Co-expression and regulation of connexins 36 and 43 in cultured neonatal rat pancreatic islets

Fetal and neonatal pancreatic islets present a lower insulin secretory response as compared with adult islets. Prolonged culturing leads to an improvement of the glucose-induced insulin secretion response in neonatal pancreatic islets that may involve regulation of gap junction mediated cell communication. In this study, we investigated the effect of culturing neonatal islet cells for varying periods of time and with different glucose medium concentrations on the cellular expression of the endocrine pancreatic gap junction associated connexin (Cx) 36 and Cx43. We report here that the 7-d culture induced upregulation of the expression of these junctional proteins in neonatal islets in a time-dependent manner. A correlation was observed between the increased mRNA and protein expression of Cx36 and Cx43 and the increased insulin secretion following islet culturing. In addition, increasing glucose concentration within the culture medium induced a concentration-dependent enhancement of Cx36 islet expression, but not of Cx43 expression in cultured neonatal islets. In conclusion, we suggest that the regulation of gap junctional proteins by culture medium containing factors and glucose may be an important event for the maturation process of beta cells observed at in vitro conditions.     

Upregulation of the expression of tight and adherens junction-associated proteins during maturation of neonatal pancreatic islets in vitro

Cell–cell contacts mediated by intercellular junctions are crucial for proper insulin secretion in the endocrine pancreas. The biochemical composition of the intercellular junctions in this organ and the role of junctional proteins in endocrine pancreatic dysfunctions are still unclear. In this study, we investigated the expression and cellular location of junctional and cytoskeletal proteins in cultured neonatal rat pancreatic islets. Neonatal B-cells had an impaired insulin secretion compared to adult cells. Cultured neonatal islets showed a time-dependent increase in the glucose-induced secretory response. The maturation of B-cells in vitro was accompanied by upregulation of the expression of some junctional proteins in islet cells. Neonatal islets cultured for only 24 h showed a low expression and a diffuse cytoplasmic location of the tight junctional proteins occludin and ZO-1 and of the adherens junctional proteins - and -catenins, as demonstrated by immunoblotting and immunocytochemistry. Culturing islets for up to 8 days significantly increased the cell expression of these junctional proteins but not of the cytoskeletal proteins vinculin and -actinin. A translocation of ZO-1 and catenins to the cell–cell contact region, as well as a higher association of F-actin with the intercellular junction, were also observed in neonatal islets following prolonged culturing. ZO-1 and -catenin were immunolocated in the endocrine pancreas of adult rats indicating that these junctional proteins are also expressed in this organ in situ. In conclusion, endocrine pancreatic cells express several junctional proteins that are upregulated following differentiation of the endocrine pancreas in vitro.     

Clusters of neural cell adhesion molecule at sites of cell-cell contact

I have examined the distribution of neural cell adhesion molecule (N-CAM) in cultured C2 myogenic cells and other cell lines to determine if N-CAM accumulates at sites of cell-cell contact. C2 cells growing in log phase display large clusters of neural cell adhesion molecule where they contact each other. These clusters are remarkably stable, do not form at cell-substrate contacts, and appear not to be enriched in a number of other cytoskeletal, membrane, or extracellular proteins. Thus, N-CAM clusters form preferentially in response to cell-cell contact and are specifically enriched in N-CAM. As C2 cultures mature and differentiate, clusters persist at contacts between aligning myoblasts and between myotubes, consistent with a role in myogenesis. N-CAM is also enriched at cell-cell contacts in cultures of PC12, NRK, and CHO cells. These cells have significant amounts of N-CAM as detected on immunoblots. Clusters are not seen in L929 cells, which do not have detectable amounts of N-CAM. Coculture of these cells with C2 cells results in the clustering of N-CAM at heterologous contacts between C2 cells and NRK, CHO, or PC12 cells, but not between C2 cells and L929 cells. These results suggest that N-CAM specifically accumulates where N-CAM-bearing cells contact one another. Clustering of N-CAM may be an important step in strengthening intercellular adhesion.     

