Studies on proinsulin and proglucagon biosynthesis and conversion at the subcellular level: II. Distribution of radioactive peptide hormones and hormone precursors in subcellular fractions after pulse and pulse- chase incubation of islet tissue

Anglerfish proinsulin and insulin were selectively labeled with [(14)C]isoleucine, while proglucagon, conversion intermediate(s), and glucagon were selectively labeled with[(3)H]tryptophan. After various periods of continuous or pulse-chase incubation, islet tissue was subjected to subcellular fractionation. Fraction extracts were analyzed by gel filtration for their content of precursor, conversion intermediate(s), and product peptides. Of the seven subcellular fractions prepared after each incubation, only the microsome and secretory granule fractions yielded significant amounts of labeled insulin-related and glucagon-related peptides. After short-pulse incubations, levels of both [(14)C]proinsulin and [(3)H]proglucagon (mol wt approximately 12,000) were highest in the microsome fraction. This fraction is therefore identified as the site of synthesis. With increasing duration of continuous incubation or during chase incubation in the absence of isotopes, proinsulin, proglucagon, and conversion intermediate(s) are transported to secretory granules. Conversion of proinsulin to insulin and proglucagon to a approximately 4,900 mol wt conversion intermediate and 3,500 mol wt glucagon occurs in the secretory granules. Converting activity also was observed in the microsome fraction. The recovery of most of the incorporated radioactivity in microsome and secretory granule fractions indicates that the newly synthesized islet peptides are relegated to a membrane-bound state soon after synthesis at the RER is completed. This finding supports the concept of intracisternal sequestration and intragranular maintenance of peptides synthesized for export from the cell of origin.     

Proinsulin precursors in catfish pancreatic islets.

The purpose of these experiments was to determine whether insulin-related peptides, larger than proinsulin, could be detected in pancreatic islet cells. Catfish pancreatic islets were incubated with radiolabeled amino acids. After 15- to 60-min incubation, two acid-alcohol-extractable peptides, larger than proinsulin, were detected which were approximately of Mr = 12,000 and 11,000 (12 K and 11K, respectively). They migrated as single polypeptide chains by sodium dodecyl sulfate-urea polyacrylamide gel electrophoresis under reducing conditions, and were therefore not aggregates of insulin or proinsulin. The 12 K protein had identical mobility with catfish preoproinsulin synthesized in a wheat germ cell-free system. On standard electrophoresis at pH 8.9, the 12 K protein migrated separately from proinsulin and was at least 65% one protein with two to three minor contaminants. The 12 K and 11 K proteins were chemically related to insulin and proinsulin as shown by tryptic peptide analysis, using cation exchange resin chromatography, and by two-dimensional tryptic peptide maps. Analysis of the tryptic digest of the 12 K protein, compared to proinsulin after leucine aminopeptidase treatment, suggested that the NH2 terminus of the larger protein was different from that of proinsulin. These peptides were specifically bound to anti-insulin antibody. The binding was only 5 to 8% of the protein added, but was specific for the 12 K and 11 K proteins when the immunoprecipitates were examined by electrophoresis and not from contaminating proinsulin. During the continuous incubation of the islets with [3H]leucine, 12 K and 11 K proteins were synthesized in the cell before proinsulin. When islets were first incubated with [3H]leucine for 30 min followed by incubation with excess unlabeled leucine, the 12 K and 11 K proteins appeared to show a precursor-product relationship to proinsulin and insulin. Even when total islet protein synthesis was inhibited by cycloheximide (100 microgram/ml), proinsulin continued to be synthesized for up to 2 h. This suggested that the conversion of the proinsulin precursors to proinsulin in the fish is a post-translational event.     

The intracellular handling of insulin-related peptides in isolated pancreatic islets. Evidence for differential rates of degradation of insulin and C-peptide.

