Identification of an intracellular pool of glucose transporters from basal and insulin-stimulated rat skeletal muscle

Sedimentation and immunological analyses of GLUT4 and alpha 2-Na,K-ATPase subunit-containing vesicles from rat skeletal muscle: evidence for segregation

In skeletal muscle insulin induces the translocation of both the GLUT4 glucose transporter and the alpha 2 subunit of the Na,K-ATPase from an intracellular membrane (IM) compartment to the plasma membrane (PM). Fractionation studies of rat skeletal muscle using a discontinuous sucrose gradient have indicated that the insulin-induced loss of both proteins occurs from a fraction containing intracellular membranes (IM) of common density. This raises the possibility that both proteins may be colocalized in a single intracellular compartment or are present in separate membrane vesicles that are of similar buoyant density. In this study we report the membrane vesicles from the insulin-responsive IM fraction can in fact be separated on the basis of differences in their sedimentation velocities; immunoblot analyses of fractions collected from a sucrose velocity gradient revealed the presence of two separate peaks for GLUT4 and the alpha 2 subunit of the Na,K-ATPase. One of these peaks representing a fast sedimenting population of vesicles (with a sedimentation coefficient of 2697 +/- 57 S) reacted against antibodies to the alpha 2 subunit of the Na,K-ATPase, whereas, the second peak contained a population of much slower sedimenting vesicles (with a sedimentation coefficient of 209 +/- 4 S) were practically devoid of the alpha 2-subunit. By contrast, the slow sedimenting vesicles were enriched by approximately 32-fold in GLUT4 relative to the starting IM fraction when the fractional protein content was taken into account. Immunoprecipitation of GLUT4-containing vesicles from the insulin-sensitive IM fraction revealed that no immunoreactivity towards either the alpha 2 or the beta 1 subunits of the Na,K-ATPase could be observed, signifying that the insulin-responsive subunits of the Na,K-ATPase and GLUT4 were present in different membrane vesicles and that it was unlikely, therefore, that the insulin-induced redistribution of these proteins to the PM occurs from a common intracellular pool.

Identification and characterization of an exercise-sensitive pool of glucose transporters in skeletal muscle

Augmentation of glucose transport into skeletal muscle by GLUT4 translocation to the plasma and T-tubule membranes can be mediated independently by insulin and by contraction/exercise. Available data suggest that separable pools of intracellular GLUT4 respond to these two stimuli. To identify and characterize these pools, we fractionated skeletal muscle membranes in a discontinuous sucrose density gradient. Fractions of 32 and 36% sucrose exhibited the highest enrichment of GLUT4 and were independently responsive to insulin and exercise, respectively. The combination of the two stimuli depleted both GLUT4 fractions simultaneously. Both vesicle populations contained the gp160 aminopeptidase, whose expression had previously been shown to be specific to muscle and fat and restricted to GLUT4 vesicles in the latter tissue. In muscle, gp160 translocates exactly as does GLUT4 in response to insulin and exercise. The contraction- and insulin-sensitive GLUT4 pools also contained secretory component-associated membrane protein/glucose transporter vesicle triplet but not GLUT1 and caveolin. Immunoadsorption of the two pools followed by silver staining did not reveal any obvious difference in their major protein components. On the other hand, sedimentational analysis in sucrose velocity gradients revealed that the insulin-sensitive GLUT4 vesicles had a larger sedimentation coefficient than the exercise-sensitive vesicles. Thus, the separation of the two intracellular GLUT4 pools should be useful in dissecting what are likely to be different signal transduction pathways that mediate their translocation to the cell surface.

