Akt substrate of 160 kDa dephosphorylation rate is reduced in insulin-stimulated rat skeletal muscle after acute exercise

Because greater Akt substrate of 160 kDa (AS160) phosphorylation has been reported in insulin-stimulated skeletal muscles without improved Akt activation several hours post-exercise, we hypothesized that prior exercise would result in attenuated AS160 dephosphorylation in insulin-stimulated rat skeletal muscle. Epitrochlearis muscles were isolated from rats that were sedentary (SED) or exercised 3 h earlier (3 h post-exercise; 3hPEX). Paired muscles were incubated with [(3)H]-2-deoxyglucose (2-DG) without insulin or with insulin. Lysates from other insulin-stimulated muscles from SED or 3hPEX rats were evaluated using AS160(Thr642) and AS160(Ser588) dephosphorylation assays. Prior exercise led to greater 2-DG uptake concomitant with greater AS160(Thr642) phosphorylation and a non-significant trend (P=0.087) for greater AS160(Ser588). Prior exercise also reduced AS160(Thr642) and AS160(Ser588) dephosphorylation rates. These results support the idea that attenuated AS160 dephosphorylation may favor greater AS160 phosphorylation post-exercise.

The B2 receptor of bradykinin is not essential for the post-exercise increase in glucose uptake by insulin-stimulated mouse skeletal muscle

Bradykinin can enhance skeletal muscle glucose uptake (GU), and exercise increases both bradykinin production and muscle insulin sensitivity, but bradykinin's relationship with post-exercise insulin action is uncertain. Our primary aim was to determine if the B2 receptor of bradykinin (B2R) is essential for the post-exercise increase in GU by insulin-stimulated mouse soleus muscles. Wildtype (WT) and B2R knockout (B2RKO) mice were sedentary or performed 60 minutes of treadmill exercise. Isolated soleus muscles were incubated with [³H]-2-deoxyglucose +/-insulin (60 or 100 microU/ml). GU tended to be greater for WT vs. B2RKO soleus with 60 microU/ml insulin (P=0.166) and was significantly greater for muscles with 100 microU/ml insulin (P<0.05). Both genotypes had significant exercise-induced reductions (P<0.05) in glycemia and insulinemia, and the decrements for glucose (approximately 14 %) and insulin (approximately 55 %) were similar between genotypes. GU tended to be greater for exercised vs. sedentary soleus with 60 microU/ml insulin (P=0.063) and was significantly greater for muscles with 100 microU/ml insulin (P<0.05). There were no significant interactions between genotype and exercise for blood glucose, plasma insulin or GU. These results indicate that the B2R is not essential for the exercise-induced decrements in blood glucose or plasma insulin or for the post-exercise increase in GU by insulin-stimulated mouse soleus muscle.

Rapid reversal of insulin-stimulated AS160 phosphorylation in rat skeletal muscle after insulin exposure

Increased phosphorylation of Akt substrate of 160 kDa (AS160) is essential to trigger the full increase in insulin-stimulated glucose transport in skeletal muscle. The primary aim of this study was to characterize the time course for reversal of insulin-stimulated AS160 phosphorylation in rat skeletal muscle after insulin removal. The time courses for reversal of insulin effects both upstream (Akt phosphorylation) and downstream (glucose uptake) of AS160 were also determined. Epitrochlearis muscles were incubated in vitro using three protocols which differed with regard to insulin exposure: no insulin (never exposed to insulin), transient insulin (30 min with 1.8 nmol/l insulin, then incubation without insulin for 10, 20 or 40 min), or sustained insulin (continuously incubated with 1.8 nmol/l insulin). After removal of muscles from insulin, Akt and AS160 phosphorylation reversed rapidly, each with a half-time of <10 min and essentially full reversal by 20 min. Glucose uptake reversed more slowly (half time between 10 and 20 min with essentially full reversal by 40 min). Removal of muscles from insulin resulted in a rapid reversal of the increase in AS160 phosphorylation which preceded the reversal of the increase in glucose uptake, consistent with AS160 phosphorylation being essential for maintenance of insulin-stimulated glucose uptake.

Relationship between protein O-linked glycosylation and insulin-stimulated glucose transport in rat skeletal muscle following calorie restriction or exposure to O-(2-acetamido-2-deoxy-d-glucopyranosylidene)amino-N-phenylcarbamate

AIMS AND BACKGROUND

Protein O-linked glycosylation is regulated in vivo by the concentration of hexosamine substrates. Calorie restriction (60% of ad libitum intake) for 20 days causes decreased UDP-N-acetylhexosamine levels and increased insulin-mediated glucose transport in rat skeletal muscle. Conversely, prolonged incubation (19 h) of muscle with O-(2-acetamido-2-deoxy-D-glucopyranosylidene)amino-N-phenyl-carbamate (PUGNAc; an inhibitor of N-acetyl-beta-D-glucosaminidase) is characterized by increased O-linked glycosylation and insulin resistance. We aimed to determine the calorie restriction effect on O-linked glycosylation and characterize the temporal relationship between PUGNAc-induced O-linked glycosylation and insulin resistance.

HYPOTHESIS

A calorie restriction protocol characterized by decreased muscle hexosamine levels will result in a global reduction in O-linked glycosylated proteins in muscle, and PUGNAc-induced insulin resistance will coincide with increased O-linked glycosylation.

METHODS

Plantaris muscle and liver from rats (ad libitum or calorie restricted) were analysed for O-linked glycosylation using two antibodies against different O-linked N-acetylglucosamine epitopes. Also, rat epitrochlearis muscles were incubated for 8.5 h +/- 100 mum PUGNAc prior to measurement of [(3)H]-3-O-methylglucose transport and O-linked glycosylation.

RESULTS

Calorie restriction did not alter protein O-linked glycosylated levels in muscle or liver. Incubation with PUGNAc for 8.5 h resulted in increased in O-linked glycosylation but unaltered basal or insulin-stimulated glucose transport.

CONCLUSIONS

The delay between O-linked glycosylation and insulin resistance in muscle incubated with PUGNAc suggests an indirect, relatively slow mechanism for insulin resistance. The effect of calorie restriction on insulin action in muscle is unlikely to be the direct result of a global change in protein O-linked glycosylation.

