Comparison of growth and development of the exocrine pancreas in pigs and rats during the immediate postnatal period

This study compared pancreatic tissue growth and functional changes during the first 3 postnatal days in piglets and rat pups. In piglets the absolute weight and the relative weight per unit body weight of the pancreas increased by 97 and 70%, respectively, while in rat pups the same parameters decreased by 33 and 48%, respectively, during this period. The specific activity of pancreatic amylase rose by 336% while that of trypsin, chymotrypsin and lipase remained at newborn level in piglets. In rat pups the specific activities of all enzymes measured declined by 61 to 92% during the first 3 postnatal days. The rate of postnatal pancreatic growth in the two species coincide with the levels of epidermal growth factor and insulin-like growth factors in maternal milk as reported in the literature, suggesting that milk-borne growth factors may stimulate pancreatic development in newborn animals.     

Variations in enzyme activity in stomach and pancreatic tissue and digesta in piglets around weaning

A study was performed to investigate the effect of weaning at 4 weeks of age on the activity of digestive enzymes in the stomach and pancreatic tissue and in digesta from 3 days prior to weaning to 9 days postweaning in 64 piglets. In stomach tissue the activity of pepsin and gastric lipase was determined. Pepsin activity declined abruptly after weaning but 5 days postweaning the weaning level was regained and in the gastric contents no change in pepsin activity was observed. Weaning did not influence the activity of gastric lipase. The activity of eight enzymes and a cofactor was measured in pancreatic tissue. The effect of weaning on the enzyme activity was highly significant for all enzymes except elastase. The activity of all enzymes remained at the weaning level during day 1-2 postweaning followed by a reduction of the activity. The activity of trypsin, carboxypeptidase A, amylase and lipase exhibited minimum activity 5 days postweaning. Trypsin activity increased to the preweaning level on day 7-9 whereas the activity of the others increased but did not reach the preweaning level. The activity of chymotrypsin, carboxypeptidase B and carboxyl ester hydrolase decreased during the entire experimental period. In digesta no effect of weaning was observed on the activity of amylase and trypsin. The activity of chymotrypsin was reduced after weaning in the proximal third of the small intestine and lipase and carboxyl ester hydrolase activity was reduced in the middle and distal parts of the small intestine after weaning. The present study shows that the activities of the digestive enzymes in the pancreatic tissue are affected by weaning. Even though the pancreatic secretion cannot be judged from these results they show that the enzymes respond differently to weaning. In general the activity of the digestive enzymes in pancreatic tissue is low on day 5 postweaning which in interaction with other factors may increase the risk of developing postweaning diarrhoea.     

Variations in enzyme activity in stomach and pancreatic tissue and digesta in piglets around weaning

A study was performed to investigate the effect of weaning at 4 weeks of age on the activity of digestive enzymes in the stomach and pancreatic tissue and in digesta from 3 days prior to weaning to 9 days postweaning in 64 piglets. In stomach tissue the activity of pepsin and gastric lipase was determined. Pepsin activity declined abruptly after weaning but 5 days postweaning the weaning level was regained and in the gastric contents no change in pepsin activity was observed. Weaning did not influence the activity of gastric lipase. The activity of eight enzymes and a cofactor was measured in pancreatic tissue. The effect of weaning on the enzyme activity was highly significant for all enzymes except elastase. The activity of all enzymes remained at the weaning level during day 1–2 postweaning followed by a reduction of the activity. The activity of trypsin, carboxypeptidase A, amylase and lipase exhibited minimum activity 5 days postweaning. Trypsin activity increased to the preweaning level on day 7–9 whereas the activity of the others increased but did not reach the preweaning level. The activity of chymotrypsin, carboxypeptidase B and carboxyl ester hydrolase decreased during the entire experimental period. In digesta no effect of weaning was observed on the activity of amylase and trypsin. The activity of chymotrypsin was reduced after weaning in the proximal third of the small intestine and lipase and carboxyl ester hydrolase activity was reduced in the middle and distal parts of the small intestine after weaning. The present study shows that the activities of the digestive enzymes in the pancreatic tissue are affected by weaning. Even though the pancreatic secretion cannot be judged from these results they show that the enzymes respond differently to weaning. In general the activity of the digestive enzymes in pancreatic tissue is low on day 5 postweaning which in interaction with other factors may increase the risk of developing postweaning diarrhoea.     

