Global ETD Search

41	Semi-mechanistic models of glucose homeostasis and disease progression in type 2 diabetes Choy, Steve January 2016 (has links) Type 2 diabetes mellitus (T2DM) is a metabolic disorder characterized by consistently high blood glucose, resulting from a combination of insulin resistance and reduced capacity of β-cells to secret insulin. While the exact causes of T2DM is yet unknown, obesity is known to be a major risk factor as well as co-morbidity for T2DM. As the global prevalence of obesity continues to increase, the association between obesity and T2DM warrants further study. Traditionally, mathematical models to study T2DM were mostly empirical and thus fail to capture the dynamic relationship between glucose and insulin. More recently, mechanism-based population models to describe glucose-insulin homeostasis with a physiological basis were proposed and offered a substantial improvement over existing empirical models in terms of predictive ability. The primary objectives of this thesis are (i) examining the predictive usefulness of semi-mechanistic models in T2DM by applying an existing population model to clinical data, and (ii) exploring the relationship between obesity and T2DM and describe it mathematically in a novel semi-mechanistic model to explain changes to the glucose-insulin homeostasis and disease progression of T2DM. Through the use of non-linear mixed effects modelling, the primary mechanism of action of an antidiabetic drug has been correctly identified using the integrated glucose-insulin model, reinforcing the predictive potential of semi-mechanistic models in T2DM. A novel semi-mechanistic model has been developed that incorporated a relationship between weight change and insulin sensitivity to describe glucose, insulin and glycated hemoglobin simultaneously in a clinical setting. This model was also successfully adapted in a pre-clinical setting and was able to describe the pathogenesis of T2DM in rats, transitioning from healthy to severely diabetic. This work has shown that a previously unutilized biomarker was found to be significant in affecting glucose homeostasis and disease progression in T2DM, and that pharmacometric models accounting for the effects of obesity in T2DM would offer a more complete physiological understanding of the disease. pharmacokinetics pharmacodynamics pharmacometrics glucose homeostasis insulin type 2 diabetes obesity weight visceral adipose tissue HbA1c non-linear mixed effects modelling disease progression ZDSD rats
42	Efeito da suplementação com leucina sobre a resposta atrófica da musculatura esquelética induzida pelo uso de dexametasona / Effects of leucine supplementation on skeletal muscle atrophy dexamethasone-induced Zanchi, Nelo Eidy 06 April 2011 (has links) A dexametasona (DEXA) é um potente agente imunossupressor e antiinflamatório, mas apresenta importantes efeitos colaterais, tais como a atrofia muscular e a resistência à ação da insulina nos músculos esqueléticos. Neste contexto, a suplementação com leucina poderia representar uma estratégia nutricional terapêutica capaz de limitar os efeitos colaterais do tratamento com DEXA. Neste estudo, foram investigados os efeitos da suplementação com leucina em baixas e altas doses sobre a massa muscular, força muscular, assim como vários marcadores metabólicos que estão sob controle da insulina em ratos com restrição calórica e em ratos tratados com DEXA. Como a resposta da suplementação com leucina pode também estar ligada à forma de administração desse aminoácido, realizamos experimentos com leucina administradas via gavagem (bolus) versus leucina diluída no bebedouro dos animais. A suplementação com leucina demonstrou preservar a massa muscular, a força muscular voluntária média e a homeostasia da glicose em animais sob restrição calórica, mas este efeito foi observado apenas com a leucina suplementada em baixas concentrações/doses. Este efeito da leucina sobre a massa muscular esteve associado com a expressão de genes envolvidos no remodelamento da musculatura esquelética. Quanto ao efeito da leucina sobre a homeostasia da glicose, um efeito benéfico do aminoácido foi observado com a suplementação em baixas doses, o qual foi evidenciado pelos dados metabólicos avaliados. No entanto, sob tratamento com DEXA, a suplementação com leucina agravou o estado \"diabetogênico\" dos animais. Por último, a via de administração da leucina influenciou significativamente a resposta a este aminoácido, onde a suplementação via gavagem mostrou-se menos prejudicial do que a suplementação com leucina diluída nos bebedouros, ao menos em relação ao aspecto diabetogênico causado pelo tratamento concomitante com DEXA / Dexamethasone (DEXA) is a potent immunosupressor and anti-inflammatory agent but presents side effects such as muscle atrophy and insulin resistance in skeletal muscles. In this context, leucine supplementation may represent a way to limit the DEXA side effects. In this study, we investigated the effects of a low and a high dose of leucine on muscle mass, on muscle strength as well as on several metabolic markers that are under insulin control in energy-restricted and DEXA-treated rats. Since leucine response may also be linked to the way of administration of this amino acid, we performed experiments with leucine given in a gavage versus leucine given in drinking water way. Leucine supplementation was found to spare muscle mass, voluntary medium strength and glucose homeostasis in energy restricted animals but the effect was observed only with the low dose/concentration of leucine. The leucine effect on muscle mass was associated with expression of genes involved in muscle remodeling. However, under DEXA treatment, leucine supplementation was found to aggravate the diabetogenic state. Lastly, the route of leucine administration was found to significantly influence this variable to this amino acid, where leucine supplemented via gavage demonstrated to be less deleterious than supplemented diluted in the water drink, concomitantly with DEXA treatment Força muscular voluntária Homeostasia da glicose. Leucine supplementation Massa muscular esquelética skeletal muscle mass Suplementação com leucina
