Sequence analysis and tissue expression pattern of Sparus aurata chymotrypsinogens and trypsinogen.

Two apparently full-length cDNA clones encoding chymotrypsinogens I and II (CHTRI, 1022 bp; CHTRII, 909 bp) and one cDNA clone encoding trypsinogen II (TRPII, 848 bp) were isolated from a cDNA library prepared from gilthead sea bream (Sparus aurata) liver. The deduced amino acid sequences of the isolated cDNAs contain highly conserved residues essential for serine protease catalytic activity and conformational maintenance. The deduced amino acid sequences of CHTRI and CHTRII are 261 aa and 277 aa long, respectively, and share only 61% identity. Sea bream CHTRII appears to be the longest of all known teleostean chymotrypsinogen forms and contains a high number of methionine residues. Compared with CHTRI, CHTRII is more hydrophobic and has a lower isoelectric point. On the other hand, deduced amino acid sequence of TRPII is 241 aa long and has a signal peptide of thirteen amino acid residues and an activation peptide of seven amino acids long. In contrast to CHTRI and CHTRII, TRPII has a low isoelectric point (4.95), which makes it anionic at neutral pH. Northern blot analysis revealed that liver is the major transcription site for all zymogens. As expected, all zymogen transcripts were detected in parts of the digestive tract (stomach, pyloric caeca, anterior and posterior intestine) and pyloric caeca presented the most intense expression. In all tissues and amongst all zymogens, TRPII constitutive expression was the highest.

Dietary amino acids promote pancreatic protease synthesis at the translation stage in rats.

In some tissues, amino acids (AA) stimulate translation initiation via interactions between eukaryote initiation factor (eIF) 4E-binding protein 1 (4E-BP1), eIF4E and eIF4G. Dietary AA have been shown to induce pancreatic proteases independently of cholecystokinin in rats, the mechanism of which has not yet been clarified. In the present study, we examined the mechanism in rats for protease induction by dietary AA and determined the involvement of translation initiation. Male Wistar/ST rats were fed a 20 or 60% casein or AA mixture diet for 7 d and were intravenously injected with [35S] methionine (Met) 30 min before killing on d 7 (expt. 1). In expt. 2, rats were fed a 20 or 60% AA diet for 7 d and after food deprivation and refeeding with the respective diet on d 7 were killed at 0, 1 or 3 h. We measured mRNA and [35S] Met incorporation into chymotrypsinogen, phosphorylation status of 4E-BP1 and the association of eIF4E with 4E-BP1 or eIF4G. In expt. 1, chymotrypsin activity and synthesis were higher in both of the 60% diet groups than in the 20% diet groups, but the mRNA level and 4E-BP1 status did not differ. In expt. 2, chymotrypsin activity increased in the 60% AA diet group in a time-dependent manner. The translation initiation activity via the mTOR pathway indicated an increase similar to chymotrypsin activity. There were no differences in chymotrypsin mRNA level at any point. These results indicate that dietary AA induce chymotrypsin synthesis by promoting translation, and transient activation of translation initiation via mTOR may be associated with this induction.

Lithostathine messenger RNA expression in different types of chronic pancreatitis.

Lithostathine may play a physiological role in preventing the precipitation of excess calcium in the pancreatic juice. The hypothesis has been advanced that in chronic calcifying pancreatitis the abnormal biosynthesis of lithostathine might be the original defect to which genetic proneness to the disease may be ascribed. The aim of the present work was to study lithostathine messenger RNA expression in the pancreas of patients with different types of pancreatitis. Lithostathine and chymotrypsinogen mRNA were determined in surgical specimens obtained from the pancreases of the following subjects: (a) 13 patients with chronic alcoholic pancreatitis (84.6% calcified); (b) 4 patients with chronic hereditary pancreatitis (all calcified); (c) 6 patients with chronic obstructive pancreatitis (4 calcified); and (d) 27 subjects suffering from pancreatic cancer. Significantly lower concentrations of both mRNAs were found in the pancreases of chronic pancreatitis patients than in non-cancerous tissue from pancreatic cancer subjects. However, about 70% of the pancreatic cancer subjects showed lithostathine and chymotrypsinogen mRNA levels comparable to those of chronic pancreatitis patients. These results indicate that the decrease in the level of mRNA is not specific to lithostathine and it is unrelated to the presence of pancreatic stones.

