Restoration Of Insulin Secretion Research Articles

Imeglimin mitigates the accumulation of dysfunctional mitochondria to restore insulin secretion and suppress apoptosis of pancreatic β-cells from db/db mice

Mitochondrial dysfunction in pancreatic β-cells leads to impaired glucose-stimulated insulin secretion (GSIS) and type 2 diabetes (T2D), highlighting the importance of autophagic elimination of dysfunctional mitochondria (mitophagy) in mitochondrial quality control (mQC). Imeglimin, a new oral anti-diabetic drug that improves hyperglycemia and GSIS, may enhance mitochondrial activity. However, chronic imeglimin treatment’s effects on mQC in diabetic β-cells are unknown. Here, we compared imeglimin, structurally similar anti-diabetic drug metformin, and insulin for their effects on clearance of dysfunctional mitochondria through mitophagy in pancreatic β-cells from diabetic model db/db mice and mitophagy reporter (CMMR) mice. Pancreatic islets from db/db mice showed aberrant accumulation of dysfunctional mitochondria and excessive production of reactive oxygen species (ROS) along with markedly elevated mitophagy, suggesting that the generation of dysfunctional mitochondria overwhelmed the mitophagic capacity in db/db β-cells. Treatment with imeglimin or insulin, but not metformin, reduced ROS production and the numbers of dysfunctional mitochondria, and normalized mitophagic activity in db/db β-cells. Concomitantly, imeglimin and insulin, but not metformin, restored the secreted insulin level and reduced β-cell apoptosis in db/db mice. In conclusion, imeglimin mitigated accumulation of dysfunctional mitochondria through mitophagy in diabetic mice, and may contribute to preserving β-cell function and effective glycemic control in T2D.

Vildagliptin inhibits high fat and fetuin-A mediated DPP-4 expression, intracellular lipid accumulation and improves insulin secretory defects in pancreatic beta cells

Dipeptidyl peptidase-4 (DPP-4), a ubiquitous proteolytic enzyme, inhibits insulin secretion from pancreatic beta cells by inactivating circulating incretin hormones GLP-1 and GIP. High circulating levels of DPP-4 is presumed to compromise insulin secretion in people with type 2 diabetes (T2D). Our group recently reported lipid induced DPP-4 expression in pancreatic beta cells, mediated by the TLR4-NFkB pathway. In the present study, we looked at the role of Vildagliptin on pancreatic DPP-4 inhibition, preservation of islet mass and restoration of insulin secretion. MIN6 mouse insulinoma cells incubated with palmitate and fetuin-A, a proinflammatory organokine associated with insulin resistance, showed activation of TLR4-NFkB pathway, which was rescued on Vildagliptin treatment. In addition, Vildagliptin, by suppressing palmitate-fetuin-A mediated DPP-4 expression in MIN6, prevented the secretion of IL-1beta and fetuin-A in the culture media. DPP-4 siRNA abrogated TLR4-NFkB pathway mediated islet cell inflammation. Vildagliptin also reduced palmitate-fetuin-A mediated intracellular lipid accumulation in MIN6 and isolated islets from high fat fed (HFD) mice as observed by Oil O Red staining with downregulation of CD36 and PPARgamma. Vildagliptin also preserved islet mass and rescued insulin secretory defect in HFD mice. Our results suggest that inhibition of DPP-4 by Vildagliptin protects pancreatic beta cells from the deleterious effects of lipid and fetuin-A, preserves insulin secretory functions and improves hyperglycemia.

Nrf2 inhibition regulates intracellular lipid accumulation in mouse insulinoma cells and improves insulin secretory function

