Effects of the type of dietary fat on acetylcholine-evoked amylase secretion and calcium mobilization in isolated rat pancreatic acinar cells

Olive oil is a major component of the Mediterranean diet, and its role in human health is being actively debated. This study aimed to clarify the mechanism of pancreatic adaptation to dietary fat. For this purpose, we examined whether dietary-induced modification of pancreatic membranes affects acinar cell function in response to the secretagogue acetylcholine (ACh). Weaning male Wistar rats were assigned to one of two experimental groups and fed for 8 weeks with a commercial chow (C) or a semisynthetic diet containing virgin olive oil as dietary fat (OO). The fatty acid composition of pancreatic plasma membranes was determined by gas-liquid chromatography. For assessment of secretory function, viable acini were incubated with ACh and amylase of supernatant was further assayed with a substrate reagent. Changes in cytosolic Ca(2+) concentration in response to ACh were measured by fura-2 AM fluorimetry. Compared to C rats, pancreatic cell membranes of OO rats had a higher level of monounsaturated fatty acids and a lower level of both saturated and polyunsaturated fatty acids, thus, reflecting the type of dietary fat given. Net amylase secretion in response to ACh was greatly enhanced after OO feeding, although this was not paralleled by enhancement of ACh-evoked Ca(2+) peak increases. In conclusion, chronic intake of diets that differ in the fat type influences not only the fatty acid composition of rat pancreatic membranes but also the responsiveness of acinar cells to ACh. This mechanism may be, at least in part, responsible for the adaptation of the exocrine pancreas to the type of fat available.     

Palmitate induced lipoapoptosis of exocrine pancreas AR42J cells

Chronic surplus of dietary consumption, typical to obesity, results in overflow of fat to non-adipose tissues. Intracellular accumulation of fat in non-adipose tissues is associated with cellular dysfunction and cell death and ultimately contributes to the pathogenesis of chronic diseases. The influence of fat overflow on the exocrine pancreas is not known. The purpose of this research was to study the lipotoxic and lipoapoptotic effect of prolonged (72 h) long chain saturated palmitic fatty acid (0.1 mM) on the survival of exocrine pancreas AR42J cells. We demonstrate that chronic exposure of AR42J cells to palmitic acid results in significant increase in triglycerides accumulation (up to 25% of cells area), compared to untreated cultures. Lipid accumulation prompted a typical apoptotic process, demonstrated by both DNA fragmentation and condensed chromatin appearance (DAPI staining). Quantitative real-time PCR studies demonstrated that prolonged palmitic acid supplementation induced down-regulation of the anti-apoptotic Bcl2 mRNA levels (22%) and up-regulation of the pro-apoptotic Bax mRNA levels (300%), leading to disruption of the pro/anti apoptotic balance (Bax/Bcl2=3). No major change was detected in iNOS mRNA expression. In conclusion, prolonged exposure to saturated palmitic acid induces lipoapoptosis in exocrine pancreatic AR42J cells, through disturbance of the Bax/Bcl-2 balance.     

Response of rat exocrine pancreas to high-fat and high-carbohydrate diets

Intake of diets with high fat content is a risk factor for acute pancreatitis and pancreatic cancer. The underlying mechanisms leading to the development of these diseases due to high fat intake are currently unknown. The current study was designed in rats to determine the physiologic and pathological consequences of a highfat diet that contained excess amounts of cottonseed oil or a high-carbohydrate diet that contained high amounts of sucrose on the exocrine pancreas. Rats were maintained on the diets for 4 weeks, and a cannula was inserted into the right jugular vein and one into the pancreatic duct for collection of pancreatic juice. Volume of the pancreatic juice and concentrations of amylase, lipase, and trypsinogen in the pancreatic juice were measured before and after infusions of CCK-8. Results showed that basal and CCK-stimulated pancreatic outputs of volume, amylase and lipase but not trypsinogen, were significantly elevated in intact rats given a high-fat diet when compared with rats given a high-carbohydrate diet. Forty-eight hours later, rats were sacrificed, and parts of the pancreas were removed for isolation of pancreatic acinar cells and for histopathologic studies. Pancreatic acini isolated from rats on a high-fat diet showed significantly lower basal and CCK-stimulated amylase release when compared with those on a high-carbohydrate diet. Histology of the pancreas of rats on a high-carbohydrate diet appeared normal; however, the pancreas of rats on high-fat diet showed significant alterations in exocrine pancreas. These results showed abnormalities in the exocrine pancreas of rats on a high-fat diet, that were not found in rats on a high-carbohydrate diet; further, they support the contention that a high-fat diet has a deleterious effect on the pancreas.     