Expression of rat chymotrypsinogen in yeast: a study on the structural and functional significance of the chymotrypsinogen propeptide.

The role of the propeptide sequence and a disulfide bridge between sites 1 and 122 in chymotrypsin has been examined by comparing enzyme activities of wild-type and mutant enzymes. The kinetic constants of mutants devoid of the Cys1-Cys122 disulfide-linked propeptide show that this linkage is not important either for activity or substrate specificity. However this linkage appears to be the major factor in keeping the zymogen stable against non-specific activation. A comparison of zymogen stabilities showed that the trypsinogen propeptide is ten times more effective than the chymotrypsinogen propeptide in preventing non-specific zymogen activation during heterologous expression and secretion from yeast. This feature can also be transferred in trans to chymotrypsinogen; i.e. the chymotrypsin trypsin propeptide chimera forms a stable zymogen.

Caerulein and gastrin(2-17 ds) regulate differently synthesis of secretory enzymes, mRNA levels and cell proliferation in pancreatic acinar cells (AR4-2J).

In order to characterize the biological functions coupled to cholecystokinin (CCK) A and B receptors, the effects of gastrin(2-17 ds) and caerulein were compared. An isolated cell model, the pancreatic acinar cell line AR4-2J, was used and the experiments were carried out in serum-free media. Caerulein was found to evoke no mitogenic effects either alone or in the presence of the CCK antagonists L364,718 and CR1409. Gastrin(2-17 ds) increased cell proliferation by 2-fold with an IC50 of 150 pM, corresponding to the occupancy of the CCK B receptors. CR1409, at concentrations that fully occupied CCK B receptors, inhibited the gastrin(2-17 ds) effects. Caerulein enhanced chymotrypsinogen biosynthesis by 100% and the corresponding mRNA level by 75%; amylase biosynthesis and mRNA level were enhanced by 40% only. Half-maximal increases in chymotrypsin activity and mRNA level were recorded in response to caerulein at concentrations of 100 pM and 50 pM respectively. Gastrin(2-17 ds) at 100 nM enhanced chymotrypsinogen biosynthesis by 26% and its mRNA level by 35%; these responses were lower than those evoked by 0.1 nM caerulein. Furthermore, CR1409 completely inhibited caerulein- and gastrin(2-17 ds)-stimulated chymotrypsinogen synthesis, with similar IC50 (4 microM). These results suggest that both peptides induced the synthesis of the secretory enzyme after occupancy of CCK A receptors.

Regulation of amylase and chymotrypsinogen expression by dexamethasone and caerulein in serum-free-cultured pancreatic acinar AR4-2J cells. Influence of glucose.

The direct effects of dexamethasone and caerulein on two pancreatic enzymes, amylase and chymotrypsin, were determined in AR4-2J cells cultured under serum-free conditions at two glucose concentrations (1.0 and 4.5 g/l). In the absence of any hormone, the higher glucose concentration resulted in a 1.6-1.8-fold increase in the basal levels of amylase and chymotrypsinogen. Dexamethasone (50 nM) increased the biosynthesis and mRNA levels of both enzymes at both glucose concentrations. However, dexamethasone had a more pronounced effect on amylase biosynthesis (5-fold induction) than on chymotrypsinogen biosynthesis (1.8-fold induction). The parallel increases in mRNA and protein indicated the existence of pre-translational regulation. This is in contrast with what was observed in serum-containing media, where a translational regulation of amylase biosynthesis took place, probably under the control of both glucose and some serum factors. By contrast, caerulein (10 nM) exerted a more specific action on chymotrypsinogen. The increases in chymotrypsinogen mRNA were 2.2- and 2.1-fold, and increases in chymotrypsin activity were 1.6- and 2.9-fold at 1.0 and 4.5 g of glucose/litre respectively. Thus the regulation by caerulein occurred mainly through the enhancement of chymotrypsinogen transcription and/or mRNA stabilization.

Pancreatic gene expression is altered during acute experimental pancreatitis in the rat.

