Insulin sensitivity and responsiveness of epitrochlearis and soleus muscles from fed and starved rats. Recognition of differential changes in insulin sensitivities of protein synthesis and glucose incorporation into glycogen.

The insulin sensitivity of protein synthesis and glucose incorporation into glycogen by the soleus and epitrochlearis muscles from fed rats and 24 h-starved rats was determined in vitro during the first and second hours of incubation after isolation of the muscles. Rates of protein synthesis by both muscles from fed rats in the first hour of incubation were 2-fold higher than in the second hour and were not increased by insulin. Rates of protein synthesis during the first hour in the presence of 6000 microunits of insulin/ml were increased in soleus, but not in epitrochlearis, muscles from starved rats. Rates of protein synthesis in both muscles from fed and starved rats were increased significantly by insulin during the second hour. High concentrations of insulin caused a marked stimulation of the rates of glucose incorporation by both muscles from fed and starved rats in both the first and second hours of incubation. The insulin sensitivity of glucose incorporation during the second hour, defined as the concentration of insulin causing half-maximal stimulation, was increased 10-fold for both muscle types from starved rats (soleus, 65 microunits/ml; epitrochlearis, 45 microunits/ml) relative to muscles from fed rats (soleus, 600 microunits/ml; epitrochlearis, 500 microunits/m). The insulin sensitivity of protein synthesis in the second hour was greater for soleus muscles from starved rats (65 microunits/ml) than from fed rats (500 microunits/ml). In contrast, the insulin sensitivity of protein synthesis in epitrochlearis muscles from starved rats was significantly decreased (225 microunits/ml) compared with fed rats (25 microunits/ml Maximal rates achieved by high concentrations of insulin were not different from those in the same muscle from fed rats. It is suggested that protein synthesis, in distinction to glucose utilization, may be resistant to insulin stimulation during periods of acute starvation in muscles with fibre compositions similar to the epitrochlearis, but not in muscles with fibre compositions similar to the soleus. Partial reversal of the resistance observed in vitro for epitrochlearis muscles from starved rats may be due to the loss of factors which suppress the effect of insulin in vivo.     

The possible involvement of prostaglandin F2 alpha in the stimulation of muscle protein synthesis by insulin

The addition of insulin (8 ng/ml) in vitro to muscles from fasted rabbits increased protein synthesis (+80%) to a value similar to that found in muscles from fed donors. The addition of either indomethacin or meclofenamate completely blocked this effect of insulin. Muscles from fasted rabbits released less prostaglandin (PG)F2 alpha into the medium and the presence of insulin increased and indomethacin and meclofenamate reduced PGF2 alpha release. Other conditions (work load and leucocyte pyrogen) which increase protein synthesis in muscle also stimulate PGF2 alpha release. As both arachidonic acid and PGF2 alpha in themselves increase protein synthesis we suggest that accelerated phospholipolysis and PG synthesis have a general role in the control of muscle protein turnover.     

Comparison of protein synthesis and degradation in incubated and perfused muscle.

Rates of muscle protein synthesis and degradation measured in the perfused hindquarter were compared with those in incubated epitrochlearis muscles. With fed or starved mature rats, results without insulin treatment were identical. With insulin treatment, protein synthesis in perfused hindquarters was greater, though protein degradation was the same. Thus rates of muscle protein degradation estimated by these two methods in vitro correspond closely.     

Protein synthesis in skeletal muscle of the perfused rat hemicorpus compared with rates in the intact animal.

The rate of protein synthesis was measured in muscles of the perfused rat hemicorpus, and values were compared with rates obtained in whole animals. In gastrocnemius muscle of fed rats the rate of synthesis measured in the hemicorpus was the same as that in the whole animal. However, in plantaris, quadriceps and soleus muscles rates were higher in the hemicorpus than those in vivo. In the hemicorpus, starvation for 1 day decreased the rate of protein synthesis in gastrocnemius and plantaris muscles, in parallel with decreases in the RNA content, but the soleus remained unaffected. Similar effects of starvation were observed in vivo, so that the relationships between rates in vivo and in the hemicorpus were the same as those in fed rats. Proteins of quadriceps and plantaris muscles were separated into sarcoplasmic and myofibrillar fractions. The rate of synthesis in the sarcoplasmic fraction of the hemicorpus from fed rats was similar to that in vivo, but synthesis in the myofibrillar fraction was greater. In the plantaris of starved rats the rates of synthesis in both fractions were lower, but the relationships between rates measured in vivo and in the perfused hemicorpus were similar to those seen in fed rats. The addition of insulin to the perfusate of the hemicorpus prepared from 1-day-starved animals increased the rates of protein synthesis per unit of RNA in gastrocnemius and plantaris muscles to values above those seen in fed animals when measured in vivo or in the hemicorpus. Insulin had no effect on the soleus. Overall, the rates of protein synthesis in the hemicorpus differed from those in vivo. However, the effect of starvation when measured in the whole animal was very similar to that measured in the isolated rat hemicorpus when insulin was omitted from the perfusate.     