Islets of Langerhans isolated from adult rats were maintained in tissue culture for 3 days in the continued presence of [3H]leucine. Labelled proinsulin, C-peptide and insulin were measured by quantitative h.p.l.c., a method which also allowed for resolution of C-peptide I and II, and of insulin I and II (the products of the two rat insulin genes). The results showed that: (1) at early times, proinsulin was the major radiolabelled product; with progressive time in culture, intra-islet levels of [3H]proinsulin decreased, despite continuous labelling with [3H]leucine, indicating that the combined rates of proinsulin conversion into insulin and of proinsulin release, exceeded the rate of synthesis; (2) insulin I levels were always greater than those of insulin II, both in the islets and for products released to the medium; (3) the molar ratio of [3H]insulin I and II to their respective 3H-labelled C-peptides increased with time for products retained within islets, reaching a value close to 3:1 by 3 days; by contrast, for products released to the medium during the culture period, the ratio was always close to unity; (4) when islets were incubated with [3H]leucine for 2 days, and then left for a further 1 day without label (chase period), the intra-islet [3H]insulin/[3H]C-peptide ratios rose to values as high as 9:1. Again, for material released to the medium, the values were close to 1:1; (5) it is concluded that C-peptide is degraded more rapidly than insulin within islet cells, thereby accounting for the elevated insulin/C-peptide ratios. The difference between the ratios observed in the islets and those for material released to the medium is taken to indicate that degradation occurs in a discrete cellular compartment and not in the secretory granule itself.     

Proinsulin modified by analogues of arginine and lysine is degraded rapidly in pancreatic B-cells.

Modified cytosolic proteins are known to be degraded more rapidly than their native counterparts. In order to determine whether the same applies to a modified protein within the potentially protective environment of secretory granules, rat islets were labelled [( 3H]leucine) in the presence or absence (controls) of 3 mM-canavanine and 3 mM-thialysine (analogues of arginine and lysine respectively), followed by a 24h 'chase' period without analogues. The results showed the following. (1) Incorporation of the analogues into newly synthesized labelled proinsulin inhibited its conversion into insulin during the chase period. (2) Despite this block in conversion, the modified proinsulin was released from islets at the same rate as native proinsulin and insulin from control islets. (3) Morphometric analysis of high-resolution autoradiographs showed that products labelled in the presence of analogues were sequestered into secretory granules at the same rate as native products in control B-cells. (4) Only 7% of prelabelled proinsulin had been degraded within islet cells during the chase period in control islets, compared with 36% for proinsulin prelabelled in the presence of analogues. (5) Control experiments showed that the analogues had no effect on the release or intracellular degradation of unmodified stored insulin (present in islets before exposure to the analogues). (6) Despite sequestration into secretory granules, modified proinsulin, if not released from B-cells, is thus degraded more rapidly than native products.     

The effects of d- and l-glyceraldehyde on glucose oxidation, insulin secretion and insulin biosynthesis by pancreatic islets of the rat

d-glyceraldehyde stimulated insulin secretion from isolated rat pancreatic islets in static incubation and perifusion systems. At low concentrations (2–4 mM) d-glyceraldehyde was a more potent secretagogue than glucose. The insulinotropic action of 15 mM d-glyceraldehyde was not affected by d-mannoheptulose, was potentiated by cytochalasin B (5 μg/ml) and theophylline (4 mM), and was inhibited by both adrenalin (2 μM) and somatostatin (10 μg/ml). D-glyceraldehyde at a concentration of 1.5 mM produced a 10-fold increase of l-[4,5-³ H]leucine incorporation into proinsulin and insulin without a significant increase into other islet proteins. Glucose at 1.5 mM did not stimulate proinsulin biosynthesis. d-Glyceraldehyde at concentrations higher than 1.5 mM, in marked contrast to glucose, progressively inhibited incorporation of labelled leucine into proinsulin + insulin and other islet proteins. d-glyceraldehyde also inhibited the oxidation of glucose. l-Glyceraldehyde did not stimulate proinsulin biosynthesis and had less effect than the d-isomer on insulin release and glucose oxidation. The results strongly suggest that metabolites below d-glyceraldehyde-3-P are signals for insulin biosynthesisand release. Interaction of d-glyceraldehyde with a “membrane receptor” cannot, however, be excluded with certainty.     