We investigated pancreatic gene expression in the rat in response to taurocholate-induced acute pancreatitis. Concentrations of transcripts encoding pancreatic protein showed noncoordinated alterations. Contents in amylase, trypsinogen I, chymotrypsinogen B, elastase 1, and procarboxypeptidase A mRNAs decreased by greater than 50% during the acute phase (days 0-2), whereas actin and lithostathine mRNAs increased 5 and 0.6 times, respectively, and pancreatitis-associated protein (PAP) mRNA increased greater than 200 times, indicating redirection of the pattern of gene expression. Synthesis of pancreatic proteins was also altered in a noncoordinated manner. During the acute phase, it decreased more for trypsinogen I and chymotrypsinogen B than for amylase and lipase, whereas synthesis of the PAP increased dramatically. For amylase and chymotrypsinogen B, we compared the patterns of changes in mRNA concentrations, rates of synthesis, and pancreatic contents. Changes in enzyme contents and synthetic rates were temporally correlated during the acute phase. On the contrary, changes in mRNA concentrations and enzyme synthesis were not coordinated, suggesting that control of synthesis partly occurred at the posttranscriptional level. It was concluded that induction of pancreatitis is accompanied by transcriptional and posttranscriptional modifications resulting in rapid and massive rearrangement of the pattern of pancreatic protein gene expression.

Time course of changes in rat pancreatic synthesis rates and retention thresholds of four hydrolases during consumption of a low-protein followed by a balanced diet.

Synthesis rates of pancreatic amylase, trypsinogen 2 (Tg2), chymotrypsinogen 1 (Chtg1), and lipase, were measured in control rats fed a 20% protein diet for 46 days and in malnourished rats fed a 5% protein diet for 23 days (protein malnutrition) followed by refeeding a balanced diet for 23 days. In the control group, a progressive pancreatic maturation (namely an increase in hydrolase synthesis per gram of tissue) appeared with age. In the malnourished group, pancreas maturation of the four hydrolases was inhibited. Synthesis rates of the four hydrolases were reduced to a lesser extent from day 2 of protein malnutrition. With continued protein malnutrition, Tg2 synthesis rates remained steady, whereas the lipase synthesis rate continued to decrease and Chtg1 and amylase rates started to increase. As soon as refeeding was initiated, an important enhancement in synthesis was observed. The synthesis rates of Tg2, Chtg1, and amylase actually showed a rebound effect, then decreased with the refeeding time to reach control values, except for Chtg1, which remained higher than control values throughout the refeeding phase. Lipase synthesis rate rose more slowly and reached the control values only after 9 days of refeeding. The retention threshold (pancreas tissue versus pancreatic secretion) values showed that the storage levels were different from one hydrolase to the other and were variable with age in the control group, and with protein malnutrition and refeeding times in the malnourished group. In the control group, a preferential secretion of newly synthesized enzymes was observed in young rats, whereas with age, the proportion of newly synthesized hydrolases excreted decreased slowly.(ABSTRACT TRUNCATED AT 250 WORDS)

Stimulation of pancreatic secretory process in the rat by low-molecular weight proteinase inhibitor. II. Regulation of total protein and individual enzyme biosynthesis.

Oral application of a single dose of a new synthetic proteinase inhibitor Camostate (Foy-305) in male Wistar rats was carried out together with studies of in vitro amino acid incorporation followed by separation of proteins by two-dimensional gel electrophoresis. The aim of this experiment was to analyze changes produced by the inhibitor in total protein and individual enzyme biosynthesis. Administration of 100 mg/kg Foy-305 resulted in significant inhibition of total pancreatic protein synthesis, without changes in fractional rates for individual enzymes. 50 mg/kg Foy-305 induced a 10-fold elevation of cholecystokinin (CCK) levels in serum; this persisted for 3 h and led to a significant increase in the total rate of protein synthesis with peak values at 6 and 9 h (78% and 84% above control levels, respectively), returning to control by 15 h. Changes in fractional rates of synthesis occurred with a latency of 6 h and were restricted to amylase and the anionic form of trypsinogen and chymotrypsinogen. Amylase biosynthesis decreased by about 40% from control levels at 9 h to return to control levels by 15 h. Increased synthesis of trypsinogen and chymotrypsinogen was observed; this was also phasic. The results show similar enzyme-specific regulation as previously described for exogenous CCK stimulation and for the adaptation of the pancreas to diets enriched in protein. They demonstrate the effectiveness of pulsatory endogenous hormone release in the regulation of protein synthesis.

