Chlorotetracycline as a fluorescent Ca2+ probe in pancreatic islet cells

Pancreatic islets, or suspensions of islet cells, from noninbred ob/ob-mice were incubated with chlorotetracycline and analyzed for Ca2+-dependent fluorescence in a microscope. Unless logarithmically transformed, signals from islets were asymmetrically distributed with unstable variance. Signals from cells pelleted in glass capillaries were more homogeneous and depended linearly on the thickness of the sample. The effect of sample thickness and a significant enhancement of fluorescence by alloxan suggest that beta-cells were involved in producing the signal from whole islets. The signal from dispersed cells was probably diagnostic of Ca2+ in beta-cell plasma membranes because it was suppressed by La3+ and had a spectrum indicative of an apolar micromilieu; fluorescent staining of cell surfaces was directly seen at high magnification. Fluorescence from cells was enhanced by 0.5-10 mM Ca2+ in a dose-dependent manner, whereas less than 0.5 mM Ca2+ saturated the probe alone in methanol. The signal from islets or dispersed cells was suppressed by 5 mM theophylline; that from cells was also suppressed by 0.5 mM 3-isobutyl-1-methylxanthine, 1.2 or 15 mM Mg2+, 3-20 mM D-glucose, and, to a lesser extent, 20 mM 3-O-methyl-D-glucose. D-glucose was more inhibitory in the absence than in the presence of Mg2+, as if Mg2+ and D-glucose influenced the same Ca2+ pool. L-glucose, D-mannopheptulose, or diazoxide had no noticeable effect and 20 mM bicarbonate was stimulatory. The results suggest that microscopy of chlorotetracycline-stained cells can aid in characterizing calcium pools of importance for secretion. Initiation of insulin release may be associated with an increas     

Hormone secretion and glucose metabolism in islets of Langerhans of the isolated perfused pancreas from normal and streptozotocin diabetic rats.

The glucose responsiveness of alpha- and beta-cells of normal as well as untreated and insulin-treated streptozotocin diabetic rats was tested in the extracorporeal perfusion system. Also assessed was the possible in vitro effect of added insulin on the glucose sensitivity of islets from untreated diabetic animals. Insulin and glucose responsiveness of the two cell types. The rate of glucose entry islet tissue was estimated, and the effect of glucose on the tissue supply of ATP and lactate and the cyclic 3':5'-AMP level of islets was measured under the above in vitro conditions. It was demonstrated that beta-cells are more accessible to glucose than alpha-cells, that glucose entry into islet cells is not significantly modified by insulin and that glucose had no effect on ATP, lactate and cyclic 3':5'-AMP levels of islet tissue under any of the conditions investigated. High insulin in vitro elevated ATP levels of alpha-cell islets independent of extracellular glucose. Glucose caused insulin release from normal but not from diabetic islets and rapidly and efficiently suppressed stimulated glucagon secretion of the pancreas from normal and insulin treated diabetic rats. Glucose was less effective in inhibiting stimulated glucagon secretion by the pancreas from untreated diabetic rats whether insulin was added to the perfusion media or not. Therefore, profound differences of glucose responsiveness of alpha-cells fail to manifest themselves in alterations of basic parameters of glucose and energy metabolism in contrast to what had been postulated in the literature. It is however, apparent that the glucose responsiveness of alpha-cells is modified by insuling by an as yet undefined mechanism.     

Islet amyloid polypeptide (amylin)-deficient mice develop a more severe form of alloxan-induced diabetes

To examine whether islet amyloid polypeptide (IAPP), other than through amyloid formation, may be of importance in diabetes pathogenesis, IAPP-deficient mice (IAPP(-/-)) were challenged with alloxan (day 0). Diabetes in IAPP(-/-) mice was more severe at day 35, indicated by greater weight loss; glucose levels were higher in alloxan-treated IAPP(-/-) mice, whereas insulin levels were lower, indicating a greater impairment of islet function. Accordingly, glucose levels upon intravenous glucose challenges at days 7 and 35 were consistently higher in alloxan-treated IAPP(-/-) mice. At day 35, insulin mRNA expression, but not beta-cell mass, was lower in untreated IAPP(-/-) mice. Yet, upon alloxan administration, beta-cell mass and numbers of beta-cell-containing islets were significantly more reduced in IAPP(-/-) mice. Furthermore, they displayed exaggerated beta-cell dysfunction, because in their remaining beta-cells, insulin mRNA expression was significantly more impaired and the localization of glucose transporter-2 was perturbed. Thus the lack of IAPP has allowed exaggerated beta-cell cytotoxic actions of alloxan, suggesting that there may be beneficial features of IAPP actions in situations of beta-cell damage.     

