Endothelial cell signalling supports pancreatic beta cell function in the rat.

AIMS/HYPOTHESIS: The proximity of endothelial cells and beta cells in islets by necessity means that they are exposed to each other's products. Whereas islet endothelial cells require signals from beta cells to function properly, endothelin-1, thrombospondin-1 and laminins, among others, have been identified as endothelial-derived molecules, although their full effects on beta cells have not been explored. We tested the hypothesis that islet endothelial-derived products affect beta cell function. METHODS: Endothelial cells from rat islets were proliferated and purified. Endothelium-conditioned culture medium (ECCM) was obtained by maintaining the endothelial cells in culture medium. Islet function was evaluated following exposure of cultured islets to standard culture medium or ECCM. Changes in mRNA levels for key beta cell metabolic enzymes were also measured in islets after ECCM exposure. RESULTS: Glucose-stimulated insulin release and islet insulin content were markedly enhanced by exposure to ECCM. This was at least partly explained by improved mitochondrial function, as assessed by glucose oxidation and an upregulation of the mitochondrial gene for glycerol-3-phosphate dehydrogenase (mGpdh [also known as Gpd2]), combined with upregulation of the rate-limiting enzyme in the glycolysis, glucokinase, in the islets. The intracellular degradation of insulin was also decreased in the islets. Islet endothelial cells produced laminins, and the positive effects of islet endothelial cells were prevented by addition of a neutralising antibody to the beta1-chain of laminin. Addition of exogenous laminin stimulated islet function. CONCLUSIONS/INTERPRETATION: This study provides proof of principle that endothelial cells can affect the function of beta cells in their vicinity and that this is at least partially mediated by laminins.

Impairment of glucose-induced insulin secretion in human pancreatic islets transplanted to diabetic nude mice.

Hyperglycemia-induced beta-cell dysfunction may be an important component in the pathogenesis of non-insulin-dependent diabetes mellitus. However, most available data in this field were obtained from rodent islets. To investigate the relevance of this hypothesis for human beta-cells in vivo, human pancreatic islets were transplanted under the renal capsule of nude mice. Experimental groups were chosen so that grafted islets were exposed to either hyper- or normoglycemia or combinations of these for 4 or 6 wk. Grafts of normoglycemic recipients responded with an increased insulin release to a glucose stimulus during perfusion, whereas grafts of hyperglycemic recipients failed to respond to glucose. The insulin content of the grafts in the latter groups was only 10% of those observed in controls. Recipients initially hyperglycemic (4 wk), followed by 2 wk of normoglycemia regained a normal graft insulin content, but a decreased insulin response to glucose remained. No ultrastructural signs of beta-cell damage were observed, with the exception of increased glycogen deposits in animals hyperglycemic at the time of killing. It is concluded that prolonged exposure to a diabetic environment induces a long-term secretory defect in human beta-cells, which is not dependent on the size of the islet insulin stores.

Steroid effects on intracellular degradation of insulin and crinophagy in isolated pancreatic islets.

Under physiological conditions substantial amounts of hormone may be degraded within endocrine cells by a crinophagic process comprising fusions of secretory granules with lysosomes. Glucocorticoids may stabilise and progesterone destabilise lysosomal membranes. The effects of corticosterone and progesterone on intracellular degradation of insulin and crinophagy were determined in pancreatic beta-cells, and possible pathways mediating these effects were evaluated. Pancreatic islets were isolated from mice, intracellular degradation of insulin was measured by a pulse-chase method, and crinophagy was studied by electron microscopy. The islets were exposed to 3.3, 5.5 or 28 mM glucose with or without corticosterone, progesterone or the receptor ligands A-224817.0 and WAY-161358. Mifepristone was used to block steroid receptors and indomethacin to inhibit prostaglandin synthesis. Corticosterone caused a concentration-dependent decrease of insulin degradation at the lower glucose concentrations. Progesterone effected a concentration-dependent stimulation of insulin degradation. These results were paralleled with changes of the crinophagic activity in the beta-cells. Corticosterone decreased and progesterone increased islet production of prostaglandin E(2). Mifepristone abolished the steroid actions on insulin degradation and prostaglandin production. The effects of corticosterone were mimicked by the selective glucocorticoid receptor modulator A-224817.0, but in contrast to progesterone, the selective progesterone receptor agonist WAY-161358 had no effect on insulin degradation or prostaglandin production. Inhibition of cyclooxygenase blocked insulin degradation. The findings indicate that both corticosterone and progesterone could affect intracellular insulin degradation and crinophagy solely via the glucocorticoid receptor, and that prostaglandins may have a regulatory role in intracellular turnover of secretory material in pancreatic islet beta-cells.

