Acute pancreatitis is an inflammatory disease of the pancreas, which varies greatly in course and severity. Severe forms are associated with serious local and/or systemic complications, and eventually death. The pathobiology of acute pancreatitis is complex. Animal models have been developed to investigate pathobiological processes and identify factors determining disease course. We performed a time-course proteomic analysis using a rat model of severe necrotizing acute pancreatitis induced by taurocholate perfusion in the pancreatic ducts. Results showed that levels of proteins associated to a given biological process changed in a coordinated fashion after disease onset. It was possible to follow the response of a particular pathobiological process to pancreatitis induction and to compare the course of protein pathways. Proteins involved in acinar cell secretion were found to follow a different kinetics than other cellular processes. After an initial decrease, secretory pathway-associated proteins raised again at 18 h post-induction. This phenomenon coincided with a burst in the expression of pancreatitis-associated protein (REG3A), an acute phase protein produced by the exocrine pancreas, and with the decrease of classical markers of pancreatic injury, suggesting that the expression of proteins associated to the secretory pathway may be a modulating factor of pancreas injury.

Acute pancreatitis (AP) is a complex inflammatory disease, the pathobiology of which is not yet fully understood. Various animal models, relying on different mechanisms of disease induction, have been developed in order to investigate pathobiological processes of AP. In this study, we performed a time-course proteomic analysis to investigate changes of the pancreas proteome occurring in an experimental model of AP induced by perfusion of taurocholate, a bile acid, into the pancreatic duct. This experimental model is characterized by a severe disease with pancreatic necrosis and systemic inflammation. The objectives of this study were to determine the kinetics of functionally related proteins in the early steps of the experimental disease in order to identify protein pathways playing key roles in AP pathobiology and to correlate these data with parameters classically used to assess disease severity. The present work provides for the first time an overview of protein expression in the pancreas during the course of taurocholate-induced necrotizing AP. We believe that correlation of these results with data obtained using proteomic or biochemical approaches in various experimental models of AP will help in highlighting new features, generating hypotheses and constitute therefore a strong and reliable basis for further targeted investigations.

Acute pancreatitis is an autodigestive disease, in which the pancreatic tissue is damaged by the digestive enzymes produced by the acinar cells. Among the tissues in the mammalian body, pancreas has the highest concentration of the natural polyamine, spermidine. We have found that pancreas is very sensitive to acute decreases in the concentrations of the higher polyamines, spermidine and spermine. Activation of polyamine catabolism in transgenic rats overexpressing SSAT (spermidine/spermine-N(1)-acetyltransferase) in the pancreas leads to rapid depletion of these polyamines and to acute necrotizing pancreatitis. Replacement of the natural polyamines with methylated polyamine analogues before the induction of acute pancreatitis prevents the development of the disease. As premature trypsinogen activation is a common, early event leading to tissue injury in acute pancreatitis in human and in experimental animal models, we studied its role in polyamine catabolism-induced pancreatitis. Cathepsin B, a lysosomal hydrolase mediating trypsinogen activation, was activated just 2 h after induction of SSAT. Pre-treatment of the rats with bismethylspermine prevented pancreatic cathepsin B activation. Analysis of tissue ultrastructure by transmission electron microscopy revealed early dilatation of rough endoplasmic reticulum, probable disturbance of zymogen packaging, appearance of autophagosomes and later disruption of intracellular membranes and organelles. Based on these results, we suggest that rapid eradication of polyamines from cellular structures leads to premature zymogen activation and autodigestion of acinar cells.

To investigate the changes of chaperonin60 (Cpn60) and pancreatic enzymes in pancreatic acinar cells, and to explore their roles in the development of experimental diabetes and acute pancreatitis (AP).

Two different pathological models were replicated in Sprague-Dawley rats: streptozotocin-induced diabetes and sodium deoxycholate-induced AP. The contents of Cpn60 and pancreatic enzymes in different compartments of the acinar cells were measured by quantitative immunocytochemistry.

The levels of Cpn60 significantly increased in diabetes, but decreased in AP, especially in the zymogen granules of the pancreatic acinar cells. The elevation of Cpn60 was accompanied with the increased levels of pancreatic lipase and chymotrypsinogen in diabetes. However, a decreased Cpn60 level was accompanied by high levels of lipase and chymotrypsinogen in AP. The amylase level was markedly reduced in both the pathological conditions.

The equilibrium between Cpn60 and pancreatic enzymes in the acinar cells breaks in AP, and Cpn60 content decreases, suggesting an insufficient chaperone capacity. This may promote the aggregation and autoactivation of the premature enzymes in the pancreatic acinar cells and play roles in the development of AP.