43	Efeito da suplementação com leucina sobre a resposta atrófica da musculatura esquelética induzida pelo uso de dexametasona / Effects of leucine supplementation on skeletal muscle atrophy dexamethasone-induced Nelo Eidy Zanchi 06 April 2011 (has links) A dexametasona (DEXA) é um potente agente imunossupressor e antiinflamatório, mas apresenta importantes efeitos colaterais, tais como a atrofia muscular e a resistência à ação da insulina nos músculos esqueléticos. Neste contexto, a suplementação com leucina poderia representar uma estratégia nutricional terapêutica capaz de limitar os efeitos colaterais do tratamento com DEXA. Neste estudo, foram investigados os efeitos da suplementação com leucina em baixas e altas doses sobre a massa muscular, força muscular, assim como vários marcadores metabólicos que estão sob controle da insulina em ratos com restrição calórica e em ratos tratados com DEXA. Como a resposta da suplementação com leucina pode também estar ligada à forma de administração desse aminoácido, realizamos experimentos com leucina administradas via gavagem (bolus) versus leucina diluída no bebedouro dos animais. A suplementação com leucina demonstrou preservar a massa muscular, a força muscular voluntária média e a homeostasia da glicose em animais sob restrição calórica, mas este efeito foi observado apenas com a leucina suplementada em baixas concentrações/doses. Este efeito da leucina sobre a massa muscular esteve associado com a expressão de genes envolvidos no remodelamento da musculatura esquelética. Quanto ao efeito da leucina sobre a homeostasia da glicose, um efeito benéfico do aminoácido foi observado com a suplementação em baixas doses, o qual foi evidenciado pelos dados metabólicos avaliados. No entanto, sob tratamento com DEXA, a suplementação com leucina agravou o estado \"diabetogênico\" dos animais. Por último, a via de administração da leucina influenciou significativamente a resposta a este aminoácido, onde a suplementação via gavagem mostrou-se menos prejudicial do que a suplementação com leucina diluída nos bebedouros, ao menos em relação ao aspecto diabetogênico causado pelo tratamento concomitante com DEXA / Dexamethasone (DEXA) is a potent immunosupressor and anti-inflammatory agent but presents side effects such as muscle atrophy and insulin resistance in skeletal muscles. In this context, leucine supplementation may represent a way to limit the DEXA side effects. In this study, we investigated the effects of a low and a high dose of leucine on muscle mass, on muscle strength as well as on several metabolic markers that are under insulin control in energy-restricted and DEXA-treated rats. Since leucine response may also be linked to the way of administration of this amino acid, we performed experiments with leucine given in a gavage versus leucine given in drinking water way. Leucine supplementation was found to spare muscle mass, voluntary medium strength and glucose homeostasis in energy restricted animals but the effect was observed only with the low dose/concentration of leucine. The leucine effect on muscle mass was associated with expression of genes involved in muscle remodeling. However, under DEXA treatment, leucine supplementation was found to aggravate the diabetogenic state. Lastly, the route of leucine administration was found to significantly influence this variable to this amino acid, where leucine supplemented via gavage demonstrated to be less deleterious than supplemented diluted in the water drink, concomitantly with DEXA treatment Força muscular voluntária Homeostasia da glicose. Massa muscular esquelética Suplementação com leucina Leucine supplementation skeletal muscle mass
44	The role of melatonin in cardioprotection : an investigation into the mechanisms involved in glucose homeostasis, microvascular endothelial function and mitochondrial function in normal and insulin resistant states Nduhirabandi, Frederic 04 1900 (has links) Thesis (PhD)-- Stellenbosch University, 2014. / ENGLISH ABSTRACT: Introduction: The cardioprotective actions of the hormone melatonin against myocardial ischaemiareperfusion injury (IRI) are well-established. It has recently been shown to prevent the harmful effects of hyperphagia-induced obesity on the susceptibility of the heart to IRI as well as many of the harmful effects of obesity and insulin resistance. However, the exact mechanism whereby it exerts its beneficial action is still unknown. The aims of this study were to determine the effects of relatively short-term melatonin treatment in a rat model of diet-induced obesity on: (i) biometric and metabolic parameters, lipid peroxidation, myocardial IRI and intracellular signalling (ii) mitochondrial oxidative phosphorylation function (iii) cardiomyocyte glucose uptake and intracellular signalling. In addition, the effects of acute melatonin treatment of cardiac microvascular endothelial cells (CMEC) were determined on cell viability, nitric oxide production (NO), TNF- -induced dysfunction and intracellular signalling. Material and Methods: Male Wistar rats were randomly allocated to two groups for 20 weeks feeding with either standard rat chow or a high calorie diet. Each group was subdivided into 3 groups receiving either water throughout or melatonin (4mg/kg/day, in the drinking water) for the last 6 or 3 weeks of the experimental programme. Hearts, perfused in the working mode, were subjected to ischaemia/reperfusion and infarct size determined. Mitochondria and cardiomyocytes were isolated according to standard techniques and oxidative function and glucose uptake respectively determined. CMEC NO production and cell viability were quantified by FACS analysis of the fluorescent probes, DAF-2/DA and propidium iodide/Annexin V respectively. Intracellular signalling was evaluated using Western blot and appropriate antibodies. Results: The high-calorie diet caused significant