GLP-1(7-36)amide binding in skeletal muscle membranes from streptozotocin diabetic rats

A higher specific binding of GLP-1(7-36)amide is found in skeletal muscle plasma membranes from adult streptozotocin (STZ)-treated rats (insulin-dependent diabetes mellitus model) and from neonatal STZ-treated rats (non insulin-dependent diabetes mellitus model), as compared to that in normal controls; no apparent change in the affinity was observed, that indicating the presence in both diabetic models of an increased number of high affinity binding sites for the peptide. The maximal specific GLP-1(7-16)amide binding in the non insulin-dependent diabetes mellitus model was found to be significantly higher than that in the insulin-dependent diabetes mellitus model. As GLP-1(7-36)amide exerts a glycogenic effect in the rat skeletal muscle, the present data suggest that the action of the peptide in the muscle glucose metabolism may be increased in states of insulin deficiency accompanied or not by insulin resistance.

Benefits of exercise for type II diabetics: convergence of epidemiologic, physiologic, and molecular evidence

In Canada diabetes affects approximately 5% of the population. The economic costs of diabetes and its attendant complications are significant, requiring approximately $1 billion a year from the health care system. Clearly the prevention and alleviation of diabetes is highly desirable. In the past few years there has been a remarkable convergence of physiologic, biochemical, molecular, and epidemiologic data, all of which indicate very strongly that exercise may be used as a therapeutic tool to prevent or alleviate non-insulin-dependent diabetes mellitus (NIDDM), or Type II diabetes. The evidence for this has been reviewed. Recently the significant therapeutic role of exercise for Type II diabetics has been endorsed by the medical community. However, there is virtually no education of exercise professionals in the area of diabetes and the benefits of lifestyle changes in treating Type II diabetics. This deficiency should be remedied. For the research community, the challenge now is to translate the physiologic, biochemical, and epidemiologic knowledge into optimally effective prescriptive exercise programs for Type II diabetic men and women.

Regulation of glucose transport in cultured muscle cells by novel hypoglycemic agents

The antidiabetic agent troglitazone (CS-045) and a metabolite designated M3 have potent blood glucose-lowering actions. The mechanism of the hypoglycemic effects of troglitazone and M3 was investigated in cultured L6 muscle cells. Short-term (2-hour) exposure of fully differentiated myotubes to troglitazone had no effect on glucose transport activity; M3 exposure caused a modest (50% to 60%) increase in basal and insulin-stimulated transport. Long-term (72-hour) treatment of myotubes with troglitazone resulted in a doubling of glucose transport in the absence of insulin, whereas M3 treatment resulted in a fivefold increase in basal glucose transport. Transport activity in M3-treated myotubes was greater than that seen after short-term insulin treatment. Insulin did not stimulate transport further in long-term M3-treated cells. A similar effect of prolonged exposure to M3 was observed in nondifferentiated myocytes. The agent had no influence on cell growth or the extent of differentiation. Augmentation of basal glucose transport by M3 was slow in onset, requiring 18 to 24 hours before significant effects were observed and 72 hours for full stimulation. M3 action on glucose transport was also dose-dependent, with half-maximal stimulation at 5 micrograms/mL of the agent and full effects at 10 to 20 micrograms/mL. Total membranes were prepared from control and M3-treated L6 myocytes and myotubes, and glucose transporter (GLUT1 and GLUT4) protein levels were measured by Western blotting. GLUT1 content was increased 2.9- +/- 1.3- and 2.8- +/- .2-fold by M3 treatment in myocytes and myotubes, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

The GLUT4 glucose transporter and the alpha 2 subunit of the Na+,K(+)-ATPase do not localize to the same intracellular vesicles in rat skeletal muscle