INGAP-related pentadecapeptide: its modulatory effect upon insulin secretion

We examined the effects of a pentadecapeptide having the 104-118 aminoacid sequence of islet neogenesis-associated protein (INGAP-PP) on insulin secretion, and the morphological characteristics of adult and neonatal pancreatic rat islets cultured in RPMI and 10 mM glucose for 4 days, with or without different INGAP-PP concentrations (0.1-100 mug/ml). A scrambled 15 aminoacid peptide was used as control for the specificity of INGAP-PP effect. Cultured neonatal and adult islets released insulin in response to glucose (2.8-16.7 mM) in a dose-dependent manner, and to leucine and arginine (10 mM). In all cases, the response was greater in adult islets. INGAP-PP added to the culture medium significantly enhanced glucose- and aminoacid-induced insulin release in both adult and newborn rats; however, no changes were observed with the scrambled peptide. Similar results were obtained incubating freshly isolated adult rat islets with INGAP-PP. Whereas INGAP-PP did not induce significant changes in islet survival rate or proportion/number of islet cells, it increased significantly beta-cell size. This first demonstration of the enhancing effect of INGAP-PP on the beta-cell secretory response of adult and newborn islets opens a new avenue to study its production mechanism and potential use to increase the secretory capacity of endogenous islets in intact animals or of islets preserved for future transplants.     

Expression of glucose transporter-2, glucokinase and mitochondrial glycerolphosphate dehydrogenase in pancreatic islets during rat ontogenesis.

To gain better insight into the insulin secretory activity of fetal beta cells in response to glucose, the expression of glucose transporter 2 (GLUT-2), glucokinase and mitochondrial glycerol phosphate dehydrogenase (mGDH) were studied. Expression of GLUT-2 mRNA and protein in pancreatic islets and liver was significantly lower in fetal and suckling rats than in adult rats. The glucokinase content of fetal islets was significantly higher than of suckling and adult rats, and in liver the enzyme appeared for the first time on about day 20 of extrauterine life. The highest content of hexokinase I was found in fetal islets, after which it decreased progressively to the adult values. Glucokinase mRNA was abundantly expressed in the islets of all the experimental groups, whereas in liver it was only present in adults and 20-day-old suckling rats. In fetal islets, GLUT-2 and glucokinase protein and their mRNA increased as a function of increasing glucose concentration, whereas reduced mitochondrial citrate synthase, succinate dehydrogenase and cytochrome c oxidase activities and mGDH expression were observed. These findings, together with those reported by others, may help to explain the decreased insulin secretory activity of fetal beta cells in response to glucose.     

Critical Role of Gap Junction Coupled KATP Channel Activity for Regulated Insulin Secretion

Pancreatic β-cells secrete insulin in response to closure of ATP-sensitive K⁺ (K_ATP) channels, which causes membrane depolarization and a concomitant rise in intracellular Ca²⁺ (Ca_i). In intact islets, β-cells are coupled by gap junctions, which are proposed to synchronize electrical activity and Ca_i oscillations after exposure to stimulatory glucose (>7 mM). To determine the significance of this coupling in regulating insulin secretion, we examined islets and β-cells from transgenic mice that express zero functional K_ATP channels in approximately 70% of their β-cells, but normal K_ATP channel density in the remainder. We found that K_ATP channel activity from approximately 30% of the β-cells is sufficient to maintain strong glucose dependence of metabolism, Ca_i, membrane potential, and insulin secretion from intact islets, but that glucose dependence is lost in isolated transgenic cells. Further, inhibition of gap junctions caused loss of glucose sensitivity specifically in transgenic islets. These data demonstrate a critical role of gap junctional coupling of K_ATP channel activity in control of membrane potential across the islet. Control via coupling lessens the effects of cell–cell variation and provides resistance to defects in excitability that would otherwise lead to a profound diabetic state, such as occurs in persistent neonatal diabetes mellitus.     