Phasic release of newly synthesized secretory proteins in the unstimulated rat exocrine pancreas.

Pancreatic lobules from fasted rats secrete pulse-labeled proteins in two phases comprising 15 and 85% of basal output, respectively. The first (0-6.5 h) is initially (less than or equal to 0.5 h) unstimulated by secretagogues, probably represents vesicular traffic of Golgi and post-Golgi origin (including condensing vaculoles/immature granules), and notably contains two groups of polypeptides with distinct release rates: zymogens (t1/2 approximately 2.4 h) and minor nonzymogens plus one unique zymogen (t1/2 approximately 1 h). The second phase (peak at 9-10 h) is stimulable, probably represents basal granule exocytosis (t1/2 approximately 5 h), and contains zymogens exclusively. Newly synthesized proteins released in both phases appear asynchronously, reiterating their asynchronous transport through intracellular compartments. Zymogens in both phases are secreted apically. The sorting of first from second phase zymogen release does not appear to be carrier-mediated, although the sorting of zymogens from other secretory proteins may use this process. Finally, data are presented that suggest that both secretory phases are subject to physiologic regulation.

Amylase and chymotrypsinogen synthesis and secretion by the anesthetized rat pancreas.

To investigate the origin of nonparallel secretion, pancreatic juice was collected in the anesthetized rat, during infusion of [3H]phenylalanine. In the basal state, the amylase to chymotrypsinogen ratios of activities and of [3H] incorporations were 3.5 and 2.5 times higher than in the homogenate, respectively. Both ratios decreased to the value in the homogenate upon caerulein stimulation (600 ng/kg). Inhibition of protein synthesis by cycloheximide (15 ng/kg) did not alter enzyme secretion ratios, and depressed basal protein output only partly, suggesting similar secretory pathways for basal and stimulated secretion. Finally, when [3H]phenylalanine was given before anesthesia, the amylase to chymotrypsinogen ratio of incorporations was again higher in basal secretion than in homogenate, even when further protein synthesis was blocked by cycloheximide before urethane injection. Hence, basal secretion comes from a pancreatic compartment which is functional, although minor, in the conscious animal, and shows a higher rate of amylase synthesis, compared to chymotrypsinogen, than the rest of the gland. It could consist of a subpopulation of acinar cells.

Translational control of protein synthesis in isolated pancreatic acini: role of CCK8, carbachol, and insulin.

We wished to determine whether the stimulation of protein synthesis by CCK8, carbachol, and insulin in isolated rat pancreatic acini resulted from translational or transcriptional induction of protein synthesis, and whether these hormones had similar or different effects on the rates of synthesis of individual enzymes. Isolated pancreatic acini were prepared from streptozocin-treated rats by collagenase digestion, mechanical dissociation, and centrifugation through a bovine serum albumin (BSA) cushion. Sixty-minute incubations, with maximally effective doses of CCK8, carbachol, and insulin, produced a 50, 90, and 100% increase, respectively, in the rate of protein synthesis. After inhibition of transcription with actinomycin D, the hormones still produced a 23, 50, and 61% increase, respectively, in the rate of protein synthesis. The study of the effect of the three hormones and the combination of CCK8 and insulin on the rate of synthesis of trypsinogen, chymotrypsinogen, lipase, and amylase, purified by isoelectric focusing, demonstrated that the hormones induced similar effects on the pattern of enzyme synthesis, and that they all induced the rate of synthesis of chymotrypsinogen slightly more than that of the other enzymes studied. We conclude that the hormones studied exert similar posttranscriptional influences in the regulation of protein synthesis in the pancreatic acinar cell.

Effect of Pseudomonas aeruginosa exotoxin-A on the synthesis and secretion of proteins in isolated rat pancreatic acini.

