Protein targeting via the "constitutive-like" secretory pathway in isolated pancreatic islets: passive sorting in the immature granule compartment.

We have suggested the existence of a novel "constitutive-like" secretory pathway in pancreatic islets, which preferentially conveys a fraction of newly synthesized C-peptide, insulin, and proinsulin, and is related to the presence of immature secretory granules (IGs). Regulated exocytosis of IGs results in an equimolar secretion of C-peptide and insulin; however an assay of the constitutive-like secretory pathway recently demonstrated that this route conveys newly synthesized C-peptide in molar excess of insulin (Arvan, P., R. Kuliawat, D. Prabakaran, A.-M. Zavacki, D. Elahi, S. Wang, and D. Pilkey. J. Biol. Chem. 266:14171-14174). We now use this assay to examine the kinetics of constitutive-like secretion. Though its duration is much shorter than the life of mature granules under physiologic conditions, constitutive-like secretion appears comparatively slow (t1/2 approximately equal to 1.5 h) compared with the rate of proinsulin traffic through the ER and Golgi stacks. We have examined whether this slow rate is coupled to the rate of IG exit from the trans-Golgi network (TGN). Escape from the 20 degrees C temperature block reveals a t1/2 less than or equal to 12 min from TGN exit to stimulated release of IGs; the time required for IG formation is too rapid to be rate limiting for constitutive-like secretion. Further, conditions are described in which constitutive-like secretion is blocked yet regulated discharge of IGs remains completely intact. Thus, constitutive-like secretion appears to represent an independent secretory pathway that is kinetically restricted to a specific granule maturation period. The data support a model in which passive sorting due to insulin crystallization results in enrichment of C-peptide in membrane vesicles that bud from IGs to initiate the constitutive-like secretory pathway.     

Distinct molecular mechanisms for protein sorting within immature secretory granules of pancreatic beta-cells

In the beta-cells of pancreatic islets, insulin is stored as the predominant protein within storage granules that undergo regulated exocytosis in response to glucose. By pulse-chase analysis of radiolabeled protein condensation in beta-cells, the formation of insoluble aggregates of regulated secretory protein lags behind the conversion of proinsulin to insulin. Condensation occurs within immature granules (IGs), accounting for passive protein sorting as demonstrated by constitutive-like secretion of newly synthesized C- peptide in stoichiometric excess of insulin (Kuliawat, R., and P. Arvan. J. Cell Biol. 1992. 118:521-529). Experimental manipulation of condensation conditions in vivo reveals a direct relationship between sorting of regulated secretory protein and polymer assembly within IGs. By contrast, entry from the trans-Golgi network into IGs does not appear especially selective for regulated secretory proteins. Specifically, in normal islets, lysosomal enzyme precursors enter the stimulus-dependent secretory pathway with comparable efficiency to that of proinsulin. However, within 2 h after synthesis (the same period during which proinsulin processing occurs), newly synthesized hydrolases are fairly efficiently relocated out of the stimulus- dependent pathway. In tunicamycin-treated islets, while entry of new lysosomal enzymes into the regulated secretory pathway continues unperturbed, exit of nonglycosylated hydrolases from this pathway does not occur. Consequently, the ultimate targeting of nonglycosylated hydrolases in beta-cells is to storage granules rather than lysosomes. These results implicate a post-Golgi mechanism for the active removal of lysosomal hydrolases away from condensed granule contents during the storage process for regulated secretory proteins.     

Protein sorting and secretion granule formation in regulated secretory cells

Formation of secretion granules in regulated secretory cells involves packaging a subject of proteins undergoing intracellular transport into specific vesicular carriers that function in stimulus-dependent exocytosis. Recent findings suggest that immature granules are a site of passive sorting, involving condensation of regulated secretory proteins. Proteins that are not condensed are stored to a lesser degree and are enriched in unstimulated, constitutive-like secretion. While these observations have helped to distinguish possible mechanisms of secretory protein sorting, there are only recent hints about the sorting processes that may be required to create the regulated secretory carrier membranes.     

