Rôle de l'estérification des acides gras dans la régulation de la sécrétion d'insuline et le stress métabolique induits par le glucose

Barbeau, Annie

04 1900

Le diabète est une maladie chronique de l’homéostasie du glucose caractérisée par une hyperglycémie non contrôlée qui est le résultat d’une défaillance de la sécrétion d’insuline en combinaison ou non avec une altération de l’action de l’insuline. La surnutrition et le manque d’activité physique chez des individus qui ont des prédispositions génétiques donnent lieu à la résistance à l’insuline. Pendant cette période dite de compensation où la concentration d’acides gras plasmatiques est élevée, l’hyperinsulinémie compense pleinement pour la résistance à l’insuline des tissus cibles et la glycémie est normale. Le métabolisme du glucose par la cellule pancréatique bêta entraîne la sécrétion d’insuline. Selon le modèle classique de la sécrétion d’insuline induite par le glucose, l’augmentation du ratio ATP/ADP résultant de la glycolyse et de l’oxydation du glucose, induit la fermeture des canaux KATP-dépendant modifiant ainsi le potentiel membranaire suivi d’un influx de Ca2+. Cet influx de Ca2+ permet l’exocytose des granules de sécrétion contenant l’insuline. Plusieurs nutriments comme les acides gras sont capables de potentialiser la sécrétion d’insuline. Cependant, le modèle classique ne permet pas d’expliquer cette potentialisation de la sécrétion d’insuline par les acides gras. Pour expliquer l’effet potentialisateur des acides gras, notre laboratoire a proposé un modèle complémentaire où le malonyl-CoA dérivé du métabolisme anaplérotique du glucose inhibe la carnitine palmitoyltransférase-1, l’enzyme qui constitue l’étape limitante de l’oxydation des acides gras favorisant ainsi leur estérification et donc la formation de dérivés lipidiques signalétiques. Le modèle anaplérotique/lipidique de la sécrétion d'insuline induite par le glucose prédit que le malonyl-CoA dérivé du métabolisme du glucose inhibe la bêta-oxydation des acides gras et augmente la disponibilité des acyl-CoA ou des acides gras non-estérifiés. Les molécules lipidiques agissant comme facteurs de couplage du métabolisme des acides gras à l'exocytose d'insuline sont encore inconnus. Des travaux réalisés par notre laboratoire ont démontré qu’en augmentant la répartition des acides gras vers la bêta-oxydation, la sécrétion d’insuline induite par le glucose était réduite suggérant qu’un des dérivés de l’estérification des acides gras est important pour la potentialisation sur la sécrétion d’insuline. En effet, à des concentrations élevées de glucose, les acides gras peuvent être estérifiés d’abord en acide lysophosphatidique (LPA), en acide phosphatidique (PA) et en diacylglycérol (DAG) et subséquemment en triglycérides (TG). La présente étude a établi l’importance relative du processus d’estérification des acides gras dans la production de facteurs potentialisant la sécrétion d’insuline. Nous avions émis l’hypothèse que des molécules dérivées des processus d’estérification des acides gras (ex : l’acide lysophosphatidique (LPA) et le diacylglycerol (DAG)) agissent comme signaux métaboliques et sont responsables de la modulation de la sécrétion d’insuline en présence d’acides gras. Afin de vérifier celle-ci, nous avons modifié le niveau d’expression des enzymes clés contrôlant le processus d’estérification par des approches de biologie moléculaire afin de changer la répartition des acides gras dans la cellule bêta. L’expression des différents isoformes de la glycérol-3-phosphate acyltransférase (GPAT), qui catalyse la première étape d’estérification des acides gras a été augmenté et inhibé. Les effets de la modulation de l’expression des isoenzymes de GPAT sur les processus d’estérifications, sur la bêta-oxydation et sur la sécrétion d’insuline induite par le glucose ont été étudiés. Les différentes approches que nous avons utilisées ont changé les niveaux de DAG et de TG sans toutefois altérer la sécrétion d’insuline induite par le glucose. Ainsi, les résultats de cette étude n’ont pas associé de rôle pour l’estérification de novo des acides gras dans leur potentialisation de la sécrétion d’insuline. Cependant, l’estérification des acides gras fait partie intégrante d’un cycle de TG/acides gras avec sa contrepartie lipolytique. D’ailleurs, des études parallèles à la mienne menées par des collègues du laboratoire ont démontré un rôle pour la lipolyse et un cycle TG/acides gras dans la potentialisation de la sécrétion d’insuline par les acides gras. Parallèlement à nos études des mécanismes de la sécrétion d’insuline impliquant les acides gras, notre laboratoire s’intéresse aussi aux effets négatifs des acides gras sur la cellule bêta. La glucolipotoxicité, résultant d’une exposition chronique aux acides gras saturés en présence d’une concentration élevée de glucose, est d’un intérêt particulier vu la prépondérance de l’obésité. L’isoforme microsomal de GPAT a aussi utilisé comme outil moléculaire dans le contexte de la glucolipotoxicité afin d’étudier le rôle de la synthèse de novo de lipides complexes dans le contexte de décompensation où la fonction des cellules bêta diminue. La surexpression de l’isoforme microsomal de la GPAT, menant à l’augmentation de l’estérification des acides gras et à une diminution de la bêta-oxydation, nous permet de conclure que cette modification métabolique est instrumentale dans la glucolipotoxicité. / Diabetes is a chronic disease of glucose homeostasis characterized by hyperglycemia and the result of a failure of insulin secretion in combination or not with impaired insulin action. Overnutrition and lack of physical activity in individuals who have acquired or inherited genetic predispositions lead to insulin resistance. During the period of compensation where the concentration of plasma fatty acids is high, hyperinsulinemia fully compensates for the insulin resistance of target tissues and blood sugar is normal. Glucose promotes insulin secretion through its metabolism by the pancreatic β cell. According to the classical model of glucose-induced insulin secretion, the increase in the ATP/ADP ratio resulting from glycolysis and glucose oxidation induces the closure of KATP channels thus changing membrane potential followed by an influx of Ca2+. This influx of Ca2+ allows the exocytosis of secretory granules containing insulin. Several nutrients like fatty acids are capable of potentiating insulin secretion. However, the classical model does not explain the potentiation of insulin secretion by fatty acids. To explain the potentiating effect of fatty acids, our laboratory has proposed a complementary model in which malonyl-CoA derived from glucose anaplerotic metabolism inhibits carnitine palmitoyltransferase 1, the enzyme catalyzing the limiting step of fatty acid oxidation, thereby promoting their esterification and thus the formation signaling derivatives. The anaplerotic model of insulin secretion predicts that malonyl-CoA derived from glucose metabolism inhibits β-oxidation of fatty acids and increases the availability of acyl-CoA or non esterified fatty acids. Thus, lipid molecules can act as coupling factors for insulin exocytosis. Fatty acid-derived signalling molecules that are active remain to be identified. Work performed by our laboratory has shown that increasing the partition of fatty acids toward β-oxidation reduced glucose-induced insulin secretion, suggesting that derivatives of fatty acid esterification are important for the potentiation of insulin secretion. Indeed, at high concentrations of glucose, fatty acids are esterified into lysophosphatidic acid (LPA), phosphatidic acid (PA) and diacylglycerol (DAG) and subsequently in triglycerides (TG). The present study established the relative importance fatty acid esterification in the production of factors potentiating insulin secretion. We hypothesized that molecules derived from the process of esterification of fatty acid (eg lysophosphatidic acid (LPA) and diacylglycerol (DAG)) act as metabolic signals and are responsible for the modulation of the secretion of insulin in the presence of fatty acids. Thus, the level of expression of key enzymes controlling the process of esterification has been altered by molecular biology approaches to increase distribution of fatty acids toward esterification in the β cell. The expression of various isoforms of glycerol-3-phosphate acyltransferase (GPAT), which catalyzes the first step of esterification of fatty acids was increased and inhibited. The effects of GPAT isoenzyme modulation on the esterification process, on β-oxidation and on glucose-induced insulin secretion were investigated. The various approaches we used have changed the levels of DAG and TG without altering insulin secretion induced by glucose in the presence or absence of fatty acids. Thus, the results of this study do not suggest a role for de novo synthesis of glycerolipid intermidiates via esterification of fatty acids in the potentiation of insulin secretion. However, the esterification of fatty acids is an integral part of a TG/fatty acid cycle with its counterpart lipolysis. Moreover, parallel studies conducted by colleagues of the laboratory have demonstrated a role for lipolysis and a cycle TG/fatty acid in the potentiation of insulin secretion by fatty acids. In parallel with our studies of the mechanisms of insulin secretion involving fatty acids, our laboratory is also interested in the negative effects of fatty acids on the β cell. The glucolipotoxicity resulting from chronic exposure to saturated fatty acids in the presence of high glucose concentrations is of particular interest in the context of obesity rates. The microsomal isoform of GPAT was also used as a molecular tool under glucolipotoxicity conditions to study the role of de novo synthesis of complex lipids in the context of decompensation when β-cell function decreases. Increased esterification of fatty acids by the overexpression of microsomal isoform of GPAT has increased the toxic effects of fatty acids in the context of glucolipotoxicity. Thus, our results allow us to conclude that the distribution of lipids toward esterification and a decrease in β-oxidation is instrumental in glucolipotoxicity.

