caused a dose-related increase in pancreatic trypsin and chymotrypsin outputs without affecting basal plasma CCK levels (0.9 +/- 0.1 pM). The volume- or osmolality-stimulated pancreatic secretions were abolished by atropine, but not by intraduodenal perfusion of trypsin. In contrast, intraduodenal perfusion of phenylalanine (10 mM) produced a significant increase in plasma CCK levels (6.7 +/- 0.8 pM) and a three- to fourfold increase in pancreatic enzyme outputs. Perfusion of the duodenum with bovine trypsin (1 g/L) reduced the plasma CCK levels to basal values and significantly attenuated the phenylalanine-stimulated enzyme secretion to 63% +/- 4% of control. Simultaneous administration of atropine and intraduodenal perfusion of trypsin completely abolished the pancreatic enzyme response to phenylalanine stimulation. These studies indicate that the intestinal phase of human pancreatic enzyme secretion is under both hormonal and neural control. Intraduodenal trypsin inhibits only pancreatic secretion mediated by CCK release, and not that mediated by cholinergic mechanisms. These observations suggest that feedback regulation of pancreatic enzyme secretion is stimulus specific.     

Interaction of the cholinergic system and cholecystokinin in the regulation of endogenous and exogenous stimulation of pancreatic secretion in humans.

Pancreatic enzyme secretion is regulated in humans by the cholinergic system and by cholecystokinin (CCK). The interaction between both regulatory systems in response to exogenous and endogenous stimulation was analyzed in the present study using the cholinergic antagonist atropine and the CCK antagonist loxiglumide. A dose-dependent stimulation of pancreatic enzyme output was achieved either by duodenal perfusion of graded caloric loads or by IV infusion of increasing doses of cerulein. Prestimulated pancreatic secretion was inhibited by atropine and loxiglumide. Atropine furthermore almost completely blocked meal-stimulated pancreatic secretion, whereas loxiglumide caused 60% inhibition. The enzyme response to graded doses of exogenous CCK was significantly inhibited by atropine and loxiglumide. Plasma levels of CCK were not altered by atropine but increased with infusion of loxiglumide. This study supports the concept that pancreatic enzyme secretion is predominantly dependent on a cholinergic tone and that CCK modulates the enzyme-secretory response.     

Effect of a liquid meal given as a bolus into the jejunum on human pancreatic secretion

Major features of pancreatic secretion stimulated by a meal depend on intestinal phase mechanisms. However, an intrajejunal (i.j.) meal infusion is widely used for the treatment of inflammatory pancreatic diseases when the resting of the gland is desired. This study was undertaken to compare the effects of an intragastric (i.g.) and an i.j. complete fluid (Lundh) test meal on pancreatic enzyme secretion. Eight men (mean age, 43 years; range, 31-48) free from pancreatic disease were studied. Pancreatic secretion was measured via a multiple-lumen tube by aspiration of the duodenal juice. After a fasting period, the Lundh test meal was placed in the stomach or the upper jejunum. After the i.g. administration of the test meal, the aspirated duodenal juice was reinfused into the jejunum. The effect of atropine infusion (0.5 microg/kg/h) on the pancreatic enzyme secretion was studied. The pancreatic amylase, trypsin, and lipase outputs were determined. The plasma levels of cholecystokinin (CCK) and of gastrin were measured by bioassay and radioimmunoassay, respectively. The trypsin, amylase, and lipase secretions increased significantly after either an i.g. or an i.j. test meal intake. The trypsin, amylase, and lipase outputs were significantly decreased during the i.j. perfusion as compared with i.g. administration. The gastrin levels increased significantly after i.g., but remained unchanged after i.j. administration. The CCK release attained its maximum 40 and 60 min after the i.g. and i.j. test meal, respectively. However, the CCK release was significantly lower during the i.j. administration as compared with i.g. perfusion. An atropine infusion significantly reduced the i.g. and i.j. test meal-stimulated enzyme outputs. An i.j.-administered meal stimulates the pancreatic enzyme secretion, but this effect is significantly lower than that which occurs on i.g. administration. The i.j. meal-stimulated secretion of pancreatic enzymes is subject to both cholinergic and peptidergic regulation. The deficiency of gastrin and the delayed and decreased CCK release are believed to account for the reduced enzyme output.     

Role of cholecystokinin in intestinal phase of human pancreatic secretion

In this study we have utilized a sensitive and specific radioimmunoassay for cholecystokinin (CCK) to determine the effects of a jejunal infusion (5 cc/min) of amino acids (44 g/liter), saline, and amino acids with intravenous atropine (20 micrograms X lg-1 X hr) on pancreatic exocrine secretion. Amino acids were found to stimulate pancreatic output of trypsin and release CCK, while a saline infusion at the same rate and osmolality (320 mosm/liter) failed to do so. In the presence of atropine, the amino acid infusion did not stimulate the pancreatic output of trypsin, despite an augmented CCK release. The total CCK released above baseline was greatest with the infusion of amino acids with atropine, while the total trypsin output above baseline was greatest with the infusion of amino acids. These results indicate that CCK release is not under cholinergic control and that cholinergic blockade inhibits pancreatic secretion by interrupting stimulating cholinergic fibers to the pancreas.     