Generalized and selective feedback inhibition of secretion of pancreatic enzymes

Selective inhibition of secretion of proteinases, amylase and lipase by the pancreas, was revealed. The inhibition is directly dependent on the dose of intraluminal enzymes. The latter's increase transforms the selective inhibition into a generalised one. Possible mechanisms of selective and generalised feedback inhibition of the exocrine pancreatic secretion is discussed, the secretion playing an important role in urgent adaptation of the pancreatic enzymes secretion to the duodenal chyme properties.     

Genetic inducible fate mapping in larval zebrafish reveals origins of adult insulin-producing β-cells

The Notch-signaling pathway is known to be fundamental in controlling pancreas differentiation. We now report on using Cre-based fate mapping to indelibly label pancreatic Notch-responsive cells (PNCs) at larval stages and follow their fate in the adult pancreas. We show that the PNCs represent a population of progenitors that can differentiate to multiple lineages, including adult ductal cells, centroacinar cells (CACs) and endocrine cells. These endocrine cells include the insulin-producing β-cells. CACs are a functional component of the exocrine pancreas; however, our fate-mapping results indicate that CACs are more closely related to endocrine cells by lineage as they share a common progenitor. The majority of the exocrine pancreas consists of the secretory acinar cells; however, we only detect a very limited contribution of PNCs to acinar cells. To explain this observation we re-examined early events in pancreas formation. The pancreatic anlage that gives rise to the exocrine pancreas is located in the ventral gut endoderm (called the ventral bud). Ptf1a is a gene required for exocrine pancreas development and is first expressed as the ventral bud forms. We used transgenic marker lines to observe both the domain of cells expressing ptf1a and cells responding to Notch signaling. We do not detect any overlap in expression and demonstrate that the ventral bud consists of two cell populations: a ptf1-expressing domain and a Notch-responsive progenitor core. As pancreas organogenesis continues, the ventral bud derived PNCs align along the duct, remain multipotent and later in development differentiate to form secondary islets, ducts and CACs.     

Comparative studies of the action of long duration alcohol drinking on rat pancreatic exocrine cells

The influence of a long term ingestion of ethanol on the rat exocrine pancreas has been studied by electron microscopy. The comparison of micrographs from alcoholic and non alcoholic pancreas allowed us to compare the different organelles of acinar pancreatic cells. These data have been submitted to factorial analysis of correspondences. The ultrastructural modifications revealed out by this analysis are in good agreement with the hypothesis of an adaptation of exocrine cells to a chronic hyperfunctional state.     

Exocrine function of the pancreas in regularly swimming rats

The exocrine function of the pancreas was investigated in the course of adaptation to regular physical activity. In albino rats exercized by swimming for six weeks it has been observed that - in response to an identical physiological stimulation (liquid food via gastric tube) and under ad libitum feeding the rate of secretion and enzyme activity exceeded control values by 100 to 150%; - in pair-fed rats the values of the exercized animals were 50 to 70% higher, and - vagotomy suspended this effect even when food was offered ad libitum. On the basis of these results adaptation to regular exercise involves the exocrine function of the pancreas. In this functional increase both the increased food intake after training sessions and the direct effect of muscular work have a share. For adaptation an intact innervation is necessary.     

