Obesity, inflammation and insulin resistance in skeletal muscle

Talbot, Nicola A.

January 2014

No description available.

616.089

Development of insulin resistance in a rat model and the effects of sutherlandia frutescens as treatment and prevention

Mackenzie, Janine

January 2010

The global number of obese people has reached pandemic proportions. High caloric diets and reduced physical exercise are to blame for this growing epidemic. Obesity has a very complex association with several other metabolic disorders, such as insulin resistance (IR), diabetes mellitus type 2 (DMT2) and cardiovascular disease. This puts a huge burden on health care systems world wide and claims many lives. Sutherlandia frutescens is a traditionally used herb, which is known to have anti-diabetic properties. However, the direct mode of action of S. frutescens still remains to be elucidated. The aim of this study was to investigate the developmental stages of high fat diet (HFD)-induced IR, to illuminate the pathogenesis of IR with a focal point on modifications in the lipid metabolism. Furthermore, the effects of S. frutescens as a treatment or prevention drug for IR and associated metabolic changes were examined. Two sets of experiments were conducted on male Wistar rats. In the first experiment rats, one week post weaning received a low fat diet (LFD), high fat diet (HFD) or HFD supplemented with S. frutescens (50mg/kg BW/d). Rats were sacrificed at week 0, 1, 2, 4, 8 and 12 in the feeding regime. In a second experiment rats were fed with a LFD or a HFD for 12 weeks and treated thereafter with S. frutescens (50mg/kg BW/d), metformin (13mg/kg BW/d) or water (control) for 28 days. Rats in the second experiment were sacrificed at week 12 to confirm IR while concurrently run rats were sacrificed after 28 days of treatment. For all the experiments rats were anaesthetized, blood was removed and rats were dissected. Plasma samples were analyzed for insulin, glucose, blood lipid parameters and cytokines. Liver, muscle and adipose tissue were analyzed for glucose uptake, total lipid content, lipid profile and fatty acid profile. It was shown that the intake of HFD caused IR and hyperinsulinaemia. The developmental stages in experiment one confirmed that an increase in plasma free fatty acids preceeded the onset of IR. Plasma and tissue lipid parameters (free fatty acid-, triglyceride- and cholesterol concentrations) showed pathological modifications in the HFD group. An ectopic accumulation of fat was observed in muscle and liver, as well as a change in membrane fatty acid profile. The results for circulating cytokines were somewhat inconclusive. Rats supplemented with S. frutescens did not develop HFD-induced IR (study one) or IR was reversed (study two). S. frutescens treatment also resulted in positive changes in plasma and tissue lipid parameters. In summary, an animal model for HFD-induced IR was established and the detrimental effect of elevated plasma FFA on glucose and lipid metabolism was observed. A novel discovery suggests that the anti-diabetic mode of action of S. frutescens is through modulation of lipid metabolism. It was also established that S. frutescens has the potential to prevent IR in vivo.

Metabolic syndrome

Insulin resistance -- Animal models

Obesity -- Treatment

The medicinal plant Sutherlandia Frutescens regulates gene expression to reverse insulin resistace in rats

Fortuin, Melissa

January 2013

Obesity can lead to Type 2 Diabetes, both conditions increase in association with physical inactivity and high-energy diets, resulting in elevated blood glucose, decreased insulin sensitivity and increased insulin resistance. Sutherlandia frutescens (S.frutescens), an anti-diabetic plant, reverses and prevents insulin resistance in a rat model and human cell culture model. Gene expression analysis in hepatocyte cultures, identified genes down regulated in insulin resistance and up regulated by S.frutescens. These included genes encoding vesicle transporter proteins, hypothesised to be linked to hepatic lipid accumulation and lipid droplet formation during insulin resistance. The aim of this study was to investigate critical genes involved in lipid droplet formation, vesicle assembly and transport in high fat diet (HFD)-induced insulin resistant rat liver tissue during the development of insulin resistance and the reversal of these changes by S.frutescens. Rats were fed a low fat diet (LFD) or HFD supplemented with S.frutescens for 2, 4 and 8 weeks. Rats fed a HFD for 12 weeks developed insulin resistance, confirmed by plasma glucose and insulin levels (compared to normal controls). Groups of these rats were gavaged with S. frutescens (50mg/kg BW), Metformin (13mg/kg BW) or water for a further 4 weeks and starved for 12 hours, anaesthetized and blood removed by heart puncture. Liver was stored in RNA-Later™ for qRT-PCR and snap-frozen in liquid nitrogen for western blotting and confocal microscopy analysis. Changes in expression of vesicle transporter genes VAMP3 and NSF were analysed by qRT-PCR and changes in the protein expression by western blotting analysis. Proteins were localised within the liver by confocal immunohistochemistry using ZEN lite™ software. Statistical analysis was performed using One-Way ANOVA and unpaired t-test. mRNA gene expression of vesicle transport components VAMP3, NSF and SNAP25 showed relatively moderate changes with considerable individual variation within control or experimental groups. Uncorrelated changes in mRNA and protein products were found and may be due to differential regulation by siRNA. Proteins also showed altered staining patterns in high fat diet rats that reverted towards normal on S. frutescens treatment, potentially reflecting functional changes associated with transport of lipid-filled vesicles.