Comparison of the effect of single and repeated administrations of a protease inhibitor (Camostate) on pancreatic secretion in man

In the present study pancreatic secretion and plasma cholecystokinin (CCK) levels were analyzed in eight volunteers after daily ingestion of the serine protease inhibitor camostate for 5 days. This was compared with the effect of a single intraduodenal dose of camostate. Prolonged administration of camostate for 5 days had no effect on basal and stimulated pancreatic secretion and plasma CCK. A single dose of camostate completely inhibited enzymatic activity of trypsin and chymotrypsin and stimulated volume, amylase, and lipase secretion but induced an only slight and insignificant increase in plasma CCK. After the ingestion of a test meal, camostate did not influence stimulated enzyme secretion and increased plasma CCK. We concluded that the intraduodenal perfusion of camostate stimulated pancreatic secretion by a feedback mechanism that is not mediated by CCK. The repeated oral administration of camostate did not induce adaptive changes in pancreatic secretion.     

Pancreatic polypeptide release: role of stimulants of exocrine pancreatic secretion in dogs

There are apparent similarities in the mechanisms of the intestinal phase of exocrine and pancreatic polypeptide (PP) secretion by the pancreas. To characterize this relationship, we measured incremental responses of protein, bicarbonate, and PP to graded doses of intravenous secretin, caerulein, CCK8, CCK33, bethanechol, and intraduodenally perfused HCl, sodium oleate, and L-phenylalanine in dogs with gastric and pancreatic fistulas and compared them with average postprandial values. Secretin did not release PP at any dose studied, whereas intraduodenal HCl increased PP levels slightly at a load maximal for pancreatic secretion. Caerulein produced dose-related increases in PP secretion (maximal, 106% of meal response) but CCK8 and CCK33 had much less effect at doses equivalent for protein secretion. Bethanechol was a weak stimulant for PP only at the largest tolerable dose. L-Phenylalanine and sodium oleate markedly increased protein secretion, but only oleate clearly stimulated PP. Our results suggest a greater quantitative importance of the intestinal phase for exocrine than endocrine (PP) pancreatic secretion.     

L-364,718, a new CCK antagonist,inhibits postprandial pancreatic secretion and PP release in dogs

The effects of L-364,718, a new CCK receptor antagonist, on food-stimulated exocrine pancreatic secretion and plasma levels of PP, insulin, CCK, and gastrin were examined in four conscious dogs with pancreatic fistulas. Intravenous injections of L-364,718 (20 nmol/kg) significantly inhibited pancreatic protein and enzyme responses by food (33% inhibition) but not juice volume output. Both rapid and secondary prolonged postprandial rises of plasma PP were also significantly suppressed by L-364,718 (50% inhibition); however, plasma levels of insulin were not altered. Postprandial levels of gastrin were not affected by L-364,718 administration, whereas 3-hr integrated CCK response was significantly enhanced by L-364,718. This study indicates that L-364,718 inhibits pancreatic protein and enzyme secretion and the release of pancreatic polypeptide stimulated by food in conscious dogs. This inhibition might be due to the selective blockage of receptor binding of circulating CCK molecules. The results suggest that L-364,718 may be useful for the physiological and pathophysiological studies associated with CCK.     

Atropine inhibits meal-stimulated release of cholecystokinin

To examine the effect of atropine on cholecystokinin (CCK) release, we studied CCK concentrations after a liquid fat meal in five volunteers both with and without pretreatment with atropine. In control studies peak plasma CCK 8 concentrations were 15.0 +/- 6.2 pmol l-1, and the integrated plasma CCK 8 response was 415 +/- 216 pmol l-1(2)h-1. Peak plasma CCK 33/39 concentrations were 16.5 +/- 4.6 pmol l-1, and integrated CCK 33/9 response was 469 +/- 200 pmol l-1(2)h-1. After pretreatment with atropine postprandial CCKs were undetectable (p less than 0.05 versus control studies). The abolition of measurable CCK release by atropine may entirely account for its inhibitory effects on biliary secretion and in part for its effect on the pancreas.     