Increased susceptibility to phenytoin teratogenicity: excessive generation of reactive oxygen species or impaired antioxidant defense?

Phenytoin is a human and animal teratogen. Accumulating evidence suggests that the teratogenicity is associated with a potential of phenytoin to cause embryonic cardiac arrhythmia and resultant generation of toxic reactive oxygen species via hypoxia-reoxygenation mechanisms. The A/J mouse is more susceptible to phenytoin teratogenicity than other mouse strains. The aim of this study was to investigate whether A/J mice have other antioxidant enzyme activities than C57BL/6J and CD-1 mice. Also, strain differences in phenytoin effects on embryonic heart rate and rhythm were determined. Another objective was to determine whether a spin trapping agent with capacity to capture reactive oxygen species alter the developmental toxicity of phenytoin. Treatment with this agent resulted in a marked decrease in phenytoin teratogenicity, which supports the idea that reactive oxygen species are important mediators for the teratogenic action of phenytoin. The A/J mice embryos were most susceptible to the adverse cardiac effects of phenytoin and had the highest activity of superoxide dismutase and glutathione peroxidase, while the activity of catalase was the same in embryos of the three different strains. The high activities of antioxidant enzymes in the A/J stain indicate that the sensitivity to develop malformations is caused by excessive arrhythmia-related generation of reactive oxygen species rather than impaired antioxidant defense.

Effects of alloxan on the islets of Langerhans: inhibition of leucine metabolism and insulin secretion.

The action of alloxan on the metabolism of the islets of Langerhans was studied in vitro. Isolated mouse islets were exposed to the drug at 4 degrees C to prevent its decomposition. Islet uptake of leucine was subsequently estimated at 37 degrees C, and was found not to be affected by the drug. However, islet leucine oxidation was strongly inhibited by the preceding alloxan exposure. The islets were protected against this inhibition by an incubation at a high glucose concentration prior to alloxan exposure. In contrast, a high concentration of leucine failed to provide full protection of either islet leucine oxidation or islet glucose oxidation. Furthermore, it was shown that alloxan impeded islet insulin response to both leucine and glucose. In addition, the potentiation of insulin release by theophylline was abolished after alloxan treatment of the islets. The results reinforce the hypothesis that the B-cytotoxicity of alloxan reflects an interaction with intracellular sites involved in the oxidative metabolism of the B-cell, and that these sites may be protected against the action of the drug by some metabolite of glucose.

Diabetes and embryonic malformations. Role of substrate-induced free-oxygen radical production for dysmorphogenesis in cultured rat embryos.

The aim of this study was to evaluate the role of free-oxygen radicals in the embryonic maldevelopment of diabetic pregnancy. Rat embryos cultured in vitro during early organogenesis showed growth retardation and severe malformations after exposure to 50 mM glucose, 3 mM PYR, 10 mM HBT, or 3 mM KIC. Combinations of 25 mM glucose, 2.5 mM HBT, and 1 mM KIC also elicited embryonic growth retardation and malformations. The deleterious effects on embryonic development by all agents were alleviated by addition of SOD to the culture media, which yielded increased enzyme activity in the embryos and their membranes. The endogenous SOD activity also increased in embryos subjected to a high concentration of glucose or PYR in the culture medium. Addition of the mitochondrial PYR transport inhibitor CHC to the culture media blocked the dysmorphogenesis caused by glucose and PYR, but was without effect on the teratogenic actions of HBT and KIC. These findings implicate the embryonic mitochondria as a likely site for enhanced substrate-induced production of free-oxygen radicals mediating the teratogenic effect of a diabetic environment. In particular, the teratogenic process in diabetic pregnancy may depend on an increased production of free-oxygen radicals in immature embryonic mitochondria in response to a metabolic overload. This notion implies that every oxidative substrate entering the mitochondrial metabolism in excess may induce embryonic malformations and emphasizes the need for an extended metabolic surveillance of pregnant diabetic women. Consequently, optimal metabolic control should aim at normalizing the maternal serum concentrations of all possible oxidative substrates.