Rates of protein turnover in vivo and in vitro in ventricular muscle of hearts from fed and starved rats.

Starvation of 300 g rats for 3 days decreased ventricular-muscle total protein content and total RNA content by 15 and 22% respectively. Loss of body weight was about 15%. In glucose-perfused working rat hearts in vitro, 3 days of starvation inhibited rates of protein synthesis in ventricles by about 40-50% compared with fed controls. Although the RNA/protein ratio was decreased by about 10%, the major effect of starvation was to decrease the efficiency of protein synthesis (rate of protein synthesis relative to RNA). Insulin stimulated protein synthesis in ventricles of perfused hearts from fed rats by increasing the efficiency of protein synthesis. In vivo, protein-synthesis rates and efficiencies in ventricles from 3-day-starved rats were decreased by about 40% compared with fed controls. Protein-synthesis rates and efficiencies in ventricles from fed rats in vivo were similar to values in vitro when insulin was present in perfusates. In vivo, starvation increased the rate of protein degradation, but decreased it in the glucose-perfused heart in vitro. This contradiction can be rationalized when the effects of insulin are considered. Rates of protein degradation are similar in hearts of fed animals in vivo and in glucose/insulin-perfused hearts. Degradation rates are similar in hearts of starved animals in vivo and in hearts perfused with glucose alone. We conclude that the rates of protein turnover in the anterogradely perfused rat heart in vitro closely approximate to the rates in vivo in absolute terms, and that the effects of starvation in vivo are mirrored in vitro.     

The effects of starvation upon protein turnover in red and white myotomal muscle of rainbow trout, Salmo gairdneri Richardson

Protein synthesis rates of both red and white muscle were measured using a constant infusion technique in fed and starved rainbow trout over a period of 2 months. In both tissues, rates of protein synthesis fell during starvation although the fall was more rapid in white than in red muscle. The reduced rates of protein synthesis were correlated to a reduced level of RNA in the tissues and a lower rate of translation of the RNA present. Estimated rates for protein degradation in white muscle showed a marked initial increase but with more prolonged starvation the degradation rate become only slightly greater than that in the fed fish.     

Regulation of protein metabolism by a physiological concentration of insulin in mouse soleus and extensor digitorum longus muscles. Effects of starvation and scald injury.

1. Although high concentrations of insulin affect both synthesis and degradation of skeletal-muscle protein, it is not known to what extent these effects occur with physiological concentrations. The effects of a physiological concentration of insulin (100 mu units/ml) on muscle protein synthesis, measured with [3H]tyrosine, and on muscle protein degradation, measured by tyrosine release in the presence of cycloheximide, were studied in mouse soleus and extensor digitorum longus muscles in vitro. 2. Insulin significantly stimualated protein synthesis in both muscles, but an inhibition of degradation was seen only in the extensor digitorum longus. 3. Starvation for 24 h decreased the rate of protein synthesis and increased the rate of breakdown in the extensor digitorum longus. Sensitivity to insulin-stimulation of proteins synthesis in the soleus was increased by starvation. 4. ;a 20%-surface-area full-skin-thickness dorsal scald injury produced a fall in total protein content in soleus and extensor digitorum muscles, maximal on the third day after injury. Soleus muscles 2 days after injury showed an impairment of protein synthesis; degradation was unaffected and neither synthesis nor degradation in vitro was significantly affected in the extensor digitorum longus. 5. The advantages and limitations of studies of protein metabolism in vitro are discussed.     

The effect of intermittent changes in tension on protein and collagen synthesis in isolated rabbit muscles.

