Calorie restriction (CR), even for brief periods (4-20 days), results in increased whole-body insulin sensitivity, in large part due to enhanced insulin-stimulated glucose transport by skeletal muscle. Evidence suggests that the cellular alterations leading to this effect are postreceptor steps in insulin signaling. To determine whether insulin receptor substrate (IRS)-1 is essential for the insulin-sensitizing effect of CR, we measured in vitro 2-deoxyglucose (2DG) uptake in the presence and absence of insulin by skeletal muscle isolated from wild-type (WT) mice and transgenic mice lacking IRS-1 (knockout [KO]) after either ad libitum (AL) feeding or 20 days of CR (60% of ad libitum intake). Three muscles (soleus, extensor digitorum longus [EDL], and epitrochlearis) from male and female mice (4.5-6 months old) were studied. In each muscle, insulin-stimulated 2DG uptake was not different between genotypes. For EDL and epitrochlearis, insulin-stimulated 2DG uptake was greater in CR compared to AL groups, regardless of sex. Soleus insulin-stimulated 2DG uptake was greater in CR compared with AL in males but not females. The diet effect on 2DG uptake was not different for WT and KO animals. Genotype also did not alter the CR-induced decrease in plasma constituents (glucose, insulin, and leptin) or body composition (body weight, fat pad/body weight ratio). Consistent with previous studies in rats, IRS-1 protein expression in muscle was reduced in WT-CR compared with WT-AL mice, and muscle IRS-2 abundance was unchanged by diet. Skeletal muscle IRS-2 protein expression was significantly lower in WT compared with KO mice. These data demonstrate that IRS-1 is not essential for the CR-induced increase in insulin-stimulated glucose transport in skeletal muscle, and the absence of IRS-1 does not modify any of the characteristic adaptations of CR that were evaluated.
We evaluated the effects of 8 mo of calorie restriction [CR: 60% of ad libitum (AL) food intake] on glucose uptake by 14 tissues in unanesthetized, adult (12 mo) F344×BN rats. Glucose metabolism was assessed by the 2-[3H]deoxyglucose tracer technique at 1500 or 2100. Despite an ∼60% decline in insulinemia with CR, plasma 2-[3H]deoxyglucose clearance for CR was greater than for AL at both times. A small, CR-related decrease in glucose metabolic index ([Formula: see text]) occurred only at 1500 in the spleen and heart, and this decrease was reversed at 2100. In some tissues (cerebellum, lung, kidney, soleus, and diaphragm),[Formula: see text] was unaffected by diet, regardless of time. In the other tissues (brown fat, 3 white fat pads, epitrochlearis, plantaris, and gastrocnemius),[Formula: see text] was higher or tended to be higher for CR vs. AL at one or both times. These findings indicate that 8 mo of CR did not cause a continuous reduction in in vivo glucose uptake by any tissue studied, and, in several insulin-sensitive tissues, glucose uptake was at times greater for CR vs. AL rats.
Previous studies have demonstrated enhanced insulin sensitivity in calorie-restricted [CR, fed 60% ad libitum (AL) one time daily] compared with AL-fed rats. To evaluate the effects of reduced food intake, independent of temporal differences in consumption, we studied AL (unlimited food access)-fed and CR (fed one time daily) rats along with groups temporally matched for feeding [fed 3 meals (M) daily]: MAL and MCR, eating 100 and 60% of AL intake, respectively. Insulin-stimulated glucose transport by isolated muscle was increased in MCR and CR vs. AL and MAL; there was no significant difference for MCR vs. CR or MAL vs. AL. Intramuscular triglyceride concentration, which is inversely related to insulin sensitivity in some conditions, did not differ among groups. Muscle concentration of UDP-N-acetylhexosamines [end products of the hexosamine biosynthetic pathway (HBP)] was lower in MCR vs. MAL despite unaltered glutamine-fructose-6-phosphate aminotransferase activity (rate-limiting enzyme for HBP). These results indicate that the CR-induced increase in insulin-stimulated glucose transport in muscle is attributable to an altered amount, not timing, of food intake and is independent of lower triglyceride concentration. They further suggest that enhanced insulin action might involve changes in HBP.
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