A potential endogenous ligand of annexin IV in the exocrine pancreas. Carbohydrate structure of GP-2, a glycosylphosphatidylinositol-anchored glycoprotein of zymogen granule membranes

We demonstrated previously that annexins IV, V, and VI, proteins of the calcium/phospholipid-binding annexin family, have glycosaminoglycan binding properties (Ishitsuka, R., Kojima, K., Utsumi, H., Ogawa, H., and Matsumoto, I. (1998) J. Biol. Chem. 273, 9935-9941). In this study, we investigated the endogenous ligands of annexin IV in the exocrine pancreas. Immunohistochemical study of bovine pancreas showed that annexin IV localized in the apical cytoplasmic region of pancreatic acinar cells where zymogen granules are concentrated. Because it is the major component of the zymogen granule membrane, the glycosylphosphatidylinositol-anchored glycoprotein GP-2 was suggested to play a role in apical sorting and secretion of zymogens. We isolated GP-2 from porcine pancreas extract and determined the structure of its N-linked oligosaccharides by two-dimensional mapping. The major carbohydrate structures of porcine GP-2 were trisialo-triantennary and tetrasialo-tetra-antennary complex-type oligosaccharides. Dot-blot assay showed that annexin IV interacts with GP-2 in the presence of calcium and that it recognizes the terminal sialic acid residues linked through alpha2-3 linkages to the carbohydrate of GP-2. Lectin blot assay showed that Maackia amurensis mitogen, a plant lectin specific for the trisaccharide sequence Sia(alpha)2-3Galbeta1-4GlcNAc of N-linked oligosaccharides, has strong affinity for GP-2. Thus, M. amurensis mitogen was used as a specific probe for GP-2 in the histochemical staining of the bovine pancreas. GP-2 was found to localize exclusively in the same apical cytoplasmic region of pancreatic acinar cells as annexin IV does. These results suggest that GP-2 is an endogenous ligand of annexin IV in the exocrine pancreas.     

Intracellular transport of the major glycoprotein of zymogen granule membranes in the rat pancreas. Demonstration of high turnover at the plasma membrane

The intracellular transport and destination of the major glycoprotein associated with zymogen granule membranes in the pancreas (GP-2) was established. In suspensions of isolated acinar cells from rat pancreas, pulse-chase experiments were performed. The incorporation of the first newly synthesized GP-2 molecules into zymogen granule membranes occurred at about 60 min after beginning of the pulse. We demonstrated by using two different methods that newly made GP-2 reaches the cell surface within the same time span. After 6-8 h chase considerable more newly synthesized GP-2 has reached the cell surface than would be expected on account of secreted newly synthesized zymogens. These observations strongly suggest that at least part of the GP-2 molecules bypass the mature zymogen granule compartment on their way to the plasma membrane. GP-2 is the only protein that appears in discernable quantity in the plasma membrane during 1-4 h after a pulse label. Nevertheless GP-2 comprises only a small percentage of externally 125I-iodinated plasma membrane proteins. We conclude that GP-2 has a high turnover rate at the plasma membrane level. Treatment of the acinar cells with the N-glycosylation inhibitor tunicamycin does not block the intracellular transport of GP-2.     

The regulation of exocytosis in the pancreatic acinar cell.

The pancreatic acinar cell synthesises a variety of digestive enzymes. In transit through the secretory pathway, these enzymes are separated from constitutively secreted proteins and packaged into zymogen granules, which are localised in the apical pole of the cell. Stimulation of the cell by secretagogues such as acetylcholine and cholecystokinin, acting at receptors on the basolateral plasma membrane, causes the generation of an intracellular Ca(2+) signal. This signal, in turn, triggers the fusion of the zymogen granules with the apical plasma membrane, leading to the polarised secretion of the enzymes. This review describes recent advances in our understanding of the control of secretion in the acinar cell. In particular, we discuss the mechanisms underlying the sorting of digestive enzymes into the zymogen granules, the molecular components of the exocytotic "membrane fusion machine," the generation and propagation of the Ca(2+ signal and the development of new techniques for the visualisation of single granule fusion events.     