increases in body weight gain, visceral adiposity, fasting blood glucose, serum insulin, triglycerides, HOMA-IR index and a concomitant reduction in serum adiponectin levels as well as larger myocardial infarct sizes after exposure to IRI compared to the control, indicating increased susceptibility to damage. Three as well as six weeks of melatonin administration to obese and insulin resistant rats reduced serum insulin levels and the HOMA-IR index. Myocardial infarct size was reduced in both control and diet groups. These effects were associated with increased activation of baseline myocardial STAT- 3 and the RISK pathway during reperfusion. The diet had no effect on the oxidative phosphorylation capacity of mitochondria, isolated from non-perfused hearts (baseline), but melatonin administration for 6 weeks induced a reduction in state 3 respiration rate; mitochondria isolated from diet hearts subjected to global ischaemia, exhibited an attenuated oxidative phosphorylation process which was improved by melatonin treatment. Melatonin in vitro enhanced cardiomycyte insulin stimulated glucose uptake of normal young rats but not of insulin resistant rats. In vivo melatonin treatment for 6 weeks increased basal (in diet group) and insulin stimulated glucose uptake in both control and diet groups. Melatonin (1nM) in vitro caused a significant reduction in necrosis and apoptosis of cultured CMEC, associated with a decrease in nitric oxide availability and eNOS activation and a concomitant increase in PKB/Akt, p38MAPK and AMPK activation. The harmful effects of TNF- treatment on signalling in CMEC could be prevented by co-treatment with melatonin. Conclusions: The results suggest that short-term melatonin treatment was able to significantly attenuate the diet-induced increased myocardial susceptibility to ischaemia/reperfusion damage. It may also improve cardiac glucose homeostasis and mitochondrial oxidative phosphorylation in an insulin resistant state. Melatonin in vitro protects CMEC against apoptosis and necrosis and reduces nitric oxide availability. These beneficial effects of melatonin may ultimately be due to its antioxidant capacity or receptor-mediated actions, but this remains to be established. / AFRIKAANSE OPSOMMING: Inleiding: Die vermoë van die hormoon, melatonien, om die hart teen iskemie/ herperfusiebesering (IHB) te beskerm, is welbekend. Onlangs is ook getoon dat melatonien IHB en verskeie van die nadelige effekte van vetsug en insulienweerstandigheid in hiperfagiegeïnduseerde vetsug kan voorkom. Die meganisme(s) betrokke by hierdie voordelige prosesse is egter grootliks onbekend. Die doel van hierdie studie was om die gevolge van korttermyn melatonienbehandeling in ‘n model van hiperfagiegeïnduseerde vetsug te ondersoek op (i) biometriese en metaboliese parameters, lipiedperoksidasie, miokardiale IHB en intrasellulêre seintransduksie, (ii) mitochondriale oksidatiewe fosforilasie, (iii) glukoseopname en intrasellulêre seintransduksie in kardiomiosiete en aanvullend, (iv) die invloed van akute melatonienbehandeling van kardiale mikrovaskulêre endoteelselle op sellulêre oorlewing, stikstofoksiedproduksie, TNF- - geïnduseerde disfunksie en seintransduksie. Metodiek: Manlike Wistarrotte is ewekansig in twee groep verdeel en vir 20 weke met standaard-rotkos of ‘n hoëkaloriedieet gevoer. Elke groep is in 3 subgroepe verdeel, wat deurgaans water of melatonien (4mg/kg/dag in die drinkwater) vir 3 of 6 weke voor die beëindiging van die eksperiment ontvang het. Harte is geperfuseer volgens die werkharttegniek, blootgestel aan iskemie/herperfusie en die infarktgrootte bepaal. Mitochondria en kardiomiosiete is volgens standaardtegnieke geïsoleer vir bepaling van oksidatiewe funksie en glukoseopname respektiewelik. NO produksie en sellewensvatbaarheid was gekwantifiseer deur vloeisitometriese analises (FACS) van die fluoresserende agense, DAF-2/DA en propidium jodied/Annexin V onderskeidelik. Intrasellulêre seintransduksie is evalueer met behulp van die Western kladtegniek en geskikte antiliggame. Resultate: Die hoëkaloriedieet het ‘n beduidende toename in liggaamsgewig, visserale vet, vastende bloedglukose, seruminsulienvlakke, trigliseriede, HOMA-IR-indeks en ‘n gepaardgaande verlaging in serumadiponektienvlakke tot gevolg gehad, sowel as groter miokardiale infarkte na iskemie/herperfusie. Laasgenoemde dui op ‘n groter vatbaarheid vir iskemiese beskadiging in harte van vetsugtige diere. Drie sowel as ses weke van melatonienbehandeling het die seruminsulienvlakke en HOMAindeks in vetsugtige diere beduidend verlaag, vergeleke met die kontroles. Miokardiale infarktgroottes was verminder in beide kontrole- en vetsuggroepe. Hierdie effekte het met ‘n verhoogde aktivering van basislyn STAT-3 en PKB/Akt en ERKp44/p42 tydens herperfusie gepaard gegaan. Die dieet het geen invloed op die oksidatiewe fosforilasiekapasiteit van mitochondria, geïsoleer uit harte van ongeperfuseerde harte, gehad nie (basislyn), maar melatonienbehandeling vir 6 weke het Staat 3 respirasie verlaag. Mitochondria, geïsoleer uit harte van vetsugtige rotte wat aan globale iskemie onderwerp was, het ‘n onderdrukte oksidatiewe fosforilasieproses gehad, wat egter deur melatonienbehandeling verbeter is. Melatonien in vitro het insuliengestimuleerde glukoseopname deur kardiomiosiete van jong, maar nie vetsugtige rotte nie, verhoog. In vivo melatonientoediening vir 6 weke het egter basale (in die dieetgroep) en insuliengestimuleerde glukoseopname in beide kontrole- en vetsuggroepe verhoog. Toediening van melatonien in vitro aan mikrovaskulêre endoteelselkulture het ‘n beduidende afname in nekrose, apoptose, stikstofoksied- beskikbaarheid en eNOS aktivering teweeggebring, tesame met ‘n verhoogde aktivering van PKB/Akt, p38MAPK en AMPK. Die nadelige effekte van TNF- toediening op seintransduksie in die mikrovaskulêre endoteelselle is deur melatonien voorkom. Gevogtrekkings: Die resultate toon dat melatonien ‘n merkwaardige beskermende effek op die toename in vatbaarheid vir iskemiese beskadiging in vetsugtige rotte gehad het. Dit mag ook miokardiale glukose-homeostase en mitochondriale oksidatiewe funksie in insulienweerstandigheid verbeter. Melatonien in vitro beskerm mikrovaskulêre endoteelselle teen nekrose asook apoptose en verminder die beskikbaarheid van stikstofoksied. Hierdie voordelige effekte van melatonien mag aan sy anti-oksidantvermoëns of stimulasie van die melatonienreseptor toegeskryf word, maar bewyse daarvoor ontbreek nog. / Division of Medical Physiology (Stellenbosch University), / National Research Foundation / Harry Crossley Foundation Metabolic syndrome Theses -- Medicine Dissertations -- Medicine Theses -- Medical physiology Dissertations -- Medical physiology Mitochondria glucose homeostasis Obesity and insulin resistance Melatonin Antioxidants Cardiac microvascular endothelial cells Glucose uptake UCTD