Sorting ourselves out: seeking consensus on trafficking in the beta-cell

Biogenesis of the regulated secretory pathway in the pancreatic beta-cell involves packaging of products, notably proinsulin, into immature secretory granules derived from the trans -Golgi network. Proinsulin is converted to insulin and C-peptide as granules mature. Secretory proteins not entering granules are conveyed by transport intermediates directly to the plasma membrane for constitutive secretion. One of the co-authors, Peter Arvan, has proposed that in addition, small vesicles bud from granules to traffic to the endosomal system. From there, some proteins are secreted by a (post-granular) constitutive-like pathway. He argues that retention in granules is facilitated by condensation, rendering soluble products (notably C-peptide and proinsulin) more available for constitutive-like secretion. Thus he argues that prohormone conversion is potentially important in secretory granule biogenesis. The other co-author, Philippe Halban, argues that the post-granular secretory pathway is not of physiological relevance in primary beta-cells, and contests the importance of proinsulin conversion for retention in granules. Both, however, agree that trafficking from granules to endosomes is important, purging granules of unwanted newly synthesized proteins and allowing their traffic to other destinations. In this Traffic Interchange, the two co-authors attempt to reconcile their differences, leading to a common vision of proinsulin trafficking in primary and transformed cells.     

Unstimulated amylase secretion is proteoglycan-dependent in rat parotid acinar cells

It is well-known that amylase is secreted in response to extracellular stimulation from the acinar cells. However, amylase is also secreted without stimulation. We distinguished vesicular amylase as a newly synthesized amylase from the accumulated amylase in secretory granules by short time pulse and chased with ³⁵S-amino acid. The newly synthesized amylase was secreted without stimulation from secretory vesicles in rat parotid acinar cells. The secretion process did not include microtubules, but was related to microfilaments. p-Nitrophenyl β-xyloside, an inhibitor of proteoglycan synthesis, inhibited the newly synthesized amylase secretion. This indicated that the newly synthesized amylase was secreted from secretory vesicles, not via the constitutive-like secretory route, which includes the immature secretory granules, and that proteoglycan synthesis was required for secretory vesicle formation.     

Characterization of the TGN exit routes in AtT20 cells using pancreatic amylase and serum albumin

The AtT20 pituitary cell is the one that was originally used to define the pathways taken by secretory proteins in mammalian cells. It possesses two secretory pathways, the constitutive for immediate secretion and the regulated for accumulation and release under hormonal stimulation. It is in the regulated pathway, most precisely in the immature granule of the regulated pathway, that proteolytic maturation takes place. A pathway that stems from the regulated one, namely the constitutive-like pathway releases proteins present in immature granules that are not destined for accumulation in mature granules. In AtT20 cells proopiomelanocortin the endogenous precursor of the accumulated adrenocorticotropic hormone, is predominantly secreted in a constitutive manner without proteolytic maturation. In order to better understand by which secretory pathway intact proopiomelanocortin is secreted by a cell line possessing a regulated secretory pathway, it was transfected with rat serum albumin (a marker of constitutive secretory proteins), and pancreatic amylase (a marker of regulated proteins). COS cells were also transfected in order to serve as control of release by the constitutive pathway. It was observed that both the basal and stimulated secretions of albumin and proopiomelanocortin from AtT20 cells are identical. In addition, secretagogue stimulation when POMC is in transit in the trans-Golgi network decreases its constitutive secretion by 50%. It was also observed using cell fractionation and 20 degrees C secretion blocks that albumin and proopiomelanocortin are present in the regulated pathway, presumably in the immature granules, and are secreted by the constitutive-like secretory pathway. These observations show that stimulation can increase sorting into the regulated pathway, and confirm the importance of the constitutive-like secretory pathway in the model AtT20 cell line.     