The GLUT4 glucose transporter and the alpha 2 subunit of the Na+,K(+)-ATPase of rat skeletal muscle are two proteins which redistribute from intracellular membranes to plasma membranes following in vivo insulin stimulation. Here we show that although both proteins co-segregate after subcellular fractionation of unstimulated rat hindlimb muscles, they do not share the same intracellular residence inside the muscle fibre. By immunogold single- and double-labeling on ultrathin muscle cryosections with specific antibodies, the GLUT4 glucose transporter and the Na+,K(+)-ATPase alpha 2 subunit were observed on different vesicular structures within the cell. GLUT4 was detected on subsarcolemmal and perinuclear membranes, and at the junction between myofibrillar A and I bands where triads are localized. The alpha 2 subunit of the Na+,K(+)-ATPase was observed at the plasma membrane and in distinct subsarcolemmal vesicles and intermyofibrillar membranes. Quantitative analysis of double-labeling of GLUT4 and Na+,K(+)-ATPase alpha 2 subunit revealed that less than 6% of the two proteins co-localize in the same continuous vesicular structures. The differential intracellular localization of the two proteins was further confirmed by immunopurification of GLUT4-containing membranes from muscle homogenates, in which the alpha 2 subunit of the Na+,K(+)-ATPase was found only at the same extent as the alpha 1 subunit of the enzyme, a protein exclusively present at the plasma membrane.

Neurotransmitter and neuropeptide modulation of high affinity choline uptake in Limulus brain

The role of neurotransmitters in the modulation of the sodium-dependent high affinity choline uptake system (HAChUS) of the horseshoe crab, Limulus polyphemus has been investigated utilizing a tissue slice preparation. Choline uptake was significantly decreased by carbachol but unaffected by atropine and d-tubocurarine. The muscarinic agonist oxotremorine decreased choline uptake by 30.4% while the muscarinic antagonist, pirenzepine, increased uptake by 29.6%. Applied in combination, pirenzepine and oxotremorine abolished their individual effects resulting in control values for choline uptake. The non-cholinergic transmitters octopamine and serotonin significantly enhanced choline uptake. The neuropeptide proctolin elicited a 20% increase in choline transport whereas Phe-Met-Arg-Phe (FMRF) amide was without effect. This study demonstrates that neurotransmitters and neuropeptides modulate the HAChUS, possibly through specific receptor-mediated second messenger systems.

Effects of contractile activity on tyrosine phosphoproteins and PI 3-kinase activity in rat skeletal muscle

Insulin stimulates signaling reactions that include insulin receptor autophosphorylation and tyrosine kinase activation, insulin receptor substrate-1 (IRS-1) tyrosine phosphorylation, and phosphatidylinositol 3-kinase (PI 3-kinase) activation. Muscle contraction has metabolic effects similar to insulin, and contraction can increase insulin sensitivity, but little is known about the molecular signals that mediate the effects of contraction. To investigate the effects of muscle contraction on insulin signaling, rats were studied after contraction of hindlimb muscles by electrical stimulation, maximal insulin injection in the absence of contraction, or contraction followed by insulin injection. Insulin increased tyrosine phosphorylation of the insulin receptor and IRS-1, whereas contraction alone had no effect. Contraction before insulin injection decreased the insulin effect on receptor and IRS-1 phosphorylation by 20-25%. Increased tyrosine phosphorylation of other proteins by insulin and/or contraction was not observed. Contraction alone had little effect on PI 3-kinase activity, but contraction markedly blunted the insulin-stimulated activation of IRS-1 and insulin receptor-immunoprecipitable PI 3-kinase. In conclusion, skeletal muscle contractile activity does not result in tyrosine phosphorylation of molecules involved in the initial steps of insulin signaling. Although contractile activity increases insulin sensitivity and responsiveness in skeletal muscle, contraction causes a paradoxical decrease in insulin-stimulated tyrosine phosphorylation and PI 3-kinase activity.

Insulin induces translocation of GLUT-4 glucose transporters in human skeletal muscle