45	Rôle de l’urée dans la dysfonction de la cellule bêta-pancréatique au cours de l’insuffisance rénale chronique Nyam, Elsa 04 1900 (has links) L’insuffisance rénale chronique (IRC) se définit par un défaut de filtration glomérulaire et est associée à plusieurs désordres. La perturbation de l’homéostasie glucidique en fait partie. L’homéostasie glucidique est contrôlée principalement par l’insuline, soit l’hormone sécrétée en réponse au glucose par les cellules bêta-pancréatiques contenues dans les îlots de Langerhans. La préservation de la fonction de la cellule bêta est essentielle au maintien de l’homéostasie glucidique. Il a été démontré que la sécrétion de l'insuline est altérée au cours l'IRC, cependant les mécanismes demeurent peu connus. Au cours de l’IRC, l’accumulation chronique de toxines urémiques pourrait contribuer à la défaillance de la cellule bêta. L’urée est une toxine urémique majeure et sa toxicité a été récemment rapportée dans plusieurs tissus. Le but de ce mémoire était donc de vérifier le rôle de l’urée dans la dysfonction de la cellule bêta-pancréatique au cours de l’IRC. Nous avons démontré que l’exposition des îlots de souris à des concentrations pathologiques d’urée entraîne une diminution de la sécrétion d’insuline via l’augmentation du stress oxydant et des O-glycosylations. Ce défaut est dû à une perturbation du métabolisme intracellulaire du glucose. Entre autres, nous avons observé une baisse de la glycolyse associée à la réduction de l’activité enzymatique de la phosphofructokinase-1. Ces résultats démontrent un effet toxique direct de l’urée sur la sécrétion d’insuline et permettent de mieux comprendre le mécanisme de dysfonction de la cellule bêta-pancréatique au cours de l’IRC. / Chronic kidney disease (CKD) is defined as a glomerular filtration defect and is associated with many disorders. Impaired glucose homeostasis is one of them. Glucose homeostasis is maintained in part by insulin, which is the hormone secreted by the pancreatic beta cells from the islets of Langerhans in response to glucose. The preservation of beta cell function is essential to maintain glucose homeostasis. It has been demonstrated that insulin secretion is altered during CKD; however, the underlying mechanisms remain unknown. In CKD, chronic accumulation of uremic toxins could contribute to beta cell dysfunction. Urea is a major uremic toxin and its toxicity has been recently reported in many tissues. The purpose of this master project was to ascertain the role of urea in pancreatic beta cell dysfunction during CKD. We have demonstrated that exposure of mouse islets to pathological concentrations of urea leads to diminution of insulin secretion via an increase in oxidative stress and O-glycosylation. This defect is due to disturbed intracellular glucose metabolism. Among others, we have observed a reduction in glycolysis associated with a decrease in the activity of phosphofructokinase-1. These results demonstrate a direct toxic effect of urea on insulin secretion and contribute to a better understanding of mechanisms of pancreatic beta cell dysfunction during CKD. Insuffisance rénale chronique Homéostasie glucidique Cellule bêta-pancréatique Insuline Métabolisme du glucose Chronic kidney disease Glucose homeostasis Pancreatic beta cell Insulin Glucose metabolism
46	Bioassay-guided antidiabetic potentials of Devil’s club (Oplopanax horridus) preparations from the traditional pharmacopeia of the Squamish and other first nations of British Columbia. Elahmer, Nyruz 02 1900 (has links) No description available. Diabète de type 2 Transport du glucose G6Pase Médecine traditionnelle Homéostasie du glucose Produits de santé naturels Type 2 diabetes Glucose transport Traditional medicine Glucose homeostasis Natural health products
47	The Origin of Human White, Brown, and Brite/Beige Adipocytes Min, So Yun 16 December 2016 (has links) During embryonic development, adipocytes emerge from microvasculature. Lineage-‐tracing studies in mice have shown that adipocyte progenitors reside in the adipose tissue capillaries. However, the direct evidence of an association between adipocyte progenitors and vasculature in humans is lacking. A specific class of adipocytes (brown and beige/brite) expresses the uncoupling protein 1 (UCP1), which consumes glucose and fatty acids to generate heat. The abundance of UCP1- containing adipocytes correlates with a lean metabolically healthy phenotype in human. However, a causal relationship between the presence of these cells and metabolic benefits in human is not clear. In this thesis, I report human adipocyte progenitors proliferate in response to pro-angiogenic factors in association with adipose capillary networks in-vitro. The capillary-derived adipocytes transform from being UCP1-negative to positive upon adenylate cyclase activation, a defining feature of the brite/beige phenotype. Activated cells have denser, round mitochondria with UCP1 protein, and display uncoupled respiration. When implanted into NOD-scid IL2rgnull (NSG) mice, the adipocytes can form a vascularized fat pad that induces vascularization and becomes integrated into mouse circulatory system. In normal or high fat diet-fed NSG mice, activated brite/beige adipocytes enhance systemic glucose tolerance and improved hepatic steatosis, thus providing evidence for their potential therapeutic use. The adipocytes also express neuroendocrine and secretory factors such as Interleukin-33, proprotein convertase PCSK1 and proenkephalin PENK, which are correlated with human obesity. Finally, analyses on single-cell clones of capillary-sprout cells reveal the existence of diverse adipogenic progenitor populations. Further characterization of the clones will define the identifying features of the diverse adipocyte progenitor types that exist in human adipose tissue. Human adipocyte White adipocyte Brown adipocyte Brite adipocyte Beige adipocyte Metabolism Thermogenic adipose tissue Insulin resistance Glucose homeostasis Adipocyte implantation Biology Cell Biology Medical Cell Biology Nutritional and Metabolic Diseases