Effect of hexoses and mannoheptulose on cyclic AMP accumulation and insulin secretion in rat pancreatic islets.

The effects of various sugars on the simultaneous release of insulin and accumulation of cyclic AMP were studied in collagenase isolated rat pancreatic islets. D-Glucose stimulated the formation of cyclic AMP at 3 and 60 min of incubation, whether measured by a label incorporation technique, or by the protein kinase binding assay of Gilman. Only D-glucose and D-mannose were able to stimulate insulin release and cyclic [3H]AMP accumulation in the absence of other substrate. D-fructose had a stimulatory effect in the presence of 3.3 mM D-glucose only at a high concentration (33.8 mM), and enhanced the effects of 8.3 mM glucose when added at the concentration of 8.3 mM. D-Galactose was effective only together with 8.3 mM D-glucose. The order of potency of these hexoses, both regarding insulin secretion and cyclic [3H]AMP accumulation, was glucose-mannose-fructose-galactose. L-Glucose and 3-O-methylglucose had no effects at 60 min when incubated together with 8.3 mM D-glucose, whereas at 3 min, 3-O-methylglucose induced a small stimulation of the cyclic [3H]AMP response. D-mannoheptulose and D-glucosamine inhibited the insulin and cyclic [3H]AMP responses to 27.7 mM glucose. Mannoheptulose suppressed completely the glucose effect on cyclic nucleotide accumulation within 90 s. Although under all incubation conditions, the threshold stimulatory or inhibitory concentration of a given agent was identical for insulin release and cyclic [3H]AMP accumulation, these two variables showed quantitative differences in incubations of 60 min, the magnitude of the changes in insulin secretion being larger than that for the cyclic nucleotide. It is suggested that modulation of islet cyclic AMP level is an important step in the transmission of the effect of various sugars on insulin release; however, glucose and possibly other sugars may also enhance insulin release by additional mechanisms not involving the adenylate cyclase-cyclic AMP system of the beta-cell.     

Alloxan inhibits glucose oxidation in the pancreatic islets.

The effects of alloxan on glucose oxidation and the protection by anomers of D-glucose from alloxan inhibition of glucose oxidation in the pancreatic islets were investigated using in vitro incubation of rat isolated islets. The pretreatment by alloxan (5-30 mg/dl) for 6 minutes inhibits significantly 14CO2 formation from 14C-U-D-glucose (10 mM) and the addition of alpha-anomer of D-glucose (8.3 mM) to alloxan (20 mg/dl) completely reverses alloxan inhibition of glucose oxidation. These findings seem to be incompatible with the recent view that alloxan acts at the glucose receptor on the plasma membrane of pancreatic beta-cells without affecting glucose metabolism in the pancreatic islets.     

Alloxan inhibition of a Ca2+- and calmodulin-dependent protein kinase activity in pancreatic islets

Alloxan was found to inhibit a Ca2+- and calmodulin-dependent protein kinase recently identified in pancreatic islets. This effect of alloxan may be specifically related to the inhibitory action of alloxan on insulin secretion from islets since: 1) in islet-cell subcellular fractions, alloxan at micromolar concentrations irreversibly inhibits the Ca2+- and calmodulin-dependent protein kinase activity; 2) pretreatment of intact islets with alloxan at concentrations that inhibit insulin secretion similarly inhibits the protein kinase activity; and 3) alloxan inhibition of both insulin secretion and protein kinase activity in intact islets can be prevented by D-glucose. This inhibition by alloxan appears to be a direct effect on the enzyme since alloxan treatment of either the islet homogenate or the microsomal fraction enriched in protein kinase activity inhibited the kinase activity with similar concentration dependence. These results suggest that alloxan-induced inhibition of a Ca2+- and calmodulin-dependent protein kinase may represent a critical inhibitory site which mediates alloxan-induced inhibition of insulin secretion.     

