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.     

Pancreas-Specific Sirt1-Deficiency in Mice Compromises Beta-Cell Function without Development of Hyperglycemia

Aims/Hypothesis

Sirtuin 1 (Sirt1) has been reported to be a critical positive regulator of glucose-stimulated insulin secretion in pancreatic beta-cells. The effects on islet cells and blood glucose levels when Sirt1 is deleted specifically in the pancreas are still unclear.

Methods

This study examined islet glucose responsiveness, blood glucose levels, pancreatic islet histology and gene expression in Pdx1^Cre; Sirt1^ex4F/F mice that have loss of function and loss of expression of Sirt1 specifically in the pancreas.

Results

We found that in the Pdx1^Cre; Sirt1^ex4F/F mice, the relative insulin positive area and the islet size distribution were unchanged. However, beta-cells were functionally impaired, presenting with lower glucose-stimulated insulin secretion. This defect was not due to a reduced expression of insulin but was associated with a decreased expression of the glucose transporter Slc2a2/Glut2 and of the Glucagon like peptide-1 receptor (Glp1r) as well as a marked down regulation of endoplasmic reticulum (ER) chaperones that participate in the Unfolded Protein Response (UPR) pathway. Counter intuitively, the Sirt1-deficient mice did not develop hyperglycemia. Pancreatic polypeptide (PP) cells were the only other islet cells affected, with reduced numbers in the Sirt1-deficient pancreas.

Conclusions/Interpretation

This study provides new mechanistic insights showing that beta-cell function in Sirt1-deficient pancreas is affected due to altered glucose sensing and deregulation of the UPR pathway. Interestingly, we uncovered a context in which impaired beta-cell function is not accompanied by increased glycemia. This points to a unique compensatory mechanism. Given the reduction in PP, investigation of its role in the control of blood glucose is warranted.     

Iron overload in Hepc1(-/-) mice is not impairing glucose homeostasis

Diabetes Mellitus is found with increasing frequency in iron overload patients with hemochromatosis. In these conditions, the pancreas shows predominant iron overload in acini but also islet beta-cells. We assess glucose homeostasis status in iron-overloaded hepcidin-deficient mice. These mice presented with heavy pancreatic iron deposits but only in the acini. The beta-cell function was found unaffected with a normal production and secretion of insulin. The mutant mice were not diabetic, responded as the control group to glucose and insulin challenges, with no alteration of insulin signalling in the muscle and the liver. These results indicate that, beta-cells iron deposits-induced decreased insulin secretory capacity might be of primary importance to trigger diabetes in hemochromatosic patients.     

Glucose-induced production of hydrogen sulfide may protect the pancreatic beta-cells from apoptotic cell death by high glucose

We examined the expression of the major H₂S-producing enzymes, cystathionine-β-synthase (CBS) and cystathionine-γ-lyase (CSE). CBS was ubiquitously distributed in the mouse pancreas, but CSE was found only in the exocrine. Freshly isolated islets expressed CBS, while CSE was faint. However, high glucose increased the CSE expression in the beta-cells. l-Cysteine or NaHS suppressed islet cell apoptosis with high glucose, and increased glutathione content in MIN6 beta-cells. Pretreatment with l-cysteine improved the secretory responsiveness following stimulation with glucose. The CSE inhibitor dl-propargylglycine antagonized these l-cysteine effects. We suggest H₂ S may function as an ‘intrinsic brake’ which protects beta-cells from glucotoxicity.     

The endocrine pancreas during pregnancy and lactation in the rat

The percentage of endocrine tissue in the whole pancreas, the volume density of the insulin producing beta-cells, the non-fasting plasma glucose level and the plasma insulin level were studied in pregnant rats and in puerperal lactating and non-lactating rats. During pregnancy there was a progressive rise in the percentage of endocrine tissue, in the volume density of the beta-cells and in the insulin level in peripheral blood. Plasma glucose levels declined during pregnancy. A lower plasma glucose level, a lower plasma insulin level, a lower percentage of endocrine tissue and a lower volume density of the beta-cells was found in lactating compared to non-lactating rats.     