Sécrétion d'insuline

Métabolisme des acides gras

Glucolipotoxicité

Glycérol-3-phosphate acyltransférase

Facteurs de couplage métabolique

Cellules bêta pancréatiques

Insulin secretion

Fatty acid metabolism

Pancreatic beta cells

Metabolic coupling factors

Glucolipotoxicity

Transcription factors and downstream genes modulating TNF-gas + IFN-gcs induced beta cell apoptosis

Barthson, Jenny

08 April 2013

In type 1 diabetes (T1D) a combination of genetic predisposition and environmental factors triggers islet inflammation (insulitis) leading to a selective and gradual destruction of the pancreatic beta cells. Beta cells mainly die through apoptosis, triggered at least in part by pro-inflammatory cytokines such as IL-1β, TNF-α and IFN-γ. Recent findings suggest that the mitochondrial pathway of cell death is involved in this death cascade. Array analysis indicated that TNF-α+IFN-γ induces transcription factors such as NF-ĸB, STAT1, and AP-1 in beta cells. We presently aimed to examine the pathway(s) of apoptosis triggered by TNF-α+IFN-γ in beta cells. <p>TNF-α+IFN-γ induces beta cell apoptosis through the intrinsic pathway of cell death. This involved activation of the BH3 only proteins DP5, PUMA and Bim. Knockdown (KD) of either DP5 or PUMA or both led to a partial protection of INS-1E cells (12-20%), while silencing Bim led to about 60% protection against cytokine-induced apoptosis. Bim is transcriptionally induced by activated STAT1. TNF-α+IFN-γ also induces downregulation of Bcl-XL, an anti-apoptotic Bcl-2 gene which inhibits Bim. Knocking down Bcl-XL alone led to increase in apoptosis, but this was prevented by the parallel KD of Bim.<p>The ultimate goal of our research is to protect beta cells from the autoimmune assault. Previous data revealed that JunB inhibits ER stress and apoptosis in beta cells treated with IL-β+IFN-γ. Here, TNF-α+IFN-γ up-regulated the expression of JunB which was downstream of activated NF-ĸB. JunB KD exacerbated TNF-α+IFN-γ induced beta cell death in primary rat beta cells and INS-1E cells. The gene networks affected by JunB were studied by microarray analysis. JunB regulates 20-25% of the cytokine-modified beta cell genes, including the transcription factor ATF3 and Bcl-XL. ATF3 expression was increased in cytokine-treated human islets and in vitro silencing of JunB led to >60% reduction in ATF3 overexpression. We confirmed direct JunB regulation of the ATF3 promoter by its binding to an ATF/CRE site. Silencing of ATF3 aggravated TNF-α+IFN-γ induced cell death in beta cells and led to the downregulation of Bcl-XL expression in INS-1E cells. Pharmacological upregulation of JunB using forskolin led to upregulation of ATF3 and consistent protection of these cells against cytokine-induced cell death, while genetic overexpression of JunB in mice increased ATF3 expression in the pancreatic islets and reversed the pro-apoptotic effects of cytokines on beta cells (±40 % protection). <p>As a whole, our findings indicate that TNF-α+IFN-γ triggers beta cell apoptosis by the upregulation of the pro-apoptotic protein Bim and downregulation of the Bcl-XL protein. These deleterious effects are at least in part antagonized by JunB via activation of ATF3. <p><p>Dans le diabète de type 1 (DT1), la combinaison de facteurs génétiques de prédisposition et de l'environnement déclenche l'inflammation des îlots de Langerhans (insulite) conduisant à une destruction sélective et progressive des cellules bêta du pancréas. Les cellules bêta meurent principalement d’apoptose, déclenchée au moins en partie par les cytokines pro-inflammatoires sécrétées par les cellules immunitaires comme l’IL-β, le TNF-α l’IFN-γ. De récentes découvertes suggèrent que la voie mitochondriale de la mort cellulaire jouerait un rôle dans la mort de ces cellules. L'analyse de réseaux de gène utilisant les biopuces d’ADN indique que l’association TNF-α+IFN-γ induit l’activation de facteurs de transcription tels que NF-ĸB, STAT1 et AP-1 dans la cellule bêta. Dans ce contexte, nous avons cherché à examiner les voies de l'apoptose déclenchées par le TNF-α+IFN-γ dans la cellule bêta. <p>En présence de TNF-α+IFN-γ les cellules bêta meurent par apoptose via la voie intrinsèque. L’activation des protéines pro-apoptotiques « BH3-seulement » dont DP5, PUMA et Bim étaient en cause de cette apoptose. Le « knockdown »1 (KD), de DP5 ou de PUMA, ou des deux en même temps conduit à une protection partielle des cellules INS-1E (12-20%), tandis que le KD de Bim conduit à environ 60% de protection contre l’apoptose induite par cette combinaison de cytokines. La transcription de Bim est induite par STAT1 activé. Parallèlement à la régulation positive de Bim, TNF-α+IFN-γ conduit à la régulation négative de la protéine Bcl-XL. Bcl-XL est une protèine anti-apoptotique de la famille de protèines Bcl-2 qui en general inhibe Bim. Réduire l’expression de Bcl-XL seul induit une augmention de l'apoptose, alors que le KD de Bim et Bcl-XL en parallèle empêche l'apoptose.<p>Le but ultime de notre recherche est de protéger les cellules bêta des agressions autoimmunitaires. Les données antérieures ont révélé que JunB inhibe le stress du réticulum endoplasmique et l'apoptose dans les cellules bêta traitées avec IL-β+IFN-γ. Nous avons observé que TNF-α+IFN-γ induit l'expression de JunB qui se produit en aval de NF-ĸB activé. Il est important de noter que l’inactivation de JunB par des agents interférants de l’ARN (siRNA) exacerbe la mort des cellules primaires bêta de rat et de cellules INS-1E induite par les cytokines. Les réseaux de gènes touchés par JunB ont été étudiés grâce a l'analyse en microréseaux. JunB règule 20-25% des gènes modifiés par des cytokines dans les cellules bêta, y compris le facteur de transcription ATF3 et Bcl-XL. L’expression d’ATF3 est augmenté dans les îlots humains traités avec les cytokines et la répression in vitro de JunB conduit à une réduction de >60% de l’expression d’ATF3. Nous avons confirmé la régulation d’ATF3 par JunB en montrant que JunB est directement lié au promoteur d’ATF3 via le site ATF/CRE. La diminution d’expression d’ATF3 en presence de TNF-α+IFN-γ a aggravé la mort cellulaire induite dans les cellules bêta et a conduit à la régulation négative de l'expression de Bcl-XL dans les cellules INS-1E. L’augmentation pharmacologique de JunB dans les cellules INS-1E par l’utilisation de forskolin a conduit à la régulation positive en aval d’ATF3 et par conséquente à la protection de cellules bêta vis-a-vis de effets indésirables des cytokines. Dans cette optique, la surexpression génétique de JunB dans le modèle Ubi-JunB de souris transgénique a conduit à une surexpression d’ATF3 dans les îlots pancréatiques et a permir d’inverser les effets pro-apoptotiques de cytokines sur la cellule bêta (protection ± 40%).<p>Globalement, ces résultats indiquent que TNF-α+IFN-γ déclenche l'apoptose des cellules bêta par la régulation positive du gène pro-apoptotique Bim et la régulation négative du gène anti-apoptotique Bcl-XL. Ces effets indésirables sont inhibé en partie par JunB via l’activation de ATF3.<p><p>1Pas d’équivalent en français. Signifie la réduction de l’expression d’un gène via utilisation d’un siRNA (agent interférant de l’ARN).<p> / Doctorat en Sciences biomédicales et pharmaceutiques / info:eu-repo/semantics/nonPublished