Role of kallikrein-kininogen system in insulin-stimulated glucose transport after muscle contractions

Serum proteins [molecular weight (MW) > 10,000] are essential for increased insulin-stimulated glucose transport after in vitro muscle contractions. We investigated the role of the kallikrein-kininogen system, including bradykinin, which is derived from kallikrein (MW > 10,000)-catalyzed degradation of serum protein kininogen (MW > 10,000), on this contraction effect. In vitro electrical stimulation of rat epitrochlearis muscles was performed in 1) rat serum +/- kallikrein inhibitors; 2) human plasma (normal or kallikrein-deficient); 3) rat serum +/- bradykinin receptor-2 inhibitors; or 4) serum-free buffer +/- bradykinin. 3-O-methylglucose transport (3-MGT) was measured 3.5 h later. Serum +/- kallikrein inhibitors tended (P = 0.08) to diminish postcontraction insulin-stimulated 3-MGT. Contractions in normal plasma enhanced insulin-stimulated 3-MGT vs. controls, but contractions in kallikrein-deficient plasma did not. Supplementing rat serum with bradykinin receptor antagonist HOE-140 during contraction did not alter insulin-stimulated 3-MGT. Muscles stimulated to contract in serum-free buffer plus bradykinin did not have enhanced insulin-stimulated 3-MGT. Bradykinin was insufficient for postcontraction-enhanced insulin sensitivity. However, results with kallikrein inhibitors and kallikrein-deficient plasma suggest kallikrein plays a role in this improved insulin action.

Absence of insulin receptor substrate-1 expression does not alter GLUT1 or GLUT4 abundance or contraction-stimulated glucose uptake by mouse skeletal muscle

The purpose of this study was to determine the influence of insulin receptor substrate-1 (IRS-1) expression on GLUT1 and GLUT4 glucose transporter protein abundance, contraction-stimulated glucose uptake, and contraction-induced glycogen depletion by skeletal muscle. Mice (6 months old) from three genotypes were studied: wild-type (IRS-1(+/+)), heterozygous (IRS-1(+/-)) for the null allele, and IRS-1 knockouts (IRS-1(-/-)) lacking a functional IRS-1 gene. In situ muscle contraction was induced (electrical stimulation of sciatic nerve) in one hindlimb using contralateral muscles as controls. Soleus and extensor digitorum longus were dissected and 2-deoxyglucose uptake was measured in vitro. 2-Deoxyglucose uptake was higher in basal muscles (no contractions) from IRS-1(-/-) vs. both other genotypes. Contraction-stimulated 2-deoxyglucose uptake and glycogen depletion did not differ among genotypes. Muscle IRS-1 protein was undetectable for IRS-1(-/-) mice, and values were approximately 40 % lower in IRS-1(+/-) than in IRS-1(+/+) mice. No difference was found in IRS-1(+/+) compared to IRS-1(-/-) groups regarding muscle abundance of GLUT1 and GLUT4. Substantial reduction or elimination of IRS-1 did not alter the hallmark effects of contractions on muscle carbohydrate metabolism--activation of glucose uptake and glycogen depletion.

Exercise training eliminates age-related differences in skeletal muscle insulin receptor and IRS-1 abundance in rats

Insulin resistance is common in old age, and exercise training can improve insulin sensitivity. The purpose of this study was to determine the influence of age (6 vs 26 months) and exercise training (10 weeks of treadmill running) on insulin signaling protein abundance in skeletal muscle from male Fisher 344 rats. Muscle levels of insulin receptor (IR), insulin receptor substrate-1 (IRS-1), phosphatidylinositol 3-kinase (PI3K), and Akt1, a serine-threonine kinase, were determined. IRS-1 was reduced with aging, IR and PI3K abundance was greater in old rats, and Akt1 was unchanged. IRS-1 was increased by training in old but not young rats, and IR was increased by training in young but not old rats. PI3K tended to increase and Akt1 did not change with training, regardless of age. Aging does not uniformly affect insulin signaling protein abundance, and exercise differentially alters IR and IRS-1 in young and old rats, thereby eliminating age-related differences in these proteins.

Genetic selection of mice for high voluntary wheel running: effect on skeletal muscle glucose uptake

Effects of genetic selection for high wheel-running activity (17th generation) and access to running wheels on skeletal muscle glucose uptake were studied in mice with the following treatments for 8 wk: 1) access to unlocked wheels; 2) same as 1, but wheels locked 48 h before glucose uptake measurement; or 3) wheels always locked. Selected mice ran more than random-bred (nonselected) mice (8-wk mean +/- SE = 8,243 +/- 711 vs. 3,719 +/- 233 revolutions/day). Body weight was 5-13% lower for selected vs. nonselected groups. Fat pad/body weight was ~40% lower for selected vs. nonselected and unlocked vs. locked groups. Insulin-stimulated glucose uptake and fat pad/body weight were inversely correlated for isolated soleus (r = -0.333; P < 0.005) but not extensor digitorum longus (EDL) or epitrochlearis muscles. Insulin-stimulated glucose uptake was higher in EDL (P < 0.02) for selected vs. nonselected mice. Glucose uptake did not differ by wheel group, and amount of running did not correlate with glucose uptake for any muscle. Wheel running by mice did not enhance subsequent glucose uptake by isolated muscles.

Calorie restriction increases insulin-stimulated tyrosine phosphorylation of insulin receptor and insulin receptor substrate-1 in rat skeletal muscle

A moderate reduction in calorie intake (calorie restriction, CR) improves insulin-stimulated glucose transport in skeletal muscle. Therefore, we studied muscle insulin signalling in ad libitum (AL) and CR ( approximately 60% AL intake for 20 days) fed rats, which received a control injection (sterile water) or an insulin injection (30 U kg-1 body weight). In control (not insulin-treated) rats, there was no detectable tyrosine phosphorylation of insulin receptor (IR), regardless of diet; no diet effect on tyrosine phosphorylation of insulin receptor substrate-1 (IRS1) or IRS1-associated phosphatidylinositol 3-kinase (PI3K) protein and 21% higher IRS1-associated PI3K activity in AL vs. CR. In insulin-treated rats, tyrosine-phosphorylated IR was 79% higher for CR vs. AL; tyrosine-phosphorylated IRS1 was 109% higher for CR vs. AL; IRS1-associated PI3K protein and IRS1-associated PI3K activity were unaffected by diet. Calorie restriction amplifies early insulin signalling steps without changing IRS1-associated PI3K, suggesting enhanced glucose transport is mediated by altering: IRS1-PI3K localization, PI3K associated with proteins other than IRS1 or post-PI3K events.

Lower calorie intake enhances muscle insulin action and reduces hexosamine levels

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.

