Project description:The pancreatic beta cell function failure is the core event of type 2 diabetes mellitus. High levels of free fatty acid and glucose are two main factor that induced pancreatic beta cell function failure. Long term exposure to palmitate can induced pancreatic beta cell apoptoss and impaired insulin secretion in vivo and in vitro, called lipotoxicity. The lipotoxicity often coupled with high glucose, their combination form called glucolipotoxcity. We carried out temporal transcriptome and proteome studies investigating the evolution of molecular events in Ins1 cells stimulated by palmitate for different times. And through compared the transcriptome and proteome between lipotoxicity and glucolipotoxicity explain the mechanism of glucolipotoxicity more harmfull to beta cell.

Project description:Pancreatic beta-cell dysfunction and eventual beta-cell loss are key steps in the course of type 2 diabetes (T2D). Endoplasmic reticulum (ER) stress, in particular the PERK-ATF4 pathway, has been implicated in promoting these beta-cell pathologies. However, the exact molecular events surrounding the PERK-ATF4 pathway in beta-cell dysfunction remain unknown. Here, we discovered that ATF4 transcriptionally promotes expression of PDE4D, which results in beta-cell dysfunction via downregulation of cAMP signaling. Beta-cell-specific transgenic expression of ATF4 resulted in early beta-cell dysfunction and loss, resembling accelerated T2D. ATF4 expression, rather than CHOP, promoted PDE4D expression, decreased cAMP signaling, and attenuated responses to incretins and elevated glucose. Further, beta-cells of leptin receptor-deficient diabetic (db/db) mice expressed increased levels of ATF4 and PDE4D, accompanying impaired beta-cell function. Moreover, inhibiting PDE4D activity with selective pharmacological inhibitors significantly ameliorated beta-cell dysfunction in both db/db mice and beta-cell-specific ATF4 transgenic mice. In summary, our findings support that ER stress causes beta-cell failure via ATF4-mediated PDE4D production, and this is a highly promising therapeutic target for protecting beta-cell function during progression of T2D.

Project description:Defective insulin secretion by pancreatic β cells underlies the development of type 2 diabetes (T2D). High fat diet-fed mice are commonly used to study diabetes progression, but studies are usually limited to a single strain, such as C57Bl/6J. Here, we use a systems biology approach to integrate large phenotypic and islet transcriptomic data sets from six commonly used strains fed a high fat or regular chow diet to identify genes associated with glucose intolerance and insulin secretion. One of these genes is Elovl2, encoding very long chain fatty acid elongase 2. ELOVL2 is responsible for the synthesis of the polyunsaturated fatty acid, docosahexaenoic acid (DHA). We show that DHA rescues glucose-induced insulin secretion and cytosolic Ca2+ influx impaired by glucolipotoxicity, and that Elovl2 over-expression is able to restore the insulin secretion defect under these conditions. We propose that increased endogenous DHA levels resulting from Elovl2 up-regulation counteracts the insulin secretion defect associated with glucolipotoxicity. Although we focus our experimental validation on Elovl2, the comprehensive data set and integrative network model we used to identify this candidate gene represents an important novel resource to dissect the molecular aetiology of β cell failure in murine models.

Project description:Defective insulin secretion by pancreatic β cells underlies the development of type 2 diabetes (T2D). High fat diet-fed mice are commonly used to study diabetes progression, but studies are usually limited to a single strain, such as C57Bl/6J. Here, we use a systems biology approach to integrate large phenotypic and islet transcriptomic data sets from six commonly used strains fed a high fat or regular chow diet to identify genes associated with glucose intolerance and insulin secretion. One of these genes is Elovl2, encoding very long chain fatty acid elongase 2. ELOVL2 is responsible for the synthesis of the polyunsaturated fatty acid, docosahexaenoic acid (DHA). We show that DHA rescues glucose-induced insulin secretion and cytosolic Ca2+ influx impaired by glucolipotoxicity, and that Elovl2 over-expression is able to restore the insulin secretion defect under these conditions. We propose that increased endogenous DHA levels resulting from Elovl2 up-regulation counteracts the insulin secretion defect associated with glucolipotoxicity. Although we focus our experimental validation on Elovl2, the comprehensive data set and integrative network model we used to identify this candidate gene represents an important novel resource to dissect the molecular aetiology of β cell failure in murine models. 6 mouse strains, 4 time points, 2 diets