Alloxan cytotoxicity in vitro. Inhibition of rubidium ion pumping in pancreatic beta-cells.

Exposing micro-dissected pancreatic islets of non-inbred ob/ob mice to 2-5 mM-alloxan for 10 min decreased the ability of the islets to accumulate Rb+. Rb+ accumulation in pieces of exocrine pancreas was unaffected by alloxan. When islets were treated with alloxan in the presence of 2-20 mM-D-glucose, the Rb+-accumulating ability was protected in a dose-dependent manner. The protective action of D-glucose was reproduced with 3-O-methyl-D-glucose but not with L-glucose or D-mannoheptulose; mannoheptulose prevented D-glucose from exerting its protective action. The inhibition of Rb+ accumulation was due to a decreased inward pumping, since alloxan did not affect Rb+ efflux from pre-loaded islets. The inhibitory effect of alloxan had a latency of about 1 min, as revealed by experiments with dispersed islet cells in suspension. Alloxan-treated islets showed only a marginal decrease in ATP and no change in glucose 6-phosphate concentration. Although alloxan slightly decreased the hydrolysis of ATP in a subcellular fraction enriched in plasma membranes, this effect could not be attributed to a ouabain-sensitive adenosine triphosphatase. The plasma membranes exhibited a K+-activated hydrolysis of p-nitrophenyl phosphate; this enzyme activity too was insensitive to alloxan. Glucose may protect the univalent-cation pump by preventing permeation of alloxan via a path coupled to the hexose-transport system. Inhibition of the pump may be fundamental to the induction of alloxan-diabetes.     

Barium mimics the effect of D-glucose on 86Rb+ fluxes in mouse pancreatic beta-cells

The interaction between Ba2+, furosemide and D-glucose on 86Rb+ fluxes in ob/ob mouse islets was investigated. Ba2+ (2 mM) significantly reduced the ouabain-resistant 86Rb+ influx, without affecting the ouabain-sensitive influx. D-Glucose (20 mM) reduced the 86Rb+ influx in the absence of Ba2+ (2 mM) but not in the presence of the cation. Furosemide, an inhibitor of Na+, K+, Cl- co-transport, reduced the 86Rb+ influx and the effect was partly additive to the effect of 2 mM Ba2+. When the islets were preincubated with Ba2+ (2 mM) the specific effect of 1 mM furosemide on the 86Rb+ influx was reduced, whereas, in acute experiments, Ba2+ (2 mM) did not affect the specific effect of furosemide on 86Rb+ influx. 86Rb+ efflux from preloaded islets was significantly reduced by 2 mM Ba2+ and during the first 5 min of ion efflux the effect of the combination of 2 mM Ba2+ and 1 mM furosemide was stronger than the effect of Ba2+ alone. The data show that Ba2+ reduces 86Rb+ fluxes in the beta-cells and suggest that this is mainly mediated by inhibition of K+ channels in the beta-cell plasma membrane. Long-term exposure to Ba2+ may also reduce the activity of the Na+, K+, Cl- co-transport system. The effect of Ba2+ on K+ channels may help to explain the stimulatory effect on insulin release in the absence of nutrient secretagogues.     

Insulin regulates ionic metabolism in a fresh water teleost, anabas testudineus (bloch)

Short term effects of insulin on total brain and branchial Na+K+ ATPase, Ca2+ ATPase and Na+, K+ and Ca2+ ions were investigated in A. testudineus. The increase in brain Ca2+ ATPase after alloxan treatment may account for an increased amount of intracellular calcium required for biochemical events taking place inside the cells. Branchial Na+K+ATPase was significantly stimulated while Ca2+ ATPase significantly inhibited after alloxan treatment. This suggests that alloxan exerts its inhibitory effect on the ATP-driven Ca2+ transport via; its action on the Ca2+ pump protein rather than the membrane permeability to Ca2+. The increased activity of brain Na+K+ ATPase at 3 and 24 hr by insulin to alloxan pretreated fish may account for the stimulated co-transport of glucose and its utilization for energy requirements and the excitatory action on neurons in the brain. The elevated brain Ca2+ ATPase may be due to the role of calcium as a second messenger in hormone action. At 24 hr, the activity of branchial Na+K+ ATPase and Ca2+ ATPase in alloxan pretreated specimens was significantly stimulated by insulin. This may be due to increased synthesis of these enzyme units. Administration of insulin (lU/fish) in normal fish significantly inhibited the activity of brain and branchial Na+K+ ATPase while brain Ca2+ ATPase showed a stimulatory effect at 3 and 24 hr compared to control. Inhibition of total branchial Ca2+ ATPase activity by insulin may be due to increased Ca2+ concentration. Higher plasma glucose level in alloxan treated groups confirms the diabetic effect of alloxan. Insulin reverses this effect. The possible mechanism by which insulin controls Na+K+ ATPase activity appears to be tissue specific. The results seem to be the first report on the effect of insulin on ATPase activity in a teleost. These data are consistent with the hypothesis that insulin performs a role in hydro mineral regulation in freshwater teleosts.     

