Secretion of old versus new exportable protein in rat parotid slics. Control by neurotransmitters

The possibility that old and new secretory granules do not mix and that older exportable protein can be secreted preferentially was tested on parotid gland in vitro. Slices from fasted animals were pulse labeled for 3 min with L-[3H]leucine. Subcellular fractionstion showed that after 1 90-min chase period, the formation of new labeled secretory granules was mostly completed. The ratio of label in secretory granules to label in microsomes increased 250-fold during the period 5--90 min postpulse. After the 90-min chase, a submaximal rate of secretion was initiated by adding a low concentration of isoproterenol to the slices. Preferential secretion of old unlabeled exportable protein was evident from the finding that the percent of total amylase secreted was 3.5-fold greater than the percent of labeled protein secreted. Preferential secretion of old unlabeled exportable amylase was undiminished even when the chase period before addition of isoproterenol was extended to 240 min. Such long chase incubations were still meaningful due to the fact that the spontaneous rat of amylase release and radioactive protein release from the slices was negligibly low. A high isoproterenol concentration added to the slices after a 90-min chase produced the following results. An initial phase of preferential secretion of old unlabeled protein was soon replaced by secretion of a random mixture of new and old exportable protein. Electron micrographs indicated that high rates of secretion involved sequential fusion of secretory granules so that the lumen extended deep into the cell where the new labeled granules were presumably located. At low rates of secretion, the lumen showed no such deep extensions. Experiments were also conducted on slices from glands which had been largely depleted of old granules by prior injection of isoproterenol into the animals. Secretion of labeled protein from such slices stopped with the export of 80% of the labeled protein. This finding indicates that about 20% of the radioactive protein is cellular nonexportable protein and that the slices are capable of exporting the entire amount of secretory protein which was symthesized in vitrol. In addition to the beta-adrenergic receptor which mediates protein secretion, the parotid acinar cell also possesses an alpha-adrenergic and a cholinergic receptor both of which cause K+ release, vacuole formation, and water secretion. Activation of either of the latter two receptors in conjunction with the beta-adrenergic receptor increased randomization of the protein secreted. It is concluded that in the rat parotid acinar cell there is little spontaneous mixing between old granules near the luminal cell membrane and new granules coming up behind from the Golgi complex. The neurotransmitters which induce secretion produce the observed randomization.     

Evidence that amylase is released from two distinct pools of secretory proteins in the pancreas

Previous experiments demonstrated the existence of at least two pools of secretory proteins in the exocrine pancreas. We have measured the specific activities of amylase released under resting conditions and of amylase in the zymogen granules. Specific activity of resting secretion was twice that found under stimulated conditions or in zymogen granules. Secretory proteins were pulse-labeled and amylase was measured after precipitation of the enzyme with glycogen. Pancreatic juice collected at 45-50 min post-pulse contained 10-25-times the amylase activity found in zymogen granules. These results confirm the existence of at least two distinct pools of secretory proteins in the exocrine pancreas and suggest the existence of an intracellular route of secretory proteins which would bypass the zymogen granule compartment.     

Isoproterenol increases sorting of parotid gland cargo proteins to the basolateral pathway

Exocrine cells have an essential function of sorting secreted proteins into the correct secretory pathway. A clear understanding of sorting in salivary glands would contribute to the correct targeting of therapeutic transgenes. The present work investigated whether there is a change in the relative proportions of basic proline-rich protein (PRP) and acidic PRPs in secretory granules in response to chronic isoproterenol treatment, and whether this alters the sorting of endogenous cargo proteins. Immunoblot analysis of secretory granules from rat parotids found a large increase of basic PRP over acidic PRPs in response to chronic isoproterenol treatment. Pulse chase experiments demonstrated that isoproterenol also decreased regulated secretion of newly synthesized secretory proteins, including PRPs, amylase and parotid secretory protein. This decreased efficiency of the apical regulated pathway may be mediated by alkalization of the secretory granules since it was reversed by treatment with mild acid. We also investigated changes in secretion through the basolateral (endocrine) pathways. A significant increase in parotid secretory protein and salivary amylase was detected in sera of isoproterenol-treated animals, suggesting increased routing of the regulated secretory proteins to the basolateral pathway. These studies demonstrate that shifts of endogenous proteins can modulate regulated secretion and sorting of cargo proteins. amylase; parotid secretory protein; polarized secretion     

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).     