Understanding the molecular mechanisms involved in the regulation of glucose transport into human muscle is necessary to unravel possible defects in glucose uptake associated with insulin resistance in humans. Here we report a strategy to subfractionate human skeletal muscle biopsies (0.5 g) removed from vastus lateralis during a euglycemic insulinemic clamp procedure. A sucrose gradient separated total membranes into five fractions. Fraction 25 (25% sucrose) contained the plasma membrane markers alpha 1- and alpha 2-subunits of the Na(+)-K(+)-adenosinetriphosphatase and the GLUT-5 hexose transporter, recently immunolocalized to the cell surface of human skeletal muscle. The dihydropyridine receptor, a transverse tubule marker, was present exclusively in this fraction. The GLUT-4 glucose transporter was more concentrated in fraction 27.5 (27.5% sucrose) and largely diminished in plasma membrane markers. Open skeletal muscle biopsies were removed before and 30 min after clamping insulin to 550 pM. This increased GLUT-4 protein by 1.61-fold in fraction 25 and lowered it by 50% in fraction 27.5. Thus physiological concentrations of insulin induce translocation of glucose transporters from an internal membrane pool to surface membranes in human skeletal muscle.

The genetics and pathophysiology of type II and gestational diabetes

The development of both type II diabetes and gestational diabetes is probably governed by a complex and variable interaction of genes and environment. Molecular genetics has so far failed to identify discrete gene mutations accounting for metabolic changes in NIDDM. Both beta cell dysfunction and insulin resistance are operative in the manifestation of these disorders. Specific and sensitive immunoradiometric assays found fasting hyperproinsulinemia and first-phase hypoinsulinemia early in the natural history of the disorder. A lack of specificity of early radioimmunoassays for insulin resulted in measuring not only insulin but also proinsulins, leading to overestimation of insulin and misleading conclusions about its role in diabetes. The major causes of insulin resistance are the genetic deficiency of glycogen synthase activation, compounded by additional defects due to metabolic disorders, receptor downregulation, and glucose transporter abnormalities, all contributing to the impairment in muscle glucose uptake. The liver is also resistant to insulin in NIDDM, reflected in persistent hepatic glucose production despite hyperglycemia. Insulin resistance is present in many nondiabetics, but in itself is insufficient to cause type II diabetes. Gestational diabetes is closely related to NIDDM, and the combination of insulin resistance and impaired insulin secretion is of importance in its pathogenesis.

Glucagon-like peptide-1 binding to rat skeletal muscle

We have found [125I]glucagon-like peptide-1(7-36)-amide-specific binding activity in rat skeletal muscle plasma membranes, with an estimated M(r) of 63,000 by cross-linking and SDS-PAGE. The specific binding was time and membrane protein concentration dependent, and displaceable by unlabeled GLP-1(7-36)-amide with an ID50 of 3 x 10(-9) M of the peptide; GLP-1(1-36)-amide also competed, whereas glucagon and insulin did not. GLP-1(7-36)-amide did not modify the basal adenylate cyclase activity in skeletal muscle plasma membranes. These data, together with our previous finding of a potent glycogenic effect of GLP-1(7-36)-amide in rat soleus muscle, and also in isolated hepatocytes, which was not accompanied by a rise in the cell cyclic AMP content, lead use to believe that the insulin-like effects of this peptide on glucose metabolism in the muscle could be mediated by a type of receptor somehow different to that described for GLP-1 in pancreatic B cells, where GLP-1 action is mediated by the cyclic AMP-adenylate cyclase system.

Kinetics of 2-deoxyglucose transport in skeletal muscle: effects of insulin and contractions