Stimulation by ATP of proinsulin to insulin conversion in isolated rat pancreatic islet secretory granules. Association with the ATP-dependent proton pump

Isolated rat pancreatic islets were pulse-labeled for 5 min with [3H]leucine then chased for 25 min, during which time endogenously labeled [3H]proinsulin becomes predominantly compartmented in immature secretory granules. The islets were then homogenized in isotonic sucrose (pH 7.4) and a beta-granule preparation obtained by differential centrifugation and discontinuous sucrose gradient ultracentrifugation. This preparation was enriched 8-fold in beta-granules. Aside from contamination with mitochondria and a limited number of lysosomes, the beta-granule preparation was essentially free of any other organelles involved in proinsulin synthesis and packaging (i.e. microsomal elements and, more particularly, Golgi complex). Conversion of endogenously labeled [3H]proinsulin was followed in this beta-granule fraction for up to 2 h at 37 degrees C in a buffer (pH 7.3) that mimicked the cationic constituents of B-cell cytosol, during which time 92% of the beta-granules remained intact. Proinsulin conversion was analyzed by high performance liquid chromatography. The rate of proinsulin conversion to insulin was stimulated by 2.2 +/- 0.1-fold (n = 6) (at a 60-min incubation) in the presence of ATP (2 mM) and an ATP regenerating system compared to beta-granule preparations incubated without ATP. This ATP stimulation was abolished in the presence of beta-granule proton pump ATPase inhibitors (tributyltin, 2.5 microM, or 1,3-dicyclohexylcarbodiimide, 50 microM). Inhibitors of mitochondrial proton pump ATPases (sodium azide, 20 mM, or oligomycin, 10 micrograms/ml) had no effect on the ATP stimulation of proinsulin conversion. When granules were incubated in a more acidic buffer (pH 5.5), proinsulin conversion was increased relative to that at pH 7.3. At pH 5.5, ATP no longer stimulated conversion, and tributyltin and 1,3-dicyclohexylcarbodiimide had no effect. Disrupted granules only converted proinsulin to a limited extent, and neither ATP nor the inhibitors affected conversion. It is therefore suggested that ATP stimulation of proinsulin conversion in isolated, intact, beta-granules is secondary to intragranular acidification by an ATP-dependent proton pump (reflecting the low pH optimum for proinsulin conversion), rather than ATP dependence of converting activity per se.     

Stimulation of proinsulin biosynthesis and insulin release by pyruvate and lactate.

Increasing concentrations of pyruvate failed to stimulate proinsulin biosynthesis and insulin release in freshly isolated islets. Glycolytic flux (3H2O from [5-3H]glucose) decreased by 80-85%, but decarboxylation of [1(-14)C]pyruvate was unaffected in islets tested immediately after alloxan exposure. This strongly suggested that in freshly isolated islets, beta-cells, in relation to other islet cells, hardly contribute to the decarboxylation of pyruvate. Non-alloxan-treated cultured islets decarboxylated 2-2.5 times as much pyruvate as did alloxan-treated islets cultured for 15-18h. Thus the contribution of beta-cells to the metabolism of pyruvate after culturing markedly increased. Concomitantly beta-cells became responsive to pyruvate. At 20mM-pyruvate, release of prelabelled proinsulin and insulin and incorporation of [3H]leucine into proinsulin reached values approximately half of those obtained with 20mM-glucose. Lactate was as effective as pyruvate in inducing responses in cultured islets. The experiments indicate that a critical degree of substrate utilization is necessary for the generation of signals for insulin release and proinsulin biosynthesis.     