Changes in digestive enzymes through developmental and molt stages in the spiny lobster, Panulirus argus

Changes in major digestive enzymes through developmental and molt stages were studied for the spiny lobster Panulirus argus. There were significant positive relationships between specific activity of trypsin and amylase enzymes and lobster size, whereas esterase and lipase specific activities decreased as lobsters aged. No relationship was found between amylase/trypsin ratio and lobster size. Positive trends were found, however, for trypsin/lipase and amylase/lipase ratios. Results suggest that changes in enzyme activity respond to the lobsters' physiological needs for particular dietary components although multivariate analysis suggested that enzyme activities could be not totally independent of diet. On the other hand, the pattern of changes of major enzyme activities through molt cycle was similar for most enzymes studied. Following molt, trypsin, chymotrypsin, amylase, and lipase activities gradually increased to maximal levels at late intermolt (C4) and premolt (D). There were no variations in the electrophoretic pattern of digestive enzymes through developmental and molt stages and thus, it is demonstrated that regulation is exerted quantitatively rather than qualitatively. Further studies on the effect of other intrinsic and extrinsic factors on digestive enzyme activities are needed to fully understand digestive abilities and regulation mechanisms in spiny lobsters.     

Changes in mRNA levels of rat pancreatic lipase in the early days of consumption of a high-lipid diet

The time-course response of rat pancreatic enzymes to a diet containing 25% sunflower oil was investigated. A 1.2-fold enhancement in lipase specific activity was observed as early as the first day of diet consumption and was further increased up to 1.9-fold on the 5th day. On the other hand, colipase activity was slightly decreased during the first two days of high-lipid diet intake and then increased. An immediate and direct effect was also exerted by the 25% lipid diet on lipase biosynthesis. Both fractional synthetic rate and specific activity of lipase were comparably induced. Due to a 1.6-fold increase in the overall protein synthesis following 5 days of lipid diet consumption, the absolute synthesis of lipase and amylase was increased by 3.5-fold and 0.98-fold, respectively, as compared to control animals. By contrast, the synthesis of procarboxypeptidases and serine proteases did not increase before day 5, probably as the result of a distinct adaptive mechanism. The pancreatic mRNA levels in control and adapted animals, which were determined by dot-blot hybridization with amylase and lipase cDNAs, were consistent with a biphasic induction of lipase synthesis since a first increase in the level of the enzyme-specific mRNA during the first two days of diet intake (4-fold on day 1) was followed by a second increase after the fourth day (6.5-fold on day 5). On the other hand, amylase mRNA level was unchanged during the dietary manipulation. Thus, hyperlipidic diets exerted an both lipase activity and synthesis but a delayed effect on procarboxypeptidase and serine protease synthesis. In a similar manner, the immediate induction of lipase mRNA level by dietary fat, followed by another increase a few days later, suggested that at least two different mechanisms are involved in lipase mRNA induction.     

Digestive tract development in rabbit according to the dietary energetic source: correlation between whole tract digestion,pancreatic and intestinal enzymatic activities

The developmental changes of both pancreatic and intestinal enzymes and the influence of dietary composition on enzyme activities were followed in suckling and weaning rabbits. In addition, whole tract digestibility of nutrients was recorded in response to two dietary energetic sources. Rabbits were fed ad libitum either a low fat and high starch diet (group LF), or a high fat and high fibre diet (group HF) between d 32 and d 42, with both groups receiving a growing finishing diet thereafter. Before weaning (d 32) nutrient digestion was high (>75% for organic matter, protein or fat), and then decreased sharply, except for fat. Between d 32 and d 42, digestion in the HF group was 7.5 and 4.6% lower, respectively, for organic matter and protein, while fibre and fat digestion was higher (+14.0 and +5.0%, respectively). Between d 25 and d 42 of age, pancreatic-specific activities of trypsin and chymotrypsin did not change while those of amylase and lipase increased by 1.5- and 76- fold (P<0.05), respectively. However, total activities and relative activities expressed on a LW basis were increased after weaning as a main consequence of a specific increased organ weight and pancreatic protein content. Relative activities of trypsin and chymotrypsin increased by 63 and 56% (P<0.01) after weaning, respectively. Total activities of pancreatic enzymes measured in the total small intestinal contents increased during the same period, but the range of variations was lower than those measured in the pancreatic gland. Total activities of lipase, trypsin and chymotrypsin measured in the small intestine contents were significantly correlated with pancreas enzyme potentialities. Total small intestine activity of lipase was 58% higher (P<0.001) in HF than in LF group while the other pancreatic and intestinal enzyme activities measured were not influenced by the energetic sources of the diet. Decreased digestibility of organic matter and protein observed with the HF diet could not be related to changes in pancreatic or intestinal enzymatic profiles and may be more dependent on quality of dietary ingredients.     