High amount of fat in the pancreas is linked to poor functioning of β-cells and raises the risk of type 2 diabetes. Here we report the putative role of a circulatory glycoprotein Fetuin-A, a known obesity marker, in promoting lipid accumulation in β-cells and its association with Fatty acid translocase/CD36 for lipid storage culminate in β-cell dysfunction. Additionally, this work reveals regulation of CD36 via Nrf2, a key regulator of oxidative stress, and reduction of lipid accumulation by suppression of Nrf2 that restores β-cell function. Palmitate (0.50 mM) and Fetuin-A (100 μg/mL) exposure showed high levels of intracellular lipid in MIN6 (mouse insulinoma cells) with a concomitant decrease in insulin secretion. This also increased the expression of important lipogenic factors, like CD36, PGC1α, PPARγ, and SREBP1. Flow cytometry analysis of CD36 membrane localization has been corroborated with an increased accumulation of lipids as indicated by Oil-Red-O staining. Immunoblotting and immunofluorescence of Nrf2 indicated its high expression in palmitate-fetuin-A incubation and translocation in the nucleus. Suppression of Nrf2 by siRNA showed a reduced expression of lipogenic genes, ablation of lipid droplets, decrease in the number of apoptotic cells, and restoration of insulin secretion with a corresponding increase of Pdx1, BETA2, and Ins1 gene expression. Our study thus suggested an important aspect of lipid accumulation in the pancreatic β-cells contributing to β-cell dysfunction and demonstrated the role of Fetuin-A in CD36 expression, with a possible way of restoring β-cell function by targeting Nrf2.

Зміна концентрації греліну при цукровому діабеті 2-го типу, асоційованому з ожирінням, після лапароскопічної рукавної резекції шлунка

Laparoscopic sleeve gastrectomy (LSG) is an effective method of treating obesity complicated by type 2 diabetes mellitus (T2DM). The performance of this metabolic surgical intervention involves removal fundus of the stomach, which in turn leads to an effect on the eating behavior of patients in the form of a decrease in appetite and loss of excess body weight with a parallel effect on the compensation of T2DM in the postoperative period, regardless of the loss of body weight. At present, mechanisms of T2DM compensation after LSG have not yet been clearly defined. The aim of our study was to study the effect of LSG on the dynamics of changes in the blood plasma ghrelin levels in patients with T2DM associated with obesity. The plasma ghrelin levels were assessed in the fasted state, 15, 30, 60, and 90 min after a standard breakfast carbohydrate preload, which included 125 ml of Nutricia Nutridrink, a balanced high-energy protein. The examination was carried out before the operation, on the 4th postoperative day and 3 months after the operation. 7 patients were diagnosed with T2DM for the first time, 3 had a history of diabetes for 2 years, one patient had a history of 3.5 years, and another had a history of 10 years. The average content of glycated hemoglobin before the operation was 7.7%, 3 months after LSG - 5.9%. The fasting ghrelin concentration before LSG performing was 6.8 ng/ml, on the 4th postoperative day – 4.6 ng/ml, and 3 months after the operation – 4.4 ng/ml (P = 0.001) in comparison with preoperative indicators). The peak insulin concentration was noted 30 min after the carbohydrate preload 3 months after the operation and was 175.1 μU/ml, and its fasting levels in the postoperative period reached a statistically significant difference compared to the preoperative values (30 μU/ml before surgery and 25.3 μU/ml 3 months after LSG). Thus, LSG leads to an early and significant suppression of fasting ghrelin secretion in patients with obesity-associated T2DM and likely to restore insulin secretion and/or reduce insulin resistance. Rapid postoperative improvement of carbohydrate metabolism components indicates the importance of the early reduction of ghrelin secretion in combination with the incretin effect of LSG in the implementation of the mechanisms of early compensation of T2DM and explains the metabolic activity of this operation and the significant role of the stomach in the regulation of glucose metabolism.

Multiple Immune Pathways to Type 1 Diabetes Mellitus: Lessons Learned from Human Clinical Trials and Animal Models of Disease Clinical Trials, Lessons Learned