Disciplines biomédicales diverses

Médecine pathologie humaine

Transcription factors

Islands of Langerhans

Pancreatic beta cells

Apoptosis

Autoimmune diseases

Facteurs de transcription

Langerhans, Ilots de

Langerhans, Cellules bêta des îlots de

Apoptose

Maladies auto-immunes

STAT1

AP1

BCL-2 proteins

transcription factors

apoptosis

beta cell

Identification and characterization of the endoplasmic reticulum (ER)-stress pathways in pancreatic beta-cells / Identification et caractérisation des voies de signalisation du stress du réticulum endoplasmique dans la cellule bêta pancréatique

Pirot, Pierre

26 November 2007

The endoplasmic reticulum (ER) is the organelle responsible for synthesis and folding of secreted and membranous protein and lipid biosynthesis. It also functions as one of the main cellular calcium stores. Pancreatic beta-cells evolved to produce and secrete insulin upon demand in order to regulate blood glucose homeostasis. In response to increases in serum glucose, insulin synthesis represents nearly 50% of the total protein biosynthesis by beta-cells. This poses an enormous burden on the ER, rendering beta-cells vulnerable to agents that perturb ER function. Alterations of ER homeostasis lead to accumulation of misfolded proteins and activation of an adaptive response named the unfolded protein response (UPR). The UPR is transduced via 3 ER transmembrane proteins, namely PERK, IRE-1 and ATF6. The signaling cascades activated downstream of these proteins: a) induce expression of ER resident chaperones and protein foldases. Increasing the protein folding capacity of the ER; b) attenuate general protein translations which avoids overloading the stressed ER with new proteins; c) upregulate ER-associated degradation (ERAD) genes, which decreases the unfolded protein load of the ER. In severe cases, failure by the UPR to solve the ER stress leads to apoptosis. The mechanisms linking ER stress to apoptosis are still poorly understood, but potential mediators include the transcription factors Chop and ATF3, pro-apoptotic members of the Bcl-2 familly, the caspase 12 and the kinase JNK. <p>Accumulating evidence suggest that ER stress contributes to beta-cell apoptosis in both type 1 and type 2 diabetes. Type 1 diabetes is characterized by a severe insulin deficiency resulting from chronic and progressive destruction of pancreatic beta-cells by the immune system. During this autoimmune assault, beta-cells are exposed to cytokines secreted by the immune cells infiltrating the pancreatic islets. Our group has previously shown that the pro-inflamatory cytokines interleukin-1beta (IL1-beta and interferon-gamma (IFN-gamma), via nitric oxide (NO) formation, downregulate expression and function of the ER Ca2+ pump SERCA2. This depletes beta-cell ER Ca2+ stores, leading to ER stress and apoptosis. Of note, IL1-beta alone triggers ER stress but does not induce beta-cell death, while IFN-gamma neither causes ER stress nor induces beta-cell death. Together, these cytokines cause beta-cell apoptosis but the mechanisms behind this synergistic effect were unknown.<p>Type 2 diabetes is characterized by both peripheral resistance to insulin, usually as a result of obesity, and deficient insulin secretion secondary to beta cell failure. Obese patients have high levels of circulating free fatty acids (FFA) and several studies have shown that the FFA palmitate induces ER stress and beta-cell apoptosis.<p>In the present work we initially established an experimental model to specifically activate the ER stress response in pancreatic beta-cells. For this purpose, insulinoma cells (INS-1E) or primary rat beta-cells were exposed to the reversible chemical SERCA pump blocker cyclopiazonic acid (CPA). Dose-response and time course experiments determined the best conditions to induce a marked ER stress without excessive cell death (<25%).<p>The first goal of the work was to understand the synergistic effects of IL1-beta and IFN-gamma leading to pancreatic beta-cell apoptosis. Our group previously observed, by microarray analysis of primary beta-cells, that IFN-gamma down-regulates mRNAs encoding for some ER chaperones. Against this background, our hypothesis was that IFN-gamma aggravates beta-cell ER stress by decreasing the ability of these cells to mount an adequate UPR. To test this hypothesis, we investigated whether IFN-gamma pre-treatment augments CPA-induced ER stress and beta cell death. The results obtained indicated that IFN-gamma pre-treatment potentiates CPA-induced apoptosis in INS-1E and primary beta-cells. This effect was specific for IFN-gamma since neither IL1-beta nor a low dose CPA pre-treatment potentiated CPA-induced apoptosis in INS-1E cells. These effects of IFN-gamma were mediated via the down regulation of genes involved in beta cell defense against ER stress, including the ER chaperones BiP, Orp150 and Grp94 as well as Sec61, a component of the ERAD pathway. This had functional consequences as evidenced by a decreased basal and CPA-induced activity of a reporter construct for the unfolded protein response element (UPRE) and augmented expression of the pro-apoptotic transcription factor Chop. <p>We next investigated the molecular regulation of the Chop gene in INS-1E cells in response to several pro-apoptotic and ER stress inducing agents, namely cytokines (IL1-beta and IFN-gamma), palmitate, or CPA. Detailed mutagenesis studies of the Chop promoter showed differential regulation of Chop transcription by these compounds. While cytokines (via NO production)- and palmitate-induced Chop expression was mediated via a C/EBP-ATF composite and AP-1 binding sites, CPA induction required the C/EBP-ATF site and the ER stress response element (ERSE). Cytokines, palmitate and CPA induced ATF4 protein expression and further binding to the C/EBP-ATF composite site, as shown by Western blot and EMSA experiments. There was also formation of distinct AP-1 dimers and binding to the AP-1 site after exposure to cytokines or palmitate. <p>\ / Doctorat en Sciences biomédicales et pharmaceutiques / info:eu-repo/semantics/nonPublished