Exposure of isolated rat dispersed pancreatic acini to increasing concentrations (10 to 1000 ng/ml) of purified exotoxin-A from Pseudomonas aeruginosa resulted in a progressive inhibition of 3H-leucine incorporation into "cellular" (those remaining in the cells) and "secretory" (those released into the medium) proteins. With each concentration of exotoxin-A, magnitude of reduction was found to be greater for the "secretory" proteins than that observed for the "cellular" proteins. Thus, in the presence of 250 ng/ml of exotoxin-A, a dose that produced maximal inhibition in protein synthesis, 3H-leucine incorporation into "cellular" and "secretory" proteins was found to be decreased by about 19 and 50%, respectively, when compared with the corresponding basal controls. Release of trypsinogen, chymotrypsinogen and amylase from the isolated pancreatic acini was also inhibited by high doses of exotoxin-A. However, whereas the exotoxin concentration of 1000 ng/ml, caused a near complete inhibition of chymotrypsinogen release, trypsinogen and amylase secretion were decreased by 40 and 50%, respectively. It is concluded that in isolated pancreatic acini, exotoxin-A inhibits the synthesis and secretion of proteins.

Hormonal stimulation in the exocrine pancreas results in coordinate and anticoordinate regulation of protein synthesis.

24-h intravenous caerulein infusion studies in the rat were combined with in vitro amino acid incorporation studies followed by high-resolution separation of proteins by two-dimensional isoelectric focusing and SDS gel electrophoresis to study the extent to which persistent changes in the biosynthesis of exocrine pancreatic proteins are regulated by cholecystokinin-like peptides. Beginning in the third hour of optimal hormone infusion at 0.25 microgram kg-1 h-1, changes were observed in the synthetic rates of 12 proteins, which progressed over the course of the 24-h study. Based on coordinate response patterns, exocrine proteins could be classified into four distinct groups. Group I (trypsinogen forms 1 and 2) showed progressive increases in synthetic rates reaching a combined 4.3-fold increase over control levels. Group II (amylase forms 1 and 2) showed progressive decreases in synthesis to levels 7.1- and 14.3-fold lower than control levels, respectively. Group III proteins (ribonuclease, chymotrypsinogen forms 1 and 2, procarboxypeptidase forms A and B, and proelastase 1) showed moderate increases in synthesis, 1.4-2.8-fold, and group IV proteins (trypsinogen 3, lipase, proelastase 2, and unidentified proteins 1-4) did not show changes in synthesis with hormone stimulation. Regulation of protein synthesis in response to caerulein infusion was specific for individual isoenzymic forms in the case of both trypsinogen and proelastase. The ratio of biosynthetic rates of trypsinogen forms 1 + 2 to amylase forms 1 + 2 increased from a control value of 0.56 to 24.4 after 24 h of hormonal stimulation (43.5-fold increase). Biosynthetic rates for an unidentified protein (P23) with an Mr = 23,000 and isoelectric point of 6.2 increased 14.2-fold, and the ratio of synthesis of P23 to amylase 2 increased 200-fold during caerulein infusion. During hormone stimulation the anticoordinate response in the synthesis of pancreatic glycosidases (decreased synthesis) and serine protease zymogens (increased synthesis) explain previous observations that showed little change in rates of total protein synthesis under similar conditions.

Effect of feeding diets of different composition on the protein synthetic pattern of the rat pancreas.

Rats were fed a protein-rich or carbohydrate-rich diet for 3 weeks. By means of a double-label technique, we compared the protein-synthesizing patterns under these conditions. After 3 weeks of feeding, the relative rates of all the identified secretory enzymes and of some unidentified components had changed. The synthetic rates of the proteolytic proenzymes and of ribonuclease were increased after feeding a protein-rich diet, whereas those of the amylases and of lipase were lowered. The protein synthetic patterns of the rat pancreas under two extreme feeding conditions were compared to that of the pancreas of rats constantly fed a balanced diet of an intermediate composition. The results indicated that changes in relative rate of synthesis are mainly provoked by the protein-rich diet. Only the synthetic rate of the anodic chymotrypsinogen was strongly influenced by the carbohydrate-rich diet.