Type 1 diabetes mellitus results from progressive autoimmune attack of the endocrine pancreas. Immune cells infiltrate the pancreatic islets and focus their attack on beta cells causing loss of insulin production. Progressive insulin loss leads to lifelong insulin replacement therapy and comorbidities. The ultimate clinical goal in type 1 diabetes is to restore and preserve beta cell function thus alleviating the need for exogenous insulin replacement. A secondary goal is to prevent complications that result from chronic inflammation including cardiovascular disease, kidney disease, neuropathy, and retinopathy. These goals are neither exclusive nor interdependent. The best clinical approach will target immune cells, although beta cell replacement in addition to immune targets might lead to a cure. At present, clinical trials have involved antigen specific therapies to attempt tolerance induction through depletion of pathogenic effector cells and/or generation of regulatory T cells; infusion of autologous Tregs to control the pathogenic inflammation; monoclonal antibodies that target total T cells, total B cells, or inflammatory cytokines; small molecule drugs; and targeting T cell co-stimulation. Moreover, newly developed pluripotent beta cell clusters with immune privilege achieved through CRISPR technology appear to restore insulin secretion and avoid immune surveillance. These approaches have not yet achieved the clinical goal of halting or reversing loss of C-peptide, a marker for beta cell function, or sustained long-term reduction of daily blood glucose and insulin requirements. Some therapies like Teplizumab (humanized anti-CD3 monoclonal antibody) have slowed loss of C-peptide and it appears that several study subjects have had long-term positive responses. The totality of clinical trials points to heterogeneity within those individuals labelled as “type 1 diabetes” making a single target approach unlikely to be successful. This review considers recent and current immune modulatory drugs in T1DM clinical trials. While none have yet been fully successful, valuable information about how to better approach this serious disease is emerging. The information from clinical trials further points to the possibility that rather than being a single disease, ‘type 1 diabetes’ may better be described as a family of diseases where different cellular mechanisms reach the same clinical outcome, loss of insulin production.

Oxidative stress and impaired insulin secretion in cystic fibrosis pig pancreas

Cystic fibrosis-related diabetes (CFRD) is one the most common comorbidities in cystic fibrosis (CF). Pancreatic oxidative stress has been postulated in the pathogenesis of CFRD, but no studies have been done to show an association. The main obstacle is the lack of suitable animal models and no immediate availability of pancreas tissue in humans. In the CF porcine model, we found increased pancreatic total glutathione (GSH), glutathione disulfide (GSSG), 3-nitrotyrosine- and 4-hydroxynonenal-modified proteins, and decreased copper zinc superoxide dismutase (CuZnSOD) activity, all indicative of oxidative stress. CF pig pancreas demonstrated increased DHE oxidation (as a surrogate marker of superoxide) in situ compared to non-CF and this was inhibited by a SOD-mimetic (GC4401). Catalase and glutathione peroxidase activities were not different between CF and non-CF pancreas. Isolated CF pig islets had significantly increased DHE oxidation, peroxide production, reduced insulin secretion in response to high glucose and diminished secretory index compared to non-CF islets. Acute treatment with apocynin or an SOD mimetic failed to restore insulin secretion. These results are consistent with the hypothesis that CF pig pancreas is under significant oxidative stress as a result of increased O2●− and peroxides combined with reduced antioxidant defenses against reactive oxygen species (ROS). We speculate that insulin secretory defects in CF may be due to oxidative stress.

Alpha-to-beta cell trans-differentiation for treatment of diabetes.

Diabetes mellitus is a significant cause of morbidity and mortality in the United States and worldwide. According to the CDC, in 2017, ∼34.2 million of the American population had diabetes. Also, in 2017, diabetes was the seventh leading cause of death and has become the number one biomedical financial burden in the United States. Insulin replacement therapy and medications that increase insulin secretion and improve insulin sensitivity are the main therapies used to treat diabetes. Unfortunately, there is currently no radical cure for the different types of diabetes. Loss of β cell mass is the end result that leads to both type 1 and type 2 diabetes. In the past decade, there has been an increased effort to develop therapeutic strategies to replace the lost β cell mass and restore insulin secretion. α cells have recently become an attractive target for replacing the lost β cell mass, which could eventually be a potential strategy to cure diabetes. This review highlights the advantages of using α cells as a source for generating new β cells, the various investigative approaches to convert α cells into insulin-producing cells, and the future prospects and problems of this promising diabetes therapeutic strategy.

1142-P: Update on BCG Clinical Trial Programs in Patients with Advanced Type 1 Diabetes