48	Déterminer les mécanismes impliqués dans les effets du récepteur à la rénine et prorénine dans l’obésité et dans le diabète = Determining mechanisms implicated in the effects of the renin and prorenin receptor in the development of obesity and diabetes Shamansurova Akhmedova, Zulaykho 11 1900 (has links) L'obésité est une épidémie mondiale qui augmente le risque de développer un diabète de type 2 ainsi que ses complications. Chez les individus obèses, le tissu adipeux sécrète de grandes quantités d'hormones et de cytokines qui affectent négativement le métabolisme du glucose et des lipides, ce qui provoque l'inflammation et la résistance à l'insuline. L'obésité augmente également l'activité du système rénine-angiotensine (RAS) localement au niveau de différents tissus et de façon systémique dans la circulation. L’angiotensinogène est convertie en angiotensine I par la rénine, ainsi que par la prorénine uniquement quand la prorénine est liée au récepteur de la rénine et prorénine [(P)RR] 1 . Ceci est la voie angiotensine-dépendante (Ang-D) du (P)RR. La liaison de la rénine et de la prorénine avec le (P)RR active également une voie angiotensine-indépendante (Ang-ND), ce qui produit une signalisation intracellulaire comportant la mitogen activated protein kinase (MAPK), la extracellular regulatory kinase 1/2 (ERK1/2), la promyelocytic leukemia zinc finger protein (PLZF) et le tumor necrosis factor alpha (TNF-a). Ceux-ci peuvent provoquer la croissance et la prolifération cellulaire, l'apoptose et la fibrose et pourraient donc être reliés aux dommages tissulaires et aux complications associées à l'obésité 1, 2. Plusieurs effets bénéfiques d’un blocage pharmacologique du (P)RR ont été rapportés tels la prévention du développement d'une fibrose cardiaque et rénale ainsi que la prévention de la néphropathie et de la rétinopathie diabétique. Cependant, les effets du (P)RR dans le tissu adipeux ont été peu étudiés. Par conséquent, notre objectif était d'étudier le rôle du (P)RR dans le développement de l'obésité et de la résistance à l'insuline par : 1) l'administration de HRP (un peptide bloquant l’effet du (P)RR) chez un modèle de souris obèse par l’administration d’une diète riche en gras (HFD), et 2) l’évaluation de souris ayant une délétion (KO) du gène (P)RR spécifiquement dans le tissu adipeux, qui a été généré dans notre laboratoire par la technologie Cre-LoxP. L'expression du gène et de la protéine du (P)RR dans les tissus adipeux était augmentée chez les souris nourries avec une HFD indépendamment du traitement au HRP. Le traitement par le HRP a réduit le poids corporel et la masse adipeuse chez les souris nourries avec une HFD alors qu’une tendance pouvait être observée chez les souris sur diète normale (ND). De façon similaire, les souris (P)RR KO spécifiquement dans le tissu adipeux avaient une réduction du poids corporel et de la masse adipeuse, même sur ND, ce qui suggère fortement l'implication du (P)RR dans le tissu adipeux dans le développement de l'obésité. Le phénotype des souris KO incluait une augmentation de l'activité horizontale uniquement dans leur période active, ce qui pourrait contribuer à augmenter leur métabolisme énergétique et ainsi réduire leur poids corporel et leur masse adipeuse. De plus, les souris KO homozygotes mâles avaient un métabolisme de base plus élevé car nous avons observé une augmentation de la consommation d'oxygène et de la production de dioxyde de carbone pendant leur période active et de sommeil. Cette augmentation du métabolisme pourrait résulter, en partie, d'une augmentation de la thermogenèse comme en témoigne l’expression accrue du gène de brunissement, PRDM16, dans le tissu adipeux péri-rénale de souris mâles KO. Conformément à cela, des résultats récents provenant de notre laboratoire ont également démontré que le HRP pouvait induire du brunissement au niveau du tissu adipeux sous-cutanée 3. Chez les souris traitées avec le HRP, bien que la glycémie eût été similaire aux souris recevant le placebo, l'insuline plasmatique et le rapport insuline/glucose était plus faible indépendamment de la diète. De façon similaire, les souris (P)RR KO avaient une insulinémie et un taux de peptide C plus faibles par rapport aux souris contrôles, sans aucune différence dans les courbes de la glycémie au cours d'un test de tolérance au glucose par voie orale. Les niveaux d'insuline dans l’état basal et stimulé étaient significativement plus faibles chez les souris KO, sans aucune modification du contenu pancréatique en insuline et du ratio insuline/peptide-C, ceci indique donc qu’il n’y a pas eu d’altération du niveau du métabolisme pancréatique de l'insuline. L’augmentation de l'adiponectine plasmatique chez les souris KO pourrait, entre autres, contribuer à une meilleure sensibilité à l'insuline observée. De plus, dans les groupes traités aux HRP, nous avons observé une amélioration du profil d'expression des gènes des transporteurs de glucose GLUT1 et GLUT4, du TNF-alpha, MCP-1, F4/80 et de la leptine dans le tissu adipeux ce qui pourrait contribuer à la meilleure sensibilité à l'insuline. Comme une meilleure sensibilité à l'insuline a été observée chez la souris suite au