Beta cell contact and insulin release

Insulin secretion by intact islets, dispersed islet cells and dispersed cells allowed to reaggregate was compared in perifusion. Although single cells and aggregates showed basal insulin secretion and a prompt response to glucose challenge, basal secretion, peak insulin secretion and total insulin secretion during a 60 minute stimulation were profoundly less than those activities of intact islets. These results suggest that dispersed beta cells are responsive to glucose as a secretagogue, but the magnitude of the response is greatly diminished and not restored by simple cell contact.     

Effects of glucose on insulin release and 86Rb permeability in cultured neonatal and adult rat islets

Glucose-induced insulin release and modifications in 86Rb outflow were studied in cultured neonatal and adult rat islets. The dose-response curve for neonatal islets was steeper than for adult islets and the maximal response was clearly shifted towards lower glucose concentrations. In neonatal islets, glucose-induced insulin release was inhibited by the Ca2+-channel blocker, nifedipine. In the absence of glucose, the 86Rb outflow from neonatal islets was lower than from adult islets. Also, the glucose-induced reduction in 86Rb outflow was less pronounced in neonatal islets. Altered K+ permeability in the B-cell membrane could explain the change in glucose sensitivity of neonatal islets.     

Heterogeneity and contact-dependent regulation of hormone secretion by individual B cells

A reverse hemolytic plaque assay was developed to visualize insulin release from individual adult pancreatic B cells. Cells obtained by mechanical dispersion of isolated rat islets of Langerhans were mixed with protein A-coated sheep red blood cells and incubated in the presence of an anti-insulin serum, under conditions known to affect insulin release. The cell mixture was further incubated with complement and finally fixed. Insulin release was revealed by the presence of hemolytic plaques which resulted from the complement-mediated lysis of red blood cells bearing insulin-anti-insulin complexes bound to protein A. Quantitation of hemolytic plaques around trypan blue-unstained and immunohistochemically identified B cells showed that stimulation of insulin release results in the recruitment of increasing numbers of secreting B cells as well as in the enhanced response of individual B cells. Reverse changes occur upon inhibition of insulin release. Comparison of freshly dispersed and one-day-cultured preparations did not reveal significant differences in the secretory response of undamaged B cells. In both preparations, single B cells responded to secretagogues in smaller proportions and to a lesser extent than clusters in which B cells had either maintained or restored contacts and junctional communication with their neighbours. However, the overall preponderant response of clusters was less than expected from the number of individually secreting B cells they contained. The data show that B cells are heterogeneous in terms of their ability to release insulin and provide evidence that cell-to-cell adhesion and/or junctional communication regulate hormone secretion from individual B cells.     

Pancreatic beta cell heterogeneity in glucose-induced insulin secretion.

Rat pancreatic beta cells differ in their individual sensitivity to glucose-inducible metabolic changes. The present study examines whether beta cells with a higher metabolic threshold require higher glucose levels for stimulation of their secretory activity. Purified beta cells were distributed according to their metabolic redox state at 7.5 mM glucose; the metabolically responsive (high responsive) and unresponsive (low responsive) subpopulations of comparable size and viability were reaggregated in the presence of [3H]tyrosine and then perfused at 2.8 mM glucose with 10-min pulses of increasing glucose concentration. Glucose elicited first-phase insulin release in both high and low responsive subpopulations from, respectively, 4.2 and 8.3 mM on. The amplitude of both secretory responses increased dose dependently, the rates in the high responsive subpopulation being 2-fold higher than in the low responsive one. At all stimulating glucose levels, fractional release of 3H-labeled insulin was 3- to 4-fold higher than that of immunoreactive insulin. Preferential release of newly formed insulin was already maximally stimulated at 4.2 mM glucose in the high responsive subpopulation, whereas it increased dose-dependently in the low responsive one. These results indicate the existence of intercellular differences in the secretory activity of glucose-exposed beta cells, both in terms of glucose sensitivity and of amplitude. This heterogeneity in beta cell secretory responsiveness parallels that which has been previously described for the cellular metabolic and biosynthetic functions. It is concluded that glucose dose-dependently recruits beta cells into both biosynthetic and secretory activities. Co-existence of inactive and activated cells can explain preferential release of newly synthesized over preformed hormone during glucose stimulation.     