There is some controversy regarding whether insulin or contractile activity alters the affinity of skeletal muscle glucose transporters for glucose and its analogues. The effects of insulin and contractions on the kinetics of glucose transport were therefore reexamined in isolated rat skeletal muscles. Concentration-dependent rates of 2-deoxyglucose (2-DG) transport were measured in the absence or presence of insulin (2 mU/ml) in the epitrochlearis and split soleus muscles. The apparent half-maximal saturating substrate concentration (Km) for basal 2-DG transport (approximately 12 mM) was similar for the split soleus and epitrochlearis, and the apparent Km was not changed by insulin in either muscle type. The presence of 2 mU/ml insulin increased the maximal transport velocity (Vmax) approximately fourfold in the epitrochlearis and approximately eightfold in the split soleus. In the epitrochlearis, in vitro muscle contractions also resulted in an approximately fourfold increases in Vmax with no change in apparent Km. The combined effects of insulin and contractions on Vmax were completely additive, but the apparent Km was not different from insulin alone. The apparent Km values for basal and insulin-stimulated glucose transport were further characterized in the epitrochlearis isolated from transgenic mice overexpressing the GLUT-1 isoform in the sarcolemma and their nontransgenic littermates. The apparent Km for basal 2-DG transport in the transgenic muscle (9 mM) was not significantly different from the apparent Km for insulin-stimulated transport in the control muscle (10 mM). The present study provides evidence that insulin and contractions, either alone or in combination, increase glucose transport activity in skeletal muscle by increasing Vmax, with no significant change in Km. Our results also suggest that, in intact skeletal muscle, the Km for basal glucose transport (a process mediated primarily by GLUT-1) is similar to the Km values for stimulated transport, mediated predominantly by GLUT-4.

Evidence that modulation of glucose transporter intrinsic activity is the mechanism involved in the allose-mediated depression of hexose transport in mammalian cells

In serum starved V79 Chinese hamster lung fibroblast cells, replacement of D-glucose with D-allose resulted in a significant 38 +/- 18% (P < 0.05) reduction of 2-deoxy-D-glucose (2-DG) transport. Similarly, in a respiration-deficient mutant cell line (V79-G14), which has elevated 2-DG transport activity, D-allose reduced 2-DG transport by 59 +/- 18% (P < 0.05). [3H]D-allose uptake by V79 cells occurred slowly and was not inhibited by cytochalasin B, suggesting diffusion as the mode of D-allose entry. Western blot analysis using a rabbit polyclonal antibody to the human erythrocyte glucose transporter (GT) demonstrated that, in both cell lines, GT content and GT subcellular distribution were not significantly different in D-glucose vs. D-allose-treated cells. delta-Antibody, which has been shown to bind to exofacial epitopes of the GT (Harrison et al., 1990, J. Biol. Chem., 265:5793-5801), did not demonstrate any differences in surface binding to D-glucose vs. D-allose-treated intact V79 cells. D-allose treatment of 3T3 fibroblasts resulted in a similar decrease (72%) of 2-DG transport, however D-allose had no apparent effect on basal sugar transport in 3T3 adipocytes. These results suggest that D-allose reduces sugar transport through a modulation of the intrinsic activity of the GT, and that D-allose may act in a tissue-specific manner.

Acute alcohol administration attenuates insulin-mediated glucose use by skeletal muscle

The aim of the present work was to test the effect of acute in vivo alcohol administration (180-190 mg/dl plasma for 3 h) on glucose utilization by tissues under basal conditions or after a hyperinsulinemic (100-130 microU/ml) euglycemic clamp in fasted rats. In vivo glucose use by individual tissues was assessed by the tracer 2-deoxy-D-glucose technique. Alcohol administration to saline-infused rats markedly inhibited glucose use by skeletal muscles, including the soleus, white and red quadriceps, and gastrocnemius, as well as by the heart. Ethanol infusion, however, had no effect on glucose use by the diaphragm, lung, liver, skin, ileum, brain, and adipose tissue. The insulin-stimulated glucose use was also inhibited by alcohol selectively in the muscles, with no effect on other tissues tested, except a moderate inhibition in the brain. Ethanol inhibited muscle glucose use by an average of approximately 50% under both basal and insulin-stimulated conditions. However, because insulin treatment more than doubled basal glucose use by these muscles, the 50% inhibition by ethanol treatment represents a greater inhibition of absolute glucose use under insulin-stimulated rather than under basal conditions. Our data demonstrate that acute alcohol intake attenuates basal and hormone-induced glucose utilization in a tissue-specific fashion. The inhibitory effect of alcohol on skeletal muscle glucose use could contribute to the previously observed decreased glucose recycling in humans after acute alcohol intake.