Lysosomes and pancreatic islet function. Time course of insulin biosynthesis, insulin secretion, and lysosomal transformation after rapid changes in glucose concentration.

The aim of this study was to estimate the time course of lysosomal transformations associated with crinophagy, i.e., the degradation of insulin within lysosomes, in the beta-cells of pancreatic islets. Primary and secondary lysosomes were identified in mouse islet beta-cells and subjected to ultrastructural morphometry. Islets from an in situ preparation were compared with isolated islets incubated in vitro. Under the in vitro conditions, the islets were initially exposed to 28 or 3.3 mM glucose for 24 h. Then the glucose concentration was rapidly changed to 3.3 and 28 mM glucose, respectively, and the islets were incubated for up to an additional 24 h. The beta-cell lysosomes were analyzed and related to alterations in insulin biosynthesis and secretion and islet insulin content after the rapid change in glucose concentration. In vivo, the beta-cell lysosomal population was predominantly composed of secondary lysosomes, which frequently contained secretory granule cores. After the initial 24-h period at 3.3 mM glucose, the volume density and the average volume of the secondary beta-cell lysosomes were increased, suggesting increased crinophagic activity. The mean diameter of the primary beta-cell lysosomes was decreased after 24 h at either 28 or 3.3 mM glucose. The change in glucose from 28 to 3.3 mM resulted in alterations in insulin biosynthesis and secretion, leading to an accumulation of insulin within the beta-cells. Lysosomal transformations suggestive of increased crinophagy were observed 24 h after the alteration in glucose concentration. The change from 3.3 to 28 mM glucose resulted in a parallel increase in insulin biosynthesis and secretion without a change in islet insulin content.(ABSTRACT TRUNCATED AT 250 WORDS)

Diabetic embryopathy. Studies with animal and in vitro models.

Diabetic pregnancy is associated with an increased risk for fetal maldevelopment for a largely unknown reason. A decade ago, Norbert Freinkel suggested that the altered fuel mixture offered to the growing conceptus may be the key to most of the changes in the embryogenesis of diabetic pregnancy. He coined the term fuel-mediated teratogenesis. During early pregnancy, periods of maternal hyper- and hypoglycemia may cause marked changes in the availability of glucose to the conceptus. Also, increased concentrations of lipids, notably ketone bodies, and branched-chain amino acids in the maternal circulation contribute to a changed fuel mixture for the embryo. In a recent experimental study of diabetic rats, it was found that the maternal metabolism of all three major classes of nutrients and maternal somatic growth during gestation covaried with the development of the embryo. Consequently, the maintenance of normal concentrations of metabolites from all nutrient classes may be important for prevention of adverse fetal outcome in diabetic pregnancy. In vitro, a high glucose concentration causes embryonic dysmorphogenesis by generation of free oxygen radicals. An enhanced production of such radicals in embryonic tissues may be directly related to an increased risk of congenital malformations in diabetic pregnancy. Thus, the notion that alterations in the net transfer of cellular fuels from the diabetic mother to her offspring may cause embryonic dysmorphogenesis, which suggests that combustion of the fuel may produce compounds that impair embryonic development, has obtained experimental support. If this is also true for human diabetic pregnancy, it has therapeutic implications.

The pseudotetrasaccharide acarbose inhibits pancreatic islet glucan-1,4-alpha-glucosidase activity in parallel with a suppressive action on glucose-induced insulin release.