EphA-Ephrin-A-mediated beta cell communication regulates insulin secretion from pancreatic islets

In vertebrates, beta cells are aggregated in the form of pancreatic islets. Within these islets, communication between beta cells inhibits basal insulin secretion and enhances glucose-stimulated insulin secretion, thus contributing to glucose homeostasis during fasting and feeding. In the search for the underlying molecular mechanism, we have discovered that beta cells communicate via ephrin-As and EphAs. We provide evidence that ephrin-A5 is required for glucose-stimulated insulin secretion. We further show that EphA-ephrin-A-mediated beta cell communication is bidirectional: EphA forward signaling inhibits insulin secretion, whereas ephrin-A reverse signaling stimulates insulin secretion. EphA forward signaling is downregulated in response to glucose, which indicates that, under basal conditions, beta cells use EphA forward signaling to suppress insulin secretion and that, under stimulatory conditions, they shift to ephrin-A reverse signaling to enhance insulin secretion. Thus, we explain how beta cell communication in pancreatic islets conversely affects basal and glucose-stimulated insulin secretion to improve glucose homeostasis.     

Soybean diet improves insulin secretion through activation of cAMP/PKA pathway in rats

Maternal malnutrition leads to permanent alterations in insulin secretion of offspring and the soybean diet contributes to improve insulin release. At least a soy component, genistein, seems to increase the insulin secretion by activating the cAMP/PKA and PLC/PKC pathways. Here, we investigated the effect of the soybean diet on the expression of PKAalpha and PKCalpha, and insulin secretion in response to glucose and activators of adenylate cyclase and PKC in adult pancreatic rat islets. Rats from mothers fed with 17% or 6% protein (casein) during pregnancy and lactation were maintained with 17% casein (CC and CR groups) or soybean (SC and SR groups) diet until 90 days of life. The soybean diet improved the insulin response to a physiological concentration of glucose in control islets, but only in the presence of supra-physiological concentrations of glucose in islets from CR and SR groups. PMA also improved the insulin response in islets of SC and SR groups. The expression of PKCalpha was similar in all groups. Forskolin increased the insulin secretion; however, the magnitude of the increment was lower in islets from CR and SR groups than in control animals and in those from rats maintained with soybean diet than in rats fed with casein diet. The PKAalpha expression was similar between SR and CR groups and lower in SC than in CC islets. Thus, soybean diet improved the secretory pattern of beta cells, at least in part, by activating the cAMP/PKA-signaling cascade.     

Expression of glucagon-like peptide-1 (GLP-1) receptor and the effect of GLP-1-(7-36) amide on insulin release by pancreatic islets during rat ontogenic development.

The expression of glucagon-like peptide-1 (GLP-1) receptor and the effects of GLP-1-(7-36) amide (t-GLP-1) on glucose metabolism and insulin release by pancreatic islets during rat development were studied. GLP-1 receptor mRNA was found in significant amounts in pancreatic islets from all age groups studied, GLP-1 receptor expression being maximal when pancreatic islets were incubated at physiological glucose concentration (5.5 mM), but decreasing significantly when incubated with either 1.67 or 16.7 mM glucose. Glucose utilization and oxidation by pancreatic islets from fetal and adult rats rose as a function of glucose concentration, always being higher in fetal than in adult islets. The addition of t-GLP-1 to the incubation medium did not modify glucose metabolism but gastric inhibitory polypeptide and glucagon significantly increased glucose utilization by fetal and adult pancreatic islets at 16.7 mM glucose. At this concentration, glucose produced a significant increase in insulin release by the pancreatic islets from 10-day-old and 20-day-old suckling rats and adult rats, whereas those from fetuses showed only a significant increase when glucose was raised from 1.67 to 5.5 mM. t-GLP-1 elicited an increase in insulin release by pancreatic islets from all the experimental groups when the higher glucose concentrations were used. Our findings indicate that GLP-1 receptors and the effect of t-GLP-1 on insulin release are already present in the fetus, and they therefore exclude the possibility that alterations in the action of t-GLP-1 are responsible for the unresponsiveness of pancreatic beta cells to glucose in the fetus, but stimulation of t-GLP-1 release by food ingestion in newborns may partially confer glucose competence on beta cells.     