Calnuc,an EF-hand Ca(2+)-binding protein,is stored and processed in the Golgi and secreted by the constitutive-like pathway in AtT20 cells

Calnuc is an ubiquitous, EF-hand Ca(2+) binding protein found in the cytoplasm where it binds to Galphai3, in the Golgi lumen where it constitutes a Ca(2+) storage pool, and secreted outside the cell. Here we investigated the pathway of secretion of calnuc in AtT20 cells. We found by pulse-chase experiments that calnuc is synthesized in the endoplasmic reticulum, transported to the Golgi where it remains greater than 12 h and undergoes posttranslational modification (O-glycosylation and sulfation) followed by secretion into the culture medium. We examined if calnuc is secreted by the constitutive or regulated secretory pathway in AtT20 cells. By immunofluorescence and immunogold labeling, endogenous calnuc is found in immature secretion granules (ISG) but not mature regulated secretory granules (RSG), whereas overexpressed calnuc-green fluorescent protein (GFP) is found in both ISG and RSG, where it colocalizes with ACTH. Neither calnuc nor calnuc-GFP are released by the regulated secretory pathway, suggesting that endogenous calnuc and calnuc-GFP are progressively removed from ISG and RSG during granule maturation. We conclude that calnuc is secreted via the constitutive-like pathway and represents a useful endogenous marker for this pathway in AtT20 cells. Together, these observations indicate that calnuc has a unique itinerary as it is retained in the Golgi and is then constitutively secreted extracellularly where it may influence cell behavior via its Ca(2+)-binding properties.     

Reduction of the disulfide bond of chromogranin B (secretogranin I) in the trans-Golgi network causes its missorting to the constitutive secretory pathways.

The role of the single, highly conserved disulfide bond in chromogranin B (secretogranin I) on the sorting of this regulated secretory protein to secretory granules was investigated in the neuroendocrine cell line PC12. Treatment of PC12 cells with dithiothreitol (DTT), a membrane permeable thiol reducing agent known to prevent disulfide bond formation in intact cells, resulted in the secretion of newly synthesized chromogranin B, but only slightly decreased the intracellular storage of newly synthesized secretogranin II, a regulated secretory protein devoid of cysteines. The secretion of newly synthesized chromogranin B in the presence of DTT occurred with similar kinetics to those of a heparan sulfate proteoglycan, a known marker of the constitutive secretory pathway in PC12 cells. Analysis of the various secretory vesicles derived from the trans-Golgi network (TGN) indicated that DTT treatment diverted newly synthesized chromogranin B to constitutive secretory vesicles, whereas the packaging of secretogranin II into immature secretory granules was unaffected by the reducing agent. The chromogranin B molecules diverted to constitutive secretory vesicles, in contrast to those stored in secretory granules, were found to contain free sulfhydryl residues. The effect of DTT on chromogranin B occurred in the TGN rather than in the endoplasmic reticulum. We conclude that the sorting of CgB in the TGN to secretory granules is dependent upon the integrity of its single disulfide bond.     

Protein traffic from the secretory pathway to the endosomal system in pancreatic beta-cells

Constitutive-like secretion involves vesicular trafficking corresponding kinetically and biochemically with a post-trans-Golgi network (TGN) origin. In pancreatic beta-cells, the budding of AP-1/clathrin-coated vesicles, a portion of which is derived from immature secretory granules, has been hypothesized to initiate constitutive-like trafficking. However, approximately 30 min after release of a 20 degrees C intracellular transport block in pancreatic beta-cells (to synchronize protein egress from the TGN), addition of brefeldin A (BFA) (which inhibits AP-1 recruitment) was reported not to block subsequent constitutive-like secretion. To further explore post-TGN trafficking in pancreatic beta-cell lines, we have followed the fate of pulse-labeled procathepsin B (ProB, a lysosomal proenyzme) after postpulse wortmannin treatment or the BFA treatment described above. We find that continuous wortmannin treatment allows ProB to reach immature secretory granules but inhibits its egress from maturing granules. Remarkably, BFA treatment causes augmented unstimulated secretion of newly synthesized ProB that is not paralleled by insulin. This effect requires a delay of 25-35 min after release from the 20 degrees C block. Further, when ProB delivery to endosomes is inhibited, its BFA-augmented secretion is eliminated. We hypothesize that the constitutive-like pathway involves an endosomal intermediate.     