The bacillus Calmette-Guerin (BCG) vaccine was first introduced a century ago for tuberculosis prevention and is today being tested in clinical trials for treatment of diverse forms of autoimmunity, including type 1 diabetes (T1D). Long-term follow up of a Phase I study of the BCG vaccine in longstanding T1D revealed potential disease-modulating effects after repeated BCG vaccination, including long-term reductions of HbA1c, death of autoreactive cells, modest restoration of insulin secretion and induction of beneficial regulatory T cells (Tregs). Here we provide an update on the BCG clinical trial program current underway at Massachusetts General Hospital (MGH): enrollment numbers, study timelines and interim outcomes for key T1D biomarkers. To date, 236 patients have been enrolled in the randomized and open-label MGH trials and 143 patients have received at least two doses of BCG, 34 of whom are being followed in open-label, unblinded trials. Enrollment of 150 participants in a pediatric study is planned for 2021. Data from ongoing analysis of the open-label BCG trials shows lowered insulin needs and decreases in HbA1c as compared to reference populations. Patients are also being monitored by RNAseq, epigenetics, Treg cell numbers and Treg signature gene expression to better define the mechanism of beneficial effects. We show a gradual and stable 3-year time course of demethylation of signature Treg genes known to be associated with Treg potency, including Foxp3, which was observed to be over-methylated at baseline in T1D and, over 3 years after BCG vaccination, demethylated to a level close to controls without T1D. The clinical time course of BCG-related improvements (i.e., improvement in HbA1C) appears to correlate with the time course of Treg induction through epigenetic modifications. Disclosure W. Kuhtreiber: None. H. Takahashi: None. R. Keefe: None. K. Nelson: None. N. Ng: None. J. Braley: None. H. Zheng: None. D. L. Faustman: None.

Blocking TLR4-NF-κB pathway protects mouse islets from the combinatorial impact of high fat and fetuin-A mediated dysfunction and restores ability for insulin secretion

Lipid mediated pancreatic β-cell dysfunction during Type 2 diabetes is known to be regulated by activation of TLR4 (Toll Like Receptor 4) and NF-κB (Nuclear factor kappa B). Recently we have reported that MIN6 cells (mouse insulinoma cells) secrete fetuin-A on stimulation by palmitate that aggravates β-cell dysfunction, but the mechanism involved in-vivo has not been demonstrated and thus remained unclear. Here we attempted to dissect the role of palmitate and fetuin-A on insulin secretion using high fat diet (HFD) fed mice model. HFD islets showed curtailed insulin secretion after 20 weeks of treatment with activated TLR4-NF-κB pathway. Further treatment of islets with palmitate raised fetuin-A expression by ~2.8 folds and cut down insulin secretion by ~1.4 folds. However, blocking the activity of TLR4, fetuin-A and NF-κB using specific inhibitors or siRNAs not only restored insulin secretion by ~2 folds in standard diet fed mice islets and MIN6 cells but also evoke insulin secretory ability by ~2.3 folds in HFD islets. Altogether this study demonstrated that blocking TLR4, fetuin-A and NF-κB protect pancreatic β-cells from the negative effects of free fatty acid and fetuin-A and restore insulin secretion.

AKAP79/150 coordinates leptin-induced PKA signaling to regulate KATP channel trafficking in pancreatic β-cells

The adipocyte hormone leptin regulates glucose homeostasis both centrally and peripherally. A key peripheral target is the pancreatic β-cell, which secretes insulin upon glucose stimulation. Leptin is known to suppress glucose-stimulated insulin secretion by promoting trafficking of KATP channels to the β-cell surface, which increases K+ conductance and causes β-cell hyperpolarization. We have previously shown that leptin-induced KATP channel trafficking requires protein kinase A (PKA)-dependent actin remodeling. However, whether PKA is a downstream effector of leptin signaling or PKA plays a permissive role is unknown. Using FRET-based reporters of PKA activity, we show that leptin increases PKA activity at the cell membrane and that this effect is dependent on N-methyl-D-aspartate receptors, CaMKKβ, and AMPK, which are known to be involved in the leptin signaling pathway. Genetic knockdown and rescue experiments reveal that the increased PKA activity upon leptin stimulation requires the membrane-targeted PKA-anchoring protein AKAP79/150, indicating that PKA activated by leptin is anchored to AKAP79/150. Interestingly, disrupting protein phosphatase 2B (PP2B) anchoring to AKAP79/150, known to elevate basal PKA signaling, leads to increased surface KATP channels even in the absence of leptin stimulation. Our findings uncover a novel role of AKAP79/150 in coordinating leptin and PKA signaling to regulate KATP channel trafficking in β-cells, hence insulin secretion. The study further advances our knowledge of the downstream signaling events that may be targeted to restore insulin secretion regulation in β-cells defective in leptin signaling, such as those from obese individuals with type 2 diabetes.