Disciplines biomédicales diverses

Médecine pathologie humaine

Pancreatic beta cells

Endoplasmic reticulum

Diabetes

Apoptosis

Langerhans, Cellules bêta des îlots de

Réticulum endoplasmique

Diabète insulinodépendant

Apoptose

ER stress

apoptosis

microarray

pancreatic beta cell

endoplasmic reticulum stress

T1DM

Type 1 Diabetes

Molecular pathways underlying beta-cell loss in vitro models of type 2 diabetes mellitus

Kharroubi, Ilham

January 2006

Doctorat en Sciences médicales / info:eu-repo/semantics/nonPublished

Médecine pathologie humaine

Pancreatic beta cells

Diabetes -- Pathogenesis

Langerhans, Cellules bêta des îlots de

Proliferação e disfunção da célula beta pancreática em modelo animal de Diabetes Melito tipo 2. Envolvimento da via de sinalização WNT/Beta-Catenina / Pancreatic beta cell proliferation and dysfunction in animal model of type 2 Diabetes Mellitus. Involvement of the WNT/Beta-catenin signaling pathway

Oliveira, Ricardo Beltrame de

18 August 2018

Orientador: Carla Beatriz Collares Buzato / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-18T15:01:37Z (GMT). No. of bitstreams: 1 Oliveira_RicardoBeltramede_M.pdf: 4343326 bytes, checksum: c45de34d36b3510fa7bea078864506dc (MD5) Previous issue date: 2011 / Resumo: Tem havido um grande interesse na determinação das vias envolvidas na proliferação e função/disfunção da célula beta e a aplicação deste conhecimento em terapias moleculares e celulares da diabetes. A patogênese da diabetes melito tipo 2 (T2DM) é complexa, mas frequentemente está associada com obesidade e distúrbios do metabolismo de lipídios (hipercolesterolemia e hipertrigliceridemia). A T2DM envolve o desenvolvimento de um quadro de resistência periférica à insulina parcialmente compensada por hiperinsulinemia e hiperplasia da célula beta pancreática, resultando em intolerância à glicose e hiperglicemia. Os mecanismos interligando os estados de obesidade/hipercolesterolemia e resistência à insulina ao fenômeno da hiperplasia da célula beta não são completamente conhecidos. A presente dissertação teve como objetivos: 1) caracterizar um modelo animal adequado para se estudar a proliferação e disfunção da célula beta pancreática, e 2) avaliar, no pâncreas endócrino desses animais, a possível ativação da via de sinalização Wnt/beta-catenina, conhecida por estar envolvida no processo de proliferação celular em outros tecidos/órgãos. Para tal, foram empregados camundongos C57BL/6, wild-type (WT) e knockout para receptor de lipoproteína LDL (LDLr-/-), os quais foram submetidos à dieta hiperlipídica (HF) por 60 dias. Após a dieta HF, os animais WT tornaram-se obesos e hipercolesterolêmicos, bem como moderadamente hiperglicêmicos, hiperinsulinêmicos, intolerantes à glicose e resistentes à insulina, caracterizando-os como pré-diabéticos. Além disso, os animais alimentados com dieta HF apresentaram uma diminuição significativa na resposta secretora das células beta à glicose. De modo geral, os animais LDLr-/- apresentaram uma susceptibilidade relativamente mais alta à dieta HF, sugerida pela acentuada hipercolesterolemia, intolerância à glicose, e reduzida secreção de insulina estimulada por glicose observadas nestes animais. No entanto, a dieta HF induziu, de forma semelhante em animais WT e LDLr-/-, uma diminuição significativa no conteúdo celular de Cx36, uma proteína associada à junção comunicante e um marcador de diferenciação terminal da célula beta. Ambos os grupos WT e LDLr-/- alimentados com dieta HF mostraram aumento na proliferação de células beta, como avaliada pela imunomarcação das ilhotas para a proteína Ki67, mas apenas os animais WT exibiram alterações morfométricas indicativas de hiperplasia do pâncreas endócrino, tais como aumento na massa total de ilhotas e de células beta. Uma vez estabelecido que camundongos WT alimentados com dieta HF por 60 dias consistiam em um modelo adequado para a segunda etapa deste estudo, fomos investigar a possível ativação da via Wnt/beta-catenina nas ilhotas pancreáticas desses animais, avaliando-se a distribuição e expressão celular das proteínas beta-catenina total, beta-catenina ativada, c-Myc e ciclina D. A análise por imunofluorescência para beta-catenina não mostrou acúmulo citoplasmático ou translocação para o núcleo desta proteína em ilhotas pancreáticas, que poderia indicar ativação da via Wnt/beta-catenina no nosso modelo de hiperplasia do pâncreas endócrino. No entanto, a análise por Western Blot revelou um aumento significativo na expressão de beta-catenina ativada e ciclina D em ilhotas de animais alimentados com dieta HF em relação ao grupo controle. Concluindo, a dieta HF por 60 dias induz alterações metabólicas típicas da pré-diabetes em animais WT e LDLr-/-. O estado de pré-diabetes está associado a uma diminuição da expressão de Cx36 nas células beta pancreáticas, sugerindo um possível papel da comunicação intercelular mediada pelas junções comunicantes na patogênese da T2DM. A maior susceptibilidade metabólica à dieta HF apresentada por camundongos LDLr-/-, em relação aos WT, pode ser explicada pela maior deficiência na secreção de insulina em resposta à glicose e ausência de hiperplasia compensatória do pâncreas endócrino. Ainda, a análise preliminar de expressão protéica de algumas proteínas da via Wnt/beta-catenina sugere que esta via parece estar ativada durante o processo de hiperplasia do pâncreas endócrino observada no nosso modelo animal / Abstract: The pathogenesis of type 2 diabetes mellitus (T2DM) is often associated with obesity and dyslipidemia (hypercholesterolemia and hypertriglyceridemia). T2DM involves intolerance to glucose and insulin resistance partially compensated by hyperinsulinemia and pancreatic beta cell hyperplasia. The mechanisms linking obesity/hypercholesterolemia and insulin resistance to beta cell hyperplasia are not fully known. The Wnt/beta-catenin signaling pathway has been reported to be involved in cell growth and differentiation in several tissues/organs but its role in endocrine pancreas development and function is still unclear. This work aimed at: 1) establishing an appropriate animal model of T2DM to study pancreatic beta cell proliferation and dysfunction and, 2) investigating a putative involvement of the Wnt/beta-catenin signaling pathway in the beta cell hyperplasia in this model. To this end, we employed C57BL/6 wild-type (WT) and LDL lipoprotein receptor knockout (LDLr-/-) mice, fed a high fat (HF) diet for 60 days. After feeding a HF diet, WT mice became obese, hypercholesterolemic and moderately hyperglycemic, hyperinsulinemic, glucose intolerant and insulin resistant, characterizing them as pre-diabetics. Moreover, animals fed a HF diet showed a significant decrease in beta-cell secretory response to glucose. In general, LDLr-/- animals showed a relatively higher susceptibility to HF diet, as suggested by a marked hypercholesterolemia, glucose intolerance and reduced insulin secretion stimulated by glucose observed in these animals as compared to the control ones. However, HF diet induced similarly in both WT and LDLr-/- mice a significant decrease in cellular content of Cx36, a gap junctional protein and marker of terminally differentiated beta cell. Both WT and LDLr-/- fed a HF diet showed increased proliferation of beta cells, as assessed by Ki67 immunostaining, but only WT mice exhibited morphometric changes indicative of endocrine pancreas hyperplasia, such as increased total islet and beta cell masses. After we investigated a possible activation of Wnt/beta-catenin signaling pathway in these hyperplasic pancreatic islets of WT animals fed a HF diet. This was done by assessing the distribution and cellular protein expression of some proteins associated to this pathway (i.e., total and activated beta-catenin, c-Myc and cyclin D) in islets of our animal model. Beta-catenin immunofluorescence showed no cytoplasmic accumulation or translocation into the nucleus of beta cells in HF-fed mice. However, immunoblotting revealed a significant increase of unphosphorylated beta-catenin (activated) and cyclin D expression in islets of HF diet-fed animals when compared to its control group. In conclusion, a HF diet for 60d induced pre-diabetes state in both WT and LDLr-/- mice. The pre-diabetes state is associated with a decreased expression of Cx36 in pancreatic beta cells, suggesting a possible role of intercellular communication mediated by gap junctions in the pathogenesis of T2DM. The relatively high metabolic susceptibility to the HF diet showed by LDLr-/- mice, as compared to WT, may be explained by a marked impairment of glucosestimulated insulin secretion and a lack of compensatory hyperplasia of the endocrine pancreas. In addition, the protein expression analysis suggests that the Wnt/beta-catenin pathway may be activated during the islet hyperplasia process in our animal model / Mestrado / Histologia / Mestre em Biologia Celular e Estrutural