To analyze the capability of N-acetylcysteine (NAC) to prevent major intra-acinar pathogenic mechanisms involved in the development of acute pancreatitis (AP).

AP was induced by pancreatic duct obstruction (PDO) in rats. Some animals received NAC (50 mg/kg) 1 h before and 1 h after PDO. During a 24-hour period of PDO, plasma amylase activity and pancreatic glutathione and malondialdehyde levels were measured. Cytosolic Ca(2+) levels and enzyme (amylase and trypsinogen) load in acinar cells were also analyzed by flow cytometry, and histological analysis of the pancreas was performed by electron microscopy.

NAC avoided glutathione depletion at early AP stages, thereby preventing pancreatic oxidative damage, as reflected by normal malondialdehyde levels. By limiting oxidative stress, NAC treatment effectively prevented the impairment of Ca(2+) homeostasis found in acinar cells from early AP onwards, thus protecting the pancreas from damage. In addition, lower quantities of digestive enzymes were accumulated within acinar cells. This finding, together with the significantly lower hyperamylasemia observed in these animals, suggests that NAC treatment palliates the exocytosis blockade induced by PDO.

By preventing oxidative stress at early AP stages, NAC administration prevents other pathological mechanisms of AP from being developed inside acinar cells, thus palliating the severity of disease.

Although oxygen free radicals (OFR) are considered to be one of the pathophysiological mechanisms involved in acute pancreatitis (AP), the contribution of acinar cells to their production is not well established. The aim of the present study was to determine the effect of N-acetylcysteine (NAC) in the course of AP induced by pancreatic duct obstruction (PDO) in rats, directly analysing by flow cytometry the quantity of OFR generated in acinar cells. NAC (50 mg/kg) was administered 1 h before and 1 h after PDO. Measurements by flow cytometry of OFR generated in acinar cells were taken at different PDO times over 24 h, using dihydrorhodamine-123 as fluorescent dye. Histological studies of pancreas and measurements of neutrophil infiltration in the pancreas, pancreatic glutathione (GSH), malondialdehyde (MDA) levels, plasma amylase activity and hemoconcentration were carried out in order to assess the severity of AP at different stages. NAC effectively blunted GSH depletion at early AP stages and prevented OFR generation found in acinar cells as a consequence of AP induced by PDO. This attenuation of the redox state impairment reduced cellular oxidative damage, as reflected by less severe pancreatic lesions, normal pancreatic MDA levels, as well as diminished neutrophil infiltration in pancreas. Hyperamylasemia and hemoconcentration following AP induction were ameliorated by NAC administration at early stages, when oxidative stress seems to be critical in the development of pancreatitis. In conclusion, NAC reinforces the antioxidant defences in acinar cells, preventing OFR generation therefore attenuating oxidative damage and subsequently reducing the severity of PDO-induced AP at early stages of the disease.

This study determines the effect of 7-day pretreatment with L364,718 (a potent cholecystokinin (CCK) receptor antagonist) on pancreatic cell turnover during the course of acute pancreatitis (AP) induced in the rat by bile-pancreatic duct obstruction (BPDO). Cell cycle distribution and apoptosis were analyzed by flow cytometry using propidium iodide (PI) and Annexin V staining. Besides altering the pancreatic redox status, long-term CCK blockade inhibited the normal proliferation of acinar cells as indicated by the significant increase in G(0)/G(1)-phase cells and the decrease in G(2)/M-cells found in control rats treated with L364,718 for 7 days. A progressive depletion in pancreatic GSH was found from 3 to 24h after BPDO with similar values in L364,718-pretreated and non-treated rats, which led to a maximum peak in malondialdehyde (MDA) levels 6h after BPDO. However, plasma amylase activity and ascites volume indicated higher severity of AP in L364,718-pretreated rats. CCK blockade enhanced the alterations that appear in cell cycle distribution of acinar cells during AP demonstrated by the significantly higher increase in G(0)/G(1)-cells and decrease in S-cells found in L364,718-treated rats 48h after BPDO. Our results indicate that the renewal of acinar cells deleted by apoptosis 48h after BPDO worsens if CCK is blocked before inducing AP.

