Localization of protein disulfide isomerase on plasma membranes of rat exocrine pancreatic cells

We investigated immunocytochemically the ultrastructural localization of protein disulfide isomerase (PDI) in rat pancreatic exocrine cells by use of the post-embedding protein A-gold technique. We found that not only the endoplasmic reticulum (ER) and nuclear envelope but also the trans-Golgi cisternae, secretory granules, and plasma membranes were heavily labeled with gold particles. Labeling density of the gold particles in the rough ER and plasma membranes of the exocrine pancreatic cells was twofold and twentyfold greater, respectively, than that of hepatocytes. In the acinar lumen, amorphous material presumably corresponding to the secreted zymogens was also labeled with gold particles. These results suggest that in rat exocrine pancreatic cells a significant amount of PDI is transported to the plasma membrane and secreted to the acinar lumen.     

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.     

Immunocytochemical localization of amylase and chymotrypsinogen in the exocrine pancreatic cell with special attention to the Golgi complex

Affinity-purified, monospecific rabbit antibodies against rat pancreatic alpha-amylase and bovine pancreatic alpha-chymotrypsinogen were used for immunoferritin observations of ultrathin frozen sections of mildly fixed exocrine pancreatic tissue from secretion-stimulated (pilocarpine) rats and from overnight-fasted rats and guinea pigs. The labeling patterns for both antibodies were qualitatively alike: Labeling occurred in (a) the cisternae of the rough endoplasmic reticulum (RER) including the perinuclear cisterna, in (b) the peripheral area between the RER and cis-Golgi face, and (c) all Golgi cisternae, condensing vacuoles, and secretory granules. Labeling of cytoplasmic matrix was negligible. Structures that appeared to correspond to rigid lamellae were unlabeled. Differences in labeling intensities indicated that concentration of the zymogens starts at the boundary of the RER and cis-side of the Golgi complex. These data support the view that the Golgi cisternae are involved in protein processing in both stimulated and unstimulated cells and that Golgi cisternae and condensing vacuoles constitute a functional unit.     

ADP-ribosylation of the molecular chaperone GRP78/BiP

Starvation of mouse hepatoma cells for essential amino acids or glucose results in the ADP-ribosylation of the molecular chaperone BiP/GRP78. Addition of the missing nutrient to the medium reverses the reaction. The signal mediating the response to environmental nutrients involves the translational efficiency. An inhibitor of proteins synthesis, cycloheximide, or reduced temperature, both of which reduce translational efficiency, stimulate the ADP-ribosylation of BiP/GRP78. Inhibition of N-linked glycosylation of proteins results in the overproduction of BiP/GRP78. The over produced protein is not ADP-ribosylated suggesting that this is the functional form of BiP/GRP78. The over produced BiP/GRP78 can, however, be ADP-ribosylated if the cells are starved for an essential amino acid. BiP/GRP78 resides in the lumen of the endoplasmic reticulum where it participates in the assembly of secretory and integral membrane proteins. ADP-ribosylation of BiP/GRP78 during starvation is probably part of a nutritional stress response which conserves limited nutrients by slowing flow through the secretory pathway.     

Disproportional immunostaining patterns of two secretory proteins in guinea pig and rat exocrine pancreatic cells. An immunoferritin and fluorescence study

Amylase (Am) and chymotrypsinogen (Chtg) were demonstrated in rat and guinea pig exocrine pancreatic cells by immunofluorescence and immunoferritin cytochemistry on thin and ultrathin frozen sections. We describe two observations indicating that Am and Chtg may behave differently in the pre-Golgi phase of their intracellular transport. Firstly, aggregates of material within the RER cisternae of the guinea pig (so-called intracisternal granules) reacted strongly with anti-Chtg, but showed no affinity for anti-Am. Secondly, in both rat and guinea pig, the increase in labeling intensity from cytoplasm (RER) to secretory granules was larger for Chtg than for Am. We hypothesize that the two proteins do not travel in-parallel towards the Golgi complex. Compared with Chtg, Am would lag behind in the RER cisternae.     