SECRETION AND ENDOCYTOSIS IN INSULIN-STIMULATED RAT ADRENAL MEDULLA CELLS

Insulin was used to deplete the adrenalin stores of rat adrenal medulla cells. Release of secretion was observed to occur by exocytosis. In addition, during the stages of massive release of secretory granules, the insulin-treated preparations showed greatly enhanced endocytic uptake of horseradish peroxidase. The tracer was taken up within vesicles, tubules, multivesicular bodies, and dense bodies. From acid phosphatase studies and from previous work it appears that many of the structures in which peroxidase accumulates are lysosomes or are destined to fuse with lysosomes. Subsequent to the period of intense exocytosis and endocytosis, there is a transient accumulation of lipid droplets in the adrenalin cells. The cells then regranulate, with new granules forming near the Golgi region. These results suggest that under the conditions used, much of the membrane that initially surrounds secretory granules is degraded after release of the granules.     

Protein discharge from immature secretory granules displays both regulated and constitutive characteristics.

At physiological glucose concentrations, isolated pancreatic islets release a minor portion of their newly synthesized insulin and precursors in a phase of secretion which is largely complete by 4 h of chase. Discharge during this period can be amplified by secretagogues, yet is not abolished by conditions which fully suppress regulated release from dense core secretory granules. The ability to stimulate the secretion and the biochemical profile of released proinsulin-related peptides indicate that secretion during this period originates from immature granules. The stoichiometry of release of labeled C-peptide:insulin during this phase is 1:1 at high glucose concentrations. However, at physiologic or low concentrations, C-peptide is released in molar excess of insulin as if the exocytotic vesicles carrying this secretion were budding from a post-Golgi compartment in which the lumen was composed of condensing insulin and soluble C-peptide. These findings can be explained by a model for regulated secretory protein traffic in which direct exocytosis of young granules is stimulated by higher glucose concentrations and vesicle budding from immature granules occurs at lower concentrations. Thus, insulin targeting from immature granules exhibits both regulated and constitutive-like characteristics.     

Secretion of Carboxypeptidase E from Cultured Astrocytes and from AtT-20 Cells, a Neuroendocrine Cell Line: Implications for Neuropeptide Biosynthesis

Cultured astrocytes have recently been shown to produce certain neuropeptides, as well as neuropeptide processing enzymes. To characterize the secretory pathway in cultured astrocytes, we used the neuropeptide processing enzyme carboxypeptidase E (CPE) as a marker for neuropeptide secretion. Cultured astrocytes and AtT-20 cells, a mouse pituitary-derived neuroendocrine cell line, were labeled with [35S]Met for 15 min and then chased with unlabeled Met. CPE was isolated from either medium or cell extracts using a substrate affinity column. The time course of secretion of radiolabeled CPE was significantly different for cultured astrocytes as compared with AtT-20 cells. CPE was rapidly secreted from the astrocytes after a 30-min lag time, presumably reflecting transport through the endoplasmic reticulum and Golgi apparatus, followed by constitutive secretion. The secretion of radiolabeled CPE was essentially complete by 2 h. In contrast, only a portion of the radiolabeled CPE was secreted from AtT-20 cells over a 2-3-h period, indicating that the majority of newly synthesized CPE is stored, presumably in secretory granules within the AtT-20 cells. The regulation of CPE secretion from astrocytes was also examined. CPE secretion is stimulated two- to threefold by prolonged treatment (3-48 h) with the phorbol ester 12-O-tetradecanoylphorbol 13-acetate (TPA) but not by treatment with other secretagogues that stimulate CPE secretion from AtT-20 cells (forskolin, isoproterenol, A23187, and vasoactive intestinal peptide) or short (less than 3 h) exposure to TPA. Taken together, these results indicate that the secretory pathway for CPE, and presumably neuropeptides, is substantially different in astrocytes than the secretory pathway for CPE in neuroendocrine cells.     