Isolated intact rabbit muscles were incubated in a medium containing radioactive proline. The rates of synthesis of collagen and total muscle protein after incubation with a constant tension or intermittent mechanical stretching were compared with the rates in vivo. Muscles incubated under a constant tension synthesized protein at 22% of the rate observed in vivo; intermittent mechanical stretching resulted in an increase of 73% in the rate of protein synthesis, to 38% of that found in vivo. Collagen synthesis was affected in the same way as total protein synthesis by both types of incubation, therefore the relative rates of collagen and total protein synthesis were unchanged. ATP concentration in the isolate muscles and the uptake of glucose from the medium were increased by intermittent mechanical stretching. Incubating the muscles with a gas phase containing 5% O2 decreased the rate of protein synthesis, abolished the effect of intermittent mechanical stretching, lowered the concentration of ATP and increased the lactate concentration. The rate of protein synthesis in muscles maintained with a constant or intermittently applied tension was not affected by a previous period of incubation with the other type of stimulus.     

Protein synthesis and degradation in isolated muscle. Effect of omega 3 and omega 6 fatty acids.

The ability of derivatives of the essential fatty acids linoleic acid (C18:2, omega 6) and alpha-linolenic acid (C18:3, omega 3) to stimulate rates of protein synthesis and degradation was investigated in isolated intact muscles from fasted rabbits. Both omega 6 derivatives examined, arachidonic acid (C20:4, omega 6) and dihomo-gamma-linolenic acid (C20:3, omega 6), when added at concentrations up to 1 microM, stimulated the rate of protein synthesis and the release of prostaglandin F2 alpha (PGF2 alpha). Metabolites of the omega 6 series, namely eicosapentaenoic acid (C20:5, omega 3) and docosahexaenoic acid (C22:6, omega 3), were without effect on the rate of protein synthesis and resulted in a decrease in the release of PGF2 alpha. None of the fatty acids had a significant effect on the rate of protein degradation. Although insulin (100 mu units/ml) also stimulated rates of protein synthesis when added alone, none of the omega 3 or omega 6 fatty acids, when added with insulin at concentrations of 0.2 microM, potentiated the effect of the hormone.     

Changes in prostaglandin release associated with inhibition of muscle protein synthesis by dexamethasone

Forelimb digit extensor muscles from fed rabbits were incubated in the absence or presence of dexamethasone (100 nM). The presence of dexamethasone decreased the rates of protein synthesis, prostaglandin F2 alpha and prostaglandin E2 release after a time lag of 2.5-3 h. Although intermittent stretching stimulated both protein synthesis and prostaglandin release in the presence of dexamethasone, the absolute activities of both processes were lower in the presence of the steroid than in its absence. It is suggested that the inhibitory action of dexamethasone on muscle protein synthesis in vitro results from its effect on the activity of plasma-membrane phospholipase A2.     

Effect of beta agonists on protein turnover in isolated chick skeletal and atrial muscle

Various beta-adrenergic agonists were found to inhibit rates of protein degradation and net protein breakdown in isolated chick extensor digitorum communis (EDC) and atrial muscles. Rates of protein synthesis were not altered by these compounds. The beta-agonist cimaterol inhibited rates of protein degradation in EDC muscles incubated with or without amino acids and insulin. Cimaterol also inhibited the increased proteolysis induced by injury to muscle or by incubating muscles at body temperature (42 degrees C) versus 37 degrees C. Thus, beta-agonists may help promote skeletal muscle accretion in vivo even under conditions of severe negative nitrogen balance by slowing muscle proteolysis.     

A comparison of rates of protein turnover in rat diaphragm in vivo and in vitro.

Protein synthesis and degradation rates in diaphragms from fed or starved rats were compared in vivo and in vitro. For fed rats, synthesis rates in vivo were approximately twice those in vitro, but for starved rats rates were similar. Degradation rates were less in vivo than in vitro in diaphragms from either fed or starved rats.     