Project description:Neonatal beta-cells undergo a maturation process to acquire glucose responsiveness. We hypothesize that in later life, a partial reversal of this maturation might promote beta-cell dysfunction. We previously ascertained that fetuin-A, a fetal glycoprotein downregulated at birth but increasingly secreted when fatty liver develops, inhibits insulin secretion. Here, we evaluate fetuin-A’s impact on beta-cell maturation. In vitro maturation of neonatal porcine islet cell clusters (NICCs) promoted expression of beta-cell markers and TGFBR/SMAD signaling. Fetuin-A reduced both functional and proliferative gene expression and SMAD phosphorylation. Consequently, fetuin-A impaired glucose- and forskolin-dependent secretion, and reduced adaptive beta-cell proliferation. In adult human islets, fetuin-A abolished glucose responsiveness, diminished SMAD phosphorylation and downregulated functional and proliferative genes. Our findings suggest that perinatal decline of fetuin-A relieves TGFBR signaling in neonatal beta-cells, thereby facilitating the onset of postnatal maturation. However, this program remains revocable during adulthood, since fatty liver-derived fetuin-A reverses beta-cells’ maturity, conferring them a neonatal-like phenotype and contributing to their failure.

Project description:Background: Prolonged exposure to elevated free fatty acids induces β-cell failure (lipotoxicity) and contributes to the pathogenesis of type 2 diabetes. In vitro exposure of β-cells to the saturated free fatty acid palmitate is a valuable model of lipotoxicity, reproducing features of β-cell failure observed in type 2 diabetes. In order to map the β-cell response to lipotoxicity, we combined RNA-sequencing of palmitate-treated human islets with iTRAQ proteomics of insulin-secreting INS-1E cells following a time course exposure to palmitate. Results: Crossing transcriptome and proteome of palmitate-treated β-cells revealed 85 upregulated and 122 downregulated genes at both transcript and protein level. Pathway analysis identified lipid metabolism, oxidative stress, amino-acid metabolism and cell cycle pathways among the most enriched palmitate-modified pathways. Palmitate induced gene expression changes compatible with increased free fatty acid mitochondrial import and β-oxidation, decreased lipogenesis and modified cholesterol transport. Palmitate modified genes regulating endoplasmic reticulum (ER) function, ER-to-Golgi transport and ER stress pathways. Furthermore, palmitate modulated cAMP/protein kinase A (PKA) signaling, inhibiting expression of PKA anchoring proteins and downregulating the GLP-1 receptor. SLC7 family amino-acid transporters were upregulated in response to palmitate but this induction did not contribute to β-cell demise. To unravel critical mediators of lipotoxicity upstream of the palmitate-modified genes, we identified overrepresented transcription factor binding sites and performed network inference analysis. These identified LXR, PPARα, FOXO1 and BACH1 as key transcription factors orchestrating the metabolic and oxidative stress responses to palmitate. Conclusions: This is the first study to combine transcriptomic and sensitive time course proteomic profiling of palmitate-exposed β-cells. Our results provide comprehensive insight into gene and protein expression changes, corroborating and expanding beyond previous findings. The identification of critical drivers and pathways of the β-cell lipotoxic response points to novel therapeutic targets for type 2 diabetes.

Project description:Peroxisome proliferator-activated receptor beta/delta protects against obesity by reducing dyslipidemia and insulin resistance via effects in various organs, including muscle, adipose tissue, liver, and heart. However, nothing is known about the function of PPAR-beta in pancreas, a prime organ in the control of glucose metabolism. To gain insight into so far hypothetical functions of this PPAR isotype in insulin production, we specifically ablated Ppar-beta in pancreas. The mutated mice developed a chronic hyperinsulinemia, due to an increase in both beta-cell mass and insulin secretion. Gene expression profiling indicated a broad repressive function of PPAR-beta impacting the vesicular compartment, actin cytoskeleton, and metabolism of glucose and fatty acids. Analyses of insulin release from the islets revealed an increased second-phase glucose-stimulated insulin secretion. Higher levels of PKD, PKC-delta and diacyglycerol in mutated animals lead to an enhanced formation of trans-Golgi network (TGN)-to-plasma-membrane transport carriers in concert with F-actin disassembly, which resulted in increased insulin secretion and its associated systemic effects. Taken together, these results provide evidence for PPAR-beta playing a repressive role on beta-cell growth and insulin exocytosis, which shed new light on its anti-obesity action. Pancreas-specific knock-out animals were generated by breeding mice harbouring a floxed Ppar-beta (PPARbetafl/fl) to mice expressing the Cre transgene under the control of the Pdx1 promoter (Pdx1Cre). Islets from 3 different animals from the knock-out group Pdx1Cre;PPARbetafl/fl and the control littermates group PPARbetafl/fl were compared.