Dietary regulation of pancreatic protein synthesis. I. Rapid and specific modulation of enzyme synthesis by changes in dietary composition.

Dietary adaptation of pancreatic protein synthesis and of pancreatic enzyme concentration, was studied over the first 24 h of exposure to a new diet. Rats were adapted to a carbohydrate-rich (G) or to a protein-rich diet (P) and were switched to the opposite regime after a 15 h fast. The evolution of the relative rate of synthesis of amylase, chymotrypsinogen and trypsinogen and of the pancreatic concentration of amylase and chymotrypsinogen were followed. Fasting caused important modifications in the relative rate of synthesis of the three enzymes in rats adapted to a P diet. Adaptative changes in the relative rate of synthesis of amylase, chymotrypsinogen and trypsinogen were seen within 2 h after the beginning of refeeding. These changes were followed by corresponding adaptative modifications in pancreatic contents 4 h after the beginning of refeeding. After 24 h of refeeding, significant adaptative changes had occurred in both the relative rates of synthesis and in enzyme concentrations. Thus exocrine pancreatic protein synthesis can be modulated as early as 2 h after refeeding and this modulation is followed by adaptative changes in pancreatic enzyme content.

Dietary regulation of pancreatic protein synthesis. II. Kinetics of adaptation of protein synthesis and its effect on enzyme content.

The kinetics of the adaptative changes in the relative rates of synthesis and pancreatic concentrations of amylase, chymotrypsinogen and trypsinogen were studied over 10 days of adaptation to a carbohydrate-rich (G), or a protein-rich (P) diet. During adaptation to the P diet, 60% of the adaptative decrease of the amylase to chymotrypsinogen ratio of incorporation was complete within 24 h of feeding and plateau values were obtained after five days. Adaptation to the G diet was only 20% complete after 24 h and plateau values were obtained later than with the P diet. The evolution of the ratio of concentrations of amylase and chymotrypsinogen followed those of incorporation in the adaptation to both diets. These results support the determinant role of adaptative changes in the rates of synthesis of individual enzymes on the dietary adaptation of enzyme proportions in the pancreas. The differences in the kinetics of adaptation to the two diets suggest that different mechanisms are involved in the adaptative regulation of protein synthesis to a carbohydrate-rich diet or a protein-rich diet.

Effect of diet composition on the protein synthetic pattern of the rat pancreas after a feeding period of five days.

Rats were fed for five days on a protein-rich and on a carbohydrate-rich diet, respectively. One half of the pancreas of these rats was incubated with [3H]leucine and the other half with [14C]leucine and extracts from these pancreas halves were prepared. Mixtures of the differently labeled extracts were subjected to electrophoresis towards the anode as well as towards the cathode on a polyacrylamide gel containing urea at pH 8.5. Several secretory enzymes could be identified on the gels. Along the gels the 3H : 14C ratio was determined in 1 mm slices. The results show that after five days of feeding a diet there is some adaptation to diet composition. Generally rather small changes in synthetic rate occur. Only one component, the cathodic chymotrypsinogen shows an important difference in synthetic rate under the two circumstances.

Changes in rat pancreatic protein synthesis after a single feeding with diets containing raw or heated soybeans.

The patterns of protein synthesis following the administration of a single meal containing defatted ground soybeans (RSD) or heated defatted ground soybeans (HSD) were compared. A double label method was used so that the determination of the relative rate of synthesis of an enzyme could not be obscured by a possible alteration of the activity or quantity of the enzyme. Rats were given one meal of RSD or HSD and were subsequently killed at different times after the meal. Eight hours after the meal, the relative rate of synthesis of one of the three trypsinogens was substantially increased with RSD feeding, whereas that of the amylases and one chymotrypsinogen were somewhat lower. The synthetic rate of lipase, ribonclease, proelastase, another chymotrypsinogen and of two trypsinogens was unaffected when feeding RSD is compared to feeding HSD. The relative rate of synthesis of one of the trypsinogens was unaffected 8 hours after RSD feeding, but was increased 16 hours after RSD feeding. Actinomycin D could suppress the effects of RSD feeding on the protein synthetic rate of some, but not of all, secretory proteins.