Mutant proinsulin that cannot be converted is secreted efficiently from primary rat beta-cells via the regulated pathway

Prohormones are directed from the trans-Golgi network to secretory granules of the regulated secretory pathway. It has further been proposed that prohormone conversion by endoproteolysis may be necessary for subsequent retention of peptides in granules and to prevent their release by the so-called "constitutive-like" pathway. To address this directly, mutant human proinsulin (Arg/Gly(32):Lys/Thr(64)), which cannot be cleaved by conversion endoproteases, was expressed in primary rat islet cells by recombinant adenovirus. The handling of the mutant proinsulin was compared with that of wild-type human proinsulin. Infected islet cells were pulse labeled and both basal and stimulated secretion of radiolabeled products followed during a chase. Labeled products were quantified by high-performance liquid chromatography. As expected, the mutant proinsulin was not converted at any time. Basal (constitutive and constitutive-like) secretion was higher for the mutant proinsulin than for wild-type proinsulin/insulin, but amounted to <1% even during a prolonged (6-h) period of basal chase. There was no difference in stimulated (regulated) secretion of mutant and wild-type proinsulin/insulin at any time. Thus, in primary islet cells, unprocessed (mutant) proinsulin is sorted to the regulated pathway and then retained in secretory granules as efficiently as fully processed insulin.     

Resting (basal) secretion of proteins is provided by the minor regulated and constitutive-like pathways and not granule exocytosis in parotid acinar cells

Resting secretion of salivary proteins by the parotid gland is sustained in situ between periods of eating by parasympathetic stimulation and has been assumed to involve low level granule exocytosis. By using parotid lobules from ad libitum fed rats stimulated with low doses of carbachol as an in vitro analog of resting secretion, we deduce from the composition of discharged proteins that secretion does not involve granule exocytosis. Rather, it derives from two other acinar export routes, the constitutive-like (stimulus-independent) pathway and the minor regulated pathway, which responds to low doses of cholinergic or beta-adrenergic agonists (Castle, J. D., and Castle, A. M. (1996) J. Cell Sci. 109, 2591-2599). The protein composition collected in vitro mimics that collected from cannulated ducts of glands given low level stimulation in situ. Analysis of secretory trafficking along the two pathways of resting secretion has indicated that the constitutive-like pathway may pass through endosomes after diverging from the minor regulated pathway at a brefeldin A-sensitive branch point. The branch point is deduced to be distal to a common vesicular budding event by which both pathways originate from immature granules. Detectable perturbation of neither pathway in lobules was observed by wortmannin addition, and neither serves as a significant export route for lysosomal procathepsin B. These findings show that parotid acinar cells use low capacity, high sensitivity secretory pathways for resting secretion and reserve granule exocytosis, a high capacity, low sensitivity pathway, for massive salivary protein export during meals. An analogous strategy may be employed in other secretory cell types.     

3-Methylcholanthrene elicits DNA adduct formation in the CYP1A1 promoter region and attenuates reporter gene expression in rat H4IIE cells