Differential effects of GLUT-1 or GLUT-4 overexpression on insulin responsiveness in transgenic mice

The effect of glucose transporter expression on insulin-stimulated whole body glucose disposal was examined in transgenic mice overexpressing GLUT-1 or GLUT-4. Transgenic mice and their control littermates were subjected to a euglycemic hyperinsulinemic clamp under pentobarbital sodium anesthesia using an insulin infusion rate of 20 mU.kg-1.min-1 and a variable glucose infusion rate (GIR). Fasted mice overexpressing GLUT-1 in skeletal muscle exhibited a GIR that was only 54% that of controls (19.3 +/- 1.8 vs. 36.0 +/- 3.9 mg.kg-1.min-1) when blood glucose was clamped at euglycemic values. In contrast, fasted mice overexpressing GLUT-4 in fat and muscle exhibited a GIR that was 40% higher than controls (53.9 +/- 2.3 vs. 39.1 +/- 2.5 mg.kg-1.min-1). At the end of the clamp, beta-hydroxybutyrate levels were 10-fold higher in the GLUT-1 transgenic mice relative to nontransgenic littermates (2.0 +/- 0.6 vs. 0.2 +/- 0.1 mM) but did not differ between the GLUT-4 transgenic mice and their control littermates (0.3 +/- 0.1 vs. 0.3 +/- 0.1 mM). These data demonstrate that the level of expression of a glucose transporter in muscle and fat can have marked effects on whole body glucose homeostasis and fuel metabolism. Insulin responsiveness was enhanced by overexpression of GLUT-4. Strikingly, however, overexpression of GLUT-1 in muscle induced a profound reduction in insulin-stimulated whole body glucose disposal.(ABSTRACT TRUNCATED AT 250 WORDS)

Modulation of Pi transport in skeletal muscle by insulin and IGF-1

In vivo, skeletal muscle Pi uptake influences both muscle cellular [Pi] and plasma [Pi], and may mediate the hypophosphataemic effects of insulin and insulin-like growth factor 1 (IGF-1). These effects were investigated in the cultured mouse myoblast cell line G8 and the isolated incubated rat soleus. The low Km for Pi in G8 cells is consistent with in vivo evidence that muscle cell [Pi] is partially protected against changes in plasma [Pi]. Insulin and IGF-1 stimulated Na-dependent Pi influx: in G8 cells both increased Vmax, with no change in Km, but while the insulin response occurred within 15 min and rapidly reversed upon insulin withdrawal, the response to IGF-1 occurred only after 60 min and persisted at least 60 min following IGF-1 withdrawal. Furthermore, only the IGF-1 response was inhibited by cycloheximide. We suggest that IGF-1 operates through de novo protein synthesis, while insulin stimulates transporter recruitment to the cell surface.

Effect of insulin on GLUT-4 mRNA and protein concentrations in skeletal muscle of patients with NIDDM and their first-degree relatives

We examined whether insulin resistance, i.e. impaired insulin stimulated glucose uptake in NIDDM patients and their first-degree relatives is associated with alterations in the effect of insulin on the expression of the GLUT-4 gene in skeletal muscle in vivo. Levels of GLUT-4 mRNA and protein were measured in muscle biopsies taken before and after a euglycaemic insulin clamp from 14 NIDDM patients, 13 of their first-degree relatives and 17 control subjects. Insulin stimulated glucose uptake was decreased in the diabetic subjects (19.8 +/- 3.0 mumol.kg LBM-1.min-1, both p < 0.001) compared with control subjects (44.1 +/- 2.5 mumol.kg LBM-1.min-1) and relatives (39.9 +/- 3.3 mumol.kg LBM-1.min-1). Basal GLUT-4 mRNA levels were significantly higher in diabetic subjects and relatives compared to control subjects (99 +/- 8 and 108 +/- 9 pg/micrograms RNA vs 68 +/- 5 pg/micrograms RNA; both p < 0.01). Insulin increased GLUT-4 mRNA levels in all control subjects (from 68 +/- 5 to 92 +/- 6 pg/micrograms RNA; p < 0.0001), but not in the diabetic patients (from 99 +/- 8 to 90 +/- 8 pg/micrograms RNA, NS), or their relatives (from 94 +/- 9 to 101 +/- 11 pg/micrograms RNA, NS). In the relatives, individual basal GLUT-4 mRNA concentrations varied between 55 and 137 pg/micrograms RNA.(ABSTRACT TRUNCATED AT 250 WORDS)