Células secretoras de insulina

Diabetes mellitus tipo 2

beta Catenina

Insulina - Secreção

Proliferação celular

Ilhotas pancreáticas

Dieta hiperlipídica

Pancreatic beta cells

Type 2 Diabetes Mellitus

Beta catenin

Insulin secretion

Cell proliferation

Islets of Langerhans

High fat diet

Regulation of glucose homeostasis by Doc2b and Munc18 proteins.

Ramalingam, Latha

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Glucose homeostasis is maintained through the coordinated actions of insulin secretion from pancreatic beta cells and insulin action in peripheral tissues. Dysfunction of insulin action yields insulin resistance, and when coupled with altered insulin secretion, results in type 2 diabetes (T2D). Exocytosis of intracellular vesicles, such as insulin granules and glucose transporter (GLUT4) vesicles is carried out by similar SNARE (soluble NSF attachment receptor) protein isoforms and Munc18 proteins. An additional regulatory protein, Doc2b, was implicated in the regulation of these particular exocytosis events in clonal cell lines, but relevance of Doc2b in the maintenance of whole body glucose homeostasis in vivo remained unknown. The objective of my doctoral work was to delineate the mechanisms underlying regulation of insulin secretion and glucose uptake by Doc2b in effort to identify new therapeutic targets within these processes for the prevention and/or treatment of T2D. Towards this, mice deficient in Doc2b (Doc2b-/- knockout mice) were assessed for in vivo alterations in glucose homeostasis. Doc2b knockout mice were highly susceptible to preclinical T2D, exhibiting significant whole-body glucose intolerance related to insulin secretion insufficiency as well as peripheral insulin resistance. These phenotypic defects were accounted for by defects in assembly of SNARE complexes. Having determined that Doc2b was required in the control over whole body glycemia in vivo, whether Doc2b is also limiting for these mechanisms in vivo was examined. To study this, novel Doc2b transgenic (Tg) mice were engineered to express ~3 fold more Doc2b exclusively in pancreas, skeletal muscle and fat tissues. Compared to normal littermate mice, Doc2b Tg mice had improved glucose tolerance, related to concurrent enhancements in insulin mumsecretion from beta cells and insulin-stimulated glucose uptake in the skeletal muscle. At the molecular level, Doc2b overexpression promoted SNARE complex assembly, increasing exocytotic capacities in both cellular processes. These results unveiled the concept that intentional elevation of Doc2b could provide a means of mitigating two primary aberrations underlying T2D development.