Antioxidant alpha-lipoic acid and protein turnover in insulin-resistant rat muscle

We have shown previously that the antioxidant alpha-lipoic acid (ALA) can stimulate glucose transport and can enhance the stimulation of this process by insulin in skeletal muscle from insulin-resistant obese Zucker rats. As insulin can also acutely activate general protein synthesis and inhibit net protein degradation in skeletal muscle, we hypothesized that ALA could directly affect protein turnover and also increase the effect of insulin on protein turnover in isolated skeletal muscle from developing obese Zucker rats. In epitrochlearis muscles isolated from obese Zucker rats, insulin (2 mU/ml) significantly (p < 0.05) increased in vitro protein synthesis (phenylalanine incorporation into protein) and decreased net protein degradation (tyrosine release), whereas a racemic mixture of ALA (2 mM) had no effect on either process. Interestingly, rates of protein synthesis in muscle from obese Zucker rats were substantially lower compared to those values observed in age-matched insulin-sensitive Wistar rats, whereas rates of protein degradation were comparable. Obese Zucker rats were also treated chronically with either vehicle or ALA (50 mg/kg/d for 10 d). Again, insulin significantly increased net protein synthesis and decreased net protein degradation in epitrochlearis muscles isolated from vehicle-treated obese Zucker rats; however, this stimulatory effect of insulin was not improved by prior in vivo ALA treatment. These results indicate that the previously described effect of the antioxidant ALA to increase insulin-stimulated glucose transport in skeletal muscle of obese, insulin-resistant rats does not apply to another important insulin-regulatable process, protein turnover. These findings imply that the cellular mode of action for ALA is restricted to signaling factors unique to the activation of glucose transport, and does not involve the pathway of stimulation of general protein synthesis and net protein degradation.     

The effect of ketone bodies on protein turnover in isolated skeletal muscle from the fed and fasted chick

1. The addition of 4 mM acetoacetate or DL-beta-hydroxybutyrate to the incubation medium decreased the rate of protein synthesis without influencing the rate of protein degradation in extensor digitorum communis (EDC) muscles from fed chicks and decreased the rates of protein synthesis and degradation in muscles from fasted chicks. 2. Ketone bodies markedly decreased intracellular concentrations of glutamine in EDC muscles from fed chicks by increasing glutamine oxidation. 3. The addition of 0.5 mM glutamine to incubation media containing 1.0 mM glutamine reversed the ketone body-induced decrease in intracellular glutamine concentration to the control value and blocked the inhibiting effect of ketone bodies on protein synthesis in skeletal muscles from fed chicks. 4. The addition of 5 mM pyruvate blocked the ability of ketone bodies to increase glutamine oxidation and prevented the associated decrease in intracellular glutamine concentration and the rate of protein synthesis in EDC muscles from fed chicks. 5. These results suggest that ketone bodies can act directly on skeletal muscle to inhibit the rate of protein synthesis in muscles from fed chicks by decreasing intracellular glutamine concentration by increasing its oxidation.     

Glucocorticoids and the regulation of phosphoenolpyruvate carboxykinase (guanosine triphosphate) in the rat.

The effect glucocorticoids on the synthesis and degradation of phosphoenolpyruvate carboxykinase (GTP)(EC4.1.1.32) in rat liver and kidney in vivo was studied immunochemically. The glucocorticoid analogue triamcinolone (9alpha-fluoro-11beta, 21-dihydroxy-16alpha,17alpha-isopropylidenedioxypregna-1,4-diene-3,20-dione) increased the synthesis rate of the kidney enzyme in starved animals. Both triamcinolone and cortisol decreased the synthesis rate of hepatic phosphoenolpyruvate carboxykinase (GTP) in fed and starved rats, but were without effect on the degradation rate of the enzyme. This effect of triamcinolone in liver was reversed by injection of dibutyryl cyclic AMP. However, in diabetic animals glucocorticoids increased the synthesis rate of hepatic phosphoenolpyruvate carboxykinase (GTP). Triamcinolone administration to starved rats in vivo is shown to cause an increase in the portal blood concentrations of insulin and glucose. Since the physiological de-inducer of liver phosphoenolpyruvate carboxykinase (GTP) is insulin, this is the probable cause of the decrease in the synthesis rate of the hepatic enzyme noted when glucocorticoids are administered to non-diabetic animals.     

Changes in rates of tissue protein synthesis in rats induced in vivo by consumption of kidney bean lectins

1. Plantaris and gastrocnemius muscles from rats fed a diet containing raw kidney beans lost proportionately more weight and protein than muscles from rats fed a protein free diet, resulting in a progressive reduction in the ratio muscle mass: body weight over a period of 6 days. Rates of muscle protein synthesis were also lower in rats fed raw beans.2. Destruction of the bean lectins by boiling abolished both these effects.3. Two hours after administration of a single dose of purified kidney bean lectin, rates of protein synthesis were unchanged in the muscle and liver but were increased in the gut mucosa.     