Effect of long-term caloric restriction on GLUT4, phosphatidylinositol-3 kinase p85 subunit, and insulin receptor substrate-1 protein levels in rhesus monkey skeletal muscle

Caloric restriction (CR), a reduction in calorie intake without malnutrition, improves insulin sensitivity in various species, including mice, rats, rhesus and cynomolgus monkeys, and humans. Skeletal muscle is quantitatively the most important tissue for blood glucose clearance. Therefore, we assessed the effect of 6 years of CR (30% reduction in calorie intake) in male rhesus monkeys (14-20 years old) on muscle expression of several proteins involved in insulin action. Whole body insulin sensitivity (assessed by Modified Minimal Model) was significantly increased in CR relative to Control monkeys. CR did not alter the expression of GLUT4 glucose transporter or phosphatidylinositol-3 kinase p85 subunit (PI3K). Insulin receptor substrate-1(IRS-1) abundance tended to be greater for CR compared to Control monkeys (p = .051), but correlational analysis revealed no association between IRS-1 and insulin sensitivity (r2 = .075, p = .271). These findings indicate that the CR-induced increase in insulin sensitivity in rhesus monkeys is unrelated to alterations in GLUT4, P13K, and IRS-1 abundance.

Calorie restriction increases insulin-stimulated glucose transport in skeletal muscle from IRS-1 knockout mice

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.

Effect of calorie restriction on in vivo glucose metabolism by individual tissues in rats

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) F344xBN rats. Glucose metabolism was assessed by the 2-[3H]deoxyglucose tracer technique at 1500 or 2100. Despite an approximately 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 (R'g) 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), R'g was unaffected by diet, regardless of time. In the other tissues (brown fat, 3 white fat pads, epitrochlearis, plantaris, and gastrocnemius), R'g 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.

Calorie restriction increases cell surface GLUT-4 in insulin-stimulated skeletal muscle

Reduced calorie intake [calorie restriction (CR); 60% of ad libitum (AL)] leads to enhanced glucose transport without altering total GLUT-4 glucose transporter abundance in skeletal muscle. Therefore, we tested the hypothesis that CR (20 days) alters the subcellular distribution of GLUT-4. Cell surface GLUT-4 content was higher in insulin-stimulated epitrochlearis muscles from CR vs. AL rats. The magnitude of this increase was similar to the CR-induced increase in glucose transport, and GLUT-4 activity (glucose transport rate divided by cell surface GLUT-4) was unaffected by diet. The CR effect was specific to the insulin-mediated pathway, as evidenced by the observations that basal glucose transport and cell surface GLUT-4 content, as well as hypoxia-stimulated glucose transport, were unchanged by diet. CR did not alter insulin's stimulation of insulin receptor substrate (IRS)-1-associated phosphatidylinositol 3-kinase (PI3K) activity. Muscle abundance of IRS-2 and p85 subunit of PI3K were unaltered by diet, but IRS-1 content was lower in CR vs. AL. These data demonstrate that, despite IRS-1-PI3K activity similar to AL, CR specifically increases insulin's activation of glucose transport by enhancing the steady-state proportion of GLUT-4 residing on the cell surface.

Effect of extracellular palmitate on 2-deoxy-d-glucose uptake in muscle from Ad libitum fed and calorie restricted rats

We studied the effect of a high physiologic concentration of palmitate (1mM) on in vitro 2-deoxy-D-glucose (2DG) uptake by flexor digitorum brevis (FDB) muscle from ad libitum fed rats (AL) and rats fed 60% of ad libitum intake (CR) for 20 days. CR did not alter muscle 2DG uptake in the absence of insulin, but relative to AL, CR significantly (p<0.01) increased 2DG uptake in the presence of 20,000 microU/ml insulin. This effect of CR persisted in the presence of 1mM palmitate. The presence of 1mM palmitate significantly (p<0.01) impaired 2DG glucose uptake, both in the presence and absence of insulin, to the same extent in AL and CR muscle, despite an 18% decrease in FABPpm expression with CR. Thus, although CR profoundly affects insulin-mediated muscle glucose uptake, it does not alter the ability of extracellular fatty acid to modulate glucose utilization by skeletal muscle.

Comparison of the effects of 20 days and 15 months of calorie restriction on male Fischer 344 rats

The aim of this study was to compare, in 19-month-old male Fischer 344 rats, the influence of brief (20 days) and prolonged (approximately 15 months) calorie restriction (CR; consuming approximately 60% of ad libitum, AL, intake) on circulating levels of glucose, insulin, C-peptide, and free fatty acids (FFA); age-matched AL rats were also studied. In the prolonged CR group, there was an approximately 85% decline in fat pad masses (epididymal and retroperitoneal) compared to AL and brief CR rats (these latter groups did not differ significantly). Compared to AL levels, glucose was 15% lower with prolonged CR (p < 0.05) while the brief CR values tended to be lower (10%) than AL; the CR groups did not differ significantly. Plasma FFA levels were significantly (p < 0.05) greater (85-106%) in the brief CR group compared to each of the other groups. Plasma insulin concentrations for the CR groups were lower (p < 0.05; approximately 50-60%) than AL levels. Plasma concentrations of C-peptide (an indicator of insulin secretion) were also lower for each CR group vs AL levels, and a high correlation was found between plasma insulin and C-peptide concentrations (r2 = 0.90; p < 0.001). The C-peptide/insulin ratios for the CR groups were similar, and the value of each CR group exceeded that for the AL rats. These results demonstrate that: the CR-induced reduction in plasma insulin is attributable in large part to reduced insulin secretion; these decreases in insulin secretion and concentration are essentially undiminished when brief CR is initiated rather late in life, and the reductions are independent of substantial reductions in body fat.

Interaction between BTBR and C57BL/6J genomes produces an insulin resistance syndrome in (BTBR x C57BL/6J) F1 mice

Insulin resistance is a common syndrome that often precedes the development of noninsulin-dependent diabetes mellitus (NIDDM). Both diet and genetic factors are associated with insulin resistance. BTBR and C57BL/6J (B6) mice have normal insulin responsiveness and normal fasting plasma insulin levels. However, a cross between these two strains yielded male offspring with severe insulin resistance. Surprisingly, on a basal diet (6.5% fat), the insulin resistance was not associated with fasting hyperinsulinemia. However, a 15% fat diet produced significant hyperinsulinemia in the male mice (twofold at 10 weeks; P < .05). At 10 weeks of age, visceral fat contributed approximately 4.3% of the total body weight in the males versus 1.8% in females. In the males, levels of plasma triacylglycerol and total cholesterol increased 40% and 30%, respectively, compared to females. Plasma free fatty acid concentrations were unchanged. Oral glucose tolerance tests revealed significant levels of hyperglycemia and hyperinsulinemia 15 to 90 minutes after oral glucose administration in the male mice. This was particularly dramatic in males on a 15% fat diet. Glucose transport was examined in skeletal muscles in (BTBR x B6)F1 mice. In the nonhyperinsulinemic animals (females), insulin stimulated 2-deoxyglucose transport 3.5-fold in the soleus and 2.8-fold in the extensor digitorum longus muscles. By contrast, glucose transport was not stimulated in the hyperinsulinemic male mice. Hypoxia stimulates glucose transport through an insulin-independent mechanism. This is known to involve the translocation of GLUT4 from an intracellular pool to the plasma membrane. In the insulin-resistant male mice, hypoxia induced glucose transport as effectively as it did in the insulin-responsive mice. Thus, defective glucose transport in the (BTBR x B6)F1 mice is specific for insulin-stimulated glucose transport. This is similar to what has been observed in muscles taken from obese NIDDM patients. These animals represent an excellent genetic model for studying insulin resistance and investigating the transition from insulin resistance in the absence of hyperinsulinemia to insulin resistance with hyperinsulinemia.