Pancreatic enzyme requirements for the dissociation of rat hearts for culture

Summary Nine crude commercially available samples of pancreatic enzyme preparations were examined in an effort to establish enzyme requirements for dissociation of rat heart to single cells for culture. Disc gel electrophoresis, using purified enzymes as references, indicated the presence of at least five enzymes. The levels of these enzymes, trypsin, chymotrypsin, elastase, lipase, and amylase were quantified in the commercial samples by established enzyme assays. The crude enzyme preparations were compared for their abilities to provide good yields of viable cells from the hearts of neonatal white rats. The abilities of the cells to thrive in culture and to beat rhythmically were also used in the comparison. Commercial purified samples of the five enzymes were used singly and in various combinations in preparing cultures to establish minimal pancreatic enzyme requirements for dissociation of rat hearts. It was concluded that at least trypsin, chymotrypsin, and elastase were required to obtain viable rat heart cells in high yield. Amylase and lipase activities were shown not to be necessary for dissociation. Most commercial samples of trypsin, commonly used to dissociate heart tissue, contain trypsin, chymotrypsin, and elastase in concentrations sufficient to release heart cells in good yield with minimal damage. The destruction of cells observed with some of the commercial samples examined was not due to improper levels of trypsin, chymotrypsin, or elastase. Work is in progress to identify the destructive agent(s). This work was supported in part by United States Public Health Service Grant HL10018 and The Pennsylvania State University Agricultural Experiment Station Grant 1858. Authorized for publication on December 28, 1973 as paper 4602 in the journal series of the Pennsylvania Agricultural Experiment Station.     

Neurotensin modulates the composition of pancreatic exocrine secretions in chickens

The effects of neurotensin on pancreatic exocrine secretion were examined in fasted, conscious White Leghorn hens. A cannula was surgically implanted in the central duct serving the ventral lobe of the pancreas in order to collect pure pancreatic juice. Following recovery, neurotensin was infused intravenously at 3.6 or 10.8 pmol/kg*min. The volume and pH of the pancreatic secretions were recorded and total pancreatic protein concentration, amylase, lipase, trypsin, and chymotrypsin activity were measured every 30 min for 2 hr and compared to secretions following the infusion of 0.9% saline. Our results demonstrated that neurotensin did not affect the pH nor the pancreatic juice protein concentration, but did increase secretion rate following neurotensin infusion at 3.6 pmol/kg*min. Amylase activity was significantly depressed during neurotensin infusions, while lipase (both pancreatic and carboxylester lipase) activity was significantly elevated. The ratio of amylase to lipase activity was especially depressed by neurotensin infusion at 10.8 pmol/kg*min. Insufficient secretory activity prevented a balanced statistical analysis of chymotrypsin activity, but from a pooled analysis, neurotensin had no effect on protease activity in the pancreatic juice. These results support our current research indicating that neurotensin may be a hormonal regulator of postprandial lipid digestion in chickens.     

Pancreatic chymotrypsin as the essential enzyme for excystation of Eimeria tenella.

Sporocysts from the protozoan parasite, Eimeria tenella, were isolated, preincubated with sodium taurocholate, and treated with various preparations of pancreatic enzymes. Crude trypsin, crude lipase, and purified alpha-chymotrypsin all could break the shells of sporocysts and release sporozoites. Purified trypsin was much less active than crude trypsin and purified lipase showed no activity at all. Specific inhibitors of chymotrypsin, tosyl-L-phenylalanyl chloromethane, diphenylcarbamyl chloride, and chymostatin inhibited the release of sporozoites by all the enzyme samples, whereas tosyl-L-lysyl chloromethane, a specific inhibitor of trypsin, exerted no inhibitory effect. It is thus postulated that chymotrypsin, not trypsin, is an essential enzyme involved in excystation of E. tenella. Purified chymotrypsin is recommended to replace crude trypsin in the vitro excystation of E. tenella as a likely improved procedure.     