Failure of IGF-1 to affect protein turnover in muscle from growth-retarded neonatal rats

To investigate the response of the growth retarded neonatal rat to insulin-like growth factor-I (IGF-I) we have measured the effect of IGF-I on in vitro muscle protein synthesis and degradation rates in growth retarded and control neonatal rat pups. The growth retarded pups were growth retarded in utero by ligation of the uterine blood supply at day 17 of gestation. Basal levels of muscle protein synthesis in vitro were significantly lower in growth retarded pups compared with controls. Protein degradation rate were not different in muscles taken from the two groups. IGF-I stimulated protein synthesis in muscle from control pups by 12% and 15% at 20 ng/ml and 200ng/ml respectively. Net protein degradation was inhibited by 20% in the presence of 20ng/ml IGF-I. IGF-I had no effect on net protein synthesis or degradation in muscle from growth retarded pups. Neither Multiplication Stimulating Activity (at 20ng/ml or 200ng/ml) nor insulin (at 40ng/ml or 800ng/ml) was able to increase synthesis or decrease degradation of protein. Specific receptors for IGF-I are present on muscle membranes from both groups. Unlabelled IGF-I was more effective than MSA or insulin in competing with 125I-IGF-I for binding to the receptor. The relative affinities are consistent with type I IGF receptors. The affinity of these receptors for IGF-I was similar (Kd approximately 5nM) in both groups and the receptor concentration in both cases was approximately 250 fmol/mg protein. The refractility of tissue from growth retarded pups to IGF-I may be partially responsible for the lack of catch up growth in growth retarded neonates.     

Contrasting response of protein degradation to starvation and insulin as measured by release of N tau-methylhistidine or phenylalanine from the perfused rat heart.

An isotope-dilution method is described for the measurement of N tau-methylhistidine release from the perfused rat heart. We argue that release of N tau-methylhistidine is indicative of cardiac actin degradation. N tau-Methylhistidine release is compared with phenylalanine release in the presence of cycloheximide (phenylalanine release being a measure of degradation of mixed proteins). In hearts perfused with glucose plus acetate, the rate of actin degradation was increased by starvation and was not inhibited by insulin. In contrast, the rate of mixed-protein degradation was decreased by starvation and was inhibited by insulin. The fractional rate of degradation of mixed proteins in hearts from fed or starved rats was greater than that for actin. It is suggested that there are at least two pools of intracellular protein, the degradation rates of which differ in terms of their response to insulin and starvation.     

The effect of calcium on synthesis and degradation of mammary cytosolic proteins and casein

In mammary explants prepared from mid-pregnant rabbits, rates of intracellular and secretory protein synthesis and degradation can be manipulated by the addition or removal of hormones (insulin, prolactin, cortisol). Under both culture conditions, depletion of extracellular calcium with EGTA markedly decreases cytosolic protein synthesis and degradation, and also decreases the rate of synthesis of casein. Culture of explants in calcium-free medium also inhibits cytosolic protein synthesis, but has no significant effect on protein degradation, either in the presence or the absence of hormones. The results suggest that mammary protein synthesis and degradation may be affected by changes in the intracellular concentration or distribution of calcium.     

Glucagon inhibition of insulin-stimulated 2-deoxyglucose uptake by rat adipocytes in the presence of adenosine deaminase.

Effects of adenosine deaminase and glucagon on insulin-stimulated 2-deoxyglucose uptake by rat adipocytes are reported. (1) Adenosine deaminase (10 micrograms/ml) caused a rightward shift in the dose-response curve for the stimulation by insulin of 2-deoxyglucose uptake, but the enzyme did not alter either the basal or the maximally insulin-stimulated uptake rate. (2) In adipocytes obtained from 24 h-starved rats, glucagon inhibited the effect of insulin on 2-deoxyglucose uptake in the presence (but not in the absence) of adenosine deaminase. Basal uptake rates were unaffected. (3) Glucagon inhibited insulin-stimulated 2-deoxyglucose uptake to a greater extent in cells isolated from starved rats than in cells from fed rats. (4) Adipocytes isolated from fed and from starved rats did not differ in their capacity for degradation of 125I-labelled glucagon. The results suggest that adenosine and glucagon are regulators of insulin action in adipose tissue.