Diabetes

SNARE proteins

exocytosis

Blood sugar -- Research

Diabetes -- Pathophysiology

Diabetes -- Research

Blood sugar -- Analysis

Homeostasis -- Research

Insulin resistance

Glucose

Glucose -- Synthesis

Proteins -- Research

Proteins -- Metabolism -- Disorders

Gluconeogenesis

Transgenic mice -- Research

Non-insulin-dependent diabetes

Pancreatic beta cells

The roles of pancreatic hormones in regulating pancreas development and beta cell regeneration

Ye, Lihua

16 June 2015

Indiana University-Purdue University Indianapolis (IUPUI) / Diabetes mellitus is a group of related metabolic diseases that share a common pathological mechanism: insufficient insulin signaling. Insulin is a hormone secreted from pancreatic β cells that promotes energy storage and consequently lowers blood glucose. In contrast, the hormone glucagon, released by pancreatic α cells, plays a critical complementary role in metabolic homeostasis by releasing energy stores and increasing blood glucose. Restoration of β cell mass in diabetic patients via β cell regeneration is a conceptually proven approach to finally curing diabetes. Moreover, in situ regeneration of β cells from endogenous sources would circumvent many of the obstacles encountered by surgical restoration of β cell mass via islet transplantation. Regeneration may occur both by β cell self-duplication and by neogenesis from non-β cell sources. Although the mechanisms regulating the β cell replication pathway have been highly investigated, the signals that regulate β cell neogenesis are relatively unknown. In this dissertation, I have used zebrafish as a genetic model system to investigate the process of β cell neogenesis following insulin signaling depletion by various modes. Specifically, I have found that after their ablation, β cells primarily regenerate from two discrete cellular sources: differentiation from uncommitted pancreatic progenitors and transdifferentiation from α cells. Importantly, I have found that insulin and glucagon play crucial roles in controlling β cell regeneration from both sources. As with metabolic regulation, insulin and glucagon play counter-balancing roles in directing endocrine cell fate specification. These studies have revealed that glucagon signaling promotes β cell formation by increasing differentiation of pancreas progenitors and by destabilizing α cell identity to promote α to β cell transdifferentiation. In contrast, insulin signaling maintains pancreatic progenitors in an undifferentiated state and stabilizes α cell identity. Finally, I have shown that insulin also regulates pancreatic exocrine cell development. Insufficient insulin signaling destabilized acinar cell fate and impairs exocrine pancreas development. By understanding the roles of pancreatic hormones during pancreas development and regeneration can provide new therapeutic targets for in vivo β cell regeneration to remediate the devastating consequences of diabetes.

Diabetes

Alpha cell

Beta cell

Glucagon

Pancreatic hormone

Transdifferentiation

Diabetes -- Pathophysiology

Diabetes -- Research

Diabetes -- Complications

Metabolism -- Disorders

Insulin -- Receptors

Insulin -- Physiology

Glucagon

Glucagon -- Physiological effect

Pancreatic beta cells

Cell proliferation

Diabetes -- Treatment

F-Actin regulation of SNARE-mediated insulin secretion

Kalwat, Michael Andrew

07 October 2013

Indiana University-Purdue University Indianapolis (IUPUI) / In response to glucose, pancreatic islet beta cells secrete insulin in a biphasic manner, and both phases are diminished in type 2 diabetes. In beta cells, cortical F-actin beneath the plasma membrane (PM) prevents insulin granule access to the PM and glucose stimulates remodeling of this cortical F-actin to allow trafficking of insulin granules to the PM. Glucose stimulation activates the small GTPase Cdc42, which then activates p21-activated kinase 1 (PAK1); both Cdc42 and PAK1 are required for insulin secretion. In conjunction with Cdc42-PAK1 signaling, the SNARE protein Syntaxin 4 dissociates from F-actin to allow SNARE complex formation and insulin exocytosis. My central hypothesis is that, in the pancreatic beta cell, glucose signals through a Cdc42-PAK1-mediated pathway to remodel the F-actin cytoskeleton to mobilize insulin granules to SNARE docking sites at the PM to evoke glucose stimulated second phase insulin secretion. To investigate this, PAK1 was inhibited in MIN6 beta cells with IPA3 followed by live-cell imaging of F-actin remodeling using the F-actin probe, Lifeact-GFP. PAK1 inhibition prevented normal glucose-induced F-actin remodeling. PAK1 inhibition also prevented insulin granule accumulation at the PM in response to glucose. The ERK pathway was implicated, as glucose-stimulated ERK activation was decreased under PAK1-depleted conditions. Further study showed that inhibition of ERK impaired insulin secretion and cortical F-actin remodeling. One of the final steps of insulin secretion is the fusion of insulin granules with the PM which is facilitated by the SNARE proteins Syntaxin 4 on the PM and VAMP2 on the insulin granule. PAK1 activation was also found to be critical for Syntaxin 4-F-actin complex dynamics in beta cells, linking the Cdc42-PAK1 signaling pathway to SNARE-mediated exocytosis. Syntaxin 4 interacts with the F-actin severing protein Gelsolin, and in response to glucose Gelsolin dissociates from Syntaxin 4 in a calcium-dependent manner to allow Syntaxin 4 activation. Disrupting the interaction between Syntaxin 4 and Gelsolin aberrantly activates endogenous Syntaxin 4, elevating basal insulin secretion. Taken together, these results illustrate that signaling to F-actin remodeling is important for insulin secretion and that F-actin and its binding proteins can impact the final steps of insulin secretion.

F-actin

SNARE

Syntaxin

Gelsolin

PAK1

Cdc42

diabetes

insulin secretion

islet

ERK

Diabetes -- Research

Diabetes -- Pathophysiology

Pancreatic beta cells

Insulin -- Physiological effect

Actin genes

Exocytosis

Glycoproteins

Synapses

Glucose

Cells -- Mechanical properties

Cellular signal transduction -- Research

ENGINEERING DESIGN OF NOVEL 3D MICROPHYSIOLOGICAL SYSTEM AND SENSOR FOR FUNCTIONAL ASSESSMENT OF PANCREATIC BETA-CELLS

Emma Vanderlaan (15348208)

25 April 2023

<p>  </p> <p>Diabetes, a chronic condition characterized by elevated blood glucose levels, arises when pancreatic β-cells lose capacity to produce a robust, dynamic glucose-stimulated insulin secretion (GSIS) response. Accurate measurement of β-cell health and function <em>ex vivo</em> is thus fundamental to diabetes research, including studies evaluating disease mechanisms, novel drug candidates, and replacement β-cell populations. However, present-day dynamic GSIS assays typically represent end-point measurements, involve expensive commercial perifusion machines, and require time-consuming enzyme-linked immunosorbent assays (ELISA) for insulin detection. Microfluidic devices developed as accessible, low-cost alternatives still rely on secondary ELISAs and suspend islets in liquid medium, limiting their survival <em>in vitro</em>. Here, we present a novel, 3D-printed microphysiological system (MPS) designed to recreate components of <em>in-vivo</em> microenvironments through encapsulation in fibrillar type I collagen and restoration of favorable molecular transport conditions. Following computational-informed design and rapid prototyping, the MPS platform sustained collagen-encapsulated mouse islet viability and cytoarchitecture for 5 days and supported <em>in-situ</em> measurements of dynamic β-cell function. To rapidly detect insulin secretion from β-cells in the MPS, we then developed a highly sensitive electrochemical sensor for zinc (Zn2+), co-released with insulin, based on glassy carbon electrodes modified with bismuth and indium and coated with Nafion. Finally, we validated sensor detection of Zn2+ released from glucose-stimulated INS-1 β-cells and primary mouse islets, finding high correlation with insulin as measured by standard ELISA. Together, the 3D MPS and Zn2+ sensor developed in this dissertation represent novel platforms for evaluating β-cell health and function in a low-cost, user-friendly, and physiologically-relevant manner. </p>