The pseudotetrasaccharide acarbose, previously known as a potent inhibitor of intestinal alpha-glucoside hydrolases, was investigated with regard to its influence on islet lysosomal enzyme activities and the insulin secretory processes. We observed that acarbose was a potent inhibitor of mouse islet lysosomal acid glucan-1,4-alpha-glucosidase activity, EC50 approximately 5 mumol/l, as well as of acid alpha-glucosidase activity. In contrast, acarbose did not influence other lysosomal enzyme activities such as acid phosphatase and N-acetyl-beta-D-glucosaminidase. Neutral alpha-glucosidase (endoplasmic reticulum) was only moderately inhibited in homogenate and was unaffected in intact islets. Incubation of isolated mouse islets with acarbose revealed that the pseudotetrasaccharide was a strong inhibitor of glucose-induced insulin secretion, EC50 approximately 500 nmol/l, and a significant inhibition was already observed at a concentration of acarbose as low as 100 nmol/l. The acarbose analogue maltotetrose did not influence either glucose-induced insulin release or islet lysosomal enzyme activities. Further, acarbose as well as two other alpha-glucoside hydrolase inhibitors, the deoxynojirimycin derivatives miglitol and emiglitate, did not affect islet glucose oxidation at low or high glucose levels. Acarbose also inhibited insulin release induced by the sulfonylurea glibenclamide, whereas insulin secretion stimulated by the cholinergic muscarinic agonist carbachol or the phosphodiesterase inhibitor isobutylmethylxanthine was unaffected by the drug. Moreover, complementary in vivo experiments showed that pretreatment of mice with acarbose to allow for endocytosis of the compound markedly suppressed the insulin secretory response to an intravenous glucose load.(ABSTRACT TRUNCATED AT 250 WORDS)

Alterations in net glucose uptake and in the pancreatic B-cell GLUT2 transporter induced by diazoxide and by secretory stimuli.

The pancreatic B-cell GLUT2 transporter and glucose metabolism were examined in isolated rat islets subjected to treatments affecting insulin secretion. Diazoxide was used to inhibit, while glipizide or depolarization of the plasma membrane with a high extracellular K(+) concentration were used to stimulate insulin release in short-term experiments. Islet GLUT2 and insulin were determined by quantitative immunohistochemistry and GLUT2 was also determined by Western blot analysis. Islet net glucose uptake and glucose oxidation were measured using radioactively labelled glucose. Exposure of the islets to diazoxide was associated with a marked increase in the B-cell plasma membrane staining for GLUT2 and increased net glucose uptake. Glucose oxidation was not changed, which may reflect a lowered energy requirement. Conversely, islets subjected to a stimulated insulin secretion with glipizide or a high extracellular K(+) concentration showed a reduced staining of the GLUT2 transporter. The net glucose uptake and glucose oxidation were also reduced. In islets exposed to the high K(+) concentration no change in the molecular weight or phosphorylation of GLUT2 was observed but a lesser amount of the transporter was found by Western blot analysis. Thus, GLUT2 and glucose uptake in the pancreatic B-cell are modified by the secretory process, which suggests that changes in the glucose transporter have a functional role in normal B-cell physiology.

Antioxidant enzyme activity and mRNA expression in the islets of Langerhans from the BB/S rat model of type 1 diabetes and an insulin-producing cell line.

