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Rôle des acides biliaires et de leur récepteur TGR5 dans la régulation de la somatostatine pancréatique et intestinale : conséquences fonctionnelles sur les îlots pancréatiques humains / Role of bile acids and their receptor TGR5 in the regulation of intestinal and pancreatic somatostatin : functional consequences for human pancreatic isletsQueniat, Gurvan 09 September 2015 (has links)
Le rôle des acides biliaires a évolué ces dernières années passant de simples molécules solubilisatrices des lipides à des composés à activité métabolique. En plus de leur fonction dans l’absorption des lipides post-repas, ils ont été montrés comme stimulant de nombreuses voies de signalisation modulant l’expression de gènes clefs du métabolisme et de nombreux mécanismes physiologiques via l’activation de récepteurs spécifiques tels que les récepteurs « Farnesoid X receptor » (FXR) et le récepteur membranaire couplé à une protéine G, TGR5. La protéine TGR5 codée par le gène GPBAR1, aussi connue sous le nom de « G-protein-membrane-type receptor for bile acids » (M-BAR) est le premier récepteur couplé à une protéine G spécifique aux acides biliaires ayant été mis en évidence. Cette protéine est exprimée dans de nombreux tissus clefs du métabolisme énergétique tels que les cellules L intestinales, le tissu adipeux, les reins, le muscle squelettique et le pancréas. En réponse à la fixation des acides biliaires au récepteur TGR5, celui-ci va être internalisé et sa sous-unité GαS va être libérée. Ce mécanisme va ensuite activer l’adénylate cyclase et augmenter la production d’AMPc à l’origine de l’activation des voies de signalisations liées à la protéine kinase A (PKA). Une fois activée, la PKA va induire la phosphorylation des protéines « cAMP-response element-binding » (CREB) et permettre la modulation de l’expression de gènes cibles.Ces dernières années de nombreux travaux ont eu pour but d’étudier le rôle du récepteur TGR5 dans le métabolisme. Chez la souris, l’activation du récepteur TGR5 stimule la dépense énergétique dans le tissu adipeux brun et dans le muscle squelettique et prévient le développement de l’obésité et de l’insulino-résistance induites par un régime riche en graisses. Le récepteur TGR5 est également impliqué au niveau des cellules L intestinales sécrétrices du GLP-1. Il y joue un rôle essentiel dans l’homéostasie glucidique via la régulation de l’activité pancréatique, des sécrétions de l’insuline et du glucagon, de l’inhibition de la vidange gastrique ou encore de la modulation des messages de satiété via des voies neuroendocrines. TGR5 présente également des fonctions immunologiques avec une expression connue dans les cellules de l’immunité telles que les monocytes, les macrophages alvéolaires ou encore les cellules de Kupffer. TGR5 a également été mis en évidence comme régulateur des mécanismes d’inflammations via les macrophages avec une diminution de l’expression des cytokines pro-inflammatoires. A l’opposé, l’activation de TGR5 serait impliquée dans de nombreux processus pathologiques tels que, le développement de carcinomes gastro-intestinaux, les pancréatites, la lithiase biliaire, suggérant un rôle potentiel du récepteur TGR5 dans la régulation de voies de signalisation responsables de la prolifération et de la mort cellulaire [...] / Bile acids (BAs) have evolved over the years from being considered as simple lipid solubilizers to metabolically active molecules. In addition to their function in dietary lipid absorption, they have also been shown to activate farnesoid X receptor (FXR) and TGR5 receptors to initiate signaling pathways and regulate metabolic gene transcription. TGR5 (encoded by the GPBAR1 gene), also known as G-protein-membrane-type receptor for bile acids (M-BAR) or G-protein-coupled bile acid receptor 1 (GPBAR1), was the first identified G-protein coupled receptor specific for bile acids. In normal individuals, the highest level of GPBAR1 mRNA expression was reported in the gallbladder, placenta and spleen, followed by moderate expression in other tissues including lungs, liver, stomach, small intestine and adipose tissue, with a relatively low level of expression in kidney, skeletal muscles and pancreas. In response to binding of BAs to the ligand-binding pocket of the TGR5 protein, the TGR5 receptor is internalized and the GαS subunit is released. This mechanism leads to activation of adenylate cyclase and an increase in cAMP production resulting in induction of the protein kinase A (PKA) pathway. Subsequently, PKA phosphorylates the cAMP-response element-binding protein (CREB) and enhances the transcription of its target genes in response to extracellular signals.To date, extensive work has been done to investigate the role of TGR5 in metabolism. In rodents, BA-activated TGR5 receptor stimulates energy expenditure in brown adipose tissue and skeletal muscle and prevents obesity and insulin resistance induced by a high fat diet. TGR5 is also implicated in intestinal L-cells secreted GLP-1, which plays an essential role in glucose homeostasis through the stimulation of glucose-dependent-insulin-secretion and inhibition of glucagon secretion, inhibition of gastric emptying and increasing satiety through neuroendocrine pathways. In terms of the immunological function of TGR5, it is now known that TGR5 is expressed in several immune cells such as monocytes, alveolar macrophages and Kupffer cells. The beneficial effects of TGR5 on macrophage-driven inflammation include reduced proinflammatory cytokine expression, thus protecting against atherosclerosis and liver steatosis. On the contrary, TGR5 activation has also been implicated in itch and analgesia, gastrointestinal-tract cell carcinogenesis, pancreatitis, and cholelithiasis, suggesting a potential role for TGR5 as a regulator of signal transduction pathways responsible for cell proliferation and apoptosis. BAs may also influence islet function via both direct and indirect mechanisms as recent studies have shown that Farnesoid X receptor (FXR) is expressed by pancreatic beta cells, and regulates insulin signaling in cultured cell lines. Kumar et al., [14] also reported that the TGR5 agonists INT-777 + oleanolic acid (OA) stimulated glucose-mediated insulin release via TGR5 activation, also in cultured cells. Still, little is known about the regulation of TGR5 expression or its involvement in pancreatic hormone secretion in response to physiological or pathological conditions such as T2D, as these studies have been performed mainly in cultured cell lines. In these contexts, the biological function of TGR5 remains enigmatic. The aim of the present study was first to establish the specific expression of TGR5 in human pancreatic islet cell subtypes. Then, a cross-sectional cohort of human islets isolated from individuals with various degrees of insulin resistance was exploited to determine if TGR5 expression and function was modified in T2D. Finally to determine if targeting TGR5 is clinically relevant, human islets were treated in-vitro with a specific agonist of TGR5 or with siRNA directed against TGR5 and hormone secretion assessed to establish whether TGR5 activation or inhibition modulate pancreatic hormone secretion.
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The roles of pancreatic hormones in regulating pancreas development and beta cell regenerationYe, Lihua 16 June 2015 (has links)
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.
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