Assay for high glucose-mediated islet cell sensitization to apoptosis induced by streptozotocin and cytokines

Pancreatic beta-cell apoptosis is known to participate in the beta-cell destruction process that occurs in diabetes. It has been described that high glucose level induces a hyperfunctional status which could provoke apoptosis. This phenomenon is known as glucotoxicity and has been proposed that it can play a role in type 1 diabetes mellitus pathogenesis. In this study we develop an experimental design to sensitize pancreatic islet cells by high glucose to streptozotocin (STZ) and proinflammatory cytokines [interleukin (IL)-1beta, tumor necrosis factor (TNF)-alpha and interferon (IFN)-gamma]-induced apoptosis. This method is appropriate for subsequent quantification of apoptotic islet cells stained with Tdt-mediated dUTP Nick-End Labeling (TUNEL) and protein expression assays by Western Blotting (WB).

LKB1 and AMPK differentially regulate pancreatic β-cell identity.

Fully differentiated pancreatic β cells are essential for normal glucose homeostasis in mammals. Dedifferentiation of these cells has been suggested to occur in type 2 diabetes, impairing insulin production. Since chronic fuel excess ("glucotoxicity") is implicated in this process, we sought here to identify the potential roles in β-cell identity of the tumor suppressor liver kinase B1 (LKB1/STK11) and the downstream fuel-sensitive kinase, AMP-activated protein kinase (AMPK). Highly β-cell-restricted deletion of each kinase in mice, using an Ins1-controlled Cre, was therefore followed by physiological, morphometric, and massive parallel sequencing analysis. Loss of LKB1 strikingly (2.0-12-fold, E<0.01) increased the expression of subsets of hepatic (Alb, Iyd, Elovl2) and neuronal (Nptx2, Dlgap2, Cartpt, Pdyn) genes, enhancing glutamate signaling. These changes were partially recapitulated by the loss of AMPK, which also up-regulated β-cell "disallowed" genes (Slc16a1, Ldha, Mgst1, Pdgfra) 1.8- to 3.4-fold (E<0.01). Correspondingly, targeted promoters were enriched for neuronal (Zfp206; P=1.3×10(-33)) and hypoxia-regulated (HIF1; P=2.5×10(-16)) transcription factors. In summary, LKB1 and AMPK, through only partly overlapping mechanisms, maintain β-cell identity by suppressing alternate pathways leading to neuronal, hepatic, and other characteristics. Selective targeting of these enzymes may provide a new approach to maintaining β-cell function in some forms of diabetes.-Kone, M., Pullen, T. J., Sun, G., Ibberson, M., Martinez-Sanchez, A., Sayers, S., Nguyen-Tu, M.-S., Kantor, C., Swisa, A., Dor, Y., Gorman, T., Ferrer, J., Thorens, B., Reimann, F., Gribble, F., McGinty, J. A., Chen, L., French, P. M., Birzele, F., Hildebrandt, T., Uphues, I., Rutter, G. A. LKB1 and AMPK differentially regulate pancreatic β-cell identity.

Étude des mécanismes associés aux effets bénéfiques de la restriction calorique sur la fonction somatotrope du rat vieillissant.

Dans les cellules somatotropes, la liaison du facteur de libération de l’hormone de croissance (GHRH) à son récepteur (GHRH-R) stimule la synthèse et la sécrétion de l’hormone de croissance (GH) ainsi que la prolifération cellulaire. Chez les mammifères, le vieillissement est caractérisé par une diminution de la sécrétion de GH, liée à une perte de sensibilité des somatotropes au GHRH. Chez le rat âgé, des modifications de niveaux d'ARNm du GHRH-R et une diminution d'affinité et de capacité de liaison du GHRH sont rapportés. Au cours du vieillissement, une augmentation des niveaux de glucose et d’acides gras libres sérique suggère qu’une gluco- ou lipotoxicité puisse contribuer au dysfonctionnement de la fonction somatotrope. À ce jour, la restriction calorique modérée de longue durée (RCMLD) constitue l’intervention la plus efficace pour prévenir ou retarder les détériorations liées à l’âge. Des études ont montré des effets bénéfiques de la RCMLD sur l’axe somatotrope au cours du vieillissement via un maintien des paramètres de liaison du GHRH-R. Compte tenu de l’importance de cet axe, la compréhension des mécanismes menant à la somatopause ainsi que ceux associés aux effets bénéfiques de la RCMLD s’avère importante. Les objectifs principaux de la présente thèse étaient : 1) de déterminer les effets de la RCMLD chez le rat, sur le GHRH-R hypophysaire et la sensibilité des somatotropes au GHRH, 2) d’identifier les mécanismes associés à la somatopause et aux effets bénéfiques de la RCMLD, et 3) de préciser les effets d’une gluco-ou lipotoxicité sur l’axe somatotrope de rats et leur implication dans la somatopause. Des rats de 8 mois ont été soumis à une restriction calorique de 40% jusqu’à l’âge de 18-20 mois et ont été comparés à des rats jeunes et âgés nourris ad libitum. Cette étude a permis de mettre en évidence des effets bénéfiques de la RCMLD sur la régulation et la fonctionnalité du GHRH-R et de proposer que le glucose et les acides gras libres (AGL) circulants soient impliqués dans le vieillissement de la somatotrope. Une étude de micro-puce à ADN à permis d’identifier des gènes associés à des mécanismes de protection et de réparation des dommages cellulaires mis en place dans l’hypophyse antérieure au cours du vieillissement et par la RCMLD. Finalement, les effets d’un stress gluco- ou lipotoxique sur la fonction somatotrope ont été étudiés chez des rats de 2 et 6 mois, infusés 72 h avec une solution de glucose ou d’Intralipides, mimant les niveaux circulants de glucose et d’AGL retrouvés chez le rat âgé. Les résultats obtenus montrent que la glucotoxicité affecte la régulation de certains gènes de la somatotrope, dont le GHRH-R, et suggèrent que la capacité de réponse à ce type de stress est altérée. Les mécanismes par lesquels la glucotoxicité exerce ces effets pourraient inclure la génération de stress oxydant. L’ensemble de ces résultats proposent de nouvelles pistes mécanistiques qui pourraient contribuer au retardement de la somatopause et, ultimement, à l’élaboration de nouvelles stratégies d’intervention nutritionnelles ou pharmacologiques ciblant les mêmes voies que la RCMLD, avec une efficacité similaire ou supérieure.