Leptin administration normalizes insulin secretion from islets of Lep(ob)/Lep(ob) mice by food intake-dependent and -independent mechanisms

Leptin-deficient Lep(ob)/Lep(ob) mice exhibit elevations in plasma insulin early in development. The present study tested the hypothesis that absence of leptin during neonatal development permanently programs islets from these mice to hypersecrete insulin. Administration of leptin for 8 days to young adult Lep(ob)/Lep(ob) mice normalized their food intake, plasma insulin concentration, and insulin secretion in response to glucose, acetylcholine, and leptin. Restriction of food intake per se of Lep(ob)/Lep(ob) mice lowered, but did not normalize, plasma insulin concentrations. Food-restricted Lep(ob)/Lep(ob) mice continued to hypersecrete insulin in response to glucose, but islets from these mice did not hyperrespond to acetylcholine or respond to leptin as occurs in ad libitum-fed Lep(ob)/Lep(ob) mice. We conclude that neonatal leptin deficiency does not permanently program islets from mice to hypersecrete insulin. The hyperphagia associated with leptin deficiency contributes substantially to the hypersecretion of insulin, but leptin also appears to have more direct effects on regulation of insulin secretion.     

Glucose refractoriness of beta-cells from fed fa/fa rats is ameliorated by nonesterified fatty acids

The aim of this study was to characterize the glucose responsiveness of individual beta-cells from fa/fa rats under ad libitum feeding conditions. Enlarged intact islets from fed fa/fa rats had a compressed insulin response curve to glucose compared with smaller islets. Size-sorted islets from obese rats yielded beta-cells whose glucose responsiveness was assessed by reverse hemolytic plaque assay to determine whether glucose refractoriness was caused by a decreased number of responsive cells or output per cell. In addition, the effects of palmitic acid on glucose-stimulated insulin secretion were assessed because of evidence that nonesterified fatty acids have acute beneficial effects. Two- to threefold more beta-cells from >250 microm diameter (large) islets than <125 microm diameter (small) or lean islets responded to low glucose. Increasing the glucose (8.3-16.5 mM) induced a >10-fold increase in recruitment of active cells from small islets, compared with only a 2.6-fold increase in large islets. This refractoriness was partially reversed by preincubation of the cells in low glucose for 2 h. In addition, secretion per cell of the large islet beta-cell population was significantly reduced compared with lean beta-cells, so that the overall response capacity of large but not small islet beta-cells was significantly reduced at high glucose. Therefore, continued near-normal function of the beta-cells from small islets of fa/fa rats seems crucial for glucose responsiveness. Incubation of beta-cells from large islets with palmitic acid normalized the secretory capacity to glucose mainly by increasing recruitment and secondarily by increasing secretion per cell. In conclusion, these studies demonstrate refractoriness to glucose of beta-cells from large islets of fa/fa rats under ad libitum feeding conditions. When acutely exposed to nonesterified fatty acids, islets from fa/fa rats have a potentiated insulin response despite chronic elevation of plasma lipids in vivo.     