Effect of intracellular alkalinization on pancreatic islet calcium uptake and insulin secretion.

Microdissected beta-cell-rich pancreatic islets of ob/ob mice were used in studies of the relationship between intracellular pH (pHi) and 45Ca2+ uptake and insulin release. Stepwise increases in extracellular pH (pHo) from 6.80 to 8.00 resulted in a parallel, although less pronounced, elevation of pHi from 7.24 to 7.69. Experimental conditions that alkalinize the islet cell interior, i.e. addition of 5 mM-NH4+, sudden withdrawal of extracellular bicarbonate buffer or increase in pHo, induced insulin secretion in the absence of other types of secretory stimulation (1 mM-D-glucose). Intracellular acidification by lowering pHo below 7.40 or sudden addition of bicarbonate buffer did not induce insulin secretion. The removal of extracellular bicarbonate buffer, increase in pHo from 7.40 to 8.00, or the addition of 5 mM-L-5-hydroxytryptophan or 5 mM-NH4+, which all alkalinize the islet cells and induce insulin secretion, also increased the La3+-non-displaceable 45Ca2+ uptake in the presence of 1 mM-D-glucose. The results suggest that intracellular alkalinization in beta-cells can trigger insulin secretion. Taken together with the fact that D-glucose increases pHi in the islet cells, the results also point to the possibility that alkalinization may be a link in the stimulus-secretion coupling sequence in beta-cells.     

Effect of extracellularly generated free radicals on the plasma membrane permeability of isolated pancreatic B-cells

Previous experiments on alloxan diabetogenicity suggest that alloxan increases the permeability of B-cell plasma membranes by generation of noxious free radicals. Whether the radicals are generated intra- or extracellularly has however been disputed. To test if extracellularly generated free radicals could decrease trypan blue exclusion of dispersed islet cells, a radical-generating solution of xanthine oxidase/hypoxanthine was employed. The solution increased dye uptake by cells in the cell suspension. Superoxide dismutase and catalase but not scavengers of hydroxyl radicals protected against the increase in dye uptake. Both L- and D-glucose protected the cells from injury. It is concluded that extracellularly generated free radicals induce damage to the plasma membrane of islet cells. The result strengthens the hypothesis of plasma membrane damage by extracellularly generated free radicals as the primary event in alloxan diabetogenicity and may provide a link for explanation of damage caused by islet inflammation in juvenile diabetes.     

Adenovirus-mediated silencing of synaptotagmin 9 inhibits Ca2+-dependent insulin secretion in islets

Synaptotagmins (Syts) are involved in Ca(2+)-dependent insulin release. However, which Syt isoform is functional in primary beta-cells remains unknown. We demonstrate by electron microscopy of pancreatic islets, the association of Syt 9 with insulin granules. Silencing of Syt 9 by RNA interference adenovirus in islet cells had no effect on the expression of Syt 5, Syt 7 and Syt 3 isoforms. The latter was localized at the plasma membrane of pancreatic polypeptide cells. Insulin release in response to glucose or tolbutamide was strongly inhibited in Syt 9 deficient islets, whereas exocytosis potentiated by raising cAMP levels, was unaltered. Thus, Syt 9 may act as Ca(2+) sensor for beta-cell secretion.     