Studies on the induction and biosynthesis of vitellogenin, an oestrogen-induced glycolipophosphoprotein

1. Oestrogen treatment induces the formation of a Ca(2+)-binding glycolipophosphoprotein, vitellogenin, in Xenopus laevis. 2. The incorporation of l-[4,5-(3)H]-leucine into vitellogenin in vivo and in vitro was observed 12-24h after hormone treatment and increased progressively up to 21 days after treatment. 3. Vitellogenin is shown to be the major protein component biosynthesized and released into the incubation medium in vitro by livers from oestrogen-treated animals. 4. The biosynthesis in vitro of vitellogenin was inhibited by cycloheximide and carbonyl cyanide m-chlorophenylhydrazone, stimulated by increased Ca(2+) concentrations and decreased by raising the incubation temperature from 22 to 37 degrees C. 5. Incorporation of labelled amino acids into vitellogenin began after approx. 2h. No lag phase was noted for the incorporation of labelled amino acids into total tissue proteins. 6. The incorporation of label from [(32)P]phosphate and [2-(14)C]acetate into the protein as well as into the lipid moiety of vitellogenin showed a lag phase similar to that noted for the incorporation of amino acids. 7. These results suggest that the release of vitellogenin into the incubation medium occurs about 2h after the initiation of its biosynthesis.     

Effects of hormones on protein and amino acid metabolism in mammary-gland explants of mice.

The effects of insulin, cortisol and prolactin on amino acid uptake and protein biosynthesis were determined in mammary-gland explants from mid-pregnant mice. Insulin stimulated [3H]leucine incorporation into protein within 15 min of adding insulin to the incubation medium. Insulin also had a rapid stimulatory effect on the rate of aminoiso[14C]butyric acid uptake, but it had no effect on the intracellular accumulation of [3H]leucine. Cortisol inhibited the rate of [3H]leucine incorporation into protein during the initial 4h of incubation, but it had no effect at subsequent times. [3H]Leucine uptake was unaffected by cortisol, but amino[14C]isobutyric acid uptake was inhibited after a 4h exposure period to this hormone. Prolactin stimulated the rate of [3H]leucine incorporation into protein when tissues were exposed to this hormone for 4h or more; up to 4h, however, no effect of prolactin was detected. At all times tested, prolactin had no effect on the uptake of either amino[14C]isobutyric acid or [3H]leucine. Incubation with actinomycin D abolished the prolactin stimulation of protein biosynthesis, but this antibiotic did not affect the insulin response. A distinct difference in the mechanism of action of these hormones on protein biosynthesis in the mammary gland is thus apparent.     

Newly synthesized proinsulin/insulin and stored insulin are released from pancreatic B cells predominantly via a regulated, rather than a constitutive, pathway

The pancreatic B cell has been used as a model to compare the release of newly synthesized prohormone/hormone with that of stored hormone. Secretion of newly synthesized proinsulin/insulin (labeled with [3H]leucine during a 5-min pulse) and stored total immunoreactive insulin was monitored from isolated rat pancreatic islets at basal and stimulatory glucose concentrations over 180 min. By 180 min, 15% of the islet content of stored insulin was released at 16.7 mM glucose compared with 2% at 2.8 mM glucose. After a 30-min lag period, release of newly synthesized (labeled) proinsulin and insulin was detected; from 60 min onwards this release was stimulated up to 11-fold by 16.7 mM glucose. At 180 min, 60% of the initial islet content of labeled proinsulin was released at 16.7 mM glucose and 6% at 2.8 mM glucose. Specific radioactivity of the released newly synthesized hormone relative to that of material in islets indicated its preferential release. A similar degree of isotopic enrichment of released, labeled products was observed at both glucose concentrations. Quantitative HPLC analysis of labeled products indicated that glucose had no effect on intracellular proinsulin to insulin conversion; release of both newly synthesized proinsulin and insulin was sensitive to glucose stimulation; 90% of the newly synthesized hormone was released as insulin; and only 0.5% of proinsulin was rapidly released (between 30 and 60 min) in a glucose-independent fashion. It is thus concluded that the major portion of released hormone, whether old or new, processed or unprocessed, is directed through the regulated pathway, and therefore the small (less than 1%) amount released via a constitutive pathway cannot explain the preferential release of newly formed products from the B cell.     