Decline in muscle insulin-dependent and -independent glucose uptake but not GLUT-4 in 21- vs. 28-day-old rats

The most rapid age-related decrease in insulin-stimulated glucose uptake in skeletal muscle occurs between 3 and 5 wk of age in rats. Therefore, we studied unstimulated, insulin-stimulated, and in vitro hypoxia-stimulated 2-deoxy-D-[G-3H]glucose (2-DG) uptake in isolated soleus, flexor digitorum brevis (FDB), and epitrochlearis muscles from rats at 21, 28, and 35 days of age. Age-related decrements in insulin- (approximately 40-60%) and hypoxia-stimulated (approximately 50%) 2-DG uptake occurred in all muscles, and most of the decline was evident by 28 days. Unstimulated 2-DG uptake declined significantly with advancing age in the epitrochlearis (73%) and FDB (60%) and tended to decrease in the soleus (38%). The time course and relative magnitude of these decrements were similar under unstimulated, insulin-stimulated, and hypoxic conditions. GLUT-4 protein concentration was unaltered by age in each muscle. These results indicate that a substantial age-related decrement in 2-DG uptake occurs in several limb muscles from rats at 21 vs. 28-35 days by a mechanism that is independent of GLUT-4 levels and not specific for the insulin-dependent pathway.

Cortical elasticity in aging rats with and without growth hormone treatments

This study quantified the orthotropic elastic changes in cortical bone due to aging as well as determined any elastic changes after acute treatments of growth hormone (GH). Three groups of twenty rats represented three age groups of young adult (9 months), middle age (20 months), and old (31 months) rats. During a ten day period, half of the rats in each age group were given twice-daily doses of recombinant human GH while the remaining half were injected with a vehicle control (saline). The effects of aging and GH on the elastic characteristics of cortical bone were quantified via ultrasonic wave propagation. Propagation velocities of longitudinal and shear waves were measured through cubic cortical specimens from the posterior femoral diaphysis. Density was measured by Archimedes' technique. The normalized, orthotropic elastic properties of Young's moduli (Eii), shear moduli (Gij), and Poisson's ratios (Vij) were calculated and used to compare the groups (where i and j = 1, 2, or 3 reference the radial, circumferential, and longitudinal axes, respectively). Cortical elastic moduli consistently increased with age with the strongest effects demonstrated in radial dependent properties such as E11 (+ 25.3% from 9 to 31 months, p = 0.0004) and G12 (+ 12.6% from 20 to 31 months, p = 0.0419). The ratio of transverse to axial displacement (Poisson's ratio) typically decreased with age (9 to 31 months) as seen in V31 (-24.95%, p = 0.0134) and V32 (-20.7%, p = 0.0015). Overall, a ten day treatment with GH produced no global statistical change in elastic properties (p > 0.05). However, GH did minimize the age related differences that were measured for E22, E33, and V32 between the 9 and 31 month old groups essentially returning old bone to its youthful elastic state. These finding add orthotropic detail to the current understanding of changing cortical elastic properties during aging as well as providing a reference for further studies of GH.

Growth hormone supplementation increases skeletal muscle mass of old male Fischer 344/brown Norway rats

Growth hormone (GH) supplementation can increase the body weight of old rats, but the individual tissues affected were previously unidentified. Therefore, the masses of the heart, spleen, kidney, epididymal fat pads, and five skeletal muscles were assessed in male Fischer 344/Brown Norway rats (9, 20, 31, months) injected with recombinant human GH (0.7 mg/kg) or vehicle twice daily for 10 days. Muscle composition (fiber type, protein concentration, dry weight/wet weight ratio, citrate synthase activity) was also evaluated. Muscle mass was increased with GH treatment, and this increment was undiminished in old age. Fiber type, protein concentration, and dry weight/wet weight ratio were unaffected by GH. Citrate synthase activity declined in the plantaris and increased in the soleus with GH treatment. GH supplementation elevated heart and spleen mass, but not fat pad or kidney weight. The data demonstrate that the capacity for GH-induced hypertrophy of skeletal muscle, myocardium, and spleen is retained during old age.

Brief dietary restriction increases skeletal muscle glucose transport in old Fischer 344 rats

The primary purpose of this study was to determine the impact of brief dietary restriction (DR; 5 or 20 days) on skeletal muscle glucose transport activity (GTA) of 24-month-old female Fischer 344 rats. Basal GTA of isolated epitrochlearis muscles was unaffected by DR. Insulin-stimulated GTA was significantly increased by DR only at 20 days (51%). We also assessed the influence of DR on energy sources (blood-borne and stored). An approximately 20% decline in glycemia occurred in each DR group, but plasma-free fatty acid and beta-hydroxybutyrate concentrations were unaffected. Plasma insulin was reduced by 50% after 20 days. Hepatic glycogen was rapidly mobilized (-69% at 5 days; -83% at 20 days). The depletions of visceral adipose stores was slower (no significant decline at 5 days; -30% at 20 days), but the eventual reduction accounts for a significant amount of energy. The results demonstrate that muscle from old rats can rapidly upregulate GTA in response to brief DR. The relative magnitude of this increase represents a substantial portion of the increases previously observed after prolonged DR.

What insights into age-related changes in skeletal muscle are provided by animal models?

This review addresses the following questions: (a) How do the age-related changes in muscle of animal models compare to those found in human muscle?, and (b) How do the changes characteristic of models for reduced or altered muscle use compare to the age-related changes in muscle? Regarding the first question, the vast majority of relevant animal research has focused on the rodents, and the age-related changes in rodent muscle are in many respects reminiscent of human aging. A possible difference is the existence of a more profound hypoplasia in human muscle. Research into the age-related changes in muscle in other species is extremely scarce. Regarding the second question, various experimental conditions of reduced or altered muscle use (e.g., denervation, limb immobilization, hindlimb suspension) offer valuable insight not because they exactly mimic normal aging; rather, they demonstrate the multifactorial nature of processes leading to muscle atrophy.