Effects of growth hormone on the in vitro maturation of fetal islets

To study the effects of growth hormone (GH) on the in vitro maturation of fetal islets, the fetal islets were cultured for 7 days in RPMI 1640 containing 10% fetal bovine serum and 11.1 mM glucose with or without GH. Culture with 1 microgram/ml of bovine GH increased the DNA content of the islets and [3H]thymidine incorporation into DNA confirming results of other investigators. In addition, however, the insulin secretory dynamics and ultrastructural morphometrics were investigated. It was found that GH-treated islets demonstrated increased insulin release during acute glucose stimulation when expressed as microunits per islet per minute. However, when insulin release during acute glucose stimulation was expressed as microunits per microgram of DNA per minute to compensate for the increased DNA content of GH-treated islets, no change in insulin release was observed compared to control islets. When GH-treated islets were perifused with a linear glucose gradient, the insulin secretory response was suppressed as indicated by changes in the threshold level, plateau level, and half-maximal response. Ultrastructural morphometric data showed that the average beta-cell volume in control and GH-treated islets was the same, eliminating the possibility that beta-cell hypertrophy occurred. Similarly, the nuclear volumes of the beta cells in control and GH-treated islets remained unchanged. This finding coupled with the observed increased DNA content and [3H]thymidine incorporation suggests that GH functions by increasing cell multiplication within the islets and not by inducing polyploidy. Finally, the volumes of cytoplasmic organelles in control and GH-treated islets were the same indicating that cytodifferentiation did not occur.     

Chemiosmotic lysis and insulin secretion: studies of isolated granules, intact and permeabilised rat islets of Langerhans

The possible involvement of chemiosmotic lysis of secretory granules in the exocytosis of insulin from pancreatic beta cells was investigated by comparing insulin release from isolated secretory granules, from intact islets of Langerhans, and from electrically permeabilised islets. Lysis of isolated granules was stimulated by ATP in the presence of Mg2+. ATP-induced granule lysis was pH and temperature dependent and was inhibited by collapsing the pH gradient across the granule membrane by removal of permeant anions, or by increasing the extragranular osmolarity. However, insulin secretion from intact islets in response to glucose, a phosphodiesterase inhibitor or a Ca2+ ionophore was only partially inhibited by anion replacement, while Ca2+ -induced insulin release from electrically permeabilised islets was not affected by altering the extragranular or intragranular pH. These results suggest that studies of the stability of isolated granules in vitro do not necessarily relate to insulin release from whole cells, and do not support a major role for chemiosmotic lysis of secretory granules in the exocytotic release of insulin.     

Insulin Secretion, DNA Damage, and Apoptosis in Human and Rat Islets of Langerhans Following Exposure to Nitric Oxide, Peroxynitrite, and Cytokines

Cytokine-induced damage may contribute to destruction of insulin-secreting beta-cells in islets of Langerhans during autoimmune diabetes. There is considerable controversy (i) whether human and rat islets respond differently to cytokines, (ii) the extent to which cytokine damage is mediated by induction of nitric oxide formation, and (iii) whether the effects of nitric oxide on islets can be distinguished from those of reactive oxygen species or peroxynitrite. We have analyzed rat and human islet responses in parallel, 48 h after exposure to the nitric oxide donor S-nitrosoglutathione, the mixed donor 3-morpholinosydnonimine, hypoxanthine/xanthine oxidase, peroxynitrite, and combined cytokines (interleukin-1beta, tumor necrosis factor-alpha and interferon-gamma). Insulin secretory response to glucose, insulin content, DNA strand breakage, and early-to-late stage apoptosis were recorded in each experiment. Rat islet insulin secretion was reduced by S-nitrosoglutathione or combined cytokines, but unexpectedly increased by peroxynitrite or hypoxanthine/xanthine oxidase. Effects on human islet insulin secretion were small; cytokines and S-nitrosoglutathione decreased insulin content. Both rat and human islets showed significant and similar levels of DNA damage following all treatments. Apoptosis in neonatal rat islets was increased by every treatment, but was at a low rate in adult rat or human islets and only achieved significance with cytokine treatment of human islets. All cytokine responses were blocked by an arginine analogue. We conclude: (i) Reactive oxygen species increased and nitric oxide decreased insulin secretory responsiveness in rat islets. (ii) Species differences lie mainly in responses to cytokines, applied at a lower dose and shorter time than in most studies of human islets. (iii) Cytokine effects were nitric oxide driven; neither reactive oxygen species nor peroxynitrite reproduced cytokine effects. (iv) Rat and human islets showed equal susceptibility to DNA damage. (v) Apoptosis was not the preferred death pathway in adult islets. (vi) We have found no evidence of human donor variation in the pattern of response to these treatments.     