Biologic data related to pancreatic regeneration and acinar-cell homeostasis after ductal decompression would be useful in clinical settings to elucidate the time at which obstructions in human biliary acute pancreatitis (AP) should be removed. Our aim was to evaluate the outcome of AP after early removal of bile-pancreatic-duct obstruction (BPDO) and to ascertain whether cholecystokinin (CCK) blockade accelerates recovery from the disease. We conducted analysis of apoptosis and cell cycle, as well as measurements of enzyme and calcium load, in acinar cells using flow cytometry to ascertain the capability of the pancreas to regain its function after AP. Male Wistar rats were subjected to AP by means of BPDO for 6 hours and 24 hours. In other groups, the BPDO was opened 24 hours after induction; 3 days and 7 days later they were killed. Half of the rats in which the BPDO was opened were administered L364,718, a CCK-receptor antagonist (0.1 mg/kg/12 hours), 30 minutes before the induction of BPDO. Plasma amylase activity, hematocrit, and pancreatic weight returned to control values after BPDO opening. The highest degree of oxidative stress was found in the pancreases of rats subjected to BPDO for 6 hours, as indicated by the decrease in pancreatic glutathione content, but it was not restored 7 days after BPDO opening. Cell-cycle distribution, as measured with propidium iodide DNA staining, showed increases in the proportion of acinar cells in S-phase from 3 days after BPDO opening in L364,718-treated and nontreated rats. Annexin V-fluorescein isothiocyanate labeling revealed deletion of acinar cells by way of apoptosis 3 days after BPDO opening. However, it may be compensated 7 days after BPDO opening because regardless of whether rats were treated with L364,718, significant increases in synthesis and mitosis were detected. Accumulation of digestive enzymes and calcium in acinar cells was found during BPDO, but this appeared to have normalized 3 days after BPDO opening and onward in both L364,718-treated and nontreated rats. In conclusion, early removal of obstruction allowed rapid cell proliferation and prevented the progression of severe alterations within acinar cells induced by BPDO. CCK blockade does not accelerate pancreatic recovery after BPDO opening.

Little information is available regarding the role of circulating leukocytes in the pathogenesis of acute pancreatitis (AP). Our aim was to explore the time-course of the potential role of inflammatory peripheral blood (PB) cells during AP induced in rats by pancreatic duct obstruction (PDO). Flow cytometry immunophenotyping was used to analyse the distribution of the major circulating leukocyte subsets, the activation state of circulating monocytes as reflected by both CD11b expression and TNF-alpha production and the relative contribution of T-cell derived pro- (TNF-alpha) and anti- (IL-10) inflammatory mediators at different stages of PDO-induced AP. A progressive increase in PB neutrophils and monocytes was observed up to 6h after PDO whereas lymphocytes, as well as CD4(+) and CD8(+) T-cell subsets, rose as early as 1.5 h after PDO and decreased thereafter. Monocytes were activated in PB from 6 h after inducing AP as reflected by increases in both CD11b expression and spontaneous TNF-alpha production; nevertheless, they showed the capability of producing TNF-alpha at earlier AP stages by lipopolysaccharide (LPS) stimulation. In contrast, T-cells were unable to produce TNF-alpha during AP neither spontaneously nor after stimulation with PMA/Ionomycin. Therefore, only PB monocytes contribute to increase TNF-alpha levels in plasma as observed from 12 h onwards after inducing AP. Interleukin-10 was produced by T-cells 6 h after PDO only after PMA/Ionomycin stimulation. We conclude that systemic inflammatory events are triggered off at early stages of PDO-induced AP, with the activation of circulating monocytes, though not T-cells, playing a central role.

The time-course of oxygen free radicals (OFR) generation within acinar cells was studied at different stages of acute pancreatitis (AP) induced in rats by duct obstruction (PDO) for 48 h by flow cytometry, using dihydrorhodamine-123 (DHR) as fluorescent dye. Parallel measurements of the most common markers of oxidative stress such as glutathione (GSH) depletion and malondialdehyde (MDA) levels in pancreas were also performed. OFR production significantly increased within acinar cells at early stages of AP, concomitant with a marked depletion in pancreatic GSH. Lipid peroxidation was significantly enhanced 6 h after PDO, suggesting that the antioxidant defence system of the cell is overwhelmed by OFR production. Both MDA and OFR production in acinar cells decreased to normal values at late AP stages, thus allowing the recovery of pancreatic GSH levels 48 h after PDO. Among the two types of acinar cells differentiated by flow cytometry, R1 and R2, it was the R2 population that showed higher values of DHR dye. However, no differences between the two cell types were found regarding the amount of OFR generation. Our results demonstrate that individual acinar cells significantly contribute to produce large amounts of OFR at early stages of AP. The two existing populations of acinar cells displayed similar behaviour regarding oxidative stress over the course of the disease.