Growth hormone reduces glucose transport but not GLUT-1 or GLUT-4 in adult and old rats

The primary purpose of this study was to investigate the influence of administration of recombinant-derived human growth hormone (rhGH) to adult male rats of several ages (9, 20, and 31 mo) on skeletal muscle glucose transport. Rats were injected with rhGH (0.7 mg/kg) or vehicle twice daily for 10 days. The rhGH treatment led to a doubling of circulating insulin-like growth factor I levels at each age. Skeletal muscle glucose transport activity was evaluated in isolated epitrochlearis muscle with use of 3-O-methylglucose at three insulin concentrations (0, 100, and 20,000 microU/ml). The results indicate that, after 10 days of rhGH administration, 1) an approximately 20-30% reduction in basal glucose transport activity was evident in muscles from every age group, 2) the ability of a submaximally effective insulin concentration (100 microU/ml) to increase glucose transport activity above basal values was not significantly reduced in any age group, 3) maximal insulin-stimulated glucose transport activity (with 20,000 microU/ml) was significantly reduced (approximately 40%) by rhGH treatment only in the oldest rats, and 4) the alterations in glucose transport activity occurred despite no change in skeletal muscle GLUT-1 or GLUT-4 protein levels.

Glucose transport with brief dietary restriction: heterogenous responses in muscles

The time course (1, 5, or 20 days) for the effect of dietary restriction (DR; approximately 25% reduction below ad libitum intake) on epitrochlearis and flexor digitorum brevis (FDB) muscle glucose transport activity was studied in female Fischer 344 rats (8 mo old). Epitrochlearis glucose transport activity with 100 microU/ml insulin was increased by 38% after 5 days of DR (P < 0.05) despite no change in glucose transport activity with 0 or 20,000 microU/ml insulin. The increase with 100 microU/ml insulin was not further enhanced by 20 days of DR. DR did not result in a significant increase in the glucose transport activity of the FDB with 0, 100, or 20,000 microU/ml insulin. Abdominal fat content was significantly (P < 0.01) reduced below ad libitum levels only after 20 days of DR. These results demonstrate that DR-induced improvement in epitrochlearis glucose transport activity with a physiological insulin concentration can occur very rapidly, preceding detectable changes in basal or maximal insulin-stimulated glucose transport activity or abdominal fat pad mass, and the enhancement of insulin action does not occur simultaneously in all muscles.

Influence of age on skeletal muscle glucose transport and glycogen metabolism

Age-related alterations in skeletal muscle carbohydrate metabolism can influence both health and performance. Exercising muscle glycogenolysis is accelerated in old, male rats compared with young animals, perhaps secondary to the age-related reduction in muscle oxidative capacity and blood flow during contractile activity. Muscle oxidative capacity and blood flow during exercise are also reduced in untrained older humans. Endurance training enhances muscle oxidative capacity and promotes muscle glycogen sparing during exercise by young and old rats. Resting muscle glycogen concentration is unchanged in old rats, but considerably reduced in untrained, older humans. Exercise training increases the muscle glycogen levels of older people. The concentration of GLUT-4 glucose transporter protein declines in some muscles of rats during growth and development, but remains stable thereafter. Exercise training can elevate the muscle GLUT-4 protein levels of both young and old humans. On the other hand, exercise training has been shown to increase the GLUT-4 values of adult, but not old rats. After one bout of exercise, muscle sensitivity for insulin-stimulated glucose transport is improved in young and old rats. These findings indicate that several age-related changes in muscle carbohydrate metabolism can be minimized by acute or chronic exercise.

Adaptation of muscle glucose transport with caloric restriction in adult, middle-aged, and old rats

The effects of prolonged caloric restriction (60% of ad libitum intake initiated at 14 wk of age) on glucose transport activity in isolated epitrochlearis muscles were studied in female Fischer 344 rats aged 8, 18, and 23 mo. Basal 3-O-methylglucose transport (3-MG) rate (without insulin) was not significantly altered by caloric restriction. With a submaximally effective insulin concentration (75 microU/ml), 3-MG transport was enhanced in the caloric-restricted groups by 59, 59, and 105% at 8, 18, and 23 mo of age, respectively. With a maximally effective insulin concentration (20,000 microU/ml), 3-MG transport was increased after caloric restriction, despite no change in muscle GLUT4 glucose transporter protein content. These results indicate that chronic caloric restriction enhances insulin stimulation of the glucose transport system independent of changes in basal glucose transport or muscle GLUT4 levels, and insulin-stimulated glucose transport is enhanced in rats with chronic caloric restriction at least until 23 mo of age.

Myocardial glucose transporters and glycolytic metabolism during ischemia in hyperglycemic diabetic swine

We assessed the effects of 4 weeks of streptozocin-induced diabetes on regional myocardial glycolytic metabolism during ischemia in anesthetized open-chest domestic swine. Diabetic animals were hyperglycemic (12.0 +/- 2.1 v 6.6 +/- .5 mmol/L), and had lower fasting insulin levels (27 +/- 8 v 79 +/- 19 pmol/L). Myocardial glycolytic metabolism was studied with coronary flow controlled by an extracorporeal perfusion circuit. Left anterior descending coronary artery (LAD) flow was decreased by 50% for 45 minutes and left circumflex (CFX) flow was constant. Myocardial glucose uptake and extraction were measured with D-[6-3H]-2-deoxyglucose (DG) and myocardial blood flow was measured with microspheres. The rate of glucose conversion to lactate and lactate uptake and output were assessed with a continuous infusion of [6-14C]glucose and [U-13C]lactate into the coronary perfusion circuit. Both diabetic and nondiabetic animals had sharp decreases in subendocardial blood flow during ischemia (from 1.21 +/- .10 to 0.43 +/- .08 mL.g-1.min-1 in the nondiabetic group, and from 1.30 +/- .15 to 0.55 +/- .11 in the diabetic group). Diabetes had no significant effect on myocardial glucose uptake or glucose conversion to lactate under either well-perfused or ischemic conditions. Forty-five minutes of ischemia resulted in significant glycogen depletion in the subendocardium in both nondiabetic and diabetic animals, with no differences between the two groups. Glycolytic metabolism is not impaired in hyperglycemic diabetic swine after 1 month of the disease when compared with that in normoglycemic nondiabetic animals. The myocardial content of the insulin-regulatable glucose transporter (GLUT 4) was measured in left ventricular biopsies.(ABSTRACT TRUNCATED AT 250 WORDS)

Exercise training does not compensate for age-related decrease in myocardial GLUT-4 content

We assessed the effects of age and endurance exercise training (treadmill running at 75% maximal running capacity, 1 h/day, 5 days/wk for 10 wk) on the total concentration of insulin-regulatable glucose transporters (GLUT-4) and GLUT-4 mRNA levels in the myocardium of male Fischer 344 rats aged 7, 15, and 25 mo. Myocardial GLUT-4 concentration was quantified with sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blotting and detected with a polyclonal antibody to the GLUT-4 transporter. Myocardial GLUT-4 mRNA levels were quantified with slot-blot analysis and a cDNA probe for GLUT-4. Myocardial GLUT-4 concentration in the 25-mo group decreased 27 and 20% compared with the 7- and 15-mo group, respectively (P < 0.0001 and P < 0.003). GLUT-4 mRNA also decreased significantly in the 25-mo group compared with the 7-mo group (20% in the trained and 11% in the untrained group, P < 0.05). Endurance training did not significantly affect myocardial GLUT-4 concentrations in any age group despite a significant increase in GLUT-4 mRNA in the 7- and 25-mo trained groups. In conclusion, myocardial GLUT-4 protein levels in the rat are significantly decreased with age but are unaffected by 10 wk of treadmill running.