Transcranial electrical stimulation activates the reparative regeneration and insulin-producing function of beta-cells in alloxan-induced diabetic rats

In alloxan-induced diabetic rats, it was demonstrated that transcranial electrical stimulation of the brain endorphinergic structures activated the reparative regeneration of the damaged beta-cells of the Langerhans pancreatic islets. This was estimated on the histological sections of pancreas with hematoxylin-eosin staining. Several small newborn islets were found to originate from pancreatic progenitor cells. After transcranial electrical stimulation of insulin granules, beta-cells (Gomori's staining) were observed as an indication of the restoration of the insulin production. Correspondingly the increase of the blood insulin level was estimated by immune-enzyme method. The dynamics of the plasma insulin increase had a significant negative correlation with decrease of the blood glucose level. The glucose-lowering action of the transcranial electrical stimulation in alloxan-induced diabetic rats seems to be based on stimulation of the regeneration of damaged beta-cells with the restoration of their insulin production.     

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.     

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.     

Tyrosine hydroxylase in mouse pancreatic islet cells, in situ and after syngeneic transplantation to kidney

Tyrosine hydroxylase (TH) is co-expressed with islet hormones in the fetal mouse pancreas. In the adult animal, the enzyme has been considered as a marker of ageing beta-cells. By immunohistochemical staining, we analyzed the expression of TH-like immunoreactivity (TH-LI), insulin-LI (INS-LI) and somatostatin-LI (SOM-LI) in adult mouse islets, in situ and after isolation and transplantation to kidney. In pancreas in situ, most TH-LI cells expressed INS-LI while less than 5% expressed SOM-LI. The total number of TH-LI cells/mm2 was significantly increased directly after isolation and in 0-day, 12-week and 52-week old grafts, but not in 3-day grafts. The proportion of TH-LI cells expressing SOM-LI increased after transplantation, amounting to about one-third by 52 weeks. As expressed per unit islet area, the frequencies of both TH/INS and TH/SOM cells increased significantly in the transplants. The results demonstrate that TH occurs in both beta-cells and D-cells of adult islets. In both cell types the enzyme appears to be responsive to the microenvironmental changes inherent in transplantation. This cellular phenotype plasticity might contribute to the altered insulin secretory dynamics in islet grafts.     

Expression of K+-Cl- cotransporters in the alpha-cells of rat endocrine pancreas

The expression of K+-Cl- cotransporters (KCC) was examined in pancreatic islet cells. mRNA for KCC1, KCC3a, KCC3b and KCC4 were identified by RT-PCR in islets isolated from rat pancreas. In immunocytochemical studies, an antibody specific for KCC1 and KCC4 revealed the expression of KCC protein in alpha-cells, but not pancreatic beta-cells nor delta-cells. A second antibody which does not discriminate among KCC isoforms identified KCC expression in both alpha-cell and beta-cells. Exposure of isolated alpha-cells to hypotonic solutions caused cell swelling was followed by a regulatory volume decrease (RVD). The RVD was blocked by 10 microM [dihydroindenyl-oxy] alkanoic acid (DIOA; a KCC inhibitor). DIOA was without effect on the RVD in beta-cells. NEM (0.2 mM), a KCC activator, caused a significant decrease of alpha-cell volume, which was completely inhibited by DIOA. By contrast, NEM had no effects on beta-cell volume. In conclusion, KCCs are expressed in pancreatic alpha-cells and beta-cells. However, they make a significant contribution to volume homeostasis only in alpha-cells.     

大鼠胰腺发育阶段Mesothelin的表达

目的:研究Mesothenlin在大鼠胰腺发育阶段的表达和细胞定位。方法:运用RT-PCR和Western Blot技术分别检测Mesothenlin在大鼠胰腺发育阶段的mRNA和蛋白表达水平;运用免疫荧光检测不同时期Mesothenlin在胰腺的组织细胞学定位。结果:RT-PCR结果显示E18.5 Mesothelin mRNA的表达水平显著增高,至P14达到高峰,成年较低。Western Blot结果显示其蛋白表达趋势与mRNA完全相同。免疫荧光结果显示在不同发育时期Mesothenlin与胰岛β细胞和间充质细胞共表达。结论:Mesothenlin在大鼠胚胎胰岛形成及生后结构重塑中出现显著性高表达,并表达于胰岛β细胞和间充质细胞。     

Immunocytochemical detection of glucagon and insulin cells in endocrine pancreas and cyclic disparity of plasma glucose in the turtle Melanochelys trijuga

