Central and peripheral administration of secretin inhibits food intake in mice through the activation of the melanocortin system.

Secretin (Sct) is released into the circulation postprandially from the duodenal S-cells. The major functions of Sct originated from the gastrointestinal system are to delay gastric emptying, stimulate fluid secretion from pancreas and liver, and hence optimize the digestion process. In recent years, Sct and its receptor (Sctr) have been identified in discrete nuclei of the hypothalamus, including the paraventricular nucleus (PVN) and the arcuate nucleus (Arc). These nuclei are the primary brain sites that are engaged in regulating body energy homeostasis, thus providing anatomical evidence to support a functional role of Sct in appetite control. In this study, the effect of Sct on feeding behavior was investigated using wild-type (wt), Sct(-/-), and secretin receptor-deficient (Sctr(-/-)) mice. We found that both central and peripheral administration of Sct could induce Fos expression in the PVN and Arc, suggesting the activation of hypothalamic feeding centers by this peptide. Consistent with this notion, Sct was found to increase thyrotropin-releasing hormone and melanocortin-4 receptor (Mc4r) transcripts in the PVN, and augment proopiomelanocortin, but reduces agouti-related protein mRNA expression in the Arc. Injection of Sct was able to suppress food intake in wt mice, but not in Sctr(-/-) mice, and that this effect was abolished upon pretreatment with SHU9119, an antagonist for Mc4r. In summary, our data suggest for the first time that Sct is an anorectic peptide, and that this function is mediated by the melanocortin system.

Small bowel injury associated to allergy is triggered by platelet-activating factor, mast cells, neutrophils and protected by nitric oxide.

Allergy to components of the diet is followed by gut inflammation which in children, sometimes progress to mucosal lesions and anaphylaxis. In newborns suffering of cow's milk allergy, bloody stools, rectal bleeding and ulcerations are found. The rat systemic anaphylaxis is a suitable model to study the intestinal lesions associated to allergy. In the present study we used this model to investigate some mechanisms involved. We found that 15 min after antigen challenge of sensitized rats, hemorrhagic lesions develop in the small intestine. The lesions were more severe in jejunum and ileum compared to duodenum. Pretreatment of the rats with a platelet-activating factor-receptor antagonist (WEB-2170) reduced the lesions whereas inhibition of endogenous nitric oxide by l-NAME, greatly increased the hemorrhagic lesions and mortality. Both, lesions and mortality were reversed by l-arginine. The hemorrhagic lesions were also significantly reduced by the mast cell stabilizers, disodium cromoglycate and ketotifen as well as by neutrophils depletion (with anti-PMN antibodies) or inhibition of selectin binding (by treatment with fucoidan). Thus, the intestinal hemorrhagic lesions in this model are dependent on platelet-activating factor, mast cell granule-derived mediators and neutrophils. Endogenous nitric oxide and supplementation with l-arginine has a protective role, reducing the lesions and preventing mortality. These results contributed to elucidate mechanisms involved in intestinal lesions which could be of relevance to human small bowel injury associated to allergy.

Characterization of differentiated Syrian golden hamster pancreatic duct cells maintained in extended monolayer culture.

Epithelial cells isolated from fragments of hamster pancreas interlobular ducts were freed of fibroblast contamination by plating them on air-dried collagen, maintaining them in serum-free Dulbecco's modified Eagle's (DME):F12 medium supplemented with growth factors, and selecting fibroblast-free aggregates of duct cells with cloning cylinders. Duct epithelial cells plated on rat type I collagen gel and maintained in DME:F12 supplemented with Nu Serum IV, bovine pituitary extract, epidermal growth factor, 3,3',5-triiodothyronine, dexamethasone, and insulin, transferrin, selenium, and linoleic acid conjugated to bovine serum albumin (ITS+), showed optimal growth as monolayers with a doubling time of about 20 h and were propagated for as long as 26 wk. Early passage cells consisted of cuboidal cells with microvilli on their apical surface, complex basolateral membranes, numerous elongated mitochondria, and both free and membrane-bound ribosomes. Cells grown as monolayers for 3 mo. were more flattened and contained fewer apical microvilli, mitochondria, and profiles of rough surfaced endoplasmic reticulum; in addition, there were numerous autophagic vacuoles. Functional characteristics of differentiated pancreatic duct cells which were maintained during extended monolayer culture included intracellular levels of carbonic anhydrase and their capacity to generate cyclic AMP (cAMP) after stimulation by 1 X 10(-6) M secretin. From 5 to 7 wk in culture, levels of carbonic anhydrase remained stable but after 25 to 26 wk decreased by 1.9-fold. At 5 to 7 wk of culture, cyclic AMP increased 8.7-fold over basal levels after secretin stimulation. Although pancreatic duct cells cultured for 25 to 26 wk showed lower basal levels of cAMP, they were still capable of generating significant levels of cAMP after exposure to secretin with a 7.0-fold increase, indicating that secretin receptors and the adenyl cyclase system were both present and functional. These experiments document that pancreatic duct monolayer cultures can be maintained in a differentiated state for up to 6 mo. and suggest that this culture system may be useful for in vitro physiologic and pathologic studies.