Project description:The NF-κB pathway is a master regulator of inflammatory processes and is implicated in insulin resistance and pancreatic beta cell dysfunction in the metabolic syndrome. While canonical NF-κB signaling is well studied, there is little information on the divergent non-canonical NF-κB pathway in the context of pancreatic islet dysfunction in diabetes. Here, we demonstrate that pharmacological activation of the non-canonical NF-κB inducing kinase (NIK) disrupts glucose homeostasis in zebrafish in vivo. Further, we identify NIK as a critical negative regulator of beta cell function as pharmacological NIK activation results in impaired glucose-stimulated insulin secretion in mouse and human islets. NIK levels are elevated in pancreatic islets isolated from diet-induced obese (DIO) mice, which exhibit increased processing of non-canonical NF-κB components p100 to p52, and accumulation of RelB. Tumor necrosis factor α (TNFα) and receptor activator of NF-κB ligand (RANKL), two ligands associated with diabetes, induce NIK in islets. Mice with constitutive beta cell intrinsic NIK activation present impaired insulin secretion with DIO. NIK activation triggers the non-canonical NF-κB transcriptional network to induce genes identified in human type 2 diabetes genome-wide association studies linked to beta cell failure. These studies reveal that NIK contributes a central mechanism for beta cell failure in diet-induced obesity. We identify a role for Nuclear Factor inducing κB (NIK) in pancreatic beta cell failure. NIK activation disrupts glucose homeostasis in zebrafish in vivo and impairs glucose-stimulated insulin secretion in mouse and human islets in vitro. NIK activation also perturbs beta cell insulin secretion in a diet-induced obesity mouse model. These studies reveal that NIK contributes a central mechanism for beta cell failure in obesity. To uncover the role of NIK in pancreatic beta cells, we performed a gene expression microarray analysis comparing pancreatic islets with constitutive beta cell intrinsicNIK activation from the 16 week old mice (beta cell specific TRAF2 and TRAF2 knockout mice) to their controls (n=3 per group).

Project description:Pancreatic beta cell failure in type 2 diabetes (T2DM) is attributed in part to perturbations of the beta cell's transcriptional landscape resulting in the aberrant regulation of glucose-stimulated insulin secretion. Recent studies identified SLC4A4 (a gene encoding an electrogenic Na+-coupled HCO3- cotransporter and intracellular pH regulator, NBCe1) as one of the mis-expressed genes in beta cells of patients with T2DM. Thus, in the current study we set out to test the hypothesis that mis-expression of SLC4A4/NBCe1 in T2DM beta cells contributes to beta cell dysfunction and impaired glucose homeostasis. To address this hypothesis, we first confirmed induction of SLC4A4/NBCe1 expression in beta cells of patients with T2DM and demonstrated that its expression is associated with loss of beta cell transcriptional identity, intracellular alkalinization, and beta cell dysfunction. In addition, we generated a beta cell selective Slc4a4/NBCe1 knockout mouse model and report that these mice are protected from diet-induced metabolic stress and beta cell failure. Importantly, improved glucose tolerance and enhanced beta cell function in Slc4a4/NBCe1 deficient mice was due to augmented mitochondrial function and increased expression of genes regulating beta cell identity and function. These results suggest that increased beta cell expression of SLC4A4/NBCe1 in T2DM plays a contributory role in promotion of beta cell failure and should be considered as a potential novel therapeutic target.

Project description:Free fatty acids (FFAs) are often stored in lipid droplet (LD) depots for eventual metabolic and/or synthetic use in many cell types, such a muscle, liver, and fat. In pancreatic islets, overt LD accumulation was detected in humans but not mice. LD buildup in islets was principally observed after roughly 11 years of age, increasing throughout adulthood under physiologic conditions, and also enriched in type 2 diabetes. To obtain insight into the role of LDs in human islet β cell function, the levels of a key LD scaffold protein, perilipin2 (PLIN2), were manipulated by lentiviral-mediated knock-down (KD) or over-expression (OE) in EndoCβH2-Cre cells, a human cell line with adult islet β-like properties. Glucose stimulated insulin secretion was blunted in PLIN2KD cells and improved in PLIN2OE cells. An unbiased transcriptomic analysis revealed that limiting LD formation induced effectors of endoplasmic reticulum (ER) stress that compromised the expression of critical β cell function and identity genes. These changes were essentially reversed by PLIN2OE or using the ER stress inhibitor, tauroursodeoxycholic acid. These results strongly suggest that LDs are essential for adult human islet β cell activity by preserving FFA homeostasis.