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.     

Changes in the dynamics of luteinizing hormone-releasing hormone-stimulated secretion of luteinizing hormone during sexual maturation of female rats

Our aim was to identify age-related changes in the dynamics of luteinizing hormone (LH) release that may contribute to the decline in pituitary sensitivity to luteinizing hormone-releasing hormone (LHRH) during sexual maturation of female rats. We studied LHRH-stimulated LH secretion curves of superfused pituitaries from rats ranging in age from 10 days to the first estrous cycle. Pituitary fragments were exposed for 10 min to medium alone or to medium plus LHRH; incubation continued in medium alone for 130 min and effluent was collected for LH analysis. Secretion curves were compared on the basis of total secretion (area under the curve), maximal change in LH secretion rate, and rates of rise and decay of the curves. The data show that total LH secretion in response to LHRH is greatest in 15-, 20-day-old and first-proestrus animals. Also, the maximal change in LH secretion rate was greater, and the increase in LH secretion rate faster in younger animals than in 30-day-old animals. Analysis of secretory granules in LH-containing gonadotropes of 15- and 30-day-old animals revealed changes in he granule population with age. We conclude that younger animals respond faster with a greater LH secretion response to LHRH than do 30-day-old or first-estrus animals, and that these age-related changes in the dynamics of LH secretion may be due in part to maturation of the LH secretory granules.     

Immunocytochemical localization of amylase in the parotid gland of developing and adult rats

An antiserum against purified rat parotid amylase was used to localize the protein in parotid glands of developing and adult rats. The unlabeled antibody peroxidase-antiperoxidase method and the protein A-gold colloid technique were used at the light and electron microscope levels, respectively. Immunoreactive amylase was detected in a few scattered cells in the glands of 2-day-old rats. During the following days the number of cells stained immunocytochemically for amylase increased rapidly; at 15 days of age all acinar cells revealed amylase, but the intensity of immunostaining varied from cell to cell. Electron microscopically, amylase was localized in the secretory granules, and by using a more concentrated antiserum, in the rough endoplasmic reticulum and Golgi complex. At early stages of development the acinar cells contained fewer and smaller secretory granules than in adult animals; the gold particles indicative of amylase were randomly distributed over the secretory granules. In the glands of adult rats, amylase was distributed inhomogeneously within the secretory granules. In the majority of secretory granules gold colloid particles were located over the electron-dense portions of the granules. However, secretory granules in which an amylase-rich shell surrounded an amylase-poor or amylase-negative "core" were not infrequent.     

Secretion granules of the rabbit parotid gland. Isolation, subfractionation, and characterization of the membrane and content subfractions.

A fraction of secretion granules has been isolated from rabbit parotid by a procedure which was found to be especially effective in reducing contamination resulting from aggregation and/or cosedimentation of granules with other cell particulates. The fraction, representing 15 percent (on the average) of the total tissue amylase activity, was homogeneous as judged by electron microscopy and contaminated to exceedingly low levels by other cellular organelles as judged by marker enzymatic and chemical assays. Lysis of the granules was achieved by their gradual exposure to hypotonic NaHCO3, containing 0.5 mM EDTA. The content and the membranes separated by centrifugation of the granule lysate were characterized primarily by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis which indicated that the content was composed of a limited number of molecular weight classes of polypeptides of which three bands (having approximate mol wt 58,000, 33, 000, and 12,000) could be considered major components. The gel profile of the membrane subfraction was characterized by 20-30 Coomassie brilliant blue-staining bands of which a single species of mol wt 40,000 was the conspicuous major polypeptide. Two types of experiments employing gel electrophoretic analysis were carried out for identifying and assessing the extent of residual secretory protein adsorbed to purified granule membranes: (a) examination of staining and radioactivity profiles after mixing of radioactive secretion granule extract with nonradioactively labeled granule membranes and (b) comparison of gel profiles of secretion granule extract and granule membranes with those of unlysed secretion granules and secretory protein dischraged from lobules in vitro or collected by cannulation of parotid ducts, the last two samples being considered physiologic secretory standards. The results indicated that the membranes were contaminated to a substantial degree by residual, poorly extractable secretory protein even though assays of membrane fractions for a typical secretory enzyme activity (amylase) indicated quite through separation of membranes and content. Hence, detailed examination of membrane subfractions for residual content species by gel electrophoresis points to the general unity and sensitivity of this technique as a means for accurately detecting a defined set of polypeptides occurring as contaminants in cellular fractions or organelle subfractions.     