blocage pharmacologique et à la suppression génétique du (P)RR, ceci suggère que le (P)RR est impliqué dans la régulation de l’homéostasie du glucose. De plus, un taux circulant réduit des triglycérides (TG) a été observé chez les souris traitées au HRP, alors que des niveaux inférieurs de TG ont été trouvés seulement dans les muscles squelettiques chez les souris KO. Ces modifications du métabolisme des lipides et des taux circulants d'adiponectine résultent probablement d'un tissu adipeux plus sain tel que révélé par nos analyses histologiques démontrant une réduction de la taille des adipocytes chez les souris KO et traitées au HRP 3. Nos résultats démontrent que le (P)RR, en particulier dans le tissu adipeux, est impliqué dans la régulation du poids corporel et de l'homéostasie du glucose probablement par la modulation de la morphologie et de la fonction des adipocytes. Le développement d'une nouvelle stratégie clinique axée sur le blocage du (P)RR pourrait aider à traiter l'obésité et ses pathologies associées telles la résistance à l'insuline et le diabète de type 2. / Obesity is a worldwide epidemic and increases the risk of developing type 2 diabetes and its complications. In obesity, adipose tissue secretes large amounts of hormones and cytokines that negatively regulate glucose and lipid metabolism, causing inflammation and insulin resistance. Obesity also increases the activity of both local (tissue-specific) and circulating renin-angiotensin system (RAS). Angiotensinogen is converted to angiotensin I by renin, whereas prorenin may only do so upon binding to the (pro)renin receptor [(P)RR] 1. This is thus the angiotensin-dependent (Ang-D) pathway of the (P)RR. The binding of renin and prorenin with the (P)RR also activates an angiotensin-independent pathway (Ang-ND), leading to intracellular signaling involving, for instance, the mitogen activated protein kinase (MAPK), the extracellular regulatory kinase ½ (Erk1/2), the promyelocytic leukemia zinc finger protein (PLZF) and tumor necrosis factor alpha (TNF-a) 1, 2. These can produce cell growth and proliferation, apoptosis and fibrosis 1, 2, and as such may contribute to tissue damage and complications associated with obesity. The beneficial effects of pharmacological blockade of the (P)RR include prevention of the development of cardiac and renal fibrosis, as well as of diabetes-associated nephropathy and retinopathy. However, effects of the (P)RR in adipose tissue have been poorly investigated. Hence, our objective was to study the role of the (P)RR in the development of obesity and insulin resistance by: 1) administering HRP (a (P)RR blocker peptide) to mice fed a high-fat diet (HFD), and 2) in knock-out (KO) mice with adipose tissue-specific (P)RR gene deletion, which were generated in our laboratory by cre-loxp technology. (P)RR gene and protein expression in adipose tissue were increased in mice fed a HFD independently of HRP treatment. HRP treatment also reduced mice body weight and fat masses in HFD-fed mice while they only tended to be lower in mice on normal diet (ND). Similarly, the adipose tissue specific (P)RR KO mice had reduced body weight and fat masses, even on ND, and as such confirmed the involvement of adipose tissue (P)RR in the development of obesity. The KO phenotype included increased horizontal activity, only in the dark cycle (active period), which would increase energy expenditure and could contribute to their lower body weight and fat mass. Male hemizygous KO mice had higher basal metabolic rate as they had increased oxygen consumption and carbon dioxide production during both their active and inactive period. This increased basal metabolism may result in part from an increase in thermogenesis as increased “beiging” gene expression, PRDM16, was observed in peri-renal fat of male KO mice. In line with this, recent results from our laboratory have also shown that HRP may induce “beiging” in subcutaneous fat 3. In mice treated with the HRP, although glycemia was similar to placebo treated mice, plasma insulin and the insulin to glucose ratio were lower compared to untreated groups on both HFD or ND. Similarly, (P)RR KO mice had lower plasma insulin and C-peptide levels compared to controls, without any differences in the glycemia curves during an oral glucose tolerance test. Given that the basal and stimulated insulin levels were significantly lower in KO mice, without any changes in total pancreatic insulin content and with similar insulin to C-peptide ratio, this suggests that pancreatic insulin metabolism was not modified. The increased circulating adiponectin levels observed in KO mice may have contributed to the better insulin sensitivity present in the mice. In the HRP treated mice, we observed an improved gene expression profile of glucose transporters GLUT1 and GLUT4, TNF-alpha, MCP-1, F4/80 and leptin in adipose tissue, which may also contribute to the increased insulin sensitivity. Given that better insulin sensitivity was observed in mice with both (P)RR pharmacological blockade and genetic suppression, this suggests that the (P)RR is involved in the regulation of glucose homeostasis. In addition, lower circulating triglycerides (TG) levels were found in mice treated with HRP, whereas lower TG levels were observed only in skeletal muscles in (P)RR KO mice. Put altogether, the lower lipid content and higher plasma adiponectin levels likely result from a healthier fat tissue as revealed by histological analysis which showed a reduction in adipocytes size in KO mice and was recently revealed in HRP treated HFD fed mice 3. Our results demonstrate that the (P)RR, particularly in adipose tissue, is implicated in the regulation of body weight and glucose homeostasis via modulation of adipocytes morphology and function. The development of a new clinical strategy focused on blockade of the (P)RR specifically in adipose tissue could help to treat obesity and its associated pathologies such as insulin resistance and type 2 diabetes. Obésité homéostasie des glucides tissu adipeux système rénine-angiotensine récepteur à la rénine et prorénine insuline peptide C adiponectin brunissement du tissu adipeux blanc Obesity glucose homeostasis adipose tissue renin-angiotensin system renin and prorenin receptor insulin C-peptide adiponectin beiging