It has been proposed that low activities of antioxidant enzymes in pancreatic beta cells may increase their susceptibility to autoimmune attack. We have therefore used the spontaneously diabetic BB/S rat model of type 1 diabetes to compare islet catalase and superoxide dismutase activities in diabetes-prone and diabetes-resistant animals. In parallel studies, we employed the RINm5F beta cell line as a model system (previously validated) to investigate whether regulation of antioxidant enzyme activity by inflammatory mediators (cytokines, nitric oxide) occurs at the gene or protein expression level. Diabetes-prone rat islets had high insulin content at the age used (58-65 days) but showed increased amounts of DNA damage when subjected to cytokine or hydrogen peroxide treatments. There was clear evidence of oxidative damage in freshly isolated rat islets from diabetes-prone animals and significantly lower catalase and superoxide dismutase activities than in islets from age-matched diabetes-resistant BB/S and control Wistar rats. The mRNA expression of antioxidant enzymes in islets from diabetes-prone and diabetes-resistant BB/S rats and in RINm5F cells, treated with a combination of cytokines or a nitric oxide donor, DETA-NO, was analysed semi-quantitatively by real time PCR. The mRNA expression of catalase was lower, whereas MnSOD expression was higher, in diabetes-prone compared to diabetes-resistant BB/S rat islets, suggesting regulation at the level of gene expression as well as of the activities of these enzymes in diabetes. The protein expression of catalase, CuZnSOD and MnSOD was assessed by Western blotting and found to be unchanged in DETA-NO treated cells. Protein expression of MnSOD was increased by cytokines in RINm5F cells whereas the expression of CuZnSOD was slightly decreased and the level of catalase protein was unchanged. We conclude that there are some changes, mostly upregulation, in protein expression but no decreases in the mRNA expression of catalase, CuZnSOD or MnSOD enzymes in beta cells treated with either cytokines or DETA-NO. The lower antioxidant enzyme activities observed in islets from diabetes-prone BB/S rats could be a factor in the development of disease and in susceptibility to DNA damage in vitro and could reflect islet alterations prior to immune attack or inherent differences in the islets of diabetes-prone animals, but are not likely to result from cytokine or nitric oxide exposure in vivo at that stage.

Sodium palmitate induces partial mitochondrial uncoupling and reactive oxygen species in rat pancreatic islets in vitro.

The aim of the present investigation was to study whether prolonged exposure of isolated rat islets to the long chain fatty acid sodium palmitate leads to uncoupling of respiration. It was found that culture of islets in the presence of palmitate abolished glucose-sensitive insulin release and decreased insulin contents. This was paralleled by decreased ATP contents, increased respiration, and decreased islet cell mitochondrial membrane potential. Using electron microscopy, an increase in the beta-cell mitochondrial volume in islets exposed to palmitate was observed. The addition of the uncoupler carbonyl cyanide p-(trifluoromethoxy)phenylhydrazone, at a concentration that decreased mitochondrial membrane potential to a similar extent as palmitate, diminished the glucose-induced insulin release. In addition, islet generation of reactive oxygen species, but not of nitric oxide, was increased in response to a long-term palmitate exposure. It is concluded that long-term exposure to a long chain fatty acid induces partial uncoupling of beta-cell oxidative phosphorylation and that this may contribute to the loss of glucose-sensitive insulin release.

Studies on the mechanisms causing inhibition of insulin secretion in rat pancreatic islets exposed to human interleukin-1 beta indicate a perturbation in the mitochondrial function.

This study aimed at a more detailed characterization of the mechanisms by which interleukin 1 (IL-1) inhibits insulin secretion. For this purpose, isolated rat pancreatic islets were kept in tissue culture for 5 days in medium RPMI 1640 plus 10% calf serum. The islets were subsequently transferred to the same culture medium containing various test substances plus 1% human serum with or without 25 U/ml human recombinant IL-1 beta. After a culture period of 48 h the islet structure was examined in the electron microscope and the islet function studied in short term incubations in the absence of IL-1. Islets exposed to IL-1 showed ultrastructural signs of degeneration in 10-20% of the B cells while such changes were not found in other types of islet cells. An increased number of secondary lysosomes and occasional myelin figures were observed in the B cells exposed to IL-1. These ultrastructural alterations were, however, reversed in islets cultured in cytokine-free medium for 6 days after the IL-1 treatment. In islets cultured in the presence of 11.1 mM glucose only, or 11.1 mM glucose plus 10 mM nicotinamide, 61 mM dimethyl area, 2 micrograms/ml indomethacin, 10 microM 4-bromophenacyl bromide or 10 microM nordihydroguaiaretic acid, 10 microM phenantroline, and 0.1 or 1.0 microgram/ml cyclosporin A, IL-1 reduced the insulin release by 64-85%. Culture at 5.6 mM glucose did not modify the IL-1-induced inhibition of insulin release, whereas a significant protective effect was observed at 28 or 56 mM glucose. The DNA content in IL-1-exposed islets cultured at 11.1 mM glucose was decreased by about 20% but not in islets cultured at other glucose concentrations. The D-[5-3H]glucose utilization at 16.7 mM glucose was unaffected by IL-1, whereas the oxidation of D-[6-14C]glucose was reduced by 50%. The present results suggest that IL-1-induced inhibition of insulin secretion is related to a disturbed mitochondrial function. This effect is not counteracted by a poly(ADP-ribose) synthetase inhibitor, a hydroxyl radical scavenger, an iron chelator, a T lymphocyte-specific immunosuppressive drug, or inhibitors of phospholipase A2 or inhibitors of prostaglandin and leukotriene synthesis. Thus, IL-1-induced inhibition of insulin secretion seems not to be mediated by the same mechanisms as those causing alloxan- or streptozotocin-induced damage of B cells. Furthermore, the action of IL-1 does not appear to be mediated via arachidonic acid metabolism. Glucose affords some protection, probably by enhancing the B cell mitochondrial function.(ABSTRACT TRUNCATED AT 400 WORDS)