Persistent effects of exercise on skeletal muscle glucose transport across the life-span of rats

Very young rats (< 2 mo) have a persistent increase in insulin-stimulated glucose transport rate in skeletal muscle for several hours after completing a bout of exercise. We studied the effect of exercise on the glucose transport activity of isolated epitrochlearis muscles from male Fischer 344/Brown Norway F1 hybrid rats across a wide range of the life-span (at 3.5, 13, and 25 mo). The stimulation of 3-O-methylglucose (3-MG) accumulation by a submaximally effective insulin concentration (100 microU/ml) was enhanced (50-75%) 4 h after exercise, regardless of age. In contrast, the 3-MG transport rate with 20,000 microU/ml insulin was enhanced after exercise only in the youngest rats (35%), and this increased responsiveness occurred despite no changes in muscle total GLUT-4 levels. In addition, epitrochlearis GLUT-4 levels were reduced by 29% between 3.5 and 13 mo of age in sedentary rats but did not decline further between 13 and 25 mo of age. GLUT-4 levels were moderately but significantly (P < 0.05) related (r = 0.554) to epitrochlearis muscle capacity for insulin-stimulated 3-MG transport.

Myocardial GLUT-4 glucose transporter protein levels of rats decline with advancing age

Age-related changes in glucose metabolism and glucose transporter protein content have been described in adipose tissue and skeletal muscle, two tissues that express the GLUT-4 isoform of the glucose transporter protein. I studied the effect of age on the levels of GLUT-4 protein in a third insulin-sensitive tissue: the heart. Cardiac ventricles were sampled from male Fischer 344/Brown Norway F1 hybrid (F344/BNNia) rats. The total protein concentration of the left ventricle did not change with age. GLUT-4 levels per mg of protein declined by 15% between 3.5 and 13 months of age, and by another 12% during adulthood (between 13 and 25 months of age); when expressed per g wet weight, the decreases were 13% and 17%, respectively. Linear regression analysis revealed a significant (p < .0001) relationship (r2 = .634) between age and myocardial GLUT-4. These results demonstrate that the GLUT-4 levels in the left ventricle decrease in an age-related fashion and suggest that the capacity for glucose transport might also be reduced.

Hypoxia causes glycogenolysis without an increase in percent phosphorylase a in rat skeletal muscle

Stimulation of skeletal muscle to contract activates phosphorylase b-to-a conversion and glycogenolysis. Despite reversal of the increase in percentage of phosphorylase a after a few minutes, continued glycogen breakdown can occur during strenuous exercise. Hypoxia causes sustained glycogenolysis in skeletal muscle without an increase in percentage of phosphorylase a. We used this model to obtain insights regarding how glycogenolysis is mediated in the absence of an increase in percentage of phosphorylase a. Hypoxia caused a 70% decrease in glycogen in epitrochlearis muscles during an 80-min incubation despite no increase in percentage of phosphorylase a above the basal level of approximately 10%. Muscle Pi concentration increased from 3.8 to 8.6 mumol/g muscle after 5 min and 15.7 mumol/g after 20 min. AMP concentration doubled, attaining a steady state of 0.23 mumol/g in 5 min. Incubation of oxygenated muscles with 0.1 microM epinephrine induced an approximately sixfold increase in percentage of phosphorylase a but resulted in minimal glycogenolysis. Muscle Pi concentration was not altered by epinephrine. Despite no increase in percentage of phosphorylase a, hypoxia resulted in a fivefold greater depletion of glycogen over 20 min than did epinephrine. To evaluate the role of phosphorylase b, muscles were loaded with 2-deoxyglucose 6-phosphate, which inhibits phosphorylase b. The rate of glycogenolysis during 60 min of hypoxia was reduced by only approximately 14% in 2-deoxyglucose 6-phosphate-loaded muscles.(ABSTRACT TRUNCATED AT 250 WORDS)

Diverse effects of calcium channel blockers on skeletal muscle glucose transport

Verapamil, a calcium channel blocker, inhibited the insulin-stimulated glucose transport rate in isolated rat epitrochlearis muscle in a dose-dependent manner (1-200 microM) without affecting basal glucose transport rate. Verapamil's inhibition was rapid in onset and disappearance; changes in glucose transport rate were detectable when verapamil was added to or removed from the incubation medium 15 min prior to measurement of glucose transport. Verapamil also inhibited the stimulation of muscle glucose transport caused by hypoxia, indicating that the effect was not limited to insulin action. Although the optical isomers of verapamil vary considerably in their potency as Ca2+ channel blockers, they were equally effective inhibitors of insulin-stimulated glucose transport rate. Nifedipine (10-200 microM), a more potent blocker of skeletal muscle Ca2+ channels than verapamil, was less effective as an inhibitor of insulin-stimulated glucose transport. Furthermore, nifedipine (10 microM) did not inhibit hypoxia-stimulated glucose transport. Diltiazem (200 microM), another Ca2+ channel blocker, did not reduce insulin-stimulated glucose transport.

Skeletal muscle atrophy in old rats: differential changes in the three fiber types

This study was undertaken to reevaluate the effects of ageing on skeletal muscle mass and on mitochondrial and glycolytic enzyme levels in the different types of skeletal muscle in rats. It was found that some muscles atrophy with ageing, while others do not, in male rats. Atrophy appears to occur in weight-bearing muscles, and is most marked in those with a high proportion of type IIb fibers. The muscles that did not atrophy are non-weight-bearing, and include the epitrochlearis (predominantly type IIb fibers) and the adductor longus (predominantly type I fibers). The average cross-sectional area of muscle fibers in the plantaris muscles of 28-30-month-old rats was approximately 30% smaller than that of 9-10-month-old animals, providing evidence that the approximately 30% lower weight of the plantaris in the old group was entirely due to fiber atrophy. The proportion of type IIa fibers was decreased and the proportion of type I fibers was increased in the plantaris of the old rats. The respiratory capacity of the soleus muscle (predominantly type I fibers), and the glycolytic capacity of the superficial, white (type IIb) and deep, red (predominantly type IIa) portions of the vastus lateralis, were reduced in the old rats. Our results provide evidence that ageing has differential effects on the three types of skeletal muscle fiber, and on weight-bearing and non-weight-bearing muscles, in the rat.