Microtubules and protein secretion in rat lacrimal glands: localization of short-term effects of colchicine on the secretory process

The pathway and kinetics of the secretory protein transport in rat lacrimal exorbital gland have been established by an in vitro time- course radioautographic study of pulse-labeled protein secretion. The colchicine-sensitive steps have been localized by using the drug at various times with respect to the pulse labeling of proteins. Colchicine (10 microM) does not block any step of the secretory protein transport, but when introduced before the pulse it decreases the transfer of labeled proteins from the rough endoplasmic reticulum to the Golgi area, suppressing their temporary accumulation in the Golgi area before any alteration of this organelle is detectable. Moreover, colchicine inhibits protein release only from the secretory granules formed in its presence because the peroxidase discharge is diminished 1 h after colchicine addition, and the secretion of newly synthesized proteins is strongly inhibited only when colchicine is introduced before secretory granule formation. Morphometric studies show that there is a great increase of secondary lysosomes, related to crinophagy, as early as 40-50 min after colchicine is added. However, changes in lysosomal enzymatic activities remained biochemically undetectable. We conclude that: (a) the labile microtubular system does not seem indispensable for protein transport in the rough endoplasmic reticulum-Golgi area but may facilitate this step, perhaps by maintaining the spatial organization of this area; and (b) in the lacrimal gland, colchicine inhibits protein release not by acting on the steps of secretion following the secretory granule formation, but by acting chiefly on the steps preceding secretory granule formation, perhaps by making the secretory granules formed in its presence incapable of discharging their content.     

Multiple effects of Na+ removal on pancreatic secretion in vitro

Summary The effects of removing Na⁺ from the incubation medium on basal and secretagogue induced zymogen release by pancreatic fragments and isolated pancreatic acini were studied by both morphological evaluation and measurement of amylase release. In both fragments and isolated acini, removal of Na⁺ led to an increased basal secretion of zymogen granule contents from acinar cells via exocytosis; secretory material, however, accumulated in acinar and ductular lumina as a result of the lack of fluid secretion necessary to wash out the enzymes. In studies with fragments, after Na⁺ removal there was no significant increase in amylase release into the medium; isolated acini, in contrast, showed an increased amylase release consistent with the shorter distance from the acinar lumen to the bathing medium. Stimulation with either bethanechol or caerulein led to a further depletion of zymogen granules in both preparations; in the absence of Na⁺ secretory product accumulated in intracellular lakes as well as in duct lumens. The hypothesis that Na⁺ influx is important in stimulus-secretion coupling to release intracellular Ca²⁺ was directly tested by measuring ⁴⁵Ca²⁺ efflux. No effect of removing Na⁺ on ⁴⁵Ca²⁺ efflux was seen. It was concluded, therefore, that while Na⁺ is essential for pancreatic fluid secretion, it is not necessary for the secretion of zymogen granule contents into acinar lumina.Supported by NIH grant GM-19998 from the United States Public Health Service     

Secretion of C-reactive protein becomes more efficient during the course of the acute phase response