The role of the pancreas in the regulation of zinc status

A low Zn diet resulted in subacute Zn deficiency in young rats. Thirty minutes after the intubation of a trace 65-Zn we determined the total tissue Zn activity in plasma, erythrocytes, liver, pancreas, bone, muscle, and proximal jejunum. Assuming the body behaved like a closed multicompartmental system in steady state, we estimated the initial Zn exchange between plasma, and the erythrocytes or these tissues. In comparison with control animals the exchanges between plasma and erythrocytes or pancreas increased threefold during subacufe Zn deficiency. In the pancreas the ratio also reversed from <1.0 to>1.0. This confirmed earlier, observations that the specific activity (kBq 65-Zn/mol Zn) increased mostly in the pancreas. By increased net Zn uptake during subacute deficiency, the pancreas Zn content remained constant in chronic Zn deficiency. We discussed the regulation of the Zn status by the pancreas. We hypothesize that the exocrine pancreas modulates Zn absorption by an exocrine ligand that enhances absorption in the jejunum during subacute deficiency: Unsaturated with Zn it binds dietary intraluminal Zn and increases the Zn absorption. The literature provides evidence in confirmation. This hypothesis explains also conflicting data on the inherited Zn malabsorption syndrome Acrodermatitis Enteropathica.     

Pancreatic organogenesis--developmental mechanisms and implications for therapy

The pancreas is a mixed exocrine and endocrine gland that controls many homeostatic functions. The exocrine pancreas produces and secretes digestive enzymes, whereas the endocrine compartment consists of four distinct hormone-producing cell types. Studies that further our knowledge of the basic mechanisms that underlie the formation of the pancreas will be crucial for understanding the development and homeostasis of this organ and of the mechanisms that cause diabetes. This information is also pivotal for any attempt to generate functional insulin-producing beta-cells that are suitable for transplantation.     

Fat absorption in cystic fibrosis mice is impeded by defective lipolysis and post-lipolytic events

Cystic fibrosis (CF) is frequently associated with progressive loss of exocrine pancreas function, leading to incomplete digestion and absorption of dietary fat. Supplementing patients with pancreatic lipase reduces fat excretion, but it does not completely correct fat malabsorption, indicating that additional pathological processes affect lipolysis and/or uptake of lipolytic products. To delineate the role of such (post) lipolytic processes in CF-related fat malabsorption, we assessed fat absorption, lipolysis, and fatty acid uptake in two murine CF models by measuring fecal fat excretion and uptake of oleate- and triolein-derived lipid. Pancreatic and biliary function was investigated by determining lipase secretion and biliary bile salt (BS) secretion, respectively. A marked increase in fecal fat excretion was observed in cftr null mice but not in homozygous DeltaF508 mice. Fecal BS loss was enhanced in both CF models, but biliary BS secretion rates were similar. Uptake of free fatty acid was delayed in both CF models, but only in null mice was a specific reduction in lipolytic activity apparent, characterized by strongly reduced triglyceride absorption. Impaired lipolysis was not due to reduced pancreatic lipase secretion. Suppression of gastric acid secretion partially restored lipolytic activity and lipid uptake, indicating that incomplete neutralization of gastric acid impedes fat absorption. We conclude that fat malabsorption in cftr null mice is caused by impairment of lipolysis, which may result from aberrant duodenal pH regulation.     

Changes in the content of nucleic acids and total protein in exocrine pancreatocytes and the composition of their population in experimental acute pancreatitis in rats]

Using cytophotometry, contents of DNA, RNA and total protein were measured in the rat's exocrine pancreatocytes (EP) in normal conditions and at different stages of pancreatitis induced by cooling the spleen part of the pancreas with chlorethyl. In the duodenal (not damaged) part of the pancreas some drastic changes in the EP ploidy distribution were shown to occur. They led to the formation of a qualitatively new population pattern with 4c and 2c + 2c cells prevailing (more than 60% of the total content), which are by 1.5-3 times more active in RNA and protein synthesis and accumulation than the normal cells. The population structure rearrangement in the EP and their functional activity rise took place at two stages. At the first one the intracellular defense mechanisms of the EP in response to acute necrobiotic processes in the pancreas tissue were activated, at the second one the supracellular mechanisms regulating synthetic processes leading to a rapid adaptation of viable EP to new conditions were switched on.     