Nutrient control of release of pancreatic enzymes in yellowtail (Seriola quinqueradiata): involvement of CCK and PY in the regulatory loop

Cholecystokinin (CCK) and neuropeptide Y (NPY)-related peptides are key regulators of pancreatic enzyme secretion in vertebrates. CCK stimulates enzyme secretion whereas peptide Y (PY), a NPY-related peptide, plays an antagonistic role to that of CCK. In fish, very little is known about how different nutrients affect the synthesis of CCK and PY in the digestive tract, and the mechanism by which CCK and PY actually regulate digestive enzyme secretion is not well understood. In order to determine how different nutrients stimulate the synthesis of CCK and PY in yellowtail (Seriola quinqueradiata), CCK and PY mRNA levels in the digestive tract were measured after oral administration of a single bolus of either phosphate-buffered saline (PBS: control), starch (carbohydrate), casein (protein), oleic acid (fatty acid) or tri-olein (triglyceride). In addition, in order to confirm the synthesis and secretion of digestive enzymes, the mRNA levels and enzymatic activities of three digestive enzymes (lipase, trypsin and amylase) were also analyzed. Casein, oleic acid and tri-olein increased the synthesis of lipase, trypsin and amylase, while starch and PBS did not affect the activity of any of these enzymes. CCK mRNA levels rose, while PY mRNA levels were reduced in fish administered casein, oleic acid and tri-olein. These results suggest that in yellowtail, CCK and PY maintain antagonistic control of pancreatic enzyme secretion after intake of protein and/or fat.     

Localization of pancreatic enzyme secretion-stimulating activity and trypsin inhibitory activity in zymogen granule of the rat pancreas

The intracellular localization of pancreatic enzyme secretion-stimulating activity in rat pancreas was investigated. We found and purified a pancreatic enzyme secretion-stimulating peptide from rat bile/pancreatic juice. The peptide is trypsin-sensitive (showing temporary trypsin inhibitory activity), and it is hypothesized that it acts as a trypsin-sensitive mediator in the feedback regulation of diet-induced pancreatic enzyme secretion. The zymogen granule fraction was purified 5-fold by ultracentrifugation by the Percoll density gradient method. The purity of the zymogen granule fraction was determined from the specific amylase activity and electron microscopic morphology. The specific enzyme activities of amylase and trypsin and the trypsin inhibitory activity increased in parallel during the purification, and the pancreatic enzyme secretion-stimulating activity was also localized in the zymogen granule fraction. These results suggest that the pancreatic enzyme secretion-stimulating peptide originates from the acinar cells, and that it is secreted through exocytosis of zymogen granules into the small intestine, its ratio to trypsin thus remaining constant. This idea supports our hypothesis that the stimulating peptide acts as a mediator for the feedback regulation of pancreatic enzyme secretion by trypsin.     

Non-parallel secretion of pancreatic enzymes in sheep following hormonal or vagal stimulation

• 1.1. The flow of pancreatic juice and its composition of protein, amylase, trypsin and chymotrypsin were measured in sheep during treatments known to induce a response in nonruminants.
• 2.2. Intraduodenal peptone (100 or 200 μg/min) had no affect but intraduodenal hydrochloric acid (66 μequiv/min) or intravenous (iv) pentagastrin (10 μg/min) doubled the flow and enzyme output. Cholecystokinin (1.0 IDU/min iv) caused smaller changes in enzyme output but no change in flow, whereas, secretin (0.5 or 1.0 CU/min iv) caused a rapid, sustained, five- or six-fold increased in flow but only a transitory increase in enzyme output.
• 3.3. The largest increases in enzyme output occurred during stimulation of the vagus (10 Hz, 10 V); the outputs were sustained at 5–10 times control levels and the flow increased two- or three-fold.
• 4.4. A non-parallel response of amylase, trypsin and chymotrypsin occurred during administration of those treatments which significantly enhanced the enzyme output. Compared with periods of basal secretion the stimulated juice contained significantly more chymotrypsin and amylase than trypsin; the relationship between chymotrypsin and amylase did not change significantly.
• 5.5. The composition of the juice during stimulation approached and often equalled the enzyme composition of pancreatic tissue.
• 6.6. These results are compatible with the view that the mixture of enzymes in pancreatic juice is derived from at least two compartments with different enzyme compositions.