Double-stranded RNA inhibits beta-cell function and induces islet damage by stimulating beta-cell production of nitric oxide

Viral infection has been implicated as a triggering event that may initiate beta-cell damage during the development of autoimmune diabetes. In this study, the effects of the viral replicative intermediate, double-stranded RNA (dsRNA) (in the form of synthetic polyinosinic-polycytidylic acid (poly IC)) on islet expression of inducible nitric oxide synthase (iNOS), production of nitric oxide, and islet function and viability were investigated. Treatment of rat islets with poly(IC) + interferon-gamma (IFN-gamma) stimulates the time- and concentration-dependent expression of iNOS and production of nitrite by rat islets. iNOS expression and nitrite production by rat islets in response to poly(IC) + IFN-gamma correlate with an inhibition of insulin secretion and islet degeneration, effects that are prevented by the iNOS inhibitor aminoguanidine (AG). We have previously shown that poly(IC) + IFN-gamma activates resident macrophages, stimulating iNOS expression, nitric oxide production and interleukin-1 (IL-1) release. In addition, in response to tumor necrosis factor-alpha (TNF-alpha) + lipopolysaccharide, activated resident macrophages mediate beta-cell damage via intraislet IL-1 release followed by IL-1-induced iNOS expression by beta-cells. The inhibitory and destructive effects of poly(IC) + IFN-gamma, however, do not appear to require resident macrophages. Treatment of macrophage-depleted rat islets for 40 h with poly(IC) + IFN-gamma results in the expression of iNOS, production of nitrite, and inhibition of insulin secretion. The destructive effects of dsRNA + IFN-gamma on islets appear to be mediated by a direct interaction with beta-cells. Poly IC + IFN-gamma stimulates iNOS expression and inhibits insulin secretion by primary beta-cells purified by fluorescence-activated cell sorting. In addition, AG prevents the inhibitory effects of poly(IC) + IFN-gamma on glucose-stimulated insulin secretion by beta-cells. These results indicate that dsRNA + IFN-gamma interacts directly with beta-cells stimulating iNOS expression and inhibiting insulin secretion in a nitric oxide-dependent manner. These findings provide biochemical evidence for a novel mechanism by which viral infection may directly mediate the initial destruction of beta-cells during the development of autoimmune diabetes.     

Glucose intolerance and reduced islet blood flow in transgenic mice expressing the FRK tyrosine kinase under the control of the rat insulin promoter

The FRK tyrosine kinase has previously been shown to transduce beta-cell cytotoxic signals in response to cytokines and streptozotocin and to promote beta-cell proliferation and an increased beta-cell mass. We therefore aimed to further evaluate the effects of overexpression of FRK tyrosine kinase in beta-cells. A transgenic mouse expressing kinase-active FRK under control of the insulin promoter (RIP-FRK) was studied with regard to islet endocrine function and vascular morphology. Mild glucose intolerance develops in RIP-FRK male mice of at least 4 mo of age. This effect is accompanied by reduced glucose-stimulated insulin secretion in vivo and reduced second-phase insulin secretion in response to glucose and arginine upon pancreas perfusion. Islets isolated from the FRK transgenic mice display a glucose-induced insulin secretory response in vitro similar to that of control islets. However, islet blood flow per islet volume is decreased in the FRK transgenic mice. These mice also exhibit a reduced islet capillary lumen diameter as shown by electron microscopy. Total body weight and pancreas weight are not significantly affected, but the beta-cell mass is increased. The data suggest that long-term expression of active FRK in beta-cells causes an in vivo insulin-secretory defect, which may be the consequence of islet vascular abnormalities that yield a decreased islet blood flow.     

Effect of insulin secretagogues and potential modulators of secretion on a plasma membrane (Ca2+ + Mg2+)-ATPase activity in islets of Langerhans