Effect of atropine on responses of exocrine pancreas and plasma cholecystokinin to intraduodenal amino acids in dogs

The effect of atropine on responses of exocrine pancreas and plasma cholecystokinin (CCK) to intraduodenal mixed amino acids has been studied in conscious dogs with Thomas gastric and duodenal fistulae. Intraduodenal amino acids provoked significant increase of pancreatic protein output and of plasma CCK concentration. Atropine significantly reduced protein output only in the initial peak after amino acid administration. Atropine had no significant effect on plasma CCK. It is indicated that cholinergic nerves predominate in the early pancreatic protein response to intraduodenal amino acids and CCK prevails in the later phase, though these two factors do not seem to be the only factors responsible for the secretion.     

Effects of SMS 201-995 on basal and stimulated pancreatic secretion in rats

Somatostatin (SRIF) is a potent inhibitor of most gastrointestinal and pancreatic functions. Recently, we showed that SRIF given either iv or intraduodenally (id) strongly inhibited stimulated pancreatic secretion induced by pancreatic juice diversion (PJD) from the duodenum. In this study we evaluate the effects of iv and id infusion of a long acting analog of SRIF, SMS 201-995 (SMS), on pancreatic secretion during basal conditions (pancreatic juice returned) and PJD. Conscious rats prepared with bile, pancreatic, duodenal, and jugular cannulae were studied 3-8 days postoperatively. Protein and fluid outputs were evaluated, and plasma cholecystokinin (CCK) was measured by bioassay. iv SMS infusion (5 micrograms kg-1 h-1) inhibited basal pancreatic protein and fluid secretion by 84 and 64%, respectively. Addition of atropine (500 micrograms kg-1 h-1 ip) did not cause further inhibition. During PJD, SMS iv from 0.005-1.28 micrograms kg-1 h-1 for 3 h caused a dose-dependent inhibition with maximal 90% and 75% reductions of protein and fluid, respectively, at 1.28 micrograms SMS. Plasma CCK was also reduced by 83% from 3.01 +/- 1.15 to 0.51 +/- 0.22 pM. SMS, id at 1.7 micrograms kg-1 h-1 for 1.5 h before and 2 h after PJD, caused inhibition of basal secretion by 25% and that induced by PJD by 60%. Plasma CCK, measured 1.5 h after diversion, increased from 1.55 +/- 0.06 to 5.9 +/- 1.14 pM in the presence of SMS. Intravenous SMS was 20 times more potent than SRIF in inhibiting pancreatic protein and volume secretion stimulated by PJD. Iv SMS inhibited basal and stimulated fluid and protein pancreatic secretion as well as plasma CCK levels. SMS was also effective when given id in inhibiting fluid and protein pancreatic secretion, but id SMS increased plasma CCK levels. This effect on plasma CCK may be due to the inhibition of hormonal inhibitors of CCK release.     

Neurotensin and the exocrine pancreas

It has been postulated that neurotensin (NT) has a physiological role in the regulation of the exocrine pancreas, but this is controversial. Using the Thomas cannula canine model, the effect of intravenous NT, in physiological and pharmacological doses on exocrine pancreatic secretion, and on plasma pancreatic polypeptide, secretin and cholecystokinin (CCK) levels is reported. The infusion of physiological doses of NT alone (0.2 pmol/kg per min) did not stimulate pancreatic secretion; however, in conjunction with secretin, NT stimulated protein and bicarbonate output, the latter synergistically. Higher doses of NT (20 and 100 pmol/kg per min) resulted in a dose-dependent stimulation of pancreatic volume, bicarbonate and protein secretion. Cholinergic blockade with atropine reduced pancreatic secretion stimulated by low doses of NT (2–20 pmol/kg per min), but at higher doses (100 pmol/kg per min) protein secretion was reduced whilst bicarbonate secretion was enhanced. The infusion of graded doses of NT had no effect on plasma secretin or CCK levels. In contrast, NT did release pancreatic polypeptide in a dose-dependent manner, but only at pharmacological infusion levels. NT, acting synergistically with other hormones, may thus play a role in exocrine pancreatic stimulation.     

The effect of pituitary adenylate cyclase activating polypeptide (PACAP) on exocrine pancreatic secretion in dogs.

The effect of new hypothalamic peptides, PACAP38 and PACAP27, on exocrine pancreatic secretion was studied in five conscious dogs each with a chronic gastric fistula and a Thomas duodenal fistula. The intravenous injections of PACAP38 and PACAP27 (2.5-100 pmol/kg) induced dose-related increases in pancreatic fluid, bicarbonate, and protein secretion. The potency of PACAP27 was equal to that of VIP but was only 1/100 that of secretin; PACAP38 was less active (less than 1/10) than PACAP27. PACAP38 and PACAP27, in contrast to secretin and VIP, stimulated protein secretion; the potency of the former was about 1/10 that of the latter. The peak response to PACAP27 was about 44% of the maximal response to CCK8. Pancreatic protein secretion, but not fluid and bicarbonate secretion, in response to PACAP38 and PACAP27 was significantly (p less than 0.05) reduced by atropine. It is concluded that PACAP has a VIP-like action on pancreatic fluid and bicarbonate secretion in conscious dogs, but differs from VIP in stimulating protein secretion via a cholinergic mechanism.     