GLUT-4 content in plasma membrane of muscle from patients with non-insulin-dependent diabetes mellitus

The abundance of GLUT-4 protein in both total crude membrane and plasma membrane fractions of vastus lateralis muscle from 13 obese non-insulin-dependent diabetes mellitus (NIDDM) patients and 14 healthy subjects were examined in the fasting state and after supraphysiological hyperinsulinemia. In the basal state the immunoreactive mass of GLUT-4 protein both in the crude membrane preparation and in the plasma membrane fraction was similar in NIDDM patients and control subjects. Moreover, in vivo insulin exposure neither for 30 min nor for 4 h had any impact on the content of GLUT-4 protein in plasma membranes. With the use of the same methodology, antibody, and achieving the same degree of plasma membrane purification and recovery, we found, however, that intraperitoneal administration of insulin to 7-wk-old rats within 30 min increased the content of GLUT-4 protein more than twofold (P < 0.01) in the plasma membrane from red gastrocnemius and soleus muscle. In conclusion, when the subcellular fractionation method was applied to human muscle biopsies taken in the basal state, no difference could be found in the plasma membrane content of immunoreactive GLUT-4 protein between NIDDM patients and normal subjects. With this technique, we were unable to show evidence for a regulatory effect of insulin on the plasma membrane level of GLUT-4 protein in human muscle.

Muscle group-specific regulation of GLUT 4 glucose transporters in control, diabetic, and insulin-treated diabetic rats

Insulin resistance in diabetic rats involves pretranslational suppression of the GLUT 4 glucose transporter in muscle. Because the capacity for insulin-mediated glucose transport varies as a function of muscle group, we hypothesized that GLUT 4 was differentially expressed and regulated by diabetes in a muscle-specific manner. We studied control (C), streptozocin (STZ)-induced diabetic (D), and insulin-treated diabetic (Tx) rats and examined the following muscles that vary in fiber composition: soleus (type I fibers), gastrocnemius (mixed type IIa > IIb), vastus lateralis and rectus abdominis (type IIb > IIa), and cardiac muscle. In C animals, these muscles exhibited significant differences in the baseline expression of GLUT 4. Relative GLUT 4 content was highest in cardiac muscle, intermediate in soleus, and significantly lower in gastrocnemius, rectus abdominis, and vastus lateralis (1.8:1.0:0.6). The impact of diabetes and insulin therapy on GLUT 4 expression also varied as a function of muscle group. After four weeks of diabetes, GLUT 4 levels were reduced by approximately 50% in cardiac muscle, soleus, and gastrocnemius. In contrast, GLUT 4 content in rectus abdominis and vastus lateralis was similar to that in control rats. Exogenous insulin treatment of diabetic rats increased GLUT 4 content in soleus, cardiac muscle, and gastrocnemius, but had no effect in either vastus lateralis or rectus abdominis. Temporal effects of diabetes and insulin treatment were also examined in different skeletal muscle. Soleus showed a significant decrease in GLUT 4 content as early as 2 days with a further decrease at 4 weeks; rectus abdominis showed little change at either time point.(ABSTRACT TRUNCATED AT 250 WORDS)

Glut 4 content in the plasma membrane of rat skeletal muscle: comparative studies of the subcellular fractionation method and the exofacial photolabelling technique using ATB-BMPA