Role of neurotensin in pancreatic secretion.

The objective of this study was to examine the effect of neurotensin (NT) on pancreatic exocrine secretion in awake dogs (n = 5) with chronic gastric and pancreatic fistulas. Intravenous (IV) infusion of NT (1 microgram/kg/hr) alone significantly stimulated pancreatic secretion of protein and bicarbonate without causing release of secretin or cholecystokinin-33 (CCK-33). IV NT potentiated the secretory response of pancreatic bicarbonate to the intraduodenal (ID) infusion of HCl alone and to ID infusions of the amino acids, phenylalanine and tryptophan (AA) alone, as well as to an ID mixture of AA plus HCl. IV NT acted in an additive manner with ID AA, ID HCl, or ID AA plus HCl in the stimulation of pancreatic protein output. The addition of IV NT to each luminal secretagogue (ID AA, ID HCl, or ID AA plus HCl) failed to elevate plasma concentrations of CCK-33 or secretin over those observed during ID infusion of each secretagogue alone. ID corn oil (Lipomul) stimulated the simultaneous release of CCK-33, NT, and secretin significantly; IV infusion of NT (0.5 microgram/kg/hr) resulted in plasma NT levels that were similar to levels observed after ID Lipomul. These studies provide evidence that endogenous NT, CCK, and secretin may interact in the physiologic regulation of pancreatic exocrine secretion.

Presence and possible site of action of secretin in the rat pituitary and hypothalamus.

Secretin-like immunoreactivity was detected in extracts of several rat brain structures by radioimmunoassay, most notably in the pituitary, hypothalamus, pineal and septum. Its localization to these structures suggested that it might play a role in neuroendocrine events similar to its structural homolog vasoactive intestinal peptide. Dose-related stimulations (MED, 10(-7) M) of prolactin (PRL) release were observed after incubation of synthetic secretin with dispersed, cultured pituitary cells from male and ovariectomized (OVX) female rats. In OVX females, i.v. infusion of a high dose of secretin (10 micrograms) resulted in a significant elevation of PRL levels. Doses of secretin as low as 0.1 micrograms when administered into the third cerebroventricle were capable of significantly inhibiting PRL release in both males and OVX females, suggesting an ultrashort-loop, negative feedback of secretin. Secretin can now be added to the growing list of putative PRL-releasing agents.

Neurohormonal control of pancreatic secretion. A review.

This is a review of current information concerning the role of hormones and the autonomic nervous system in the control of exocrine secretions of the pancreas. A greater emphasis has been placed on the role of hormones because of information accumulated during the last several years. With the development of radioimmunoassay techniques, it is now possible to correlate circulating hormone concentrations with biological function. The role of hormones has been discussed with the framework of the secretin-glucagon family, the cholecystokinin-gastrin family, and other proposed gastrointestinal hormones and related peptides. Gastrin, secretin and cholecystokinin-pancreozymin are three prime gut hormones that regulate pancreatic secretion. Other hormones that may have a role in pancreatic secretion include glucagon, vasoactive intestinal polypeptide, chymodenin, somatostatin, pancreatic polypeptide, motilin, and bombesin. Neural mechanisms play an important although not so succinct a role in the over-all control of exocrine secretion. A complex relationship exists between the parasympathetic nervous system and the release of the hormones and their effect on pancreatic acinar and duct cells.