Glucose transporter (GLUT 4) content and insulin receptor kinase activity in muscles of the LA/N-cp rat.

In this study we compared insulin binding activity, insulin receptor tyrosine kinase activity, and GLUT 4 protein content in six muscles from LA/N-cp rats and their lean controls. LA/N-cp rats had an approximate 20-fold increase in insulin concentration (837 +/- 113 vs 40 +/- 1), associated with significant (p < 0.01) decreases in both insulin binding activity per mg muscle and in muscle GLUT 4 content. Maximum insulin tyrosine kinase activity was also lower in muscle from LA/N-cp rats, but no difference was noted when tyrosine kinase activity was expressed per receptor. These data indicate that there are at least two defects in the insulin action cascade in muscle from LA/N-cp rats that contribute to the insulin resistance in these animals.

The insulin receptor--single function and dual effect.

Net effects of insulin on glucose entry, metabolism and other cellular processes have been well documented over the past 30-40 years. Although it is known that insulin binds to a specific cell membrane receptor protein which undergoes autophosphorylation and tyrosine kinase activation, the individual reactions following receptor activation that cause the metabolic changes remain unknown. It is well documented that the isolated insulin receptor has a high degree of basal autophosphorylation capacity and externally directed tyrosine kinase. There is also evidence that some in vivo autophosphorylation can take place in the total absence of insulin. If receptor activity does exist in the absence of insulin, then receptor function needs to be reanalyzed. It will be proposed here that the insulin binding membrane protein functions mainly to inhibit glucose transport under low physiological levels of insulin. Evidence of basal receptor enzymatic activity in the absence of insulin supports this theory. Under metabolically sufficient conditions, enough insulin receptors are functionally active to interact with the glucose transport system in an inhibitory manner, providing membrane control of internal glucose metabolism. Insulin acts by aggregating this inhibitory system. If inhibitory insulin receptors are aggregated following insulin elevation, their inhibitory action is prevented and glucose transport increases. This increase in transport will be in direct proportion to the temporal inhibitory level of the receptor and to the area of the cell membrane cleared of their inhibitory effect. When insulin receptor protein is confined to small areas of the cell membrane through aggregation, any potential inhibitory function is negated and glucose entry increases dramatically. This is the classical insulin effect. Both of these concepts were suggested 37 years earlier. Randle & Smith (1957, Biochem. Biophys. Acta 25, 442; 1958, Biochem. J. 70, 490) proposed that the internal supply of energy rich compounds limited glucose entry and that the effect of insulin was to inhibit this process which was inhibiting glucose entry. The present report provides a mechanism for this.

Characterization of insulin receptor kinase activity and autophosphorylation in different skeletal muscle types.

We have examined insulin binding, autophosphorylation, and tyrosine kinase activity in detergent-solubilized and wheat germ agglutinin-purified insulin receptor preparations from four rat muscles of different fiber composition (i.e., tensor fascia latae, soleus, vastus intermedius, and plantaris). Insulin binding activity was similar in three of the four muscles but lower in tensor fascia latae. No significant differences were noted in the affinity of insulin for its receptor from various muscle types. Insulin receptor tyrosine kinase activity measured in the absence (basal) and presence of insulin (0.3-300 nM) was comparable in all muscle types (normalized to the amount of insulin bound). Insulin sensitivity, measured as the dose of insulin required for half-maximal activation of kinase activity, was also similar in all muscle types. Likewise, incubation of receptor preparations with [gamma-32P]ATP, Mn2+, and insulin (0.25-100 nM) resulted in a dose-dependent autophosphorylation of the beta-subunit (relative molecular weight approximately 95 kDa) with similar kinetics in all muscle types. In conclusion, these results show that the functional behavior of the insulin receptor autophosphorylation-kinase system (in vitro) is not changed by alterations in muscle fiber composition, indicating that differences in insulin sensitivity between different skeletal muscle types is probably not due to modulation of the insulin receptor phosphorylation system.

Endocrine effects of meternal alcoholization: plasma and brain testosterone, dihydrotestosterone, estradiol, and corticosterone.

Maternal ethanol consumption was associated with reduced levels of dihydrotestosterone in the brains of 1--2-day-old male rats when compared to those of sex-matched pups obtained from dames that were fed sucrose. In contrast, brain levels of corticosterone were increased significantly in the pups of ethanol-fed animals when compared to those from sucrose-fed controls. Brain and plasma estradiol did not differ between groups. These results suggest that maternal ethanol consumption may influence the central nervous system and plasma levels of certain steroidal hormones in the offspring.

Brain corticosterone in lactating rats: possible relation to the attenuation of the pituitary-adrenocortical response to stress.

In an attempt to elucidate the mechanism of suppression of the plasma corticosterone stress response in the lactating female rats, nonstress levels of corticosterone in plasma and hypothalamus, cerebral cortex, hippocampus and pituitaries were determined in the lactating and nonlactating Sprague-Dawley rats at 1600-1700 hr by the protein binding assay. The brain corticosterone levels were significantly higher (64-92%) in the lactating than in nonlactating rats, while the plasma corticosterone levels were identical. We conclude that the suppression of the stress response in the lactating female rats is directly or indirectly related to the high basal levels of corticosterone in the brain, which result from a chronic hyperactivation of the endocrine axis.

The fluorometric assay of rat plasma corticosterone: evaluation of nonspecific fluorescence.

An analysis of 168 plasma samples from intact rats, one to 35 days of age, was performed using both brief and specific fluorometric procedures. The amount of fluorescence produced by the brief procedure which could be attributed to corticosterone ranged from a maximum of 72% to a minimum of 16% of the total fluorescence value. Corticosterone represented 50% or more of the brief assay value in only five out of 18 groups of animals assayed. Following statistical analysis of the nonspecific fluorescence, a significant variation was found due to the age of the animal. A highly significant increase in nonspecific fluorescence was found in 21-day old animals following histamine injection. It was concluded that the brief fluorometric assays for corticosterone were of little value if specificity was desired.

Circadian rhythm of corticosterone levels in rat brain.

In the present study the circadian changes which occur in the levels of corticosterone in the brain and plasma in Sprague-Dawley rats are reported. The levels of corticosterone in the brain were found to have a daily trough and crest with timing similar to that observed for the plasma steroid. In addition, the effect of histamine stress on the corticosterone content of the particulate and the soluble fractions at the trough and crest was examined. The levels of both brain fractions were significantly higher 20 min after histamine injection. The time of day at which the stress was applied was not a significant factor in the magnitude of the stress response.