Employing subcellular membrane fractionation methods it has been shown that insulin induces a 2-fold increase in Glut 4 protein content in the plasma membrane of skeletal muscle from rats. Data based upon this technique are, however, impeded by poor plasma membrane recovery and cross-contamination with intracellular membrane vesicles. The present study was undertaken to compare the subcellular fractionation technique with the technique using [3H]ATB-BMPA exofacial photolabelling and immunoprecipitation of Glut 4 on soleus muscles from 3-week-old Wistar rats. Maximal insulin stimulation resulted in a 6-fold increase in 3-O-methylglucose uptake, and studies based on the subcellular fractionation method showed a 2-fold increase in Glut 4 content in the plasma membrane, whereas the exofacial photolabelling demonstrated a 6- to 7-fold rise in cell surface associated Glut 4 protein. Glucose transport activity was positively correlated with cell surface Glut 4 content as estimated by exofacial labelling.

IN CONCLUSION

(1) the increase in glucose uptake in muscle after insulin exposure is caused by an augmented concentration of Glut 4 protein on the cell surface membrane, (2) at maximal insulin stimulation (20 mU/ml) approximately 40% of the muscle cell content of Glut 4 is at the cell surface, and (3) the exofacial labelling technique is more sensitive than the subcellular fractionation technique in measuring the amount of glucose transporters on muscle cell surface.

Effects of exercise training on muscle GLUT-4 protein content and translocation in obese Zucker rats

The rates of muscle glucose uptake of trained (TR) and untrained (UT) obese Zucker rats were assessed by hindlimb perfusion under basal conditions (no insulin) in the presence of a maximally stimulating concentration of insulin (10 mU/ml) and after muscle contraction elicited by electrical stimulation of the sciatic nerve. Perfusate contained 28 mM glucose and 7.5 microCi/mmol of 2-deoxy-D-[3H]glucose. Muscle GLUT-4 concentration was determined by Western blot analysis and expressed as a percentage of a heart standard. The rates of insulin-stimulated glucose uptake were significantly higher in the plantaris, red gastrocnemius (RG), and white gastrocnemius (WG), but not the soleus or extensor digatorum longus (EDL) of TR compared with UT rats. After muscle contraction the rates of glucose uptake in the TR rats were significantly higher in the soleus, plantaris, and RG. TR rats had significantly higher GLUT-4 protein concentration and citrate synthase activity than the UT rats in the soleus, plantaris, RG, and WG. Basal plasma membrane GLUT-4 protein concentration of TR rats was 144% above UT rats (P < 0.01). Stimulation by insulin and contraction resulted in a significant increase in plasma membrane GLUT-4 protein concentration in UT rats only. However, plasma membrane GLUT-4 protein concentration in insulin- and contraction-stimulated TR rats remained 53% and 30% greater than that of UT rats, respectively (P < 0.05). Exercise training did not alter basal, insulin-, or contraction-stimulated GLUT-4 functional activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Insulin and platelet-derived growth factor acutely stimulate glucose transport in 3T3-L1 fibroblasts independently of protein kinase C

Insulin and platelet-derived growth factor (PDGF) are mitogenic for murine 3T3-L1 fibroblasts. Both these mitogens acutely stimulate glucose transport by 2-4-fold in these cells, evident within minutes of agonist exposure. The tumour promoter and protein kinase C activator, phorbol 12-myristate 13-acetate (PMA) also stimulates glucose transport by 2-3-fold over a similar time frame, suggesting that protein kinase C may be involved in the mitogenic action of insulin and PDGF in this cell line. In an attempt to address this, we have measured intracellular sn-1,2-diacylglycerol (DAG) levels in response to insulin, PDGF and PMA. We show that PDGF and PMA induce a rapid elevation in intracellular diacylglycerol levels, but insulin was without effect. In addition, we have shown that PMA and PDGF, but not insulin, stimulate protein kinase C activity. However, depletion of protein kinase C by overnight exposure to PMA, abolished PMA-stimulated glucose transport but had no effect on insulin- and PDGF-stimulated glucose transport, suggesting that the stimulