The relationship between diet and insulin sensitivity was examined in isolated soleus muscle from 10-wk-old lean Zucker rats. Rats were fed either a high fat or high carbohydrate diet that had 67% of calories as fat or carbohydrate, respectively, for 10 days. Plasma insulin but not plasma glucose concentrations were significantly elevated in high-fat-fed rats, indicating that a state of insulin resistance existed. The mechanisms responsible for the insulin resistance were studied by measuring insulin binding, 2-deoxyglucose uptake, and glucose metabolism in soleus muscle. The soleus muscle from the high-fat-fed rats bound significantly less insulin than high carbohydrate control rats under equilibrium binding conditions. The 35% decrease in insulin binding at maximal insulin concentrations resulted from a decrease in insulin receptor number but no change in receptor affinity. Maximal insulin-stimulated 2-deoxyglucose uptake was reduced in soleus muscle from high-fat-fed rats when compared with high carbohydrate controls. A decrease in postmembrane basal and insulin-stimulated glucose utilization was produced by high rat feeding and varied depending upon the pathway involved. An estimate of glycolysis (3H2O) formation from [5-3H]glucose) and glucose oxidation (14CO2 production from 14C-glucose) demonstrated a greater decrease in basal and insulin-stimulated utilization than in [5-3H]glucose conversion to [3H]glycogen. These results suggest that multiple sites are responsible for the observed insulin resistance in soleus muscle after high fat feeding.
The relationship between insulin binding and its biological effects was studied in soleus muscle of 3- to 15-wk-old genetically obese (ob/ob) mice. At 3 and 4 wk of age, soleus muscle from lean and obese mice bound similar amounts of insulin under equilibrium binding conditions. However, by 6 wk of age, insulin binding and total receptor concentration (Ro) were significantly decreased in soleus muscle from obese compared to lean mice. In addition lean and obese mice demonstrated an age-dependent decrease in insulin binding, Ro, and receptor affinity. At 4 wk of age, insulin-stimulated 2-deoxyglucose transport and glucose utilization were significantly lower in soleus muscle from obese mice and preceded alterations in insulin binding. The postmembrane decrease in insulin sensitivity was dissimilar for various pathways of glucose metabolism. Glucose conversion of glycogen, but not the glycolytic rate or glucose oxidation, remained sensitive to insulin stimulation. These data indicate that glucose transport and utilization rather than insulin binding may play the primary role in the development of insulin resistance of muscle in the obese diabetic syndrome.
A non-invasive method has been developed for measuring milk intake of suckling mice under physiological conditions. This method was used to determine whether genetically obese (ob/ob) mice are hyperphagic at 10 and 15 days of age. Lactating dams were injected with tritiated water (3H2O), which equilibrated in body water within 30 minutes. A constant specific activity of 3H2O was maintained over a 24-hour period by provision of 3H2O in drinking water. Tritium accumulation in body water of pups was proportional to their milk intake. After 24 hours, pups were removed from the dam, weighed, and blood samples (less than 10 microliters) obtained for assay of plasma 3H content by liquid scintillation counting. Body water content was computed from body weight. The composition of mouse milk taken from dams on days 10 and 15 of lactation was analyzed both volumetrically and gravimetrically. Water content was 68 to 69%; lipid content was 20% on day 10, 17% on day 15. At 10 days, mean milk intake was 0.96 ml, independent of litter size. At 15 days, intake per pup tended to decrease, from 1.4 to 0.8 ml, with increasing litter size. Using this method we have established that under physiological conditions ob/ob mice, which were identified as such at 4 to 5 weeks of age, do not have increased milk consumption at either 10 or 15 days of age.
Milk composition and milk intake were measured in lean and preobese Zucker rat pups. Lactating dams were injected with 3H2O, which equilibrated with plasma water within 30 minutes. A constant specific activity of 3H was maintained by adding 3H2O to drinking water. Blood samples of 5 microliters were obtained from 1, 15 and 20-day-old suckling pups every 4 hours for a 24-hour period and the accumulation of tritium was used to calculate pups' milk intake. No diurnal variation in milk intake of pups was observed. Obese pups were identified at 5 weeks of age and showed no difference in milk intake compared to lean littermates at 10, 15 and 20 days of age. Milk intake of pups increased with age from 2.0 ml at day 10 to 15.8 ml by day 20. Food and water intake of dams also increased from day 10 to 20 of lactation. The protein and carbohydrate component of rat milk did not change significantly from day 5 to 20 of lactation; however, the fat component decreased significantly from 12.7% at day 5 to 4.2% at day 20.
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