Studies were undertaken to determine whether factors which affect insulin secretion may exert their effects by altering the activity of an islet-cell plasma membrane Ca2+ extrusion pump. The insulin secretagogue, D-glucose, and a variety of phosphorylated hexoses, glucose 6-P, glucose 1,6-P, fructose 6-P, and fructose 2,6-P, were evaluated for their effect on an islet-cell plasma membrane (Ca2+ + Mg2+)-ATPase and were found to be ineffective in altering enzyme activity. D-Glucose also did not alter the rate of ATP-dependent Ca2+ uptake into plasma membrane vesicles. Similarly, cAMP, the catalytic subunit of cAMP-dependent protein kinase, arachidonic acid, or prostaglandin E2 did not affect either the plasma membrane (Ca2+ + Mg2+)-ATPase or the rate of ATP-dependent Ca2+ uptake into plasma membrane vesicles. Whereas previous studies have suggested that D-glucose and/or cAMP may inhibit ATPase activities in islets, these results indicate that the agents, i.e., D-glucose and cAMP, which stimulate and/or potentiate insulin secretion from the islet cell, do not modify Ca2+ fluxes by directly regulating the islet-cell plasma membrane (Ca2+ + Mg2+)-ATPase. In contrast, the acidic phospholipids, phosphatidic acid and phosphatidylserine, stimulated the enzyme activity in a concentration-dependent manner whereas phosphatidylcholine had only a minimal effect. The diacylglycerol, dilinolein, stimulated the (Ca2+ + Mg2+)-ATPase activity in the presence of phosphatidylserine, but not in the absence of phospholipids. These effects were independent of phospholipid-stimulated protein phosphorylation in the islet-cell plasma membrane under the conditions of the ATPase assay.     

Calcium and pancreatic beta-cell function. I. Stimulatory effects of pentobarbital on insulin release.

Islets microdissected from ob/ob-mice were exposed to 3mM pentobarbital in media which were normal or deficient in Ca2+. This treatment resulted in marked decrease of the islet content of cyclic AMP recorded in the presence of the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine. Pentobarbital had a dual effect on insulin release. In addition to being a potent inhibitor of glucose-stimulated insulin release in media containing 2.56 mM Ca2+ it increased the amounts of insulin released in high glucose media deficient in Ca2+. There was a transient stimulation with ordinary concentrations of Ca2+ and 3mM glucose whtn the media also contained 3-isobutyl-1-methylxanthine. The stimulatory effect of pentobarbital persisted after replacing part of the Ca2+ in the beta-cell membrane with lanthanum ions and it could not be mimicked by lowering the oxygen tension of the incubation medium. It is suggested that pentobarbital stimulation of insulin release is the result of a specific action of the drug on the distribution of Ca2+ within the pancreatic beta-cells.     

Pancreatic beta-cell damage mediated by beta-cell production of interleukin-1. A novel mechanism for virus-induced diabetes

Viral infection is one environmental factor that may initiate beta-cell damage during the development of autoimmune diabetes. Formed during viral replication, double-stranded RNA (dsRNA) activates the antiviral response in infected cells. In combination, synthetic dsRNA (polyinosinic-polycytidylic acid, poly(I-C)) and interferon (IFN)-gamma stimulate inducible nitric-oxide synthase (iNOS) expression, inhibit insulin secretion, and induce islet degeneration. Interleukin-1 (IL-1) appears to mediate dsRNA + IFN-gamma-induced islet damage in a nitric oxide-dependent manner, as the interleukin-1 receptor antagonist protein prevents dsRNA + IFN-gamma-induced iNOS expression, inhibition of insulin secretion, and islet degeneration. IL-1beta is synthesized as an inactive precursor protein that requires cleavage by the IL-1beta-converting enzyme (ICE) for activation. dsRNA and IFN-gamma stimulate IL-1beta expression and ICE activation in primary beta-cells, respectively. Selective ICE inhibition attenuates dsRNA + IFN-gamma-induced iNOS expression by primary beta-cells. In addition, poly(I-C) + IFN-gamma-induced iNOS expression and nitric oxide production by human islets are prevented by interleukin-1 receptor antagonist protein, indicating that human islets respond to dsRNA and IFN-gamma in a manner similar to rat islets. These studies provide biochemical evidence for a novel mechanism by which viral infection may initiate beta-cell damage during the development of autoimmune diabetes. The viral replicative intermediate dsRNA stimulates beta-cell production of pro-IL-1beta, and following cleavage to its mature form by IFN-gamma-activated ICE, IL-1 then initiates beta-cell damage in a nitric oxide-dependent fashion.     

Polarization of chlorotetracycline fluorescence in pancreatic islet cells and its response to calcium ions and D-glucose.

