Susan M. Beale scite author profile

A reduced capacity for mitochondrial fatty acid oxidation in skeletal muscle has been proposed as a major factor leading to the accumulation of intramuscular lipids and their subsequent deleterious effects on insulin action. Here, we examine markers of mitochondrial fatty acid oxidative capacity in rodent models of insulin resistance associated with an oversupply of lipids. C57BL/6J mice were fed a high-fat diet for either 5 or 20 weeks. Several markers of muscle mitochondrial fatty acid oxidative capacity were measured, including 14 C-palmitate oxidation, palmitoyl-CoA oxidation in isolated mitochondria, oxidative enzyme activity (citrate synthase, ␤-hydroxyacyl CoA dehydrogenase, medium-chain acyl-CoA dehydrogenase, and carnitine palmitoyl-transferase 1), and expression of proteins involved in mitochondrial metabolism. Enzyme activity and mitochondrial protein expression were also examined in muscle from other rodent models of insulin resistance. Compared with standard diet-fed controls, muscle from fat-fed mice displayed elevated palmitate oxidation rate (5 weeks ؉23%, P < 0.05, and 20 weeks ؉29%, P < 0.05) and increased palmitoyl-CoA oxidation in isolated mitochondria (20 weeks ؉49%, P < 0.01). Furthermore, oxidative enzyme activity and protein expression of peroxisome proliferator-activated receptor ␥ coactivator (PGC)-1␣, uncoupling protein (UCP) 3, and mitochondrial respiratory chain subunits were significantly elevated in fat-fed animals. A similar pattern was present in muscle of fat-fed rats, obese Zucker rats, and db/db mice, with increases observed for oxidative enzyme activity and expression of PGC-1␣, UCP3, and subunits of the mitochondrial respiratory chain. These findings suggest that high lipid availability does not lead to intramuscular lipid accumulation and insulin resistance in rodents by decreasing muscle mitochondrial fatty acid oxidative capacity.

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Enhancement of Muscle Mitochondrial Oxidative Capacity and Alterations in Insulin Action Are Lipid Species Dependent

Turner

et al. 2009

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OBJECTIVEMedium-chain fatty acids (MCFAs) have been reported to be less obesogenic than long-chain fatty acids (LCFAs); however, relatively little is known regarding their effect on insulin action. Here, we examined the tissue-specific effects of MCFAs on lipid metabolism and insulin action.RESEARCH DESIGN AND METHODSC57BL6/J mice and Wistar rats were fed either a low-fat control diet or high-fat diets rich in MCFAs or LCFAs for 4–5 weeks, and markers of mitochondrial oxidative capacity, lipid levels, and insulin action were measured.RESULTSMice fed the MCFA diet displayed reduced adiposity and better glucose tolerance than LCFA-fed animals. In skeletal muscle, triglyceride levels were increased by the LCFA diet (77%, P < 0.01) but remained at low-fat diet control levels in the MCFA-fed animals. The LCFA diet increased (20–50%, P < 0.05) markers of mitochondrial metabolism in muscle compared with low-fat diet–fed controls; however; the increase in oxidative capacity was substantially greater in MCFA-fed animals (50–140% versus low-fat–fed controls, P < 0.01). The MCFA diet induced a greater accumulation of liver triglycerides than the LCFA diet, likely due to an upregulation of several lipogenic enzymes. In rats, isocaloric feeding of MCFA or LCFA high-fat diets induced hepatic insulin resistance to a similar degree; however, insulin action was preserved at the level of low-fat diet–fed controls in muscle and adipose from MCFA-fed animals.CONCLUSIONSMCFAs reduce adiposity and preserve insulin action in muscle and adipose, despite inducing steatosis and insulin resistance in the liver. Dietary supplementation with MCFAs may therefore be beneficial for preventing obesity and peripheral insulin resistance.

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Altered feeding differentially regulates circadian rhythms and energy metabolism in liver and muscle of rats

Reznick

Preston

Wilks

et al. 2013

Biochimica et Biophysica Acta (BBA) - Molecular Basis of Diseas

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Energy metabolism follows a diurnal pattern responding to the light/dark cycle and food availability. This study investigated the impact of restricting feeding to the daylight hours and feeding a high fat diet on circadian clock (bmal1, dbp, tef and e4bp4) and metabolic (pepck, fas, ucp3, pdk4) gene expression and markers of energy metabolism in muscle and liver of rats. The results show that in chow-fed rats switched to daylight feeding, the peak diurnal expression of genes in liver was shifted by 6-12h while expression of these genes in muscle remained in a similar phase to rats feeding ad libitum. High fat feeding during the daylight hours had limited effect on clock gene expression in liver or muscle but shifted the peak expression of metabolic genes (pepck, fas) in liver by 6-12h. The differential effects of daylight feeding on gene and protein expression in muscle and liver were accompanied by an 8% reduction in whole body energy expenditure, a 20-30% increased glycogen content during the light phase in muscle of day-fed rats and increased adipose tissue deposition per gram food consumed. These data demonstrate that a mismatch of feeding and light/dark cycle disrupts tissue metabolism in muscle with significant consequences for whole body energy homeostasis.

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Dual Ablation of Grb10 and Grb14 in Mice Reveals Their Combined Role in Regulation of Insulin Signaling and Glucose Homeostasis

Holt¹,

Lyons²,

Ryan³

et al. 2009

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Growth factor receptor bound (Grb)10 and Grb14 are closely related adaptor proteins that bind directly to the insulin receptor (IR) and regulate insulin-induced IR tyrosine phosphorylation and signaling to IRS-1 and Akt. Grb10- and Grb14-deficient mice both exhibit improved whole-body glucose homeostasis as a consequence of enhanced insulin signaling and, in the case of the former, altered body composition. However, the combined physiological role of these adaptors has remained undefined. In this study we utilize compound gene knockout mice to demonstrate that although deficiency in one adaptor can enhance insulin-induced IRS-1 phosphorylation and Akt activation, insulin signaling is not increased further upon dual ablation of Grb10 and Grb14. Context-dependent limiting mechanisms appear to include IR hypophosphorylation and decreased IRS-1 expression. In addition, the compound knockouts exhibit an increase in lean mass comparable to Grb10-deficient mice, indicating that this reflects a regulatory function specific to Grb10. However, despite the absence of additive effects on insulin signaling and body composition, the double-knockout mice are protected from the impaired glucose tolerance that results from high-fat feeding, whereas protection is not observed with animals deficient for individual adaptors. These results indicate that, in addition to their described effects on IRS-1/Akt, Grb10 and Grb14 may regulate whole-body glucose homeostasis by additional mechanisms and highlight these adaptors as potential therapeutic targets for amelioration of the insulin resistance associated with type 2 diabetes.

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Dual Ablation of Grb10 and Grb14 in Mice Reveals Their Combined Role in Regulation of Insulin Signaling and Glucose Homeostasis

Holt¹,

Lyons²,

Ryan³

et al. 2009

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Susan M. Beale

Excess Lipid Availability Increases Mitochondrial Fatty Acid Oxidative Capacity in Muscle

Enhancement of Muscle Mitochondrial Oxidative Capacity and Alterations in Insulin Action Are Lipid Species Dependent

Altered feeding differentially regulates circadian rhythms and energy metabolism in liver and muscle of rats

Dual Ablation of Grb10 and Grb14 in Mice Reveals Their Combined Role in Regulation of Insulin Signaling and Glucose Homeostasis

Dual Ablation of Grb10 and Grb14 in Mice Reveals Their Combined Role in Regulation of Insulin Signaling and Glucose Homeostasis

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