The present investigation was carried out to know the seasonal variation in plasma glucose,insulin and glucagon cells during the reproductive cycle of untreated Melanochelys trijuga. Pancreatic endocrine cells were immunochemically localized.Insulin-immunoreactive (IR) cells occurred in groups of 3-20 and were in close apposition, while glucagon-IR cells were distributed individually between the exocrine pancreas or formed anastomosing cords where cells were not intimately attached. Whenever both IR cell types were present together forming an islet,insulin-IR cells formed clusters in the centre with glucagon-IR cells being scattered at the periphery. Glucagon-IR cells seemed to be secretory throughout the pancreas during the reproductive cycle,while insulin-IR cells were found to be pulsating in their secretion. Mean size of the islet was 1.306, 0.184 and 2.558 mm in the regenerative, reproductive and regressive periods,respectively. In general,insulin-IR cells measured 5.18 (mu)m and glucagon-IR cells 5.22 (mu)m in their longest axis. Invariably, glucagon-IR cells were more in number than insulin-IR cells. The fasting plasma glucose level was 69.97 mg% during the regenerative period, which increased to 97.96 mg% during the reproductive period,and reached a peak value of 113.52 mg% in the regressive period.     

Cytochemical glucose-6-phosphatase activity in the cells of mouse pancreas and submandibular gland

Ultrastructural localization of glucose-6-phosphatase activity was studied in the cells of the pancreas and submandibular gland of the mouse using a incubation medium modified from that of Wachstein & Meisel (1956). In pancreatic acinar cells, the reaction product for the enzyme activity was not found even after 90 min of incubation with three changes of the medium. However, the reaction product was localized in the endoplasmic reticulum and nuclear envelope of all other cell types composing the pancreas and submandibular gland. The reaction product appeared in moderate to abundant amounts in acinar cells and striated duct cells of the submandibular gland, and in the B cells, A and D cells of the pancreatic islet, but it was scarce in other cell types.     

Islet Formation during the Neonatal Development in Mice

The islet of Langerhans is a unique micro-organ within the exocrine pancreas, which is composed of insulin-secreting beta-cells, glucagon-secreting alpha-cells, somatostatin-secreting delta-cells, pancreatic polypeptide-secreting PP cells and ghrelin-secreting epsilon-cells. Islets also contain non-endocrine cell types such as endothelial cells. However, the mechanism(s) of islet formation is poorly understood due to technical difficulties in capturing this dynamic event in situ. We have developed a method to monitor beta-cell proliferation and islet formation in the intact pancreas using transgenic mice in which the beta-cells are specifically tagged with a fluorescent protein. Endocrine cells proliferate contiguously, forming branched cord-like structures in both embryos and neonates. Our study has revealed long stretches of interconnected islets located along large blood vessels in the neonatal pancreas. Alpha-cells span the elongated islet-like structures, which we hypothesize represent sites of fission and facilitate the eventual formation of discrete islets. We propose that islet formation occurs by a process of fission following contiguous endocrine cell proliferation, rather than by local aggregation or fusion of isolated beta-cells and islets. Mathematical modeling of the fission process in the neonatal islet formation is also presented.     

Receptors for insulin and insulin-like growth factor-1 and insulin receptor substrate-1 mediate pathways that regulate islet function

The insulin/insulin-like growth factor-1 (IGF-1) signalling pathways are present in most mammalian cells and play important roles in the growth and metabolism of tissues. Most proteins in these pathways have also been identified in the beta-cells of the pancreatic islets. Tissue-specific knockout of the insulin receptor (betaIRKO) or IGF-1 receptor (betaIGFRKO) in pancreatic beta-cells leads to altered glucose-sensing and glucose intolerance in adult mice, and betaIRKO mice show an age-dependent decrease in islet size and beta-cell mass. These data indicate that these receptors are important for differentiated function and are unlikely to play a major role in the early growth and/or development of the pancreatic islets. Conventional insulin receptor substrate-1 (IRS-1) knockouts manifest growth retardation and mild insulin resistance. The IRS-1 knockouts also display islet hyperplasia, defects in insulin secretory responses to multiple stimuli both in vivo and in vitro, reduced islet insulin content and an increased number of autophagic vacuoles in the beta-cells. Re-expression of IRS-1 in cultured beta-cells is able to partially restore the insulin content indicating that IRS-1 is involved in the regulation of insulin synthesis. Taken together, these data provide evidence that insulin and IGF-1 receptors and IRS-1, and potentially other proteins in the insulin/IGF-1 signalling pathway, contribute to the regulation of islet hormone secretion and synthesis and therefore in the maintenance of glucose homeostasis.     

beta-cell adaptation in 60% pancreatectomy rats that preserves normoinsulinemia and normoglycemia