Biofabrication

Computational physiology

Tissue engineering

microphysiological system

pancreatic beta cells

diabetes

organ-on-a-chip devices

3D printing

computational modeling

electrochemical sensor

Glucose stimulated insulin secretion

zinc (Zn2+)

anodic stripping voltammetry

Étude de l'implication des navettes du pyruvate découlant du métabolisme mitochondrial du glucose dans la régulation de la sécrétion d'insuline par les cellules bêta pancréatiques

Guay, Claudiane

01 1900

Le diabète est une maladie métabolique qui se caractérise par une résistance à l’insuline des tissus périphériques et par une incapacité des cellules β pancréatiques à sécréter les niveaux d’insuline appropriés afin de compenser pour cette résistance. Pour mieux comprendre les mécanismes déficients dans les cellules β des patients diabétiques, il est nécessaire de comprendre et de définir les mécanismes impliqués dans le contrôle de la sécrétion d’insuline en réponse au glucose. Dans les cellules β pancréatiques, le métabolisme du glucose conduit à la production de facteurs de couplage métabolique, comme l’ATP, nécessaires à la régulation de l’exocytose des vésicules d’insuline. Le mécanisme par lequel la production de l’ATP par le métabolisme oxydatif du glucose déclenche l’exocytose des vésicules d’insuline est bien décrit dans la littérature. Cependant, il ne peut à lui seul réguler adéquatement la sécrétion d’insuline. Le malonyl-CoA et le NADPH sont deux autres facteurs de couplage métaboliques qui ont été suggérés afin de relier le métabolisme du glucose à la régulation de la sécrétion d’insuline. Les mécanismes impliqués demeurent cependant à être caractérisés. Le but de la présente thèse était de déterminer l’implication des navettes du pyruvate, découlant du métabolisme mitochondrial du glucose, dans la régulation de la sécrétion d’insuline. Dans les cellules β, les navettes du pyruvate découlent de la combinaison des processus d’anaplérose et de cataplérose et permettent la transduction des signaux métaboliques provenant du métabolisme du glucose. Dans une première étude, nous nous sommes intéressés au rôle de la navette pyruvate/citrate dans la régulation de la sécrétion d’insuline en réponse au glucose, puisque cette navette conduit à la production dans le cytoplasme de deux facteurs de couplage métabolique, soit le malonyl-CoA et le NADPH. De plus, la navette pyruvate/citrate favorise le flux métabolique à travers la glycolyse en réoxydation le NADH. Une étude effectuée précédemment dans notre laboratoire avait suggéré la présence de cette navette dans les cellules β pancréatique. Afin de tester notre hypothèse, nous avons ciblé trois étapes de cette navette dans la lignée cellulaire β pancréatique INS 832/13, soit la sortie du citrate de la mitochondrie et l’activité de l’ATP-citrate lyase (ACL) et l’enzyme malique (MEc), deux enzymes clés de la navette pyruvate/citrate. L’inhibition de chacune de ces étapes par l’utilisation d’un inhibiteur pharmacologique ou de la technologie des ARN interférant a corrélé avec une réduction significative de la sécrétion d’insuline en réponse au glucose. Les résultats obtenus suggèrent que la navette pyruvate/citrate joue un rôle critique dans la régulation de la sécrétion d’insuline en réponse au glucose. Parallèlement à notre étude, deux autres groupes de recherche ont suggéré que les navettes pyruvate/malate et pyruvate/isocitrate/α-cétoglutarate étaient aussi importantes pour la sécrétion d’insuline en réponse au glucose. Ainsi, trois navettes découlant du métabolisme mitochondrial du glucose pourraient être impliquées dans le contrôle de la sécrétion d’insuline. Le point commun de ces trois navettes est la production dans le cytoplasme du NADPH, un facteur de couplage métabolique possiblement très important pour la sécrétion d’insuline. Dans les navettes pyruvate/malate et pyruvate/citrate, le NADPH est formé par MEc, alors que l’isocitrate déshydrogénase (IDHc) est responsable de la production du NADPH dans la navette pyruvate/isocitrate/α-cétoglutarate. Dans notre première étude, nous avions démontré l’importance de l’expression de ME pour la sécrétion adéquate d’insuline en réponse au glucose. Dans notre deuxième étude, nous avons testé l’implication de IDHc dans les mécanismes de régulation de la sécrétion d’insuline en réponse au glucose. La diminution de l’expression de IDHc dans les INS 832/13 a stimulé la sécrétion d’insuline en réponse au glucose par un mécanisme indépendant de la production de l’ATP par le métabolisme oxydatif du glucose. Ce résultat a ensuite été confirmé dans les cellules dispersées des îlots pancréatiques de rat. Nous avons aussi observé dans notre modèle que l’incorporation du glucose en acides gras était augmentée, suggérant que la diminution de l’activité de IDHc favorise la redirection du métabolisme de l’isocitrate à travers la navette pyruvate/citrate. Un mécanisme de compensation à travers la navette pyruvate/citrate pourrait ainsi expliquer la stimulation de la sécrétion d’insuline observée en réponse à la diminution de l’expression de IDHc. Les travaux effectués dans cette deuxième étude remettent en question l’implication de l’activité de IDHc, et de la navette pyruvate/isocitrate/α-cétoglutarate, dans la transduction des signaux métaboliques reliant le métabolisme du glucose à la sécrétion d’insuline. La navette pyruvate/citrate est la seule des navettes du pyruvate à conduire à la production du malonyl-CoA dans le cytoplasme des cellules β. Le malonyl-CoA régule le métabolisme des acides gras en inhibant la carnitine palmitoyl transférase 1, l’enzyme limitante dans l’oxydation des acides gras. Ainsi, l’élévation des niveaux de malonyl-CoA en réponse au glucose entraîne une redirection du métabolisme des acides gras vers les processus d’estérification puis de lipolyse. Plus précisément, les acides gras sont métabolisés à travers le cycle des triglycérides/acides gras libres (qui combinent les voies métaboliques d’estérification et de lipolyse), afin de produire des molécules lipidiques signalétiques nécessaires à la modulation de la sécrétion d’insuline. Des études effectuées précédemment dans notre laboratoire ont démontré que l’activité lipolytique de HSL (de l’anglais hormone-sensitive lipase) était importante, mais non suffisante, pour la régulation de la sécrétion d’insuline. Dans une étude complémentaire, nous nous sommes intéressés au rôle d’une autre lipase, soit ATGL (de l’anglais adipose triglyceride lipase), dans la régulation de la sécrétion d’insuline en réponse au glucose et aux acides gras. Nous avons démontré que ATGL est exprimé dans les cellules β pancréatiques et que son activité contribue significativement à la lipolyse. Une réduction de son expression dans les cellules INS 832/13 par RNA interférant ou son absence dans les îlots pancréatiques de souris déficientes en ATGL a conduit à une réduction de la sécrétion d’insuline en réponse au glucose en présence ou en absence d’acides gras. Ces résultats appuient l’hypothèse que la lipolyse est une composante importante de la régulation de la sécrétion d’insuline dans les cellules β pancréatiques. En conclusion, les résultats obtenus dans cette thèse suggèrent que la navette pyruvate/citrate est importante pour la