Regulated apical secretion of zymogens in rat pancreas. Involvement of the glycosylphosphatidylinositol-anchored glycoprotein GP-2, the lectin ZG16p, and cholesterol-glycosphingolipid-enriched microdomains

We examined the role of glycosphingolipid- and cholesterol-enriched microdomains, or rafts, in the sorting of digestive enzymes into zymogen granules destined for apical secretion and in granule formation. Isolated membranes of zymogen granules from pancreatic acinar cells showed an enrichment in cholesterol and sphingomyelin and formed detergent-insoluble glycolipid-enriched complexes. These complexes floated to the lighter fractions of sucrose density gradients and contained the glycosylphosphatidylinositol (GPI)-anchored glycoprotein GP-2, the lectin ZG16p, and sulfated matrix proteoglycans. Morphological and pulse-chase studies with isolated pancreatic lobules revealed that after inhibition of GPI-anchor biosynthesis by mannosamine or the fungal metabolite YW 3548, granule formation was impaired leading to an accumulation of newly synthesized proteins in the Golgi apparatus and the rough endoplasmic reticulum. Furthermore, the membrane attachment of matrix proteoglycans was diminished. After cholesterol depletion or inhibition of glycosphingolipid synthesis by fumonisin B1, the formation of zymogen granules as well as the formation of detergent-insoluble complexes was reduced. In addition, cholesterol depletion led to constitutive secretion of newly synthesized proteins, e.g. amylase, indicating that zymogens were missorted. Together, these data provide first evidence that in polarized acinar cells of the exocrine pancreas GPI-anchored proteins, e.g. GP-2, and cholesterol-sphingolipid-enriched microdomains are required for granule formation as well as for regulated secretion of zymogens and may function as sorting platforms for secretory proteins destined for apical delivery.     

Loss of BiP/GRP78 function blocks translocation of secretory proteins in yeast

BiP/GRP78 is an essential member of the HSP70 family that resides in the lumen of the endoplasmic reticulum. In yeast, BiP/GRP78 is encoded by the KAR2 gene. A temperature sensitive mutation was isolated in KAR2 and found to cause a rapid block in protein secretion. Secretory precursors of a number of proteins (invertase, carboxypeptidase Y, alpha-factor, and BiP) accumulated that were characteristic of a block in translocation into the lumen of the ER. Protease protection experiments confirmed that the precursors accumulated on the cytoplasmic side of the ER membrane. Moreover, depletion of wild-type KAR2 protein also resulted in a block in translocation of secretory proteins. These results implicate BiP/GRP78 function in the continued translocation of proteins into the lumen of the ER.     

In exocrine pancreas, the basolateral endocytic pathway converges with the autophagic pathway immediately after the early endosome

Intracisternal granules (ICGs) are insoluble aggregates of pancreatic digestive enzymes and proenzymes that develop within the lumen of the rough endoplasmic reticulum of exocrine pancreatic cells, especially in guinea pigs. These ICGs are eliminated by autophagy. By morphological criteria, we identified three distinct and sequential classes of autophagic compartments, which we refer to as phagophores, Type I autophagic vacuoles, and Type II autophagic vacuoles. Lobules of guinea pig pancreas were incubated in media containing HRP for periods of 5-120 min to determine the relationship between the endocytic and autophagic pathways. Incubations with HRP of 15 min or less labeled early endosomes at the cell periphery that were not involved in autophagy of ICGs, but after these short incubations none of the autophagic compartments were HRP positive. After 30-min incubation with HRP, early endosomes at the cell periphery, late endosomes in the pericentriolar region, and, in addition, Type I autophagic vacuoles containing ICGs were all labeled by the tracer. Type II autophagic vacuoles were not labeled after 30-min incubation with HRP but were labeled after incubations of 60-120 min. Phagophores did not receive HRP even after 120 min incubations. We concluded that the autophagic and endocytic pathways converge immediately after the early endosome level and that Type I autophagic vacuoles precede Type II autophagic vacuoles on the endocytic pathway. We studied the distribution of acid phosphatase, lysosomal proteases and cation-independent-mannose-6-phosphate receptor (CI-M6PR) in the three classes of autophagic compartments by histochemical and immunocytochemical methods. Phagophores, the earliest autophagic compartment, contained none of these markers. Type I autophagic vacuoles contained acid phosphatase but, at most, only very low levels of cathepsin D and CI-M6PR. Type II autophagic vacuoles, by contrast, are enriched for acid phosphatase, cathepsin D, and other lysosomal enzymes, and they are also enriched for CI-M6PR. Moreover, soluble fragments of bovine CI-M6PR conjugated to colloidal gold particles heavily labeled Type II but not Type I autophagic vacuoles, and this labeling was specifically blocked by mannose-6-phosphate. This indicates that the lysosomal enzymes present in Type II autophagic vacuoles carry mannose-6-phosphate monoester residues. Using 3-C2, 4-dinitroanilino-3'-amino-N-methyldipropylamine (DAMP), we showed that Type II autophagic vacuoles are acidic. We interpret these findings as indicating that Type II autophagic vacuoles are a prelysosomal compartment in which the already combined endocytic and autophagic pathways meet the delivery pathway of lysosomal enzymes.     

Differential aggregation properties of secretory proteins that are stored in exocrine secretory granules of the pancreas and parotid glands

Low-pH- and calcium-induced aggregation of regulated secretory proteins has been proposed to play a role in their retention and storage in secretory granules. However, this has not been tested for secretory proteins that are stored in the exocrine parotid secretory granules. Parotid granule matrix proteins were analyzed for aggregation in the presence or absence of calcium and in the pH range of 5.5 to 7.5. Amylase did not aggregate under these conditions, although <10% of parotid secretory protein (PSP) aggregated below pH 6.0. To test aggregation directly in isolated granules, rat parotid secretory granules were permeabilized with 0.1% saponin in the presence or absence of calcium and in the pH range of 5.0 to 8.4. In contrast to the low-pH-dependent retention of amylase in exocrine pancreatic granules, amylase was quantitatively released and most PSP was released from parotid granules under all conditions. Both proteins were completely released upon granule membrane solubilization. Thus neither amylase nor PSP show low-pH- or calcium-induced aggregation under physiological conditions in the exocrine parotid secretory granules.     

Reinternalization of secretory proteins during membrane recycling in rat pancreatic acinar cells

Membrane recycling in pancreatic acinar cells involves endocytic vesicle formation at the apical cell surface and rapid membrane traffic to the Golgi complex. During this process a small amount of extracellular content is taken up from the acinar lumen. In order to determine whether secretory proteins already released into the pancreatic acinar lumen are reinternalized during membrane retrieval, 3H-labeled amylase or 125I-labeled secretory proteins were reinfused through the pancreatic duct until the lumina were reached. Tissue samples from various time points were prepared for light and electron microscope autoradiography. The observations showed that [3H]amylase and, to a lesser extent, the 125I-labeled secretory proteins were internalized at the apical cell surface and rapidly (within 2-5 min) transferred to the Golgi cisternae and the condensing vacuoles; only a minor proportion of silver grains was observed over lysosomes. In addition, at later time points, mature secretion granules close to the Golgi complex became labeled. The results indicate that exocytosis in the rat exocrine pancreas does not operate at 100% efficiency; part of the exported amylase and part of the total secretion product are reinternalized concomitantly with the endocytic removal of plasma membrane and are copackaged together with newly synthesized secretory proteins.     

Immunocytochemical localization of BiP to the rough endoplasmic reticulum: evidence for protein sorting by selective retention

Immunoglobulin heavy chain binding protein (BiP) (also known as GRP 78) is a protein of the endoplasmic reticulum (ER) which has been shown to be involved in post-translational processing of nascent membrane and secretory proteins. To determine BiP's location in the exocytic pathway, we localized BiP at the electron microscopic level in mouse myeloma cell lines by immunoperoxidase cytochemistry. BiP was found to be present within the cisternal spaces of the RER and nuclear envelope but was not detected in the cisternae of the Golgi complex. BiP reaction product was also found within transitional elements of the RER but was absent from smooth-surfaced vesicles found between the ER and the Golgi complex. Immunoperoxidase staining of BiP was reduced or absent in regions of a smooth ER membrane system in myelomas that contained endogenous murine retrovirus A particles. All compartments of the exocytic pathway, including the virus-containing smooth ER, stained for IgG, a secretory protein. These observations suggest that BiP is selectively retained in the cisternae of the ER and is not free to enter Golgi-directed transport vesicles. These studies suggest that BiP's subcellular localization may occur by selective interaction with component(s) of the ER.     

Immunocytochemical localization of exocrine enzymes in rat pancreatic acinar carcinoma

Ten pancreatic secretory proteins have been demonstrated in differentiated pancreatic acinar carcinoma cells by the protein A-gold immunocytochemical approach. The high resolution of the technique has allowed for the localization of the different proteins in the cellular compartments involved in protein secretion: RER, Golgi and secretory granules. The quantitative evaluation of the labeling for amylase has demonstrated the presence of an increasing gradient in the intensity from the RER to the Golgi and to the secretory granules which may reflect the process of protein concentration along the secretory pathway. These results, together with those obtained using the pulse-labeling autoradiographic approach, demonstrate that differentiated acinar carcinoma cells are capable of processing secretory proteins. When intensities of labeling obtained for different proteins on acinar carcinoma cells were compared to those obtained on normal pancreatic acinar cells, major differences were observed for some proteins. In addition, studies performed on the pancreatic tissue of the tumor-bearing animals have shown the presence of morphological alterations in the acinar cells.     

KAR2, a karyogamy gene, is the yeast homolog of the mammalian BiP/GRP78 gene

The yeast KAR2 gene was isolated by complementation of a mutation that blocks nuclear fusion. The predicted KAR2 protein sequence is most homologous to mammalian BiP/GRP78 and has several structural features in common with it: a functional secretory signal sequence, a yeast endoplasmic reticulum retention signal (HDEL) at the carboxyl terminus, and the absence of potential N-linked glycosylation sites. Moreover KAR2 is regulated like BiP/GRP78: the level of mRNA is increased by drug treatments and mutations that cause accumulation of secretory precursors in the endoplasmic reticulum. However, unlike BiP/GRP78, KAR2 is also regulated by heat shock. Deletion of the KAR2 gene generated a recessive lethal mutation, showing that BiP/GRP78 function is required for cell viability.     

Effect of serum-free and serum-containing medium on cellular levels of ER-based proteins in various mouse hybridoma cell lines

BiP, GRP94 and PDI, three endoplasmic reticulum (ER) based proteins are involved in the maturation of secretory proteins and might represent a bottleneck in the secretory pathway of monoclonal antibodies (MAB). With the three hybridoma cell lines tested, MAB production kinetics were significantly increased for the batch cultures done in serum-free medium (SFM) with respect to those done in serum-containing medium (SCM). It could be established that there was a correlation between the cellular levels of PDI and GRP94 and the specific MAB production rate. With respect to BiP, no correlation with the MAB production rate was observed. The non-producing myeloma cell line X63, used as a reference, showed increased cellular PDI levels when cultivated in SFM. However, in this cell, the cellular GRP94 levels were not significantly influenced by the medium composition.It was concluded that SFM induced an increase of cellular PDI levels and this elevation seemed to be responsible for the increase in the specific MAB production rates. On the other hand, only MAB producing cells showed an increase in the cellular GRP94 levels which might be a result of increased MAB sythesis. Indeed, I.13.17 cultivated in SFM supplemented with serum showed a significantly reduced (about 50%) specific MAB production rate in comparison to I.13.17 cultivated in non-serum supplemented SFM. The cellular PDI and BiP levels did not vary between these conditions of culture, whereas the cellular GRP94 level was about two-fold lower in I.13.17 cultivated in SFM when supplemented with serum than in I.13.17 cultivated in SFM without futher supplementation. These results are discussed with respect to the medium composition as well as in the context of apparent and potential bottlenecks within the secretory pathway of MAB. (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 54: 165-180, 1997.     

Protein disulfide-isomerase in rat exocrine pancreatic cells is exported from the endoplasmic reticulum despite possessing the retention signal

Recently we found by immunogold electron microscopy that protein disulfide-isomerase (PDI), a major resident protein in the lumen of the endoplasmic reticulum (ER) of many cells, is exceptionally localized in rat exocrine pancreatic cells not only in the ER but also in plasma membranes and other organelles along secretory pathway (Akagi, S., Yamamoto, A., Yoshimori, T., Masaki, R., Ogawa, R., and Tashiro, Y. (1988) J. Histochem. Cytochem. 36, 1069-1074). These observations suggest that another type of PDI, e.g. one with a defective ER retention signal, might exist and be transported in the exocrine pancreatic cells. We therefore compared biochemical and immunochemical properties of the transported PDI with the authentic ER resident PDI. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis, peptide mapping, urea-polyacrylamide gel electrophoresis, and isoelectric focusing showed that the former was indistinguishable from the latter. We prepared a polyclonal antibody against the synthetic hexapeptide, which corresponds to the carboxyl terminus of PDI containing the putative ER retention signal "KDEL." The epitopes of this antibody (anti-KDEL antibody) were located within the KDEL sequence. Anti-KDEL antibody reacted with PDI in both the plasma membranes and the ER of rat pancreatic cells in immunoblot analysis as well as in immunogold electron microscopy. These results suggest that PDI exported from the ER to the plasma membranes in rat exocrine pancreatic cells possesses the KDEL sequence.     

Differential Sorting of Lysosomal Enzymes Out of the Regulated Secretory Pathway in Pancreatic β-Cells

In cells specialized for secretory granule exocytosis, lysosomal hydrolases may enter the regulated secretory pathway. Using mouse pancreatic islets and the INS-1 β-cell line as models, we have compared the itineraries of procathepsins L and B, two closely related members of the papain superfamily known to exhibit low and high affinity for mannose-6-phosphate receptors (MPRs), respectively. Interestingly, shortly after pulse labeling INS cells, a substantial fraction of both proenzymes exhibit regulated exocytosis. After several hours, much procathepsin L remains as precursor in a compartment that persists in its ability to undergo regulated exocytosis in parallel with insulin, while procathepsin B is efficiently converted to the mature form and can no longer be secreted. However, in islets from transgenic mice devoid of cation-dependent MPRs, the modest fraction of procathepsin B normally remaining within mature secretory granules is increased approximately fourfold. In normal mouse islets, immunoelectron microscopy established that both cathepsins are present in immature β-granules, while immunolabeling for cathepsin L, but not B, persists in mature β-granules. By contrast, in islets from normal male SpragueDawley rats, much of the proenzyme sorting appears to occur earlier, significantly diminishing the stimulusdependent release of procathepsin B. Evidently, in the context of different systems, MPR-mediated sorting of lysosomal proenzymes occurs to a variable extent within the trans-Golgi network and is continued, as needed, within immature secretory granules. Lysosomal proenzymes that fail to be sorted at both sites remain as residents of mature secretory granules.     

Acceleration of asynchronous enzyme transport in the rat exocrine pancreas following hormonal stimulation in vivo

We have measured the rate of secretion in vitro of individual rat exocrine pancreatic enzymes and proenzymes from cells in pancreatic lobules of control animals and animals subjected to 24 h optimal hormonal prestimulation with cerulein, in vivo. With the controls secreted proteins were first detectable at 20 to 25 min of chase after a 5-min pulse label, and the amount of total secretion increased slowly thereafter. With stimulated lobules secretion was first detectable at 10 to 15 min postpulse. Comparison of the rates of secretion from control and experimental lobules showed that 24 h prestimulation in vivo resulted in a fivefold increase in the rate of secretion. Measurement of the rates of secretion of the individual enzymes and proenzymes showed that they were all increased to the same extent. In both situations the serine endoproteases, proelastase 2, chymotrypsinogen 1, and trypsinogen 1 and 2, were the most rapidly secreted proteins, while amylase, the procarboxypeptidases and prophospholipase A2 were amongst the slowest. The difference in the rates of secretion of proelastase 2 and prophospholipase A2, the two extremes, was three-fold before and after prestimulation, and their halftimes of secretion from the hormonally prestimulated lobules were 34 min and 190 min, respectively. Both electron microscopic autoradiography and immunocytochemistry showed that in the hormonally prestimulated cells the secreted proenzymes and enzymes followed the normal regulated exocytotic pathway and were transported between the Golgi apparatus and the apical plasma membrane in dense cored secretory granules.     