Islet beta-cells are the regulatory element of the glucose homeostasis system. When functioning normally, they precisely counterbalance changes in insulin sensitivity or beta-cell mass to preserve normoglycemia. This understanding seems counter to the dogma that beta-cells are regulated by glycemia. We studied 60% pancreatectomy rats (Px) 4 wk postsurgery to elucidate the beta-cell adaptive mechanisms. Nonfasting glycemia and insulinemia were identical in Px and sham-operated controls. There was partial regeneration of the excised beta-cells in the Px rats, but it was limited in scope, with the pancreas beta-cell mass reaching 55% of the shams (40% increase from the time of surgery). More consequential was a heightened glucose responsiveness of Px islets so that glucose utilization and insulin secretion per milligram of islet protein were both 80% augmented at normal levels of glycemia. Investigation of the biochemical basis showed a doubled glucokinase maximal velocity in Px islets, with no change in the glucokinase protein concentration after adjustment for the different beta-cell mass in Px and sham islets. Hexokinase activity measured in islet extracts was also minimally increased, but the glucose 6-phosphate concentration and basal glucose usage of Px islets were not different from those in islets from sham-operated rats. The dominant beta-cell adaptive response in the 60% Px rats was an increased catalytic activity of glucokinase. The remaining beta-cells thus sense, and respond to, perceived hyperglycemia despite glycemia actually being normal. beta-Cell mass and insulin secretion are both augmented so that whole pancreas insulin output, and consequently glycemia, are maintained at normal levels.     

Glucose promotes pancreatic islet beta-cell survival through a PI 3-kinase/Akt-signaling pathway

The concentration of glucose in plasma is an important determinant of pancreatic beta-cell mass, whereas the relative contributions of hypertrophy, proliferation, and cell survival to this process are unclear. Glucose results in depolarization and subsequent calcium influx into islet beta-cells. Because depolarization and calcium (Ca(2+)) influx promote survival of neuronal cells, we hypothesized that glucose might alter survival of islet beta-cells through a similar mechanism. In the present studies, cultured mouse islet beta-cells showed a threefold decrease in apoptosis under conditions of 15 mM glucose compared with 2 mM glucose (P < 0.05). MIN6 insulinoma cells incubated in 25 mM glucose for 24 h showed a threefold decrease in apoptosis compared with cells in 5 mM glucose (1.7 +/- 0.2 vs. 6.3 +/- 1%, respectively, P < 0.001). High glucose (25 mM) enhanced survival-required depolarization and Ca(2+) influx and was blocked by phosphatidylinositol (PI) 3-kinase inhibitors. Glucose activation of the protein kinase Akt was demonstrated in both insulinoma cells and cultured mouse islets by means of an antibody specific for Ser(473) phospho-Akt and by an in vitro Akt kinase assay. Akt phosphorylation was dependent on PI 3-kinase but not on MAPK. Transfection of insulinoma cells with an Akt kinase-dead plasmid (Akt-K179M) resulted in loss of glucose-mediated protection, whereas transfection with a constitutively active Akt enhanced survival in glucose-deprived insulinoma cells. The results of these studies defined a novel pathway for glucose-mediated activation of a PI 3-kinase/Akt survival-signaling pathway in islet beta-cells. This pathway may provide important targets for therapeutic intervention.     

Transgenic mice with green fluorescent protein-labeled pancreatic beta -cells

We have generated transgenic mice that express green fluorescent protein (GFP) under the control of the mouse insulin I gene promoter (MIP). The MIP-GFP mice develop normally and are indistinguishable from control animals with respect to glucose tolerance and pancreatic insulin content. Histological studies showed that the MIP-GFP mice had normal islet architecture with coexpression of insulin and GFP in the beta-cells of all islets. We observed GFP expression in islets from embryonic day E13.5 through adulthood. Studies of beta-cell function revealed no difference in glucose-induced intracellular calcium mobilization between islets from transgenic and control animals. We prepared single-cell suspensions from both isolated islets and whole pancreas from MIP-GFP-transgenic mice and sorted the beta-cells by fluorescence-activated cell sorting based on their green fluorescence. These studies showed that 2.4 +/- 0.2% (n = 6) of the cells in the pancreas of newborn (P1) and 0.9 +/- 0.1% (n = 5) of 8-wk-old mice were beta-cells. The MIP-GFP-transgenic mouse may be a useful tool for studying beta-cell biology in normal and diabetic animals.