Glucosamine potentiates the differentiation of adipose-derived stem cells into glucose-responsive insulin-producing cells

BackgroundIslet transplantation might be a logical strategy to restore insulin secretion for the treatment of diabetes, however, the scarcity of donors poses an obstacle for such a treatment. As an alternative islet source, differentiation of stem cells into insulin-producing cells (IPCs) has been tried. Many protocols have been developed to improve the efficiency of differentiation of stem cells into IPCs. In this study, we investigated whether glucosamine supplementation during differentiation of human adipose-derived stem cells (hADSCs) into IPCs can improve the insulin secretory function.MethodsGlucosamine was added to the original differentiation medium at different stages of differentiation of hADSCs into IPCs for 12 days and insulin secretion was analyzed.ResultsAddition of glucosamine alone to the growth medium of hADSCs did not affect the differentiation of hADSCs to IPCs. Supplementation of the differentiation medium with glucosamine at a later stage (protocol G3) proved to have the greatest effect on IPC differentiation. Basal and glucose-stimulated insulin secretion (GSIS) was significantly increased and the expression of insulin and C-peptide was increased in differentiated IPCs as compared with that in differentiated IPCs using the conventional protocol (protocol C). In addition, the expression of beta-cell specific transcription factors such as pancreatic and duodenal homeobox1 (PDX1) and neurogenin 3 (NGN3) was also increased. Furthermore, the expression of genes related to insulin secretion, including synaptotagmin 4 (Syt4), glucokinase (Gck) and glucose transporter 2 (Glut2), was also increased.ConclusionsWe conclude that glucosamine supplementation potentiates the differentiation of hADSCs into IPCs.

Arsenite and its trivalent methylated metabolites inhibit glucose-stimulated calcium influx and insulin secretion in murine pancreatic islets.

Chronic exposure to inorganic arsenic (iAs), a common drinking water and food contaminant, has been associated with an increased risk of type 2 diabetes in population studies worldwide. Several mechanisms underlying the diabetogenic effects of iAs have been proposed through laboratory investigations. We have previously shown that exposure to arsenite (iAs(III)) or its methylated trivalent metabolites, methylarsonite (MAs(III)) and dimethylarsinite (DMAs(III)), inhibits glucose-stimulated insulin secretion (GSIS) in pancreatic islets, without significant effects on insulin expression or insulin content. The goal of the present study was to determine if iAs(III) and/or its metabolites inhibit Ca2+ influx, an essential mechanism that regulates the release of insulin from β cells in response to glucose. We found that in vitro exposures for 48h to non-cytotoxic concentrations of iAs(III), MAs(III), and DMAs(III) impaired Ca2+ influx in isolated murine pancreatic islets stimulated with glucose. MAs(III) and DMAs(III) were more potent inhibitors of Ca2+ influx than iAs(III). These arsenicals also inhibited Ca2+ influx and GSIS in islets treated with depolarizing levels of potassium chloride in the absence of glucose. Treatment with Bay K8644, a Cav1.2 channel agonist, did not restore insulin secretion in arsenical-exposed islets. Tolbutamide, a KATP channel blocker, prevented inhibition of insulin secretion in MAs(III)- and DMAs(III)-exposed islets, but only marginallyin islets exposed to iAs(III). Our findings suggest that iAs(III), MAs(III), and DMAs(III) inhibit glucose-stimulated Ca2+ influx in pancreatic islets, possibly by interfering with KATP and/or Cav1.2 channel function. Notably, the mechanisms underlying inhibition of GSIS by iAs(III) may differ from those of its trivalent methylated metabolites.