Analyses of pancreas development by generation of gfp transgenic zebrafish using an exocrine pancreas-specific elastaseA gene promoter

In contrast to what we know on development of endocrine pancreas, the formation of exocrine pancreas remains poorly understood. To create an animal model that allows observation of exocrine cell differentiation, proliferation, and morphogenesis in living animals, we used the zebrafish elastaseA (elaA) regulatory sequence to develop transgenic zebrafish that display highly specific exocrine pancreas expression of GFP in both larvae and adult. By following GFP expression, we found that the pancreas in early development was a relatively compact organ and later extended posterior along the intestine. By transferring the elaA:gfp transgene into slow muscle omitted mutant that is deficient in receiving Hedgehog signals, we further showed that Hedgehog signaling is required for exocrine morphogenesis but not for cell differentiation. We also applied the morpholino knockdown and toxin-mediated cell ablation approaches to this transgenic line. We showed that the development of exocrine pancreas is Islet-1 dependent. Injection of the diphtheria toxin A (DTA) construct under the elastaseA promoter resulted in selective ablation of exocrine cells while the endocrine cells and other endodermal derivatives (liver and intestine) were not affected. Thus, our works demonstrated the new transgenic line provided a useful experimental tool in analyzing exocrine pancreas development.     

Effect of pectin on the function of the rat exocrine pancreas

The author studied the effect of three weeks' administration of a 5% pectin concentration in the standard (Larsen) diet on basal and cholecystokinin octapeptide-(CCK8-) stimulated pancreatic exosecretion in rats. Protein, amylase and trypsinogen output determined in pancreatic juice obtained under basal conditions and after CCK8 stimulation of the exocrine pancreas showed no statistically significant differences between rats fed on the standard and the pectin-enriched Larsen diet. Our observations and studies by other authors show that the direct effect of dietary fibre on the exocrine function of the pancreas is an open question as far as further research is concerned.     

Deconstructing Pancreas Developmental Biology

The relentless nature and increasing prevalence of human pancreatic diseases, in particular, diabetes mellitus and adenocarcinoma, has motivated further understanding of pancreas organogenesis. The pancreas is a multifunctional organ whose epithelial cells govern a diversity of physiologically vital endocrine and exocrine functions. The mechanisms governing the birth, differentiation, morphogenesis, growth, maturation, and maintenance of the endocrine and exocrine components in the pancreas have been discovered recently with increasing tempo. This includes recent studies unveiling mechanisms permitting unexpected flexibility in the developmental potential of immature and mature pancreatic cell subsets, including the ability to interconvert fates. In this article, we describe how classical cell biology, genetic analysis, lineage tracing, and embryological investigations are being complemented by powerful modern methods including epigenetic analysis, time-lapse imaging, and flow cytometry-based cell purification to dissect fundamental processes of pancreas development.     

Protective effect of long term high fiber diet consumption on rat exocrine pancreatic function after chronic ethanol intake

The effects of ethanol administration on exocrine pancreas have been widely studied, but little is known about the effect of dietary fiber in combination with chronic ethanol on exocrine pancreatic function. The aim of this work was to examine the chronic effects of a high fiber diet, ethanol ingestion, and a combination of both on the function of the rat exocrine pancreas. Four groups of rats were fed for six months the following diets: 1.- NW: standard laboratory diet; 2.- FW: high fiber diet (15% cellulose); 3.- NE: standard laboratory diet and 20% ethanol in the drinking water; and 4.- FE: high fiber diet and 20% ethanol. Cholecystokinin (CCK) and acetylcholine (Ach) effects on amylase release and intracellular calcium mobilization in pancreatic acini were studied. In rats fed a 20% ethanol (NE), both the basal amylase release and the basal [Ca(2+)](i) were significantly increased; nonetheless, CCK and Ach-induced amylase release were significantly reduced compared with control rats. Ach- but not CCK-stimulated [Ca(2+)](i) increase in NE rats was significantly decreased compared with NW. In rats fed a combination of ethanol and a high fiber diet (FE) all the parameters under study were not significantly affected compared to control rats (NW). In conclusion, high fiber consumption does not alter the function of the exocrine pancreas. However, it ameliorates the deleterious effect of chronic ethanol consumption on pancreatic amylase secretion and, at least partially, reverses the ethanol-induced alterations on [Ca(2+)](i) in the rat exocrine pancreas.     