Prolonged incubation of skeletal muscle in vitro: prevention of increases in glucose transport

During experiments involving prolonged incubation of skeletal muscle, we observed large increases in glucose transport activity. The basal rate of 3-O-methylglucose (3-MG) transport increased two- to fourfold in rat epitrochlearis muscles incubated for 9 h without insulin in Krebs-Henseleit buffer supplemented with 8 mM glucose. The stimulatory effect of a low concentration of insulin (30 microU/ml, added during the final 30 or 60 min of incubation) on glucose transport activity was enhanced 2.5-fold after 6 h and approximately 5-fold after 9 h of incubation. Exposure of muscles to 100 microU/ml of insulin for the first 8 h inhibited slightly but significantly the increase in insulin-stimulated 3-MG transport over a 9-h incubation period. Incubation of muscles in minimal essential medium (MEM) for 9 h inhibited the time-dependent rise in basal and insulin-stimulated transport by approximately 45%. The effect of MEM was reproduced with MEM essential, but not nonessential, amino acids. Incubation of muscles with MEM plus 100 microU/ml of insulin for the first 8 h prevented the increases in 3-MG transport activity measured after a 9-h incubation period. Muscles incubated for 9 h maintained ATP and phosphocreatine concentrations, and changes in glycogen concentrations were small. Thus we have defined conditions for long-term incubation of skeletal muscle under which a progressive increase in glucose transport is prevented.

Stimulation of glucose transport in skeletal muscle by hypoxia

Hypoxia caused a progressive cytochalasin B-inhibitable increase in the rate of 3-O-methylglucose transport in rat epitrochlearis muscles to a level approximately six-fold above basal. Muscle ATP concentration was well maintained during hypoxia, and increased glucose transport activity was still present after 15 min of reoxygenation despite repletion of phosphocreatine. However, the increase in glucose transport activity completely reversed during a 180-min-long recovery in oxygenated medium. In perfused rat hindlimb muscles, hypoxia caused an increase in glucose transporters in the plasma membrane, suggesting that glucose transporter translocation plays a role in the stimulation of glucose transport by hypoxia. The maximal effects of hypoxia and insulin on glucose transport activity were additive, whereas the effects of exercise and hypoxia were not, providing evidence suggesting that hypoxia and exercise stimulate glucose transport by the same mechanism. Caffeine, at a concentration too low to cause muscle contraction or an increase in glucose transport by itself, markedly potentiated the effect of a submaximal hypoxic stimulus on sugar transport. Dantrolene significantly inhibited the hypoxia-induced increase in 3-O-methylglucose transport. These effects of caffeine and dantrolene suggest that Ca2+ plays a role in the stimulation of glucose transport by hypoxia.

Prolonged incubation of skeletal muscle increases system A amino acid transport

During the course of experiments involving prolonged incubation of skeletal muscle, we observed large increases in system A amino acid transport activity. System A activity was monitored with the nonmetabolizable amino acid analogue alpha-(methylamino)isobutyrate (MeAIB). When rat epitrochlearis muscles are incubated in Krebs-Henseleit buffer supplemented with 0.1% bovine serum albumin and 8 mM glucose, basal MeAIB transport doubles after 5 h and is elevated approximately sevenfold after 9 h compared with rates measured in muscles incubated for 1 h. Insulin-stimulated transport also doubles after 5 h and increases by fourfold after 9 h. The increases in basal and insulin-stimulated system A transport over time can be prevented by incubating muscles in the presence of cycloheximide. Addition of minimum essential medium essential amino acids (EAA) to the incubation medium blocks the increase in basal and insulin-stimulated MeAIB transport measured after 9 h by 85-90 and 60%, respectively. A single amino acid, glutamine, can account for half of the inhibitory effect of EAA on the time-dependent increase in basal system A transport. Amino acid metabolism is not necessary for inhibition of the rise in basal MeAIB transport. At concentrations normally present in minimum essential medium, nonessential amino acids are less effective (51% inhibition) in preventing the rise in basal transport occurring over 9 h. At three times normal concentrations, however, the ability of nonessential amino acids to prevent the time-dependent increases in basal and insulin-stimulated MeAIB transport is comparable to that of EAA. These changes in MeAIB transport with prolonged incubation are not due to muscle deterioration.(ABSTRACT TRUNCATED AT 250 WORDS)

Reversal of enhanced muscle glucose transport after exercise: roles of insulin and glucose

Exercise stimulates insulin-independent glucose transport in skeletal muscle and also increases the sensitivity of the glucose transport process in muscle to insulin. A previous study [D. A. Young, H. Wallberg-Henriksson, M. D. Sleeper, and J. O. Holloszy. Am. J. Physiol. 253 (Endocrinol. Metab. 16): E331-E335, 1987] showed that the exercise-induced increase in glucose transport activity disappears rapidly when rat epitrochlearis muscles are incubated for 3 h in vitro in the absence of insulin and that 7.5 microU/ml insulin in the incubation medium apparently slowed the loss of enhanced sugar transport. We examined whether addition of insulin several hours after exercise increases glucose transport to the same extent as continuous insulin exposure. Addition of 7.5 microU/ml insulin 2.5 h after exercise (when glucose transport has returned to basal levels) increased sugar transport to the same level as that which resulted from continuous insulin exposure. This finding provides evidence for an increase in insulin sensitivity rather than a slowing of reversal of the exercise-induced increase in insulin-independent glucose transport activity. Glucose transport was enhanced only at submaximal, not at maximal, insulin concentrations. Exposure to a high concentration of glucose and a low insulin concentration reduced the exercise-induced increase in insulin-sensitive glucose transport. Incubation with a high concentration of 2-deoxy-D-glucose (2-DG) did not alter the increase in insulin sensitivity, even though a large amount of 2-DG entered the muscle and was phosphorylated.(ABSTRACT TRUNCATED AT 250 WORDS)

Recruitment of GLUT-4 glucose transporters by insulin in diabetic rat skeletal muscle

The cause of reduced insulin-stimulated glucose transport in skeletal muscle of diabetic rats was investigated. Basal and insulin-stimulated glucose uptake into hindquarter muscles of 7-day diabetic rats were 70% and 50% lower, respectively, than in nondiabetic controls. Subcellular fractionation of hindquarter muscles yielded total crude membranes, plasma membranes and intracellular membranes. The number of GLUT-4 glucose transporters was lower in crude membranes, plasma membranes and intracellular membranes, relative to non-diabetic rat muscles. These results were paralleled by reductions in D-glucose-protectable binding of cytochalasin B. Insulin caused a redistribution of GLUT-4 transporters from intracellular membranes to plasma membranes, in both control and diabetic rat muscles. This redistribution was also recorded using binding of cytochalasin B. The insulin-dependent decrement in glucose transporters in intracellular membranes was similar for both animal groups, but the gain and final amount of transporters in the plasma membrane were 50% lower in the diabetic group. The results suggest that insulin signalling and recruitment of GLUT-4 glucose transporters occur in diabetic rat muscle, and that the diminished insulin response may be due to fewer glucose transporters operating in the muscle plasma membrane.