Glucocorticoids modulate the in vitro development of the embryonic rat pancreas

The effect of the glucocorticoid analogue, dexamethasone, on the development of the embryonic pancreas was studied in tissue culture. It specifically enhances the accumulation of exocrine enzymes without altering the level of general cell proteins. The enhancement, however, is not symmetrical: the cellular levels of the two major exocrine products, amylase and chymotrypsinogen, are increased about 10- and 2- fold, respectively. Two other zymogens that are present in minor quantities, procarboxypeptidases A and B, are also increased, whereas no effect is seen on lipase A. Coordinate with these effects on synthesis, there is a dramatic change in the morphology of dexamethasone-stimulated acinar cells. Their number of zymogen granules is higher and crystalline arrays are found in the rough endoplasmic reticulum. Dexamethasone also inhibits cell replication, perhaps by selectively inhibiting the last cell divisions of the culture period. At the same time, there is a disproportionate reduction in the insulin content of cultured rudiments. We find that pancreatic development is normal in the absence of dexamethasone and that this glucocorticoid does not precociously induce the appearance of the specific secretory products, but rather enhances by a constant degree their synthesis and accumulation. Therefore, we conclude that glucocorticoids may play a modulatory but not an inductive role in pancreatic development.     

Synthesis, intracellular transport, and discharge of secretory proteins in stimulated pancreatic exocrine cells

Our previous observations on the synthesis and transport of secretory proteins in the pancreatic exocrine cell were made on pancreatic slices from starved guinea pigs and accordingly apply to the resting, unstimulated cell. Normally, however, the gland functions in cycles during which zymogen granules accumulate in the cell and are subsequently discharged from it in response to secretogogues. The present experiments were undertaken to determine if secretory stimuli applied in vitro result in adjustments in the rates of protein synthesis and/or of intracellular transport. To this intent pancreatic slices from starved animals were stimulated in vitro for 3 hr with 0.01 mM carbamylcholine. During the first hour of treatment the acinar lumen profile is markedly enlarged due to insertion of zymogen granule membranes into the apical plasmalemma accompanying exocytosis of the granule content. Between 2 and 3 hr of stimulation the luminal profile reverts to unstimulated dimensions while depletion of the granule population nears completion. The acinar cells in 3-hr stimulated slices are characterized by the virtual complete absence of typical condensing vacuoles and zymogen granules, contain a markedly enlarged Golgi complex consisting of numerous stacked cisternae and electron-opaque vesicles, and possess many small pleomorphic storage granules. Slices in this condition were pulse labeled with leucine-³H and the route and timetable of intracellular transport assessed during chase incubation by cell fractionation, electron microscope radioautography, and a discharge assay covering the entire secretory pathway. The results showed that the rate of protein synthesis, the rate of drainage of the rough-surfaced endoplasmic reticulum (RER) compartment, and the over-all transit time of secretory proteins through the cells was not accelerated by the secretogogue. Secretory stimulation did not lead to a rerouting of secretory proteins through the cell sap. In the resting cell, the secretory product is concentrated in condensing vacuoles and stored as a relatively homogeneous population of spherical zymogen granules. By contrast, in the stimulated cell, secretory proteins are initially concentrated in the flattened saccules of the enlarged Golgi complex and subsequently stored in numerous small storage granules before release. The results suggest that secretory stimuli applied in vitro primarily affect the discharge of secretory proteins and do not, directly or indirectly, influence their rates of synthesis and intracellular transport.     

A sulfated proteoglycan is necessary for storage of exocrine secretory proteins in the rat parotid gland

Sulfated proteoglycans have beenproposed to play a role in the sorting and storage of secretoryproteins in exocrine secretory granules. Rat parotid acinar cellsexpressed a 40- to 60-kDa proteoglycan that was stored in secretorygranules. Treatment of the tissue with the proteoglycan synthesisinhibitor paranitrophenyl xyloside resulted in the complete abrogationof the sulfated proteoglycan. Pulse-chase experiments in the presenceof the xyloside analog showed a significant reduction in the stimulatedsecretion and granule storage of the newly synthesized regulatedsecretory proteins amylase and parotid secretory protein. Inhibition ofproteoglycan sulfation by chlorate did not affect the sorting of theseproteins. The effect of proteoglycan synthesis inhibition on proteinsorting was completely reversed upon treatment with a weak acid. These results suggest that the sulfated proteoglycan is necessary for sortingand storage of regulated secretory proteins in the exocrine parotidgland. Preliminary evidence suggests that the mechanism involves themodulation of granule pH by the proteoglycan rather than a directinteraction with other granule components.