Interleukin-1 beta increases the activity of superoxide dismutase in rat pancreatic islets.

The suppressive effects of interleukin-1 beta (IL-1 beta) on the function of pancreatic islets may be related to induction of gene transcription and protein synthesis. Presently, the effects of human recombinant IL-1 beta (rIL-1 beta) on the activities of superoxide dismutase (SOD) and the expression of corresponding genes were studied in rat pancreatic islets. Islets that were exposed to rIL-1 beta for 48 h showed a 2.6-fold greater activity of mitochondrial manganese containing SOD (MnSOD) than control islets. The cytosolic copper- and zinc-containing SOD (CuZnSOD) was, however, less affected by rIL-1 beta. Also, brief exposure of the islets to rIL-beta induced an increase in SOD activities. Hence, 12 h after a 1-h exposure of the islets to rIL-1 beta, there was a 1.4-fold increase in the activity of both MnSOD and CuZnSOD. The early induction of SOD by rIL-1 beta was inhibited by an interleukin-1 receptor antagonist protein and actinomycin-D, which is a blocker of gene transcription. This suggests that the effects of rIL-1 beta on the islet SOD activities are dependent on binding to membrane receptors and activation of gene transcription. Northern blot analysis showed a 4-fold increase in islet MnSOD mRNA content after a 90-min incubation and a 10-fold increase after a 180-min incubation with rIL-1 beta. Thus, the enhanced MnSOD activity in the islets reflects increased gene expression. To evaluate a possible role for free oxygen radicals as mediators of the early action of rIL-1 beta on the pancreatic B-cells, isolated islets were exposed to rIL-1 beta only or to rIL-1 beta plus various free radical scavengers. None of the scavengers, single or in combinations, could counteract the suppressive action of rIL-1 beta on islet insulin secretion. The present data suggest that rIL-1 beta induces increased activity of SOD, in particular MnSOD, in pancreatic islets. This may be due to a direct action of rIL-1 beta that is mediated by an increase in gene transcription.

Mitochondrial deoxyribonucleic acid content is specifically decreased in adult, but not fetal, pancreatic islets of the Goto-Kakizaki rat, a genetic model of noninsulin-dependent diabetes.