We studied the kinetics of synthesis and secretion of the acute phase plasma protein, C-reactive protein, in primary hepatocyte cultures prepared from rabbits manifesting differing degrees of the acute phase response to inflammatory stimulus. In cultures prepared from progressively more responsive animals, rate of C-reactive protein secretion increased to a much greater degree than did intracellular C-reactive protein content, resulting in a progressive decrease in the ratio of intracellular content to rate of secretion. This ratio, which represents the time required to secrete the amount of C-reactive protein contained within the intracellular pool, decreased from 18 h in cultures from unstimulated rabbits to 2.5 h in cells from highly responsive animals. In contrast, these ratios for albumin were short and fell within a narrow range (0.8-2.1 h). In pulse-chase labeling experiments, the time required for secretion of 50% of pulse-labeled C-reactive protein varied markedly, ranging from well over 6 h in cells from a minimally responsive animal to about 75 min in cells from a highly responsive rabbit. In contrast, the half-time for secretion of albumin was consistently about 45 min in the same cultures. Taken together, these findings indicate that the process by which C-reactive protein is secreted becomes more efficient during the course of the acute phase response. Recent studies have indicated that secretory proteins pass from the rough endoplasmic reticulum to Golgi at different and characteristic rates, possibly by a receptor-mediated process in which rate of transfer is determined by receptor affinity. We postulate that C-reactive protein secretion is regulated, during the course of the acute phase response, either by alterations in availability of specific receptors or by competition between different secretory proteins for a common receptor.     

Caerulein-induced acute pancreatitis in the rat. Pancreatic secretory response to cholecystokinin.

The response of pancreatic exocrine secretion to cholecystokinin (CCK), has been studied in experimental acute pancreatitis induced in rats by supramaximal doses of caerulein. Several doses of caerulein were used (4, 20 and 40 micrograms/Kg) and each one was administered by four subcutaneous injections over 3 h at hourly intervals. Pancreatic juice was collected 9 h after the first injection. The caerulein-treated animals showed a statistically significant increase in serum amylase levels. Secretory activity of ductular cells remained unchanged in all the caerulein-treated animals, but total protein and amylase secretion decreased significantly at all the caerulein doses used, both in resting conditions and under stimulation with CCK (1.25 micrograms/Kg/h). Despite this the acinar cells of rats treated with the lowest dose of caerulein retained a certain degree of secretory function since amylase activity in pancreatic juice was greater than in other groups of rats treated with higher doses of caerulein. Moreover, the percentage of increase observed in total protein and amylase in response to CCK respect to basal secretion is similar to that of the untreated animals. At higher doses (20 and 40 micrograms/Kg) the secretory capacity in response to CCK was inhibited. Therefore CCK administration in slight acute pancreatitis could be used as a therapy since it favours the secretion of pancreatic enzymes at percentual levels similar to those of the controls.     

Protein sorting among two distinct export pathways occurs from the content of maturing exocrine storage granules

We have developed a method for separating purified parotid secretory granules according to their degree of maturation, and we have used this method to examine the relationship between granule formation and stimulus-independent (constitutive) protein secretion. Constitutive export of pulse-labeled secretory proteins occurs almost entirely after their appearance in newly formed granules, and this secretion can be resolved kinetically into two distinct components. Later-phase secretion is the more prominent component and, according to kinetic and compositional criteria, appears to result from basal exocytosis of mature granules. In contrast, early-phase secretion (1.5-15% of constitutive protein output) appears to originate from maturing granules but differs significantly from granule content in composition; that is, the early component exports individual protein species in different relative amounts. Maturing granules, which are labeled most highly before and during the appearance of early-phase secretion, possess numerous coated membrane evaginations suggestive of vesicular traffic. We propose that, in addition to basal exocytosis of relatively mature granules, constitutive exocrine secretion results from limited, selective removal of content proteins from forming and maturing granules. Thus protein sorting and packaging occur together in granule compartments. Exocrine secretory granules constitute an extension of the post-Golgi sorting system and are not merely terminal depots for proximally targeted polypeptides.     

Glycoprotein transport in the surface mucous cells of the rat stomach

The intracellular transport of glycoproteins pulse-labeled in vitro with tritiated leucine and galactose in the surface mucous lining cells (SMC) of the fundus of the rat stomach was studied by electron microscope autoradiography. The SMC survive for several hours in pieces of the fundus incubated in a bicarbonate-buffered medium. The SMC have a normal ultrastructure for at least 4 h of incubation. Kinetic activity is normal for at least 5 h, as demonstrated by the normal nuclear incorporation of tritiated thymidine; The SMC incorporate labeled leucine and galactose at normal rates up to 4 h and 6 h, respectively. In contrast to the SMC, the cells of the gastric glands show signs of degeneration within 1 h after the start of incubation. In the SMC the secretory protein forms a smaller part of the total protein synthesized than in other secretory cells studied. The intracellular tranpsort of the leucine-labeled moiety of the glycoproteins follows the normal pathway. The RER loses 35% of its transportable labeled protein within 30 min. The Golgi complex is maximally labeled at 40 min and the mucous granules after 120 min. Galactose is attached to the glycoproteins mainly in the Golgi complex. Glycoproteins are not secreted within 2 h after synthesis of their protein moiety.     