Suspensions rich in pancreatic beta-cells were prepared from non-inbred ob/ob-mice, incubated with 10 micrometer-chlorotetracycline, and analysed for fluorescence polarization in a microscope. Throughout the temperature range 16--38 degrees C, fluorescence was enhanced by 5 mM-Ca2+ in the incubation medium; 20 mM-D-glucose decreased the fluorescence measured in the presence of Ca2+. Fluorescence showed a curvilinear negative regression on temperature. The curves were rectified to a virtually ideal degree by Arrhenius transformations of data. Non-parametric testing of differences between linearized regression lines forms the basis for the following conclusions. The temperature-dependence of fluorescence intensity appeared to be smaller for Ca2+-specific signals than for the background fluorescence of chlorotetracycline in Ca2+-deficient cells. D-Glucose significantly diminished the polarization of fluorescence in cells incubated with Ca2+. It is suggested that D-glucose increases the mobility of Ca2+ in beta-cell plasma membranes; this mobility increase may help to explain previously reported effects of D-glucose on 45Ca2+ fluxes and membrane electric potential.     

Differences in neutral amino acid and glucose transport between brush border and basolateral plasma membrane of intestinal epithelial cells.

A comparison of L-valine and D-glucose transport was carried out with vesicles of plasma membrane isolated either from the luminal (brush border) or from the contra-luminal (basolateral) region of small intestinal epithelial cells. The existence of transport systems for both non-electrolytes was demonstrated by stereospecificity and saturability of uptake, as well as tracer coupling. Transport of L-valine and D-glucose differs markedly in the two types of plasma membrane with respect to stimulation by Na+. The presence of Na+ stimulated initial L-valine and D-glucose uptake in brush border, but not in basolateral membrane. Moreover, an electro-chemical Na+ gradient, oriented with the lower potential on the inside, supported accumulation of the non-electrolytes above medium concentration only in the brush border membrane. L-Valine and D-glucose transport also were saturated at lower concentrations in brush border (10-20 mM) than in basolateral plasma membranes (30-50 mM). A third difference between the two membranes was found in the effectiveness of known inhibitors of D-glucose transport. In brush border membranes phlorizin was more potent than phloretin and 2', 3', 4'-trihydroxy-4-methoxy chalcone and cytochalasin B did not inhibit at all. In contrast, with the basolateral plasma membranes the order of potency was changed to phloretin = 2',3',4'-trihydroxy-4-methoxy chalcone greater than cytochalasin B greater than phlorizin. These results indicate the presence of different types of transport systems for monosaccharides and neutral amino acids in the luminal and contra-luminal region of the plasma membrane. Active transepithelial transport can be explained on the basis of the different properties of the non-electrolyte transport systems in the two cellular regions and an electro-chemical Na+ gradient that is dependent on cellular metabolism.     

Expression of islet inducible nitric oxide synthase and inhibition of glucose-stimulated insulin release after long-term lipid infusion in the rat is counteracted by PACAP27

Chronic exposure of pancreatic islets to elevated plasma lipids (lipotoxicity) can lead to beta-cell dysfunction, with overtime becoming irreversible. We examined, by confocal microscopy and biochemistry, whether the expression of islet inducible nitric oxide synthase (iNOS) and the concomitant inhibition of glucose-stimulated insulin release seen after lipid infusion in rats was modulated by the islet neuropeptide pituitary adenylate cyclase-activating polypeptide (PACAP)27. Lipid infusion for 8 days induced a strong expression of islet iNOS, which was mainly confined to beta-cells and was still evident after incubating islets at 8.3 mmol/l glucose. This was accompanied by a high iNOS-derived NO generation, a decreased insulin release, and increased cyclic GMP accumulation. No iNOS expression was found in control islets. Addition of PACAP27 to incubated islets from lipid-infused rats resulted in loss of iNOS protein expression, increased cyclic AMP, decreased cyclic GMP, and suppression of the activities of neuronal constitutive (nc)NOS and iNOS and increased glucose-stimulated insulin response. These effects were reversed by the PKA inhibitor H-89. The suppression of islet iNOS expression induced by PACAP27 was not affected by the proteasome inhibitor MG-132, which by itself induced the loss of iNOS protein, making a direct proteasomal involvement less likely. Our results suggest that PACAP27 through its cyclic AMP- and PKA-stimulating capacity strongly suppresses not only ncNOS but, importantly, also the lipid-induced stimulation of iNOS expression, possibly by a nonproteasomal mechanism. Thus PACAP27 restores the impairment of glucose-stimulated insulin release and additionally might induce cytoprotection against deleterious actions of iNOS-derived NO in beta-cells.