Early indicators of exocrine pancreas carcinogenesis produced by non-genotoxic agents

In the past 40 years the incidence of pancreatic cancer in many Western countries had increased. Since no single factor responsible for the development of pancreatic cancer has been identified, it is believed that non-genotoxic factors may play an important role in the pathogenesis of this highly fatal form of cancer. Focal abnormalities of acinar cells, referred to as atypical acinar cell foci or nodules, occur spontaneously in rats and some other species. Their incidence increases with age from zero at birth to about 75% in 2-year-old rats. These spontaneous lesions have a phenotype that cannot be distinguished from the putative, atypical preneoplastic, acinar cell foci induced in rat pancreas by the carcinogen azaserine. Unsaturated fat (corn oil) has been found to increase the incidence of atypical acinar cell nodules and adenomas in the pancreas of non-carcinogen-treated rats without influencing the weight of the pancreas. Furthermore, unsaturated fat has a specific promoting effect on the growth potential of atypical acinar cell foci and nodules induced in rat pancreas by azaserine, resulting in an increase in the number and size of these lesions. Rats fed raw soya flour or trypsin inhibitors develop an enlarged pancreas as a result of hypertrophy and hyperplasia. They also develop acidophilic atypical acinar cell foci and nodules, adenomas and adenocarcinomas after being fed full-fat raw soya flour for 2 years. It may be concluded from the observations in rat pancreas that non-genotoxic compounds or conditions that enhance pancreatic growth may be classified as non-genotoxic pancreatic tumour promoters. The observations with corn oil, however, indicate that there may be non-genotoxic compounds that specifically enhance growth of spontaneous initiated atypical acinar cell foci without causing hyperplasia of the pancreas. The possible mechanisms whereby unsaturated fat and trypsin inhibitors exert their effects on exocrine pancreatic carcinogenesis are discussed.     

Minireview possible roles of dietary fats in carcinogenesis

Epidemiological data have implicated dietary fat as an important factor in the aetiology of various cancers in humans. This suggestion is supported by the results of experiments with animals which have shown that increased amounts of dietary fat, in particular polyunsaturated fat, increase the incidence of some spontaneous and induced tumours. The enhancement of carcinogenesis by dietary fats appears to be exerted at the promotional stage of carcinogenesis. Changes induced by dietary fats in several biological systems involved in carcinogenesis may well indicate the underlying mechanisms responsible for the results of these experiments. These include the effects of dietary fats on the metabolism of chemical carcinogens, the structure and function of membranes, immunocompetence, DNA repair potential and endocrine function.     

Spontaneous formation of intercellular bile canaliculi and hybrid biliary-pancreatic canaliculi in co-culture of hepatocytes and exocrine pancreas cells from carp

When cultured together in a primary serum-free hormone-free system, hepatocytes and exocrine pancreas cells from the carp, Cyprinus carpio, spontaneously establish unique morphological structures that do not occur in vivo. These structures include intercellular bile canaliculi between neighbouring hepatocytes and hybrid canaliculi between hepatocytes and pancreas cells. In vivo, carp hepatocytes form only unicellular bile canaliculi; hybrid canaliculi between hepatocytes and exocrine pancreas cells do not exist at all in nature. This study shows that, in an artificial environment, cells are able spontaneously to establish novel morphological structures that are absent in the animal from which the cells have been obtained. Received: 3 January 1996 / Accepted: 17 March 1997     

Innervation of the pancreas by vasoactive intestinal polypeptide (VIP) immunoreactive nerves

The vasoactive intestinal polypeptide (VIP) has been shown to exert effects on endocrine and exocrine pancreatic secretion. Immunocytochemistry reveals that VIP immunoreactive nerves occur in the porcine, canine, feline and avian pancreas. In the pancreas of pig and cat VIP nerves are abundant around non-immunoreactive nerve cell bodies of the intrapancreatic ganglia but scarce in the islets and in the exocrine parenchyma. In the dog pancreas, however, the intrapancreatic ganglia contain strongly immunoreactive VIP nerve cell bodies which give off axons that seem to heavily innervate vessels as well as endocrine and exocrine cells. We suggest that in the pig and cat the pancreatic VIP nerves mainly affect the activity of a second type of intrapancreatic neuron, whose transmitter is unknown, whereas in the dog pancreas VIP nerves directly contact their putative effector structures.