Dynamin-mediated Nephrin Phosphorylation Regulates Glucose-stimulated Insulin Release in Pancreatic Beta Cells

We have previously demonstrated a role for Nephrin in glucose stimulated insulin release (GSIR). We now hypothesize that Nephrin phosphorylation is required for GSIR and that Dynamin influences Nephrin phosphorylation and function. MIN6-C3 Nephrin-deficient pancreatic beta cells and human islets were transfected with WT-Nephrin or with a mutant Nephrin in which the tyrosine residues responsible for SH2 domain binding were substituted with phenylalanine (3YF-Nephrin). GSIR and live images of Nephrin and vesicle trafficking were studied. Immunoprecipitation experiments and overexpression of WT-Dynamin or dominant negative Dynamin mutant (K44A-Dynamin) in WT-Nephrin, 3YF-Nephrin, or Nephrin siRNA-transfected cells were utilized to study Nephrin-Dynamin interaction. In contrast to WT-Nephrin or to single tyrosine mutants, 3YF-Nephrin did not positively affect GSIR and led to impaired cell-cell contacts and vesicle trafficking. K44A-Dynamin prevented the effect of Nephrin on GSIR in the absence of protein-protein interaction between Nephrin and Dynamin. Nephrin gene silencing abolished the positive effects of WT-Dynamin on GSIR. The effects of protamine sulfate and vanadate on Nephrin phosphorylation and GSIR were studied in MIN6 cells and human islets. WT-Nephrin phosphorylation after glucose occurred at Tyr-1176/1193 and resulted in improved GSIR. On the contrary, protamine sulfate-induced phosphorylation at Tyr-1176/1193/1217 was associated with Nephrin degradation and impaired GSIR. Vanadate, which prevented Nephrin dephosphorylation after glucose stimulation, improved GSIR in human islets and MIN6 cells. In conclusion, Dynamin-dependent Nephrin phosphorylation occurs in response to glucose and is necessary for Nephrin-mediated augmentation of GSIR. Pharmacological modulation of Nephrin phosphorylation may thus facilitate pancreatic beta cell function.     

Learning Theories Reveal Loss of Pancreatic Electrical Connectivity in Diabetes as an Adaptive Response

Cells of almost all solid tissues are connected with gap junctions which permit the direct transfer of ions and small molecules, integral to regulating coordinated function in the tissue. The pancreatic islets of Langerhans are responsible for secreting the hormone insulin in response to glucose stimulation. Gap junctions are the only electrical contacts between the beta-cells in the tissue of these excitable islets. It is generally believed that they are responsible for synchrony of the membrane voltage oscillations among beta-cells, and thereby pulsatility of insulin secretion. Most attempts to understand connectivity in islets are often interpreted, bottom-up, in terms of measurements of gap junctional conductance. This does not, however, explain systematic changes, such as a diminished junctional conductance in type 2 diabetes. We attempt to address this deficit via the model presented here, which is a learning theory of gap junctional adaptation derived with analogy to neural systems. Here, gap junctions are modelled as bonds in a beta-cell network, that are altered according to homeostatic rules of plasticity. Our analysis reveals that it is nearly impossible to view gap junctions as homogeneous across a tissue. A modified view that accommodates heterogeneity of junction strengths in the islet can explain why, for example, a loss of gap junction conductance in diabetes is necessary for an increase in plasma insulin levels following hyperglycemia.