Considerable interest has recently been focused on the putative role of mutations in the mitochondrial genome for the development of noninsulin-dependent diabetes. The Goto-Kakizaki (GK) rat, a genetic model of defective insulin secretion and hyperglycemia, is characterized by partial maternal inheritance. Because the mitochondrial genome is known to be maternally transmitted, the aim of this study was to investigate whether the GK syndrome can be explained in terms of alterations of the mitochondrial DNA (mtDNA). For this purpose, pancreatic islets were isolated from adult and fetal control Wistar and diabetic GK rats. Using electron microscopy, the ultrastructural morphology of beta-cell mitochondria was analyzed in control and GK islets. It was found that the beta-cells of adult GK rats had a significantly smaller mitochondrial volume and an increased number of mitochondria per unit tissue volume as compared with the beta-cells of corresponding control islets. Moreover, mtDNA and mtRNA were isolated from the islets and, as a control tissue, from liver, and subsequently analyzed using Southern and Northern blot techniques. No major deletions or restriction fragment polymorphism could be detected in mtDNA from both GK liver and GK islets. The mtDNA sequence of the transfer RNAleu(UUS) gene was identical in both strains of rats. mtDNA contents of fetal GK islets and fetal GK liver were not different from those of fetal Wistar rats. However, adult GK islets contained markedly less mtDNA than the corresponding control islets, contrary to the mtDNA contents of adult liver, which were similar in the two strains. The lower islet mtDNA contents were paralleled by a decreased content of islet mtRNA (12S ribosomal RNA and cytochrome b messenger RNA). Islet insulin messenger RNA contents were similar in GK and Wistar rats. In conclusion, our results do not support a role of a genetic defect in mtDNA as a cause of the GK syndrome. Instead, mtDNA damage may occur specifically in islet cells as a consequence of the disturbed metabolic environment of the adult GK rat. It is speculated that a long-lasting metabolic dysfunction may induce mtDNA damage and/or inhibition of mtDNA replication leading to a gradual and late decrease in the mitochondrial volume fraction and subsequently an impaired capacity for oxidative metabolism.

Short-term exposure of rat pancreatic islets to human interleukin-1 beta increases cellular uptake of calcium.

Interleukin-1 (IL-1) may be one of the effector molecules involved in the destruction of the pancreatic islet B cells resulting in insulin-dependent diabetes mellitus. Isolated islets exposed to IL-1 show an acutely increased substrate metabolism and insulin release, which is followed by a metabolic and functional suppression. Since an increased cellular uptake of calcium in the islets may be associated with both nutrient-induced insulin release and cell damage, the effects of recombinant IL-1 beta (rIL-beta) on net cellular calcium uptake by isolated rat pancreatic islets were investigated. In short-term experiments the islets were exposed to 25 U/ml rIL-1 beta for 120 min in the presence of 1.7 mM or 16.7 mM glucose, or 16.7 mM glucose plus 5 mM verapamil. In these experiments rIL-1 beta induced an increase both in net cellular uptake of calcium and in insulin release only in the presence of 16.7 mM glucose. The stimulatory effect of rIL-1 beta at 16.7 mM glucose was blocked by verapamil. By long-term experiments, under tissue culture conditions in the presence of 11.1 mM glucose, islet net calcium uptake, insulin release and glucose oxidation were measured at different time points over a 24-h period. During the first 2 h of incubation 25 U/ml rIL-1 beta effected a significant increase of net calcium uptake, insulin release and glucose oxidation. However, after 4-5 h of incubation with the cytokine no such stimulatory effects were seen. After longer incubations with rIL-1 beta all the islet functions studied were suppressed.(ABSTRACT TRUNCATED AT 250 WORDS)

The priming effect of glucose on insulin release does not involve redistribution of secretory granules within the pancreatic B-cell.

Short-term stimulation of the pancreatic B-cell with glucose produces a time-dependent potentiation of this cell, which markedly enhances the insulin response to a renewed stimulation with the hexose. To study if a redistribution of the B-cell secretory granules to a location close to the B-cell plasma membrane could underlie the priming effect of glucose, an investigation by ultrastructural morphometry was performed. After exposure of perfused rat pancreas to non-priming or priming concentrations of glucose, pale and dark B-cell secretory granules were distinguished and analysed both within a central and a peripheral zone of the B-cell. The pale secretory granules comprised 30-40% of the total granule population in the B-cell. Whereas no difference in diameter of the granules was observed, there was evidence for a greater numerical density of dark granules in the central than in the peripheral part of the B-cell. This finding may be in line with observations implying that newly synthesized insulin is released preferentially to older insulin. The present experiments did, however, not reveal any significant priming effect of glucose on the intracellular distribution of secretory granules in the pancreatic B-cell. The lack of morphological changes in the B-cell by glucose priming of insulin release should, rather, direct increased attention to the biochemical aspects of the priming phenomenon.

Lysosomes and pancreatic islet function: adaptation of beta-cell lysosomes to various metabolic demands.