Preparation of beta-cells from fetal bovine pancreas: characterization of insulin biosynthetic activity.

Dispersed cell preparations enriched in beta-cells were obtained by collagenase digestion of fetal bovine pancreas and separation by Ficoll gradient centrifugation. These cells actively incorporated [3H]leucine into proinsulin and insulin. Incubation of these cells in the presence of the arginine analogue, L-canavanine, resulted in the inhibition of conversion of newly formed proinsulin to insulin and the appearance of a radioactive component of molecular weight 11,000-12,000. Incorporation of [35S]methionine into this component was detected in the presence of canavanine, an event not observed in control incubation. Canavanine thus induced the formation of a component possessing molecular weight and compositional properties expected for preproinsulin. Further characterization of cellular products by polyacrylamide slab gel electrophoresis in sodium dodecyl sulfate showed a highly labeled band corresponding to molecular weight 18,000-20,000 which might be involved in insulin biosynthesis.     

Transglutaminase and cellular motile events: Retardation of proinsulin conversion by glycine methylester

Glycine methylester, an inhibitor of transglutaminase, decreased glucose-stimulated insulin release and delayed proinsulin conversion in rat pancreatic islets pulselabelle with L-[4-[³H]phenylalanine. Sarcosine methylester, which does not inhibit transglutaminase activity, failed to affect insulin release and proinsulin conversion. The incorporation of L-[4-³H]phenylalanine into islet peptides, the ratio of hormonal to total tritiated peptides and the insulin content of the islets failed to be affected by either of these methylesters. It is proposed that transglutaminase participates in the control of motile events involved in both the transfer of proinsulin from its site of synthesis to its site of conversion, and the translocation of insulin from its site of storage to its site of release.     

Differential effect of D-glucose anomers on proinsulin biosynthesis by the pancreatic islets.

Pancreatic islets of Langerhans of the rat were used to study effects of D-glucose anomers on the incorporation of [3H]leucine into proinsulin and other islet proteins. At low (1 mg/ml), but not at high (2 mg/ml) glucose concentration, the alpha-anomer stimulated more proinsulin biosynthesis than the beta-anomer. This observation adds to the growing list of islet functions showing anomeric preference for alpha-D-glucose.     

Studies on the assembly and secretion of a multicomponent protein. The biosynthesis of vitellogenin, an oestrogen-induced glycolipophosphoprotein

1. Incorporation of [(32)P]P(i) and [(3)H]leucine into vitellogenin secreted in vitro by liver slices from oestrogen-treated Xenopus laevis is accompanied by a 2h lag; no lag is apparent for the incorporation into total tissue protein. 2. The addition of cycloheximide was found immediately to inhibit further incorporation of radioactive leucine into total tissue protein. The incorporation into secreted vitellogenin, however, continued for 2h after the addition of cycloheximide. 3. Pulse-labelling of liver slices with [(3)H]leucine for 30min, followed by a chase with a large excess of unlabelled leucine, resulted in the appearance of radioactivity in secreted vitellogenin from 90min after the end of the pulse period. 4. Evidence is presented which suggests that of the radioactivity from [(3)H]leucine incorporated into proteins by the liver of oestrogen-treated Xenopus some 70% is present in the single protein vitellogenin. 5. The incorporation of [(32)P]P(i) into vitellogenin followed a pattern identical with that found for [(3)H]leucine in the pulse-labelling experiments and this indicates that synthesis of the polypeptide chain and incorporation of P(i) are closely linked processes. 6. The cumulative evidence suggests that the 2h lag phase represents the time required for the assembly and secretion of this multicomponent protein.     