Glucose-Induced Regulation of NHEs Activity and SGLTs Expression Involves the PKA Signaling Pathway

The effect of glucose on the intracellular pH (pH(i)) recovery rate (dpH(i)/dt) and Na(+)-glucose transporter (SGLT) localization was investigated in HEK-293 cells, a cell line that expresses endogenous NHE1, NHE3, SGLT1, and SGLT2 proteins. The activity of the Na(+)/H(+) exchangers (NHEs) was evaluated by using fluorescence microscopy. The total and membrane protein expression levels were analyzed by immunoblotting. In cells cultivated in 5 mM glucose, the pH(i) recovery rate was 0.169 +/- A 0.020 (n = 6). This value did not change in response to the acute presence of glucose at 2 or 10 mM, but decreased with 25 mM glucose, an effect that was not observed with 25 mM mannitol. Conversely, the chronic effect of high glucose (25 mM) increased the pH(i) recovery rate (similar to 40%, P < 0.05), without changes in the total levels of NHE1, NHE3, or SGLT1 expression, but increasing the total cellular (similar to 50%, P < 0.05) and the plasma membrane (similar to 100%, P < 0.01) content of SGLT2. Treatment with H-89 (10(-6) M) prevented the stimulatory effect of chronic glucose treatment on the pH(i) recovery rate and SGLT2 expression in the plasma membrane. Our results indicate that the effect of chronic treatment with a high glucose concentration is associated with increased NHEs activity and plasma membrane expression of SGLT2 in a protein kinase A-dependent way. The present results reveal mechanisms of glucotoxicity and may contribute to understanding the diabetes-induced damage of this renal epithelial cell.

Apoptosis rate and transcriptional response of pancreatic islets exposed to the PPAR gamma agonist Pioglitazone

To explore the molecular pathways underlying thiazolidinediones effects on pancreatic islets in conditions mimicking normo- and hyperglycemia, apoptosis rate and transcriptional response to Pioglitazone at both physiological and supraphysiological glucose concentrations were evaluated. Adult rat islets were cultured at physiological (5.6 mM) and supraphysiological (23 mM) glucose concentrations in presence of 10 μM Pioglitazone or vehicle. RNA expression profiling was evaluated with the PancChip 13k cDNA microarray after 24-h, and expression results for some selected genes were validated by qRT-PCR. The effects of Pioglitazone were investigated regarding apoptosis rate after 24-, 48- and 72-h. At 5.6 mM glucose, 101 genes were modulated by Pioglitazone, while 1,235 genes were affected at 23 mM glucose. Gene networks related to lipid metabolism were identified as altered by Pioglitazone at both glucose concentrations. At 23 mM glucose, cell cycle and cell death pathways were significantly regulated as well. At 5.6 mM glucose, Pioglitazone elicited a transient reduction in islets apoptosis rate while at 23 mM, Bcl2 expression was reduced and apoptosis rate was increased by Pioglitazone. Our data demonstrate that the effect of Pioglitazone on gene expression profile and apoptosis rate depends on the glucose concentration. The modulation of genes related to cell death and the increased apoptosis rate observed at supraphysiological glucose concentration raise concerns about Pioglitazone’s direct effects in conditions of hyperglycemia and reinforce the necessity of additional studies designed to evaluate TZDs effects on the preservation of β-cell function in situations where glucotoxicity might be more relevant than lipotoxicity.

Effect of dapagliflozin in patients with type 2 diabetes who have inadequate glycaemic control with metformin:a randomised, double-blind, placebo-controlled trial

Correction of hyperglycaemia and prevention of glucotoxicity are important objectives in the management of type 2 diabetes. Dapagliflozin, a selective sodium-glucose cotransporter-2 inhibitor, reduces renal glucose reabsorption in an insulin-independent manner. We assessed the efficacy and safety of dapagliflozin in patients who have inadequate glycaemic control with metformin.

Interpreting adverse signals in diabetes drug development programs

Detection and interpretation of adverse signals during preclinical and clinical stages of drug development inform the benefit-risk assessment that determines suitability for use in real-world situations. This review considers some recent signals associated with diabetes therapies, illustrating the difficulties in ascribing causality and evaluating absolute risk, predictability, prevention, and containment. Individual clinical trials are necessarily restricted for patient selection, number, and duration; they can introduce allocation and ascertainment bias and they often rely on biomarkers to estimate long-term clinical outcomes. In diabetes, the risk perspective is inevitably confounded by emergent comorbid conditions and potential interactions that limit therapeutic choice, hence the need for new therapies and better use of existing therapies to address the consequences of protracted glucotoxicity. However, for some therapies, the adverse effects may take several years to emerge, and it is evident that faint initial signals under trial conditions cannot be expected to foretell all eventualities. Thus, as information and experience accumulate with time, it should be accepted that benefit-risk deliberations will be refined, and adjustments to prescribing indications may become appropriate. © 2013 by the American Diabetes Association.