49	Bioassay-guided fractionation of Larix laricina du Roi, and antidiabetic potentials of ethanol and hot water extracts of seventeen medicinal plants from the traditional pharmacopeia of the James Bay Cree Shang, Nan 06 1900 (has links) Nous avons utilisé une approche ethnobotanique pour identifier des espèces de plantes utilisées par les Cris afin de traiter les symptômes du diabète de type 2. Larix laricina du Roi (L. laricina) a récemment été identifiée comme une des meilleures plantes qui a stimulé le transport de glucose dans les cellules C2C12 et fortement potentialisé la différenciation des 3T3-L1 en indiquant une sensibilité potentiellement accrue à l’insuline. Ensuite, ces études de criblage ont été effectuées sur des extraits éthanolique (EE) en utilisant une série de bioessais in vitro. Cependant, les préparations traditionnelles des plantes sont souvent faites avec l’eau chaude. Le but de cette thèse de doctorat était d’isoler les principes actifs de L. laricina par un fractionnement guidé par l’adipogenèse; d’évaluer et de comparer l’activité et les mécanismes antidiabétiques des EE et des extraits aqueux (HWE) de ces 17 plantes. Pour le fractionnement de L. laricina, on a isolé plusieurs composés connus et identifié un nouveau composé actif cycloartane triterpene, qui a amélioré fortement l’adipogenèse et a été responsable en partie de l’activité adipogénique (potentiellement similaire à l’effet sensibilisateur à l’insuline des glitazone) de l’extrait éthanolique issu de l’écorce de L. laricina. Pour le métabolisme lipidique, nos résultats ont confirmé que 10 parmi les 17 EE ont augmenté la différenciation des adipocytes alors que 2 extraits seulement l’ont inhibée. Les HWE ont montré une faible activité adipogénique ou antiadipogénique. Les EE de R. groenlandicum et K. angustifolia ont le PPAR γ (peroxisome proliferator-activated receptor γ), le SREBP-1 (sterol regulatory element binding protein-1) et le C/EBP (CCAAT-enhancer binding proteins) α, alors que ceux de P. balsamifera et A. incana les ont inhibés. L’effet inhibiteur de P. balsamifera a également été prouvé d’avoir impliqué l’activation de la protéine kinase activée par l’AMP (AMPK). Les EE et HWE de R. groenlandicum ont stimulé les mêmes facteurs de transcription alors que les extraits aqueux d’autres plantes sélectionnées ont perdu ces effets en comparaison avec leurs extraits éthanoliques respectifs. L’analyse phytochimique a également identifié le groupe des espèces actives et inactives, notamment lorsque les espèces ont été séparées par famille de plante. Finalement concernant l’homéostasie de glucose, nos résultats ont confirmé que plusieurs EE ont stimulé le transport de glucose musculaire et inhibé l’activité de la glucose-6-phosphatase (G6Pase) hépatique. Certains des HWE ont partiellement ou complètement perdu ces activités antidiabétiques par rapport aux EE, tandis qu’une seule plante (R.groenlandicum) a juste conservé un potentiel similaire entre les EE et HWE dans les deux essais. Dans les cellules musculaires, les EE de R.groenlandicum, A. incana et S. purpurea ont stimulé le transport de glucose en activant la voie de signalisation de l’AMPK et en augmentant le niveau d’expression des GLUT4. En comparaison avec les EE, les HWE de R.groenlandicum ont montré des activités similaires; les HWE de A. incana ont complètement perdu leur effet sur tous les paramètres étudiés; les HWE de S. purpurea ont activé la voie de l’insuline au lieu de celle de l’AMPK pour augmenter le transport de glucose. Dans les cellules H4IIE, les EE et HWE des 5 plantes ont activé la voie de l’AMPK, et en plus les EE et HWE de 2 plantes ont activé la voie de l’insuline. La quercétine-3-O-galactoside et la quercétine 3-O-α-L-arabinopyranoside ont été identifiées comme des composés ayant un fort potentiel antidiabétique et donc responsables de l'activité biologique des plantes HWE actifs avec le transport du glucose. En conclusion, on a isolé plusieurs composés connus et identifié un nouveau triterpène actif à partir du fractionnement de L. laricina. Nous avons fourni également une preuve directe pour l'évaluation et la comparaison d'une action analogue à l'insuline ou insulino-sensibilisateur des EE et HWE de plantes médicinales Cris au niveau de muscle, de foie et de tissus adipeux. Une partie de leur action peut être liée à la stimulation des voies de signalisation intracellulaire insulino-dépendante et non-insulino-dépendante, ainsi que l’activation de PPARγ. Nos résultats indiquent que les espèces de plantes, les tissus ou les cellules cibles, ainsi que les méthodes d'extraction sont tous des déterminants significatifs de l'activité biologique de plantes médicinales Cris sur le métabolisme glucidique et lipidique. / We have used a collaborative ethnobotanical approach to identify plant species used by the Cree of Eeyou Istchee (CEI) to treat symptoms of type 2 diabetes. Several screening studies were performed on 17 species identified in a survey of the Cree Nation. Firstly, Larix laricina du Roi (L. laricina) was recently identified as one of the top plants, which stimulated glucose uptake in C2C12 muscle cells and strongly potentiated the differentiation of 3T3-L1 pre-adipocytes suggesting enhanced insulin sensitivity. Secondly, these screening studies were performed on ethanol extracts (EE) using an in vitro bioassay platform, however, traditional preparations are often based on hot water. So the purpose of this PhD thesis was to isolate the active principles from L. laricina through adipogenesis-guided fractionation, and to evaluate and compare the antidiabetic activity and mechanisms of EE and hot water extracts (HWE) of these 17 Cree plants. For the fractionation of L. laricina, we isolated several known compounds and identified a new active