régulation de la sécrétion d’insuline en réponse au glucose. Ce mécanisme impliquerait la production du NADPH et du malonyl-CoA dans le cytoplasme en fonction du métabolisme du glucose. Cependant, nos travaux remettent en question l’implication de la navette pyruvate/isocitrate/α-cétoglutarate dans la régulation de la sécrétion d’insuline. Le rôle exact de IDHc dans ce processus demeure cependant à être déterminé. Finalement, nos travaux ont aussi démontré un rôle pour ATGL et la lipolyse dans les mécanismes de couplage métabolique régulant la sécrétion d’insuline. / Diabetes is a metabolic disorder characterized by a combination of insulin resistance in peripheral tissues with an inappropriate amount of insulin secreted by the pancreatic β-cells to overcome this insulin resistance. In order to help find a cure for diabetic patients, we need to elucidate the mechanisms underlying the proper control of insulin secretion in response to glucose. In pancreatic β-cells, glucose metabolism leads to the production of metabolic coupling factors, like ATP, implicated in the regulation of insulin vesicle exocytosis. The mechanism linking ATP production by the oxidative metabolism of glucose to the triggering of insulin release that involves Ca2+ and metabolically sensitive K+ channels is relatively well known. Other mechanisms are also involved in the regulation of insulin secretion in response to glucose and other nutrients, such as fatty acids and some amino acids. Malonyl-CoA and NADPH are two metabolic coupling factors that have been suggested to be implicated in the transduction of metabolic signaling coming from glucose metabolism to control the release of insulin granules. However, the mechanisms implicated remained to be defined. The goal of the present thesis was to further our understanding of the role of the pyruvate shuttles, derived from mitochondrial glucose metabolism, in the regulation of insulin secretion. In pancreatic β-cells, pyruvate shuttles are produced by the combination of anaplerosis and cataplerosis processes and are thought to link glucose metabolism to the regulation of insulin secretion by the production metabolic coupling factors. In our first study, we wished to determine the role of the pyruvate/citrate shuttle in the regulation of glucose-induced insulin secretion. The pyruvate/citrate shuttle leads to the production in the cytoplasm of both malonyl-CoA and NADPH and also stimulates the metabolic flux through the glycolysis by re-oxidating NADH. A previous study done in the group of Dr Prentki has suggested the feasibility of the pyruvate/citrate shuttle in pancreatic β-cells. To investigate our hypothesis, we inhibited three different steps of this shuttle in INS 832/13 cells, a pancreatic β-cell line. Specifically, we repressed, using pharmacological inhibitors or RNA interference technology, the mitochondrial citrate export to the cytoplasm and the expression of malic enzyme (MEc) and ATP-citrate lyase (ACL), two key enzymes implicated in the pyruvate/citrate shuttle. The inhibition of each of those steps resulted in a reduction of glucose-induced insulin secretion. Our results underscore the importance of the pyruvate/citrate shuttle in the pancreatic β-cell signaling and the regulation of insulin secretion in response to glucose. Other research groups are also interested in studying the implication of pyruvate cycling processes in the regulation of insulin exocytosis. They suggested a role for the pyruvate/malate and the pyruvate/isocitrate/α-ketoglutarate shuttles. Therefore, three different shuttles derived from the mitochondrial glucose metabolism could be implicated in the regulation of glucose-induced insulin release. All those three shuttles can produce NADPH in the cytoplasm. In the pyruvate/malate and the pyruvate/citrate shuttles, the NADPH is formed by cytosolic malic enzyme (MEc), whereas in the pyruvate/isocitrate/α-ketoglutarate, NADPH is produced by cytosolic isocitrate dehydrogenease (IDHc). In our first study, we established the importance of MEc expression in the regulation of insulin secretion. In our second study, we wanted to investigate the importance of IDHc expression in glucose-induced insulin secretion. The reduction of IDHc expression in INS 832/13 cells stimulated insulin release in response to glucose by a mechanism independent of ATP production coming from glucose oxidative metabolism. This stimulation was also observed in isolated rat pancreatic cells. IDHc knockdown cells showed elevated glucose incorporation into fatty acids, suggesting that isocitrate metabolism could be redirected into the pyruvate/citrate shuttle in these cells. Taken together, these results suggest that IDHc is not essential for glucose-induced insulin secretion and that a compensatory mechanism, probably involving the pyruvate/citrate shuttle, explains the enhanced insulin secretion in IDHc knockdown cells . The pyruvate/citrate shuttle is the only pyruvate shuttle that is linked to the production of malonyl-CoA. Malonyl-CoA is a known inhibitor of carnitine palmitoyl transferase 1, the rate-limiting step in fatty acid oxidation. Therefore, the raising level of malonyl-CoA in response to glucose redirects the metabolism of fatty acids into the triglycerides/free fatty acids cycle which combine esterification and lipolysis processes. Previous studies done in the laboratory of Dr Prentki supported the concept that lipolysis of endogenous lipid stores is an important process for the appropriate regulation of insulin secretion. A first lipase, hormone-sensitive lipase (HSL), has been identified in pancreatic β-cells. HSL expression is important, but not sufficient, for the β-cell lipolysis activity. In a complementary study, we have investigated the role of another lipase, adipose triglyceride lipase (ATGL), in the regulation of insulin secretion in response to glucose and to fatty acids. We first demonstrated the expression and the activity of ATGL in pancreatic β-cells. Reducing ATGL expression using shRNA in INS 832/13 cells caused a reduction in insulin secretion in response to glucose and to fatty acids. Pancreatic islets from ATGL null mice also showed defect in insulin release in response to glucose and to fatty acids. The results demonstrate the importance of ATGL and intracellular lipid signaling in the regulation of insulin secretion. In conclusion, the work presented in this thesis suggests a role for the pyruvate/citrate shuttle in the regulation of insulin secretion in response to glucose. This mechanism possibly implicates the production of NADPH and malonyl-CoA in the cytoplasm. The results also points to a re-evaluation of the role of IDHc in glucose-induced insulin secretion. The precise role of IDHc in pancreatic β-cells needs to be determined. Finally, the data have also documented a role of lipolysis and ATGL in the coupling mechanisms of insulin secretion in response to both fuel and non-fuel stimuli.

Cellules bêta pancréatiques

Sécrétion insuline

Métabolisme du glucose

Anaplérose

Navettes du pyruvate

Navette pyruvate/citrate

Facteurs de couplage métabolique

NADPH

Pancreatic beta cells

Insulin secretion

Glucose metabolism

Anaplerosis

Pyruvate cycling

Pyruvate/citrate shuttle

metabolic coupling factors

NADPH