UNSTIMULATED SECRETION OF PROTEIN FROM RAT EXOCRINE PANCREAS CELLS

Our earlier work demonstrated that the rate of protein synthesis in the exocrine cells of the rat pancreas is constant in different physiological states, including prolonged fasting. In this study we have followed the fate of the protein in the pancreatic cells of the fasting animal in vivo as well as in vitro. The data were obtained by quantitative radioautography and by biochemical determinations. In nonanesthesized, fasting rats, without cannulated pancreatic duct, some 80% of the proteins synthesized at a given time leaves the cell within 12 hr by way of secretion, intracellular breakdown not being important. Two mechanisms of fasting secretion exist. The first, starting at a slow rate after 20 min, is inferred to result from fortuitous contacts of young secretory granules with the apical cell membrane. The rate of secretion is the same in vivo as in vitro, at least during the first 4 hr after pulse labeling. Within 7 hr about 20% of the total amount of newly synthesized protein has left the cell. The second mechanism consists of an orderly movement of the mass of secretory granules towards the apical cell membrane as caused by the continuous assembly of new granules. The granules that come into contact with the cell membrane are discharged. It takes about 7–12 hr for secretory protein transported in this way to reach the cell membrane. The addition of new secretory granules to those present is essential for the second mechanism, for the blockade of protein synthesis by cycloheximide decreases the rate of this phase of secretion without interfering with the secretory process proper. Atropin does not inhibit the fasting secretion in vitro, nor does extensive washing of the tissue slices, excluding possible secretagogues as important factors in fasting secretion.     

Changes in parotid acinar cells accompanying salivary secretion in rats on sympathetic or parasympathetic nerve stimulation

Morphological and secretory effects of stimulating autonomic nerves have been studied in parotid glands of rats. Sympathetic stimulation evoked a slow flow of saliva which had a high concentration of amylase. After long term sympathetic stimulation secretory granules were heavily depleted from the parotid acinar cells. Parasympathetic stimulation evoked a copious flow of saliva with a low concentration of amylase. However, at high frequency stimulation the total amount of amylase secreted on parasympathetic stimulation was as great or even greater than on symphatetic stimulation, nevertheless, any loss of secretory granules from the acinar cells was very small. It is concluded that secretion of parotid acinar granules in the rat is prinicipally a sympathetic function. Secretion of fluid is more effectively produced by parasympathetic stimulation and much of the amylase in such saliva appears to have arisen from sources other than the 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.     

Effects of GP2 expression on secretion and endocytosis in pancreatic AR4-2J cells

GP2 is the major membrane protein present in secretory granules of the exocrine pancreas. GP2's function is unknown, but a role in digestive enzyme packaging or secretion from secretory granules has been proposed. In addition, GP2 has been proposed to influence endocytosis and membrane recycling following stimulated secretion. Adenovirus-mediated GP2 overexpression in the rat pancreatic cell line AR4-2J was used to study its impact on digestive enzyme secretion and membrane recycling. Immunoelectron microscopy showed that GP2 and amylase co-localized in secretory granules in infected AR4-2J cells. CCK-8 stimulation resulted in a fourfold increase in amylase secretion with or without GP2 expression. GP2 expression also did not influence endocytosis following CCK-8 stimulation. Thus, GP2 expression in AR4-2J cells does not affect amylase packaging in secretory granules or stimulated secretion. GP2 expression also does not influence membrane recycling in response to stimulated stimulation in AR4-2J cells.     

Neurotensin modulates the composition of pancreatic exocrine secretions in chickens

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

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.