Alterations in regulation of insulin biosynthesis in pregnancy and starvation studied in isolated rat islets of Langerhans

1. Insulin biosynthesis in isolated rat islets of Langerhans was determined by the incorporation of [(3)H]leucine into newly synthesized islet proteins. Anti-insulin serum covalently coupled to a solid phase (CNBr-activated Sepharose 4B) was used to separate the immunoreactive proinsulin and insulin from other islet proteins. This method was applied to a study of the regulation of insulin biosynthesis in isolated rat islets of Langerhans during pregnancy, and immediately after a period of food deprivation. 2. Islets isolated from pregnant rats showed an increased basal rate of synthesis compared with the non-pregnant controls. In addition, they showed a significant increase in biosynthesis of proinsulin and insulin in comparison with the normal islets over a range of glucose concentrations of 2-20mm. 3. Addition of the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine significantly increased the insulin-synthetic response of normal islets over the glucose range 5-20mm, so that their glucose response approached that of islets from pregnant rats. 4. Normal female rates were injected with a long-acting progesterone derivative (hydroxyprogesterone hexanoate), to investigate the role of progesterone on the increased insulin biosynthesis observed in islets in pregnancy. There appeared to be no marked difference in insulin biosynthesis between the islets from the progesterone-injected and control rats in the presence of 2mm- or 6mm-glucose alone. However, in the presence of 4mm- or 6mm-glucose and 3-isobutyl-1-methylxanthine there was a significant increase in insulin biosynthesis in the progesterone-treated animals. 5. Total islet protein biosynthesis was determined by the incorporation of [(3)H]leucine into trichloroacetic acid-precipitable islet proteins. Islets isolated from normal rats showed a 1.6-fold increase in incorporation over the glucose concentration range 2-20mm, and this value remained unchanged during starvation; however, rates of incorporation were significantly raised in islets isolated from pregnant rats in the presence of 20mm-glucose. 6. Islets from starved and fed control rats were incubated in the presence of increasing concentrations of glucose or glucose+3-isobutyl-1-methylxanthine. The islets isolated from the starved animals showed a diminished insulin-synthetic response to glucose as compared with the controls; this response was partially restored to normal values by elevation of cyclic AMP concentrations by using 3-isobutyl-1-methylxanthine. 7. It is suggested that the alterations in glucose-stimulated insulin biosynthesis observed in islets during pregnancy and after a period of starvation could be attributable, at least in part, to a long-term alteration of the cyclic AMP system, and in pregnancy to a direct or indirect effect of progesterone on beta-cell function.     

Reconstitution of ATP- and cytosol-dependent transport of de novo synthesized ceramide to the site of sphingomyelin synthesis in semi-intact cells

Transport of ceramide synthesized at the endoplasmic reticulum to the Golgi compartment, where sphingomyelin (SM) synthase exists, was reconstituted within semi-intact Chinese hamster ovary cells. When [(3)H]ceramide that had been produced from [(3)H]sphingosine at 15 degrees C in perforated cells was chased at 37 degrees C, [(3)H]ceramide-to-[(3)H]SM conversion occurred in a cytosol-dependent manner. In various aspects (i.e. kinetics, ATP dependence, and temperature dependence), [(3)H]ceramide-to-[(3)H]SM conversion in perforated cells was consistent with that in intact cells. The cytosol from LY-A strain, a Chinese hamster ovary cell mutant defective in endoplasmic reticulum-to-Golgi transport of ceramide, did not support [(3)H]ceramide-to-[(3)H]SM conversion in perforated wild-type cells, whereas the wild-type cytosol rescued the conversion in perforated LY-A cells. Brefeldin A-treated cells, in which the endoplasmic reticulum and the Golgi apparatus were merged, no longer required cytosol for conversion of [(3)H]ceramide to [(3)H]SM. These results indicated that the assay of [(3)H]ceramide-to-[(3)H]SM conversion in semi-intact cells is a faithful in vitro assay for the activity of cytosol-dependent transport of ceramide and that LY-A cells are defective in a cytosolic factor involved in ceramide transport. In addition, conversion of [(3)H]ceramide to [(3)H]glucosylceramide in semi-intact cells was little dependent on cytosol, suggesting that ceramide reached the site of glucosylceramide synthesis by a cytosol-independent (or less dependent) pathway.     