Since it was reported that components of immature secretory granules (ISGs) are different from those of mature secretory granules (MSGs) in rat parotid acinar cells, we have been considering that components of secretory granules (SGs) change dynamically during granule maturation. As the first step to understand the mechanism of granule maturation, we separated low-density detergent-resistant membrane fractions (DRMs) from purified SGs of rat parotid gland. When SGs were lysed by the detergent Brij-58, syntaxin6 and VAMP4 were found in DRMs that were different from the GM1a-rich DRMs containing VAMP2. Because syntaxin6 and VAMP4 are known to be related to granule formation, we attempted to separate DRMs from ISGs. To enrich for ISGs, glands were removed from rats 5h after intraperitoneal injection of isoproterenol and used to purify the newly synthesized granules. Compared to mature granules prepared without injection, these newly formed granules were lower in density and contained higher concentrations of syntaxin6, VAMP4, and gamma-adaptin. This composition is consistent with the characterizations of ISGs. DRMs isolated from the newly formed granules were GM1a-rich and contained syntaxin6, VAMP4, and VAMP2 together. Thus, our findings suggest that syntaxin6 and VAMP4 associate with a GM1a-rich membrane microdomain during granule formation but enter a separate membrane microdomain before transport from granules during maturation.     

Low temperature blocks transport and sorting of cathepsin D in fibroblasts

The transport of newly synthesized cathepsin D in fibroblasts at 16-28 degrees C was compared to that at 37 degrees C. At 37 degrees C newly synthesized cathepsin D passes the trans Golgi within 30-60 min, becomes segregated from the secretory route into prelysosomal organelles within 1-2 h and processed to mature forms in dense lysosomes within 1.5-3 h after synthesis. The small fraction of cathepsin D that escapes transport into lysosomes is secreted within less than 2 h. At 16-28 degrees C the transport of cathepsin D to lysosomes is inhibited in a temperature-dependent manner. At 16-28 degrees C cathepsin D precursors are slowly transported to the trans Golgi. The cathepsin D precursors accumulate at a site that is in continuity with the secretory pathway and located within or distal of the trans Golgi and proximal to the site where cathepsin D precursors leave the secretory pathway as complexes with mannose 6-phosphate receptors. The arrest at this site is not complete. The receptor-dependent segregation of the cathepsin D precursors released from the block is impaired at less than or equal to 26 degrees C. The inhibition of segregation results in an increased, albeit retarded secretion of cathepsin D. The fraction of cathepsin D precursors that is segregated from the secretory pathway encounters a further low temperature block in prelysosomal organelles. There cathepsin D precursors are proteolytically processed to an intermediate form, which accumulates transiently.(ABSTRACT TRUNCATED AT 250 WORDS)     

Vesicle Associated Membrane Protein 8 (VAMP8)-mediated Zymogen Granule Exocytosis Is Dependent on Endosomal Trafficking via the Constitutive-Like Secretory Pathway

Acinar cell zymogen granules (ZG) express 2 isoforms of the vesicle-associated membrane protein family (VAMP2 and -8) thought to regulate exocytosis. Expression of tetanus toxin to cleave VAMP2 in VAMP8 knock-out (−/−) acini confirmed that VAMP2 and -8 are the primary VAMPs for regulated exocytosis, each contributing ∼50% of the response. Analysis of VAMP8^−/− acini indicated that although stimulated secretion was significantly reduced, a compensatory increase in constitutive secretion maintained total secretion equivalent to wild type (WT). Using a perifusion system to follow secretion over time revealed VAMP2 mediates an early rapid phase peaking and falling within 2–3 min, whereas VAMP8 controls a second prolonged phase that peaks at 4 min and slowly declines over 20 min to support the protracted secretory response. VAMP8^−/− acini show increased expression of the endosomal proteins Ti-VAMP7 (2-fold) and Rab11a (4-fold) and their redistribution from endosomes to ZGs. Expression of GDP-trapped Rab11a-S25N inhibited secretion exclusively from the VAMP8 but not the VAMP2 pathway. VAMP8^−/− acini also showed a >90% decrease in the early endosomal proteins Rab5/D52/EEA1, which control anterograde trafficking in the constitutive-like secretory pathway. In WT acini, short term (14–16 h) culture also results in a >90% decrease in Rab5/D52/EEA1 and a complete loss of the VAMP8 pathway, whereas VAMP2-secretion remains intact. Remarkably, rescue of Rab5/D52/EEA1 expression restored the VAMP8 pathway. Expressed D52 shows extensive colocalization with Rab11a and VAMP8 and partially copurifies with ZG fractions. These results indicate that robust trafficking within the constitutive-like secretory pathway is required for VAMP8- but not VAMP2-mediated ZG exocytosis.     