cycloartane triterpene, which strongly enhanced adipogenesis in 3T3-L1 cells and was responsible partly for the adipogenic (potentially glitazone-like insulin sensitizing) activity of the ethanol extract of the bark of L. laricina. In the adipocyte lipid metabolism course, the results confirmed that 10 of the 17 EE stimulated adipocyte differentiation and adipogenesis, whereas 2 had inhibitory effects. Corresponding HWE exhibited partial or complete loss of such adipogenic or anti-adipogenic activity. R. groenlandicum and K. angustifolia EEs activated Peroxisome proliferator-activated receptor γ (PPAR γ), sterol regulatory element binding protein-1 (SREBP-1) and CCAAT-enhancer binding protein (C/EBP) α, whereas P. balsamifera and A. incana decreased these transcription factors. P. balsamifera’s inhibitory effect was also found to involve AMP-activated protein kinase (AMPK) activation. R. groenlandicum HWE and EE stimulated similar transcription factors, but HWE of other selected plants lost such effects compared to their respective EE. Phytochemical analysis also uncovered clustering of active versus inactive species, notably when species were segregated by plant family. The results showed that several EE stimulated muscle glucose uptake and inhibited hepatic glucose-6-phosphatase (G6Pase) activity. Some of the HWE partially or completely lost these antidiabetic activities in comparison to EE; while one plant (R.groenlandicum) retained similar potential between EE and HWE in both assays. In C2C12 muscle cells, EE of R.groenlandicum, A. incana and S. purpurea stimulated glucose uptake by activating AMPK pathway and increasing GLUT4 expression level. In comparison to EE, HWE of R.groenlandicum exhibited similar activities; HWE of A. incana completely lost its effect on all parameters; interestingly, HWE of S. purpurea activated insulin pathway instead of AMPK pathway to increase glucose uptake. In the H4IIE cells, all selected 5 plants HWE and EE activated AMPK pathway, and in addition, 2 plants EE and HWE also activated insulin pathways. Quercetin-3-O-galactoside and quercetin 3-O-α-L-arabinopyranoside were identified as potential candidates to be responsible for the biological activity of the active HWE plants in the glucose transport assay. In conclusion, we isolated several known compounds and identified a new active triterpene from fractionation of L. laricina. We also provide direct evidence evaluating and comparing of an insulin-like or insulin-sensitizing action of EE and HWE of Cree medicinal plants at the level of muscle, liver and adipose tissue. Part of their actions may be related to stimulation of insulin-dependent and insulin-independent intracellular signaling pathways, as well as to PPARγ activation. The results indicate that plant species, target tissues or cells, as well as extraction methods, are all significant determinants of the biological activity of Cree medicinal plants on glucose and lipid metabolism. Le diabète de type 2 l'AMPK l’Akt le PPAR γ le SREBP-1 le C / EBP α la G6Pase la médecine traditionnelle type 2 diabetes AMPK Akt PPAR γ SREBP-1 C/EBP α G6Pase traditional medicine lipid and glucose homeostasis
50	Pharmacometrics Modelling in Type 2 Diabetes Mellitus : Implications on Study Design and Diabetes Disease Progression Ghadzi, Siti Maisharah Sheikh January 2017 (has links) Pharmacometric modelling is widely used in many aspects related to type 2 diabetes mellitus (T2DM), for instance in the anti-diabetes drug development, and in quantifying the disease progression of T2DM. The aim of this thesis were to improve the design of early phase anti-diabetes drug development studies with the focus on the power to identify mechanism of drug action (MoA), and to characterize and quantify the progression from prediabetes to overt diabetes, both the natural progression and the progression with diet and exercise interventions, using pharmacometrics modelling. The appropriateness of a study design depends on the MoAs of the anti-hyperglycaemic drug. Depending on if the focus is power to identify drug effect or accuracy and precision of drug effect, the best design will be different. Using insulin measurements on top of glucose has increase the power to identify a correct drug effect, distinguish a correct MoA from the incorrect, and to identify a secondary MoA in most cases. The accuracy and precision of drug parameter estimates, however, was not affected by insulin. A natural diabetes disease progression model was successfully added in a previously developed model to describe parameter changes of glucose and insulin regulation among impaired glucose tolerance (IGT) subjects, with the quantification of the lifestyle intervention. In this model, the assessment of multiple short-term provocations was combined to predict the long-term disease progression, and offers apart from the assessment of the onset of T2DM also the framework for how to perform similar analysis. Another previously published model was further developed to characterize the weight change in driving the changes in glucose homeostasis in subjects with IGT. This model includes the complex relationship between dropout from study and weight and glucose changes. This thesis has provided a first written guidance in designing a study for pharmacometrics analysis when characterizing drug effects, for early phase anti-diabetes drug development. The characterisation of the progression from prediabetes to overt diabetes using pharmacometrics modelling was successfully performed. Both the natural progression and the progression with diet and exercise interventions were quantified in this thesis. Pharmacometric type 2 diabetes mellitus impaired glucose tolerance prediabetes anti-diabetes drug development insulin glucose natural diabetes disease progression lifestyle intervention short-term provocation long-term effect glucose homeostasis glucose and insulin regulation weight dropout Pharmaceutical Sciences Farmaceutisk vetenskap Endocrinology and Diabetes Endokrinologi och diabetes

Search results