Somatostatin analog, SMS 201-995, inhibits pancreatic exocrine secretion and release of secretin and cholecystokinin in rats.

We studied the effect of a synthetic octapeptide somatostatin analog, SMS 201-995 (sandostatin), on pancreatic exocrine secretion and on plasma secretin and cholecystokinin (CCK) levels in vivo in anesthetized rats. The exocrine pancreas was stimulated by either intravenous infusion of both secretin (0.06 CU/kg/h) and cholecystokinin octapeptide (CCK-8) (0.03 micrograms/kg/h) or intraduodenal infusion of oleic acid (pH 6.5) in a dose of 0.25 mmol/h. Intravenous administration of SMS 201-995 in three different doses of 100, 200, and 400 ng/kg/h resulted in dose-related inhibition of pancreatic secretion in terms of volume, bicarbonate, and amylase stimulated by exogenous secretin and CCK. Intraduodenal oleic acid stimulated pancreatic secretion, including volume, bicarbonate, and amylase, and this was accompanied by a significant elevation in the plasma concentrations of secretin and CCK. Intravenous administration of SMS 201-995 in the three different doses described above caused dose-dependent suppression of the increase in pancreatic exocrine secretion as well as the plasma concentration of secretin and CCK induced by intraduodenal infusion of oleic acid. It is concluded that SMS 201-995 inhibits pancreatic exocrine secretion and the release of endogenous hormones, such as secretin and CCK, in rats.     

Effect of intraduodenai infusion of tocamphyl on pancreatic exocrine secretion and gastrointestinal hormone release in rats

Tocamphyl is a synthetic choleretic that is derived from a root extract ofCurcuma longa, L. We investigated the effect of tocamphyl on pancreatic exocrine secretion and bile flow, and on the release of some gastrointestinal hormones, by administering it intraduodenally using anesthetized rats. Tocamphyl stimulated pancreatic exocrine secretion in terms of volume and amylase output in a dose-related manner. Neither a CCK-receptor antagonist, CR1505 (loxiglumide), nor atropine sulfate infused intravenously suppressed the stimulatory effects of tocamphyl on pancreatic exocrine secretion and bile flow. The stimulatory effect on bile flow was stronger than that on pancreatic exocrine secretion. Plasma secretin levels were augmented with the increasing doses of tocamphyl, but CCK levels were not. These results indicate that intraduodenally administered tocamphyl stimulates pancreatic exocrine secretion and bile flow, and suggest that the stimulatory action is, at least in part, mediated by secretin, but not by either CCK or the cholinergic pathway.     

Diazepam binding inhibitor is a potent cholecystokinin-releasing peptide in the intestine.

Pancreatic proteases in the duodenum inhibit the release of cholecystokinin (CCK) and thus exert feedback control of pancreatic exocrine secretion. Exclusion of proteases from the duodenum either by the diversion of bile-pancreatic juice or by the addition of protease inhibitors stimulates exocrine pancreatic secretion. The mechanism by which pancreatic proteases in the duodenum regulate CCK secretion is unknown. In this study, we isolated a trypsin-sensitive peptide that is secreted intraduodenally, releases CCK, and stimulates pancreatic enzyme secretion in rats. This peptide was found to be identical to the porcine diazepam binding inhibitor by peptide sequencing and mass spectrometry analysis. Intraduodenal infusion of 200 ng of synthetic porcine diazepam binding inhibitor1-86 in rats significantly stimulated pancreatic amylase output. Infusion of the CCK antagonist MK-329 completely blocked the diazepam binding inhibitor-stimulated amylase secretion. Similarly, diazepam binding inhibitor33-52 [corrected] also stimulated CCK release and pancreatic secretion in a dose-dependent manner although it was 100 times less potent than the whole peptide. Using a perfusion system containing isolated mucosal cells from the proximal intestine of rats, porcine diazepam binding inhibitor 10(-12) M) dose dependently stimulated CCK secretion. In separate studies, it was demonstrated that luminal secretion of the diazepam binding inhibitor immunoreactivity (7.5 X 10(11) M) could be detected in rat's intestinal washing following the diversion of bile-pancreatic juice. The secretion of this peptide was inhibited by atropine. In conclusion, we have isolated and characterized a CCK-releasing peptide that has a sequence identical to the porcine diazepam binding inhibitor from pig intestinal mucosa and that stimulates CCK release when administered intraduodenally in rat. This peptide may mediate feedback regulation of pancreatic enzyme secretion.