The effect of various functional demands on the lysosomes of pancreatic islet beta cells was studied in vivo. To expose pancreatic islets to different metabolic situations, normal syngeneic mouse islets were transplanted to either lean mice, alloxan-diabetic mice, or obese hyperglycemic mice. Two weeks after transplantation, primary and secondary beta-cell lysosomes of the islet grafts were analyzed by morphometry. The beta-cell lysosomes and secretory granules of the endogenous islets of lean and obese hyperglycemic mice were also measured. The beta cells of the islets transplanted to lean normoglycemic mice showed only a moderately developed synthetic apparatus and a great number of secretory granules. They had mainly secondary lysosomes, frequently containing secretory granule material, indicating a high crinophagic activity. The islet beta cells exposed to the high serum glucose concentration of alloxan-diabetic and obese hyperglycemic mice had an extensive synthetic apparatus, but a very small content of secretory granules. In these beta cells, there was a predominance of small primary lysosomes, indicating a low crinophagic activity. It is concluded that crinophagy may provide a mechanism for the pancreatic beta cell to moderate its content of insulin. When its secretory granule stores are diminished due to increased demands on insulin secretion, the beta cell seems able to drastically decrease the crinophagic activity. The detailed morphometric analysis of the endogenous islets of the lean and obese hyperglycemic mice showed that the beta cells of the obese hyperglycemic mice had a smaller number and size of the secretory granules.(ABSTRACT TRUNCATED AT 250 WORDS)

Altered levels of scavenging enzymes in embryos subjected to a diabetic environment.

Maternal diabetes during pregnancy is associated with an increased rate of congenital malformations in the offspring. The exact molecular etiology of the disturbed embryogenesis is unknown, but an involvement of radical oxygen species in the teratological process has been suggested. Oxidative damage presupposes an imbalance between the activity of the free oxygen radicals and the antioxidant defence mechanisms on the cellular level. The aim of the present study was to investigate if maternal diabetes in vivo, or high glucose in vitro alters the expression of the free oxygen radical scavenging enzymes superoxide dismutase (CuZnSOD and MnSOD), catalase and glutathione peroxidase in rat embryos during late organogenesis. We studied offspring of normal and diabetic rats on gestational days 11 and 12, and also evaluated day-11 embryos after a 48 hour culture period in 10 mM or 50 mM glucose concentration. Both maternal diabetes and high glucose culture caused growth retardation and increased rate of congenital malformations in the embryos. The CuZnSOD and MnSOD enzymes were expressed on gestational day 11 and both CuZnSOD, MnSOD and catalase were expressed on day 12 with increased concentrations of MnSOD transcripts when challenged by a diabetic milieu. There was a good correlation between mRNA, protein, and activity levels, suggesting that the regulation of these enzymes occurs primarily at the pretranslational level. Maternal diabetes in vivo and high glucose concentration in vitro induced increased MnSOD expression, concomitant with increased total SOD activity, and a tentative decrease in catalase expression and activity in the embryos. These findings support the notion of enhanced oxidative stress in the embryo as an etiologic agent in diabetic teratogenesis.

Metabolic alteration in neural tissue of rat embryos exposed to beta-hydroxybutyrate during organogenesis.

Hyperketonemia has been identified as an important factor in diabetic pregnancy affecting growth and development of the offspring. In order to assess the immediate metabolic alterations in embryos caused by excess ketone bodies, we studied rat embryonic neural tissue exposed to a high concentration of beta-hydroxybutyrate in vitro. Beta-hydroxybutyrate inhibited oxygen uptake of the neural tissue of day 9 and day 10 embryos by 12.8% and 1 1.2%, but did not affect that of day 11 and day 12 tissue. In contrast, glucose utilization of the neural tissue of day 9 and day 10 embryos was not altered. However, a 30% decrease in glucose utilization was observed in the neural tissue of day 11 and day 12 embryos exposed to beta-hydroxybutyrate. Thus, beta-hydroxybutyrate induced different metabolic alterations in the embryonic neural tissue during early and late organogenesis, which suggests different modes of teratogenic action of ketone bodies in different parts of gestation.