Oxidative and energetic stresses mediate beta-cell dysfunction induced by PGC-1α

AimAlteration of functional beta-cell mass in adults can be programmed by adverse events during fetal life. Previously, it was demonstrated that high glucocorticoid (GC) levels during fetal life participate in this programming by inhibition of beta-cell development. More specifically, GC levels stimulate expression of peroxisome proliferator-activated receptor-gamma coactivator 1-alpha (PGC-1α), a transcriptional co-regulator of the GC receptor (GR), which per se impairs beta-cell mass and function when overexpressed. As PGC-1α is also a potent inducer of mitochondrial biogenesis, our study aimed to determine how PGC-1α modifies mitochondrial function in beta cells and how it might regulate insulin secretion. MethodsBeta-cell function was studied in mice overexpressing PGC-1α specifically in beta cells and in MIN6 cells overexpressing PGC-1α in vitro. ResultsPGC-1α overexpression in beta cells in vivo leads to a reduced beta-cell mass early in fetal life, whereas PGC-1α overexpression in vitro stimulates mitochondrial biogenesis and respiratory activity without improving ATP production, while increasing oxidative stress and impairing insulin secretion in response to glucose. While oxidative stress with PGC-1α overexpression in beta cells activates AMPK, it has also been revealed that blocking such oxidative stress or AMPK activation restores insulin secretion. ConclusionPGC-1α induces oxidative stress, which disrupts insulin secretion by AMPK activation. Thus, control of oxidative or energetic stress in beta cells may help to restore insulin secretion.

Fasting-Mimicking Diet Promotes Ngn3-Driven β-Cell Regeneration to Reverse Diabetes

Stem-cell-based therapies can potentially reverse organ dysfunction and diseases, but the removal of impaired tissue and activation of a program leading to organ regeneration pose major challenges. In mice, a 4-day fasting mimicking diet (FMD) induces a stepwise expression of Sox17 and Pdx-1, followed by Ngn3-driven generation of insulin-producing βcells, resembling that observed during pancreatic development. FMD cycles restore insulin secretion and glucose homeostasis in both type 2 and type 1 diabetes mouse models. In human type 1 diabetes pancreatic islets, fasting conditions reduce PKA and mTOR activity and induce Sox2 and Ngn3 expression and insulin production. The effects of the FMD are reversed by IGF-1 treatment and recapitulated by PKA and mTOR inhibition. These results indicate that a FMD promotes the reprogramming ofpancreatic cells to restore insulin generation in islets from T1D patients and reverse both T1D and T2D phenotypes in mouse models. PAPERCLIP.

Mulberry branch bark powder significantly improves hyperglycemia and regulates insulin secretion in type II diabetic mice

ABSTRACTThis experiment, based on the previous study on R. mori, introduces whole mulberry branch powder into the diet to treat diabetic mice. Mulberry branch bark powder (MBBP) was administered orally to streptozotocin (STZ)-induced type II diabetic (T2D) mice to investigate hypoglycemic effects. After a 4-week period of diet consumption containing 5%, 10% and 20% MBBP, the fasting blood glucose, body weight and the related western blotting were measured, pathologic and immunohistochemical were observed. The 20% MBBP group showed a significant reduction in hyperglycemia and hyperinsulinemia; fasting blood glucose and insulin decreased from 25.0 to 14.8 mmol/L and 26.5 to 16.0 mU/L, respectively. Pathologic and immunohistochemical observation showed that MBBP administration lead to the repair of pancreas cells and restoration of insulin secretion. Dietary MBBP was associated with the decrease in the contents of 3, 4-methylenedioxeamphetamine, 8-OHdG, aspartate aminotransferase, and alanine aminotransferase, and the increase in antioxidative ability and glucose tolerance. Western blotting (WB) analysis suggested that MBBP decreased the TNF-α levels, thus relieving inflammation and improving liver function. It also led to the downregulation of apoptosis factor expression. WB also confirmed that MBBP enhanced the gene expression of the key enzymes: insulin receptor, insulin receptor substrate, p-AKT, GSK3β, glycogen synthase, G6Pase and phosphoenolpyruvate carboxykinase, which are related to glucose metabolism in the liver, and increase the expression of the genes PDX-1, GLUT2, MafA, and glucokinase, related to insulin secretion. Thus, oral administration of MBBP regulated insulin secretion and effectively maintained normal levels of glucose metabolism in mice, which may be done by improving the antioxidant capacity and activating insulin signaling with T2D..

Green tea extract intake during lactation modified cardiac macrophage infiltration and AMP-activated protein kinase phosphorylation in weanling rats from undernourished mother during gestation and lactation.

Maternal dietary restriction is often associated with cardiovascular disease in offspring. The aim of this study was to investigate the effect of green tea extract (GTE) intake during lactation on macrophage infiltration, and activation of adenosine monophosphate (AMP)-activated protein kinase (AMPK) and serine-threonine kinase Akt (Akt) in the hearts of weanlings exposed to maternal dietary protein restriction. Pregnant Wistar rats were fed control (C) or low-protein diets (LP) throughout gestation. Following delivery, the dams received a control or a GTE-containing control diet during lactation: control diet during gestation and lactation (CC), low-protein diet during gestation and lactation (LPC), low-protein diet during gestation and 0.12% GTE-containing low-protein diet during lactation (LPL), and low-protein diet during gestation and 0.24% GTE-containing low-protein diet during lactation (LPH). The female offspring were sacrificed at day 22. Biochemical parameters in the plasma, macrophage infiltration, degree of fibrosis and expression levels of AMPK and Akt were examined. The plasma insulin level increased in LPH compared with LPC. Percentage of the fibrotic areas and the number of macrophages in LPC were higher than those in CC. Conversely, the fibrotic areas and the macrophage number in LPH were smaller (21 and 56%, respectively) than those in LPC. The levels of phosphorylated AMPK in LPL and LPH, and Akt in LPH were greater than those in LPC. In conclusion, maternal protein restriction may induce macrophage infiltration and the decrease of insulin levels. However, GTE intake during lactation may suppress macrophage infiltration and restore insulin secretion function via upregulation of AMPK and insulin signaling in weanlings.

Eltrombopag (ELT) Reverses Iron Mediated Suppression of Insulin Secretion in Pancreatic Cells By Chelating Iron and Decreasing ROS

Introduction: Eltrombopag (ELT) is an orally active, nonpeptide, small-molecule thrombopoietin receptor agonist (TPO-R), used to treat chronic immune thrombocytopenic purpura (ITP). We have recently reported its ability to mobilise cellular iron, and act as an iron shuttle when combined with currently licensed chelation therapies (Vlachodimitropoulou et al, Blood 2014, Volume 124, 21). Tissue damage induced by ROS production in iron overload conditions includes endocrine dysfunction including type I diabetes. We have developed a model where iron overload of the pancreatic cell line (RINm5F) inhibits insulin secretion. We investigated the ability of ELT, compared with clinically licensed iron chelators, to reverse ROS production and concomitant suppression of insulin production by iron loading of these cells.Methods:Cell line: RINm5F is a clonal rat pancreatic b cell line (LGC ATCC Sales, UK). These cells secrete insulin following a glucose challenge (Praz et al., 1983, Biochemistry J).Intracellular Iron: Cellular iron loading and mobilisation were measured as a decrease in cellular iron content using the ferrozine assay (Vlachodimitropoulou et al. 2015, British Journal of Haematology). A four-fold increase in intracellular iron compared to control was obtained by serially treating cells with 10% Fetal Bovine Serum (FBS) RPMI media in pancreatic cells over two ten hour periods (Figure 1A). The cells were then exposed to iron chelators/ELT, lysed and intracellular iron concentration determined, normalised against protein content.Reactive oxygen species (ROS) estimation: A cell-permeable oxidation-sensitive fluorescent probe 5,6-carboxy-2’,7’- dichlorofluorescein diacetate (DCFH-DA); (Molecular Probes, Leiden, Netherlands) was used to measure intracellular ROS. Following iron loading, the cells were pre-incubated with 6 mM H2DCF-DA for 30 minutes at 37°C. Chelators were added and the fluorescence of control and treated cells was read throughout the treatment period in the plate reader (excitation 504 nm, emission 526 nm).Insulin quantification: Following iron loading and chelator treatment, the cells were challenged with Kreb's Ringer Buffer twice, for one hour at a time, containing 2.8mM and 16.7mM glucose (Lu et al. 2010, Toxicology letter). The supernatant was then collected and insulin concentration determined using a standard rat insulin ELISA kit (Life Technologies Limited, UK).Viability: The Sulforhodamide B (SRB) viability assay was used to ensure viability >98% and assess the toxicity on the pancreatic cell line. It is commonly used to measure drug-induced cytotoxicity and is a colorimetric assay dependent on healthy adherent cells.Results: Pancreatic cell iron loading was achieved with serial changes of media containing 10% FBS. This loading method was comparable to treating cells with ferric ammonium citrate (FAC) for 24 hours, which was not adopted as FAC adheres to the extracellular surface and produces bias to our intracellular iron quantification system when using iron chelators (Figure 1A). When cells were then treated with increasing ELT concentrations, a dose-dependent cellular iron removal were demonstrated so that at 10μΜ for 8hours, approximately 40% of total cellular iron was mobilised (Figure 3A). Iron mobilisation by ELT was further enhanced by combination with DFO, DFX or DFP (Figure 3). For example, when 10μΜ DFP is combined with 3μΜ ELT, iron mobilisation increases by a further 17% when compared to DFP treatment alone (Figure 3C). ROS production was also decreased in iron-loaded cells in a concentration-dependent manner by increasing ELT concentrations (Figure 2). These reductions in ROS and cellular iron were associated with restoration of insulin secretion, which was reduced by 2.6 fold following iron loading (Figure 1B). The levels of insulin secretion returned back to higher than baseline levels (better than with DFX 1μΜ) (Figure 1C).Conclusions: This is the first demonstration of a link between cellular iron overload and reduced insulin secretion using pancreatic b-cell line. This is also the first demonstration of improved pancreatic b-cell function, evidenced by restoration of insulin secretion, when iron is chelated and ROS decreased by ELT and other iron chelators. ELT may be useful alone or in combination with other chelators for decreasing iron-mediated ROS induced damage to pancreatic b-cells. [Display omitted] [Display omitted] [Display omitted] DisclosuresPorter:Novartis: Consultancy, Honoraria, Research Funding; Bluebird Bio: Consultancy; Agios Pharmaceuticals: Consultancy, Honoraria; Celegene: Consultancy.

Comparison of two techniques for evaluation of pancreatic islet viability: flow cytometry and FDA/PI staining

Background Type 1 diabetes (T1D) accounts for approximately 10% of all diabetes cases, and it is caused by autoimmune destruction of pancreatic beta-cells, which leads to insulin deficiency and fates individuals to require insulin treatment to survive. Although important advances in the treatment of T1D have been achieved in recent yrs., this disease is associated with chronic complications that lead to high morbidity and mortality rates in young adults of productive age. In patients with unstable T1D, pancreatic islet transplantation is a therapeutic option to restore insulin secretion and improve glycemic control. However, the success of islet transplantation is dependent, in part, on the number of isolated islets as well as factors associated with their quality, which is assessed by functional and viability tests. In this context, the method currently used for islet viability evaluation [fluorescein diacetate (FDA)/propidium iodide (PI) staining] is not accurate enough, and new methods have been researched, such as flow cytometry.

Co-culture of human pancreatic islets with human adipose-derived stromal/stem cells can improve islet quality in vitro

Background In patients with unstable type 1 diabetes mellitus (T1D), allogeneic pancreatic islet transplantation is a therapeutic option to restore insulin secretion and improve metabolic control. However, the success of islet transplantation is dependent on the number and quality of isolated islets. It is known that the inflammatory environment related to the donor’s brain-death (BD) and the stress induced during islet isolation reduces islet quality. Adipose-derived stromal/stem cells (ASC) are multipotent cells that release several trophic factors with anti-inflammatory and cytoprotective actions. Thus, in vitro co-culture of islets with ASCs may improve islet quality isolated from BD-donors, attenuating inflammation and apoptosis.

Distinct roles of β-cell mass and function during type 1 diabetes onset and remission.

Cure of type 1 diabetes (T1D) by immune intervention at disease onset depends on the restoration of insulin secretion by endogenous β-cells. However, little is known about the potential of β-cell mass and function to recover after autoimmune attack ablation. Using a longitudinal in vivo imaging approach, we show how functional status and mass of β-cells adapt in response to the onset and remission of T1D. We demonstrate that infiltration reduces β-cell mass prior to onset and, together with emerging hyperglycemia, affects β-cell function. After immune intervention, persisting hyperglycemia prevents functional recovery but promotes β-cell mass increase in mouse islets. When blood glucose levels return to normoglycemia β-cell mass expansion stops, and subsequently glucose tolerance recovers in combination with β-cell function. Similar to mouse islets, human islets exhibit cell exhaustion and recovery in response to transient hyperglycemia. However, the effect of hyperglycemia on human islet mass increase is minor and transient. Our data demonstrate a major role of functional exhaustion and recovery of β-cells during T1D onset and remission. Therefore, these findings support early intervention therapy for individuals with T1D.