Ammonium chloride alters secretory protein sorting within the maturing exocrine storage compartment

Addition of 20 mM ammonium chloride during in vitro chase incubation of [35S]methionine pulse-labeled parotid tissue does not perturb the magnitude or radiochemical composition of secretion stimulated by isoproterenol. An apparent inhibition of stimulated output of radiolabeled secretory proteins that was observed when ammonium chloride was added immediately postpulse (but not at later time points prior to stimulation) could be accounted for by slowdown in Golgi transit of exocrine secretory protein at a stage prior to completion of terminal glycosylation. Thus, ammonium chloride does not block entry of newly synthesized secretory proteins into the secretagogue-releasable storage granule compartment. By contrast, ammonium chloride increases the output and substantially alters the relative composition of newly synthesized protein in unstimulated secretion. The latter effects could be assigned to stages of intracellular transport that normally occur at chase times greater than 60 min postpulse and thus are focused within the maturing acinar storage granule. Notably, the compositional alterations cannot reflect the preferential exocytosis of immature granules. Taken together, these results suggest that the sorting of exocrine secretory proteins into the secretagogue-regulated pathway may not involve positive selection by a pH-based process initiated in a pregranule compartment. Rather, unstimulated secretion may arise by a negative sorting (or exclusion) process that occurs during compaction of proteins for storage within maturing granules and that is perturbed by weak base addition. Sorted (or excluded) proteins would appear to follow the vesicular (nongranular) secretory pathway that originates in maturing granules (von Zastrow, M., and Castle, J.D. (1987) J. Cell Biol. 105, 2675-2684).     

Molecular genetics of regulated secretion in paramecium

Paramecium is a unicell in which cellular processes are amenable to genetic dissection. Regulated secretion, which designates a secretory pathway where secretory products are first stored in intracellular granules and then released by exocytotic membrane fusion upon external trigger, is an important function in Paramecium, involved in defensive response through the release of organelles called trichocysts. In this review, we focus on recent advances in the molecular genetics of two major aspects of the regulated pathway in Paramecium, the biogenesis of the secretory organelles and their exocytosis.     

Passive Sorting in Maturing Granules of AtT-20 Cells: The Entry and Exit of Salivary Amylase and Proline-rich Protein

Previous studies have suggested that salivary amylase and proline-rich protein are sorted differently when expressed in AtT-20 cells (Castle, A.M., L.E. Stahl, and J.D. Castle. 1992. J. Biol. Chem. 267:13093– 13100; Colomer, V., K. Lal, T.C. Hoops, and M.J. Rindler. 1994.EMBO (Eur. Mol. Biol. Organ.) J. 13:3711– 3719). We now show that both exocrine proteins behave similarly and enter the regulated secretory pathway as judged by immunolocalization and secretagogue- dependent stimulation of secretion. Analysis of stimulated secretion of newly synthesized proline-rich protein, amylase, and endogenous hormones indicates that the exogenous proteins enter the granule pool with about the same efficiency as the endogenous hormones. However, in contrast to the endogenous hormones, proline-rich protein and amylase are progressively removed from the granule pool during the process of granule maturation such that only small portions remain in mature granules where they colocalize with the stored hormones. The exogenous proteins that are not stored are recovered from the incubation medium and are presumed to have undergone constitutive-like secretion. These results point to a level of sorting for regulated secretion after entry of proteins into forming granules and indicate that retention is essential for efficient storage. Consequently, the critical role of putative sorting receptors for regulated secretion may be in retention rather than in granule entry.