Absence of the major zymogen granule membrane protein, GP2, does not affect pancreatic morphology or secretion

The majority of digestive enzymes in humans are produced in the pancreas where they are stored in zymogen granules before secretion into the intestine. GP2 is the major membrane protein present in zymogen granules of the exocrine pancreas. Numerous studies have shown that GP2 binds digestive enzymes such as amylase, thereby supporting a role in protein sorting to the zymogen granule. Other studies have suggested that GP2 is important in the formation of zymogen granules. A knock-out mouse was generated for GP2 to study the impact of the protein on pancreatic function. GP2-deficient mice displayed no gross signs of nutrient malab-sorption such as weight loss, growth retardation, or diarrhea. Zymogen granules in the GP2 knock-out mice appeared normal on electron microscopy and contained the normal complement of proteins excluding GP2. Primary cultures of pancreatic acini appropriately responded to secretagogue stimulation with the secretion of digestive enzymes. The course of experimentally induced pancreatitis was also examined in the knock-out mice because proteins known to associate with GP2 have been found to possess a protective role. When GP2 knock-out mice were subjected to two different models of pancreatitis, no major differences were detected. In conclusion, GP2 is not essential for pancreatic exocrine secretion or zymogen granule formation. It is unlikely that GP2 serves a major intracellular role within the pancreatic acinar cell and may be functionally active after it is secreted from the pancreas.     

Membrane detachment and release of the major membrane glycoprotein of secretory granules in rat pancreatic exocrine cells

The major glycoprotein of pancreatic zymogen granule membranes (GP-2) was detected in the medium of acinar cell suspensions from rat pancreas. Its release from the cells was studied in pulse-chase metabolic labeling experiments with radioactive methionine. GP-2 (apparent Mr = 80 000) was found to be processed to a form of slightly lower apparent Mr (75 000) after about 4 h chase. At about the same time this smaller form of GP-2 appeared in the medium. These results are in accordance with earlier findings in vivo. At different chase times acinar cells were extracted with Triton X-114 to separate water-soluble proteins from membrane-associated (hydrophobic) proteins. This experiment showed that GP-2 is slowly converted from a membrane-bound glycoprotein to a soluble glycoprotein after its reduction in apparent molecular mass, causing its detachment from the membrane. Further analysis indicated that the detachment process may occur at the zymogen granule membrane as well as the plasma membrane. Immunocytochemistry on ultrathin cryosections of pancreatic tissue showed that GP-2 is localized on zymogen granule membranes, plasma membranes and in the acinar lumen. Although in much smaller quantities, GP-2 is also present in the granule content. Thus, in summary, GP-2 is synthesized as a true membrane glycoprotein which is gradually processed to a soluble species and is found in the secretion.     

Chromogranin B (secretogranin I), a neuroendocrine-regulated secretory protein, is sorted to exocrine secretory granules in transgenic mice.

Chromogranin B (CgB, secretogranin I) is a secretory granule matrix protein expressed in a wide variety of endocrine cells and neurons. Here we generated transgenic mice expressing CgB under the control of the human cytomegalovirus promoter. Northern and immunoblot analyses, in situ hybridization and immunocytochemistry revealed that the exocrine pancreas was the tissue with the highest level of ectopic CgB expression. Upon subcellular fractionation of the exocrine pancreas, the distribution of CgB in the various fractions was indistinguishable from that of amylase, an endogenous constituent of zymogen granules. Immunogold electron microscopy of pancreatic acinar cells showed co-localization of CgB with zymogens in Golgi cisternae, condensing vacuoles/immature granules and mature zymogen granules; the ratio of immunoreactivity of CgB to zymogens being highest in condensing vacuoles/immature granules. CgB isolated from zymogen granules of the pancreas of the transgenic mice aggregated in a mildly acidic (pH 5.5) milieu in vitro, suggesting that low pH-induced aggregation contributed to the observed concentration of CgB in condensing vacuoles. Our results show that a neuroendocrine-regulated secretory protein can be sorted to exocrine secretory granules in vivo, and imply that a key feature of CgB sorting in the trans-Golgi network of neuroendocrine cells, i.e. its aggregation-mediated concentration in the course of immature secretory granule formation, also occurs in exocrine cells although secretory protein sorting in these cells is thought to occur largely in the course of secretory granule maturation.     

The pancreatic membrane protein GP-2 localizes specifically to secretory granules and is shed into the pancreatic juice as a protein aggregate

GP-2 is the major secretory granule membrane glycoprotein of the exocrine pancreas and appears in the pancreatic juice in a modified sedimentable form. We have localized GP-2 in the rat pancreas at the electron microscopic level using affinity-purified antibodies and found it to be concentrated in the zymogen granules and in the acinar lumen. Label was also present on the apical and basolateral plasma membranes but prior treatment of the sections with periodate to eliminate the contribution of highly antigenic oligosaccharide moieties reduced substantially the staining of the basolateral surface. Approximately 45% of the GP-2 in the granules was not membrane-associated but appeared instead in the granule lumen. Parallel biochemical characterization of GP-2 in isolated secretory granules demonstrated that 60% fractionated with the membranes after granule lysis while 40% remained in the content fraction. Unlike the membrane-associated form of the protein, which is linked to the membrane via glycosyl-phosphatidylinositol (GPI), GP-2 in the content did not enter the detergent phase upon Triton X-114 extraction; nor was it sedimentable at 200,000g, as is characteristic of the form collected in the pancreatic juice. In addition, GP-2 in the pancreatic juice was recovered in the aqueous phase during Triton X-114 extraction and yet remained sedimentable after detergent extraction, demonstrating that its ability to remain in large aggregates was independent of lipid. These results are consistent with a life cycle for the protein that begins with synthesis of a membrane-associated precursor that can be converted by lipolytic or proteolytic cleavage to a soluble form within the zymogen granule. Further modification to a sedimentable form may then occur in the pancreatic juice.     

Loss of the zymogen granule protein syncollin affects pancreatic protein synthesis and transport but not secretion

Syncollin is a small protein that is abundantly expressed in pancreatic acinar cells and that is tightly associated with the lumenal side of the zymogen granule membrane. To shed light on the hitherto unknown function of syncollin, we have generated syncollin-deficient mice. The mice are viable and show a normal pancreatic morphology as well as normal release kinetics in response to secretagogue stimulation. Although syncollin is highly enriched in zymogen granules, no change was found in the overall protein content and in the levels of chymotrypsin, trypsin, and amylase. However, syncollin-deficient mice reacted to caerulein hyperstimulation with a more severe pancreatitis. Furthermore, the rates of both protein synthesis and intracellular transport of secretory proteins were reduced. We conclude that syncollin plays a role in maturation and/or concentration of zymogens in zymogen granules.     

A secretion granule membrane protein (GRAMP 92) is found in non-granule membranes including those of the endocytic pathway.

GRAMP 92, a secretion granule-associated membrane protein, has been identified in exocrine and endocrine storage granule membranes using a monoclonal antibody against rat parotid secretion granule membranes. This integral membrane glycoprotein has a M(r) of 92,000 in pancreatic zymogen granule membranes, and is slightly smaller in endocrine granule membranes. In both cases, deglycosylation produces core proteins of M(r) 52,000, that have identical peptide fingerprints. Unlike the slightly smaller zymogen granule membrane glycoprotein GP-2, GRAMP 92 does not appear to be bound to the membrane by a glycophosphatidyl inositol anchor, is not found on the plasma membrane and is not released into the secretion. Within acinar cells, low levels of antigen are observed immunocytochemically over the membranes of most granules. Antigen is highly concentrated on small vesicles that are closely apposed to (and possibly interact with) granules. As well, antigen is localized to organelles in the Golgi and basolateral regions that are part of the endocytic pathway. In hepatocytes a glycoprotein similar if not identical to GRAMP 92 marks the endocytic pathway including lysosomes. These findings indicate that GRAMP 92 is a widely distributed endocytic component and suggest that cells specialized for regulated secretion may adapt such components for storage granule function. Granule-associated GRAMP 92-rich membranes may link the exocytotic and endocytic pathways.     

The major zymogen granule membrane protein GP-2 in the rat pancreas is not involved in granule formation.

The major membrane protein of zymogen granules in the rat pancreas is a glycoprotein of 78 kDa (GP-2), which is inserted into the membrane via a glycosyl-phosphatidylinositol (GPI) anchor. GP-2 occurs in both, a membrane-attached and a soluble form. Due to its specific luminal orientation and its quantitative contribution to the zymogen granule membrane, GP-2 has been postulated to play an important role in sorting of digestive enzymes into the granule and in the formation of the granule as a storage organelle. We have tested this hypothesis in the rat pancreas under three different functional conditions, where both the rates of enzyme/isoenzyme synthesis change drastically, and new zymogen granules form at a high rate: a) during prolonged hormonal stimulation of the adult rat pancreas, b) during the differentiation of AR4-2J cells induced by dexamethasone in vitro, and c) during embryonic development and early postnatal life, when gene expression is modulated due to the differentiation program. Both, GP-2 mRNA levels and the rate of GP-2 biosynthesis were quantitated and compared to the immunohistochemical localization of this protein in tissue sections. Under all three functional conditions, significant changes could be demonstrated at the level of digestive enzyme gene expression, but no concomitant modulation of GP-2 expression was observed. GP-2 mRNA is absent from the embryonic pancreas and for the first time is expressed after birth with a significant increase during the period of weaning. Furthermore, GP-2 mRNA and protein levels are not modulated by hormonal stimulation, either in the adult pancreas or in AR4-2J cells in culture. Therefore, we conclude that GP-2, in spite of its quantitative contribution to the zymogen granule membrane, is not involved in enzyme protein sorting or granule formation. Alternative functions for GP-2 are discussed.     

Use of colloidal gold particles in double-labeling immunoelectron microscopy of ultrathin frozen tissue sections

Complexes of protein-A with 5 and 16 nm colloidal gold particles (PA/Au5 and PA/Au16) are presented as sensitive and clean immunoprobes for ultrathin frozen sections of slightly fixed tissue. The probes are suitable for indirect labeling and offer the opportunity to mark multiple sites. The best procedure for double labeling was to use the smaller probe first, i.e., antibody 1 - PA/Au5 - antibody 2 - PA/Au16. When this was done, no significant interference between PA/Au5 and PA/Au16 occurred. Using this double-labeling procedure we made an accurate comparison between the subcellular distributions of amylase as a typical secretory protein and of GP-2 a glycoprotein, characteristic for zymogen granule membrane (ZGM) preparations. We prepared two rabbit antibodies against GP-2. One antibody (R x ZGM) was obtained by immunizing with native membrane material. The specificity of R x ZGM was achieved by adsorption with the zymogen granule content subfraction. The other, R x GP-2, was raised against the GP-2 band of the SDS polyacrylamide profile of ZGM. We found that the carbohydrate moiety of GP-2 was involved in the antigenic determinant for R x ZGM, while R x GP-2 was most likely directed against GP-2 polypeptide backbone. THe immunocytochemical observations showed that GP-2, on the one hand, exhibited the characteristics of a membrane protein by its occurrence in the cell membrane, the Golgi membranes, and its association with the membranes of the zymogen granules. On the other hand, GP-2 was present in the contents of the zymogen granules and in the acinar and ductal lumina. Also, a GP-2-like glycoprotein was found in the cannulated pancreatic secretion (Scheffer et al., 1980, Eur. J. Cell Biol. 23:122-128). Hence, GP-2 should be considered as a membrane-associated secretory protein of the rat pancreas.     

Exocrine granule specific packaging signals are present in the polypeptide moiety of the pancreatic granule membrane protein GP2 and in amylase: implications for protein targeting to secretory granules.

The mechanisms for segregation of secretory and membrane proteins incorporated into storage granules from those transported constitutively have been thought to be conserved in diverse cell types, including exocrine and endocrine cells. However, GP2, the major protein of pancreatic zymogen granule membranes, in its native glycosyl phosphatidylinositol (GPI)-linked form, is incorporated into secretory granules when expressed in exocrine pancreatic AR42J cells, but not in the endocrine cells such as pituitary AtT20. To determine whether the protein moiety of GP2 contains the cell-type specific information for packaging into granules, a secretory form of GP2 (GP2-GPI-), with the GPI attachment site deleted, was generated and introduced into AR42J and AtT20 cells. Like native GP2, GP2-GPI- localized to the zymogen-like granules of AR42J cells and underwent regulated secretion. In AtT20 cells expressing GP2-GPI-, however, the protein was secreted by the constitutive pathway. Thus, a granule packaging signal is present in the luminal portion of GP2 that is functional only in the exocrine cells. However, this cell-type dependent sorting process is not limited to GP2 or membrane proteins. Amylase, a major content protein of pancreatic acinar and serous salivary gland granules, was also secreted exclusively by the constitutive pathway when expressed in AtT20 cells. The cell-type specific targeting of GP2 to granules correlated with its behavior in an in vitro aggregation assay where it co-aggregated more effectively with content proteins from pancreatic zymogen granules than with those from pituitary granules.(ABSTRACT TRUNCATED AT 250 WORDS)     

Detection and characterization of microvesicles in the acinar lumen and in juice of unstimulated rat pancreas

Small vesicles were visualized in the lumen of rat pancreas acini by freeze-substitution and conventional electron microscopy. Microvesicles were subsequently isolated from pancreatic juice. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed that these vesicles contain only one major protein. The major protein was identified by an immunoblot technique as GP-2, an 80 kD glycoprotein also found in the zymogen granule membrane. The immunocytochemical localization of rabbit anti-GP-2 and anti-amylase by the protein A-gold technique confirmed that GP-2 was associated with clusters of microvesicles, whereas amylase was virtually excluded. Freeze-fracture of the microvesicles revealed that their membrane was devoid of intramembrane particles. Biochemical analysis indicated also that the membrane did not contain any detectable cholesterol. These results demonstrate that GP-2 is released from the acinar cell in the gland lumen within microvesicles by a hitherto undescribed mode of secretion.     

Modulating zymogen granule formation in pancreatic AR42J cells

Zymogen granules (ZG) are specialized organelles in the exocrine pancreas which allow digestive enzyme storage and regulated secretion. To investigate ZG biogenesis, cargo sorting and packaging, suitable cellular model systems are required. Here, we demonstrate that granule formation in pancreatic AR42J cells, an acinar model system, can be modulated by altering the growth conditions in cell culture. We find that cultivation of AR42J cells in Panserin^? 401, a serum-free medium, enhances the induction of granule formation in the presence or absence of dexamethasone when compared to standard conditions including serum. Biochemical and morphological studies revealed an increase in ZG markers on the mRNA and protein level, as well as in granule size compared to standard conditions. Our data indicate that this effect is related to pronounced differentiation of AR42J cells. To address if enhanced expression of ZG proteins promotes granule formation, we expressed several zymogens and ZG membrane proteins in unstimulated AR42J cells and in constitutively secreting COS-7 cells. Neither single expression nor co-expression was sufficient to initiate granule formation in AR42J cells or the formation of granule-like structures in COS-7 cells as described for neuroendocrine cargo proteins. The importance of our findings for granule formation in exocrine cells is discussed.     

Redistribution of a rab3-like GTP-binding protein from secretory granules to the Golgi complex in pancreatic acinar cells during regulated exocytosis

Regulated secretion from pancreatic acinar cells occurs by exocytosis of zymogen granules (ZG) at the apical plasmalemma. ZGs originate from the TGN and undergo prolonged maturation and condensation. After exocytosis, the zymogen granule membrane (ZGM) is retrieved from the plasma membrane and ultimately reaches the TGN. In this study, we analyzed the fate of a low M(r) GTP-binding protein during induced exocytosis and membrane retrieval using immunoblots as well as light and electron microscopic immunocytochemistry. This 27-kD protein, identified by a monoclonal antibody that recognizes rab3A and B, may be a novel rab3 isoform. In resting acinar cells, the rab3-like protein was detected primarily on the cytoplasmic face of ZGs, with little labeling of the Golgi complex and no significant labeling of the apical plasmalemma or any other intracellular membranes. Stimulation of pancreatic lobules in vitro by carbamylcholine for 15 min, resulted in massive exocytosis that led to a near doubling of the area of the apical plasma membrane. However, no relocation of the rab3-like protein to the apical plasmalemma was seen. After 3 h of induced exocytosis, during which time approximately 90% of the ZGs is released, the rab3- like protein appeared to translocate to small vesicles and newly forming secretory granules in the TGN. No significant increase of the rab3-like protein was found in the cytosolic fraction at any time during stimulation. Since the protein is not detected on the apical plasmalemma after stimulation, we conclude that recycling may involve a membrane dissociation-association cycle that accompanies regulated exocytosis.     

ZG16p, an animal homolog of β-prism fold plant lectins, interacts with heparan sulfate proteoglycans in pancreatic zymogen granules

ZG16p is a soluble 16?kDa pancreatic protein having structural similarities with plant β-prism fold lectins such as the banana lectin BanLec and the jackfruit lectin jacalin. ZG16p is postulated to be involved in the formation of zymogen granules by interacting with proteoglycans (PGs) localized in pancreatic exocrine granule membranes, but direct evidence was lacking. We characterized the structural properties of rat pancreatic zymogen granule PGs and examined their interaction with ZG16p. Structural analysis of the glycosaminoglycans (GAGs) showed that rat pancreatic zymogen granule PGs have heparan sulfate chains with a unique property, a high degree of sulfation (ΔUA-GlcNAc:ΔUA-GlcNS:ΔUA-GlcNAc6S:ΔUA-GlcNS6S:ΔUA2S-GlcNS:ΔUA2S-GlcNS6S, 27.9:16.6:5.7:22.5:6.2:21.1). After heparin lyase II digestion, the core proteins derived from the PGs were detected at molecular weights of 66,000 and 35,000-40,000. An overlay binding assay revealed that ZG16p binds specifically to heparan sulfate PGs by recognizing their GAG chains. Affinity chromatography demonstrated that ZG16p binds most strongly to heparin among the zymogen granule proteins. Site-directed mutational analysis revealed that the basic amino acid residues located in two putative carbohydrate-binding sites (CBSs) of ZG16p, which were found in association with the crystal structure of BanLec, are responsible for the recognition of heparin. These observations suggest that ZG16p is the primary binding partner of the granule heparan sulfate PGs. ZG16p may cross-link the granule heparan sulfate chains via two CBSs and facilitate the formation of a submembranous matrix, a sorting platform for enzyme proteins on the luminal side of the zymogen granule membrane.     

Structure of the pig pancreatic GP-2: role of intramolecular disulfides in the resistance to proteolysis

GP-2 is the major membrane glycoprotein characteristic of the pancreatic zymogen granule membrane. When granules are lysed in the presence of DTT, GP-2 becomes completely and specifically degraded. This proteolysis was reproducible with the same characteristics in the purified granule membrane. The protease was purified from this source using hydrophobic interaction chromatography. The proteolytic activity was identified as a 29-kDa protein because, in a reconstituted system containing both the purified GP-2 and the 29-kDa protein, the proteolytic degradation of GP-2 was sensitive to the same spectrum and concentrations of inhibitors or reducing agents as in the membrane. The activity was characteristic of a serine protease. It was also shown that GP-2 only becomes sensitive to proteolytic digestion when its disulfide bonds are reduced, and that DTT does not activate the protease. Seven intramolecular disulfide bonds were identified on GP-2. All of them are located in a 65-kDa tryptic fragment that is very resistant to exogenous proteases under nonreducing conditions. Because of the quite specific degradation of GP-2 under reducing conditions, we believe that the 29-kDa protease must be closely associated with GP-2 on the membrane. This protease could be responsible, in part, for the solubilization of the GP-2 from the membrane into the zymogen granule content and its resulting secretion by the pancreas.     

Expression of Rab27B-binding protein Slp1 in pancreatic acinar cells and its involvement in amylase secretion

Slp1 is a putative Rab27 effector protein and implicated in intracellular membrane transport; however, the precise tissue distribution and function of Slp1 protein remain largely unknown. In this study we investigated the tissue distribution of Slp1 in mice and found that Slp1 is abundantly expressed in the pancreas, especially in the apical region of pancreatic acinar cells. Slp1 interacted with Rab27B in vivo and both proteins were co-localized on zymogen granules. Morphological analysis of fasted Slp1 knockout mice showed an increased number of zymogen granules in the pancreatic acinar cells, indicating that Slp1 is part of the machinery of amylase secretion by the exocrine pancreas.     

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.     

Different patterns of proteins are secreted by the pig pancreas when stimulated by secretin alone or in combination with caerulein

The protein compositions of pig pancreatic secretions collected under stimulation by secretin alone or in combination with caerulein were compared by SDS polyacrylamide gel electrophoresis. Different sets of proteins were observed in these two different conditions. One of the major proteins secreted under secretin alone was immunologically similar to the 92 kDa glycoprotein characteristic of the pig zymogen granule membrane. Since its proportion in the two secretions was drastically different and since this protein is exclusively found in the acinar cell, these observations support the view that the proteins released by the pig pancreas under secretin stimulation alone, and under the combination of secretin + caerulein do not originate from the same intracellular pool of the acinar cell and that the secretin-induced secretion does not derive from zymogen granules.