Insulin resistance

Medicinal plants

Genetic regulation

Insulin resistance -- Animal models

The role of microRNAs in skeletal muscle insulin resistance

Andersen, Ditte K.

January 2016

No description available.

616.4

The impact of activation of the renin-angiotensin system in the development of insulin resistance in experimental models of obesity

Perel, Shireen J. C.

03 1900

Thesis (MScMedSc (Biomedical Sciences. Medical Physiology))--University of Stellenbosch, 2009. / Insulin stimulates the production of nitric oxide (NO) in endothelial cells and cardiac myocytes by a signalling pathway that involves the insulin receptor substrate (IRS)-1, phosphatidylinositol-3-kinase and protein kinase B (PKB/Akt). Physiological concentrations of NO play an important part in maintaining normal vascular function. It has been suggested that nitric oxide synthase (NOS) activity and NO production are chronically impaired in diabetes mellitus by an unknown mechanism. The reninangiotensin system and subsequent production of angiotensin II (Ang II) are elevated in obesity and diabetes while antagonism of the AT1 receptor with Losartan has beneficial effects in patients with insulin resistance and type II diabetes. Aims: We therefore aimed to investigate (i) the effect of Ang II on myocardial insulin signalling with regards to key proteins (IRS-1, PKB/Akt, eNOS and p38 MAPK) in correlation with NO production, (ii) the effect of Losartan on these parameters. Methods: Hyperphagia-induced obese, insulin resistant rats (DIO=diet supplemented with sucrose and condensed milk) were compared to age-matched controls. Half the animals were treated with 10mg/kg Losartan per day for 1 week. Isolated hearts were perfused with or without 0.03 μIU/mL insulin for 15 min. Blood glucose, bodyweight, intraperitoneal fat and plasma insulin and Ang II were recorded. Proteins of interest and their phosphorylation were determined by Western blotting. NO production was flow cytometrically analyzed. ANOVA followed by the Bonferroni correction was used with a p< 0.05 considered significant. Results: DIO animals had significant elevated bodyweight, blood glucose, plasma insulin and Ang II levels. Our data showed that the hearts from the DIO animals are insulin resistant, ultimately reflected by the attenuated activation of the key proteins (IRS-1, PKB/Akt and eNOS) involved in insulin signalling as well as NO production. AT1 receptor antagonism improved NO production in isolated adult ventricular myocytes from DIO animals while concurrently enhancing expression of eNOS, PKB/Akt and p38 MAPK. In contrast, NO production as well as expression of eNOS and PKB/Akt was attenuated in control animals after Losartan treatment. Conclusion: These results suggested that Ang II via AT1 or AT2 receptors, modulates protein expression of both PKB/Akt and eNOS. This encouraged us to investigate the involvement of AT2 receptors in the observed changes. To investigate this we needed to establish a culture of neonatal rat cardiac myocytes treated with raised fatty acids and Ang II. If similar changes were induced as observed in the hearts of DIO animals, the involvement of the AT1 and AT2 receptors could be investigated using specific antagonists against these receptors. Primary cultured ventricular myocytes were isolated from 1-3 day old Wistar rat pups. They were cultured for 48 hours before the addition of palmitate and oleate at a concentration of 0.25 mM each and were treated with or without the fatty acids for a period of 4 days. After 18 hours of serum starvation, cells were stimulated with or without 10 nM insulin for 15 minutes. The effect of fatty acid treatment on cell viability and glucose uptake were assessed by trypan blue and propidium iodide staining and 2-deoxy-D-3[H] glucose uptake respectively. Protein levels and phosphorylation of key proteins (PKB/Akt, PTEN and p38 MAPK) in insulin signalling was determined by Western blotting. 0.25 mM Fatty acids did not result in the loss of cell viability. Contrary to expectation, fatty acid treatment led to enhanced basal glucose uptake but lower Glut 1 protein expression. Basal protein expression of PPARα was, however, upregulated as was the expression of the phosphatase, PTEN. The latter could explain the lower PKB/Akt phosphorylation also documented. From these results we conclude that neonatal cardiac myocytes, cultured in the presence of elevated fatty acids, did not respond in a similar manner as the intact hearts of our animals and further modifications of the system might be needed before it can be utilized as initially planned.