Semisynthetic human [[3H2]Phe1]proinsulin.

Biosynthetic human proinsulin (obtained by recombinant DNA techniques) was used as the starting material for the preparation, by semisynthetic methods, of [3H]proinsulin with the label at the N-terminal phenylalanine residue. The labelled proinsulin was characterized by its retention time on reversed-phase h.p.l.c., by polyacrylamide-gel electrophoresis, by the time course of its enzymic conversion into insulin and by chromatographic analysis after extensive proteolytic degradation. The specific radioactivity of the product was 5 Ci/mmol. Experimental details of the preparation of human [[3H]Phe1]proinsulin, the isolation of this product by isocratic h.p.l.c. and gel filtration, and further characterization of protein intermediates have been deposited as supplement SUP 50138 (12 pages) at the British Library Lending Division, Boston Spa, Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies can be obtained on prepayment [see Biochem. J. (1987) 241, 5].     

Proinsulin biosynthesis in broken-cell preparations of islets of Langerhans.

1. Rabbit islets of Langerhans were disrupted by ultrasonic methods and the sonicated preparations were used to study proinsulin biosynthesis. 2. When [3h]leucine is incubated in such preparations, incorporation takes place into proinsulin, as evidenced by characterization on polyacrylamide gels, and by the conversion of this labelled material into insulin, by using trypsin. 3. The labelled proinsulin may also be purified by antiinsulin antibody bound to Sepharose. 4. With the broken-cell preparation it was shown that incorporation of leucine is accelerated by increasing the glucose content of the medium from 2mM to 16mM. However, 16mM-galactose or -sucrose did not stimulate incorporation significantly from basal values. This effect of glucose was abolished by cycloheximide. 5. The significance of these findings in relation to the mechanism of glucose stimulation of proinsulin biosynthesis is discussed.     

Control of amylase biosynthesis and release in the parotid gland of the rat

1. Amylase biosynthesis and release in the rat parotid were studied under various conditions. Incorporation of [(3)H]leucine into amylase, extracted from the tissue by immunoadsorbent, was measured and found to be time-dependent and totally inhibited by the protein synthesis inhibitor puromycin. 2. Adrenaline, at a concentration (10mum) that gave maximum stimulation of release, inhibited [(3)H]leucine incorporation into both total protein and amylase. This effect was reversed by phentolamine. 3. Adrenaline (1mum) and isoproterenol (10mum) stimulated biosynthesis of total protein and amylase. These effects were blocked by propranolol, as were the effects on release. Dibutyryl cyclic AMP (2mm) mimicked the effects of isoproterenol and adrenaline (1mum) on both amylase biosynthesis and release. All the above stimulatory effects on amylase biosynthesis were only observed if the tissue was pretreated with effector before pulse-labelling with [(3)H]leucine. 4. Insulin (625muunits/ml initial concentration, 150muunits/ml final concentration) stimulated incorporation of [(3)H]leucine into total protein and amylase when added to the tissue at the same time as the leucine. 5. Carbamoylcholine (10mum) decreased [(3)H]leucine incorporation into total protein and amylase when both were added to the tissue simultaneously, but this effect was prevented by removal of effector and washing the tissue before addition of [(3)H]leucine. 6. Stimulation of beta-adrenergic receptors increased both amylase release and biosynthesis, but stimulation of alpha-receptors can inhibit biosynthesis without inhibiting release. Cholinergic agents can also inhibit amylase biosynthesis, but stimulate release. Insulin at approximately physiological concentration can increase incorporation of leucine into amylase without stimulating release. The system described therefore provides an excellent model for the further investigation of the mechanisms of these diverse effects.