Exercise induces recruitment of the "insulin-responsive glucose transporter". Evidence for distinct intracellular insulin- and exercise-recruitable transporter pools in skeletal muscle

Acute exercise, like insulin, increases D-glucose uptake into rat hind limb muscles. Here we examine the distribution of the muscle glucose transporters GLUT-4 and GLUT-1 in plasma membrane and intracellular membrane fractions of skeletal muscle prepared from control, exercised, and acutely insulin-treated rats. Immunoblotting with an anti-GLUT-4 polyclonal antibody showed that acute insulin treatment (by hind limb perfusion or in vivo injection) increased GLUT-4 transporters in a plasma membrane fraction and decreased them in an intracellular membrane fraction. Exercise also increased the GLUT-4 transporters in the plasma membrane, but in contrast to insulin, did not significantly decrease them in the intracellular fraction. Immunoblotting with anti-GLUT-1 antibody revealed that this transporter is largely localized in the plasma membrane. Neither insulin nor exercise significantly increased GLUT-1 transporters in the plasma membrane. The data show that GLUT-4 is an insulin-responsive glucose transporter in skeletal muscle and, furthermore, that GLUT-4 also responds to acute exercise. The results are consistent with recruitment of GLUT-4 glucose transporters to the plasma membrane from intracellular stores. Moreover, exercise-sensitive GLUT-4 transporters do not originate from the insulin-sensitive intracellular membrane fraction, suggesting the existence of distinct intracellular insulin- and exercise-recruitable GLUT-4 transporter pools.

Exercise modulates the insulin-induced translocation of glucose transporters in rat skeletal muscle

Insulin and acute exercise (45 min of treadmill run) increased glucose uptake into perfused rat hindlimbs 5-fold and 3.2-fold, respectively. Following exercise, insulin treatment resulted in a further increase in glucose uptake. The subcellular distribution of the muscle glucose transporters GLUT-1 and GLUT-4 was determined in plasma membranes and intracellular membranes. Neither exercise nor exercise----insulin treatment altered the distribution of GLUT-1 transporters in these membrane fractions. In contrast, exercise, insulin and exercise----insulin treatment caused comparable increases in GLUT-4 transporters in the plasma membrane. The results suggest that exercise might limit insulin-induced GLUT-4 recruitment and that following exercise, insulin may alter the intrinsic activity of plasma membrane glucose transporters.

Exercise increases susceptibility of muscle glucose transport to activation by various stimuli

The insulin sensitivity of glucose transport in skeletal muscle is enhanced after exercise. In this study, stimulation of transport of the nonmetabolizable glucose analogue 3-O-methylglucose by the insulin-mimetic agents vanadate and H2O2 was markedly enhanced in rat epitrochlearis muscles 18 h after a bout of swimming. This increase in susceptibility of the glucose transport process in muscle to stimulation by insulin-mimetic agents that act beyond the insulin-binding step provides evidence that the increased insulin sensitivity results from an effect of exercise on a later step in the activation of glucose transport. Hypoxia and insulin appear to stimulate glucose transport by different pathways in muscle as evidenced by an additivity of their maximal effects. The effect of a submaximal hypoxic stimulus on muscle sugar transport was greatly amplified 3 h after exercise. This increase in susceptibility of glucose transport to stimulation by hypoxia after exercise suggests that the increased sensitivity is not limited to the insulin sensitive pathway. In contrast to exercise (i.e., swimming), in vitro muscle contractions did not result in an increase in sensitivity of muscle glucose transport to insulin, raising the possibility that a humoral factor is necessary for this effect.

Effects of aging and exercise on insulin action in rat adipocytes are correlated with changes in fat cell volume

The effects of exercise on insulin action were evaluated in epididymal adipocytes from 9-mo and 26-mo-old rats. Exercised animals were given voluntary access to running wheels at 6 mo of age. Comparisons were made among these animals, freely eating sedentary rats, and sedentary animals maintained at body weights comparable to those of the runners. When expressed as percentage changes, the responses to insulin, in terms of stimulation of both [U-14C]glucose oxidation and 14C-labeled lipid accumulation, were largest in fat cells from the runners, followed by the paired-weight adipocytes, and the cells from the freely eating sedentary animals. However, the absolute changes in the rates of glucose oxidation and 14C-labeled lipid synthesis produced by insulin were comparable among the different groups. Basal rates of oxidation and 14C-labeled lipid accumulation were directly correlated with average cell size, independent of the treatment group, whereas the percentage increases in these processes produced by insulin were inversely correlated with cell size. Little, if any, effect of age or exercise was observed that could not be attributed to the average fat cell volume.

Prolonged increase in insulin-stimulated glucose transport in muscle after exercise

Exercise can induce short-term increases in the sensitivity and responsiveness of skeletal muscle glucose transport to insulin. The purpose of this study was to determine the effect of carbohydrate deprivation on the persistence of increased insulin sensitivity and responsiveness after a bout of exercise. Three hours after a bout of exercise, epitrochlearis muscles from carbohydrate-deprived (fat fed) rats showed a 25% greater increase in 3-O-methylglucose (3-MG) transport in response to a maximal insulin stimulus compared with muscles of nonexercised rats; this increase in insulin responsiveness had reversed 18 h postexercise. Muscles of rats fed carbohydrate showed no increase in insulin responsiveness 3 h after exercise. The effect of 60 microU/ml of insulin on 3-MG transport was approximately twofold greater in muscles studied 3 h after exercise than in nonexercised controls regardless of dietary carbohydrate intake. This increase in insulin sensitivity was lost within 18 h in carbohydrate-fed rats but persisted for at least 48 h in carbohydrate-deprived rats. Muscle glycogen increased approximately 41 mumol/g in the rats fed carbohydrate for 18 h, and only approximately 14.5 mumol/g in the rats fed fat for 48 h, after exercise. The persistent increase in insulin sensitivity after exercise in carbohydrate-deprived rats was unrelated to caloric intake, as muscles of fasted and fat-fed rats behaved similarly.