Insulin resistance -- Nitric oxide

Theses -- Medicine

Dissertations -- Medicine

Angiotensin II

Insulin resistance -- Animal models

Metabolic syndrome

Obesity

Biomedical Sciences

Medical Physiology

β-cell response to high fat diet induced metabolic demands in the obese Wistar rat

Roux, Candice Rene

03 1900

Thesis (MScMedSc)--University of Stellenbosch, 2011. / ENGLISH ABSTRACT: Introduction: A westernized diet rich in saturated fats and sugars, together with a sedentary lifestyle, has contributed to the dramatic increase in obesity during the last decade (Zimmett et al, 2001; Wild et al, 2004). Obesity is associated with dyslipidemia and insulin resistance which are major risk factors for the development of type 2 diabetes (T2D) (Zimmet et al, 2001, Kahn et al, 2006; Schröder et al, 2007). High-fat feeding in rodents induces symptoms similar to the human metabolic syndrome without progression to T2D (Woods et al, 2002; Weir and Bonner-Weir, 2007). The addition of fructose to a high-fat diet exacerbates the insulin resistance and leads to impaired pancreatic function of insulin secretion and glucose intolerance (Basciano et al, 2005; Stanhope et al, 2009). Aims: The aim of this study was to establish the effect of a high-fat and sucrose/fructose diet on glucose metabolism, the development of insulin resistance and β-cell dynamics. Methods: Weanling Wistar rats were randomized into two study groups; study one over an experimental period for three months and study two for twelve months. Each study consisted of a control group that received standard rat chow and water; and two experimental groups receiving either a high-fat diet and water (HFD) or a café diet consisting of HFD with the addition of 15% sucrose/fructose (CFD). Fasting glucose and insulin concentrations, intravenous glucose tolerance test (IVGTT), glucose stimulated insulin secretion rates and 2-deoxy-[3H]-D-glucose uptake in muscle, liver and fat were measured. The pancreata were harvested for immunohistochemical labeling of β-cells (insulin), α-cells (glucagon), GLUT2 (glucose transport) and MIB5 (proliferation). Samples of the pancreata were also collected for electron microscopy. Results and discussion: Feeding Wistar rats a CFD induced obesity, insulin resistance and glucose intolerance. By twelve months the rats had an impaired glucose response with increased IVGTT peak values, area under the curve (AUC) values and glucose clearance rates. Concomitantly, the glucose stimulated insulin secretion rate (GS-ISR) was attenuated. Stimulated glucose disposal as measured by 2-deoxy-[3H]-D-glucose uptake was reduced in muscle and adipose tissue at three months. By twelve months, due to the age of the rats, stimulated glucose uptake declined compared to three months with no difference between groups. After three months the diets had no observable effect on the islets using light microscopy. However, by twelve months morphological changes were observed in both the HFD and CFD groups. In the HFD group large hypertrophied irregular islets with fibrous changes were observed. In the CFD group these morphological changes were more prominent with fibrous segregation and disruption of the normal endocrine arrangement. In addition, the presence of inflammatory cells within the affected islets is consistent with T2D. Conclusion: High-fat diet fed to Wistar rats induced obesity, abdominal adiposity and insulin resistance. The addition of sucrose/fructose to a high-fat diet exacerbated the insulin resistance and resulted in glucose intolerance and mild hyperglycemia. Morphological changes in the large islets were observed which are consistent with the development of T2D. / AFRIKAANSE OPSOMMING: Inleiding: ‘n Verwesterde dieët, ryk aan versadigde vette en suikers tesame met 'n passiewe lewenstyl, het bygedra tot die dramatiese verhoging in vetsug gedurende die laaste dekade (Zimmett et al, 2001; Wild et al, 2004). Vetsug word met dislipidemie en insulienweerstandigheid geassosieer wat hoof risikofaktore is vir die ontwikkeling van tipe 2 diabetes (T2D) (Zimmet et al, 2001; Kahn et al, 2006; Schröder et al, 2007). Hoë-vet voeding in knaagdiere induseer simptome soortgelyk aan menslike metaboliese sindroom sonder die ontwikkeling van T2D (Woods et al, 2002; Weir and Bonner-Weir, 2007). Die byvoeging van fruktose tot 'n hoë-vet dieët vererger insulienweerstandigheid en lei tot verswakte pankreas funksie, insuliensekresie en glukoseintoleransie (Basciano et al, 2005; Stanhope et al, 2009). Doelwitte: Die doelwitte van die studie was om die effek van hoë-vet en sukrose/fruktose voeding op glukosemetabolisme, die ontwikkeling van insulienweerstandigheid en β-sel dinamika te bepaal. Metodes: Gespeende Wistar rotte was in twee groepe gerandomiseer; studie een oor ʼn tydperk van drie maande en studie twee oor ʼn tydperk van twaalf maande onderskeidelik. Elke studie het 'n kontrole groep met standaard rot kos en water (control); en twee experimentele diëte wat of ʼn hoë-vet dieët en water (HFD) of 'n kafeedieët groep wat die HFD met die byvoeging van 15% sukrose/fruktose in hul drink water (CFD) ontvang. Fastende glukose en insulien, binneaarse glukose toleransie toets (IVGTT), glukose gestimuleerde insulien sekresie tempo en 2-deoxi-[3H]-D-glukose opname in spier, lewer en vet is gebruik om die effek van die dieët op glukosemetabolisme te bepaal. Die pankreata is uitgehaal vir immunohistochemiese identifisering van β-selle (insulien), α-selle (glukagoon), GLUT2 (glukose transport) en MIB5 (proliferasie). Monsters van die pankreata was ook vir elektronmikroskopie versamel. Resultate en bespreking: Voeding van ʼn CFD aan Wistar rotte induseer vetsug, insulienweerstandigheid en glukose-intoleransie Teen twaalf maande toon die rotte 'n verswakte respons tot glukose met verhoogde IVGTT piekwaardes, AUC waardes en glukose opruimingswaardes. Terselfdetyd is die glukose gestimuleerde insuliensekresie tempo (GS-ISR) ook verswak. Gestimuleerde glukose opruiming, soos deur 2-deoxi-[3H]-D-glukose opname bepaal, was verlaag in spier en vetweefsel teen drie maande. Teen twaalf maande, weens die ouderdom van die rotte, is die gestimuleerde glukose opname verlaag in vergelyking met drie maande sonder 'n verskil tussen groepe. Na drie maande kon geen sigbare morfologiese verskille met ligmikroskopie tussen die diëte waargeneem word nie. Teen twaalf maande is morfologiese verskille waargeneem in beide die HFD en die CFD groepe. In die HFD groep is groot hipertrofiese onreëlmatige eilande met fibrotiese verandering waargeneem. In die CFD groep was die morfologiese verandering meer gevorder met fibrotiese onderverdeling en ontwrigting van die normale endokriene rangskikking. Die teenwoordigheid van inflammatoriese selle in die geaffekteerde eilande is verenigbaar met T2D. Afleiding: Die voer van 'n hoë-vet dieët aan Wistar rotte veroorsaak vetsug, abdominale adipositeit en insulienweerstandigheid. Die byvoeging van sukrose/ fruktose tot die hoë-vet dieët vererger die insulienweerstandigheid en veroorsaak glukoseintoleransie en matige hiperglukemie. Morfologiese veranderings in die groter eilande was verenigbaar met T2D.

Insulin resistance

Obesity and Type 2 diabetes

High-fat diet

Type 2 diabetes

Theses -- Anatomy

Dissertations -- Anatomy

Theses -- Histology

Dissertations -- Histology

Insulin resistance -- Animal models

Rats as laboratory animals

Biomedical Sciences