     

Large doses of zinc oxide increases the activity of hydrolases in rats

The effect of pharmacological doses of zinc oxide (1000; 2500; 5000 mg per kg diet) and two levels of dietary protein on pancreatic and intestinal hydrolase activity in rats were studied. It was hypothesized that ZnO would increase intestinal and pancreatic hydrolase enzyme activity. Male Wistar rats, averaging 64 g body weight, were randomly allocated to dietary treatments (chow diets- meeting all NRC requirements) containing 10% or 15% protein supplemented with additional ZnO (above 100 mg/kg ZnSO(4)) as follows: 0.0; 0.1; 0.25; 0.5% w/w. Water and food were provided ad libitum. Animals were fed the diets for 10 days and body weights were recorded; after decapitation blood and organ samples were collected. Amylase, lipase, trypsin, and total protease activity of pancreatic homogenates and small intestinal contents were determined. ZnO supplementation dose dependently increased the plasma Zn concentration and significantly increased amylase, lipase, trypsin and total protease activity in pancreatic homogenates and small intestinal contents. The statistical analysis showed significant protein and ZnO interaction on the activity of amylase in the pancreas, and amylase, trypsin and total-protease in the small intestinal content. Therefore ZnO at high dietary concentration may influence the digestion of nutrients via increased hydrolase activity.     

Effect of duodenal trypsin on pancreatic secretion in men

The effect of tryptic activity in duodenum on L-phenylalanine (100 mmol.1-1 intraduodenally) stimulated pancreatic secretion in 18 healthy volunteers has been evaluated. Intraduodenal infusion of trypsin (150 mg) during 1 h caused the reduction of alpha-amylase and lipase output by ca 30%. The infusion of aprotinin at the dose of 0.5.10(6) KIU during 30 min caused return of the alpha-amylase and lipase output to the pretryptic values. The infusion of trypsin in higher dose (300 mg) caused more pronounced decrease of amylase and lipase output (ca 45%). Our data indicate that active trypsin in duodenum is responsible for the inhibition of L-phenylalanine stimulated pancreatic enzyme secretion in man. These results corroborate the existence of feedback regulation of stimulated pancreatic secretion by intraduodenal trypsin in man.     

Developmental changes in digestive physiology of nestling house sparrows, Passer domesticus

Six decades of studies have speculated that digestive capacity might limit avian growth rate or that developmental changes in the gut might determine developmental changes in digestive efficiency. However, there are no studies on digestive enzymes during avian development, except for studies on mainly domestic birds that exhibit the precocial mode of development. We studied alimentary organ masses, intestinal enzyme activities (sucrase, maltase, isomaltase, aminopeptidase-N), and pancreatic enzyme activities (amylase, trypsin, chymotrypsin) during development of a wild passerine bird exhibiting the altricial mode of development. Wild nestling house sparrows were studied immediately after removal from the nest (days 0, 3, 6 of age; day 0=hatch), whereas captives were raised in the laboratory beginning day 3 on a formulated casein/starch-based diet until fledging age (after day 12). Digestive biochemistry was dynamic. Tissue-specific activities of some digestive enzymes continued to increase through fledging, by >10 times in some cases (e.g., sucrase and maltase in midintestine). Total pancreatic amylase activity increased 100 times between hatch and day 12 through a combination of increases in tissue-specific activity and pancreas mass. House sparrows differ from poultry, in whom after about 2 wk of age the specific activity of intestinal and pancreatic digestive enzymes is generally constant or declines during development. The data on intestinal and pancreatic enzymes help explain why digestive efficiency of nestling house sparrows improves with age, and the data seem consistent with the idea that digestive capacity might limit feeding rate and hence growth rate.     

The flow and fate of digestive enzymes in the field cricket,Gryllus bimaculatus

The flow of enzymes, the ratio of bound to unbound enzymes, and their inactivation in the cricket Gryllus bimaculatus was studied. The digestive enzymes are forced forward into the crop by caecal contraction and then they are mixed with freshly chewed food and saliva, forming a crop‐chyme. This chyme is blended by crop peristalsis, and periodic opening of the preproventricular valve (PPV) allows posterior movement into the proventriculus and further into the midgut. The contraction of the crop is modulated by Grybi‐AST and Grybi‐SK peptides, which are partially secreted by the caecal endocrine cells. Most of the aminopeptidase and the four disaccharidases examined are membrane bound (62–80%); the remaining (20–38%) as well all trypsin, chymotrypsin, lipase, and amylase are secreted free into the caecal lumen. Cricket trypsin loses only 30% of its activity in 4 h and very little thereafter. The presence of digestive products in the lumen appears to retard further trypsin autolysis. Cricket trypsin digests 42% of the chymotrypsin, 37% of the lipase, and 45% of the amylase in the caecal fluids over 24 h in vitro no significant difference. Without Ca ion amylase was almost completely digested. About 50% of the membrane bound and free aminopeptidase was digested in the caecal lumen, and about 30–38% of the bound and free maltase. This loss of digestive enzyme activity is possible, because enzyme secretion rates are high, the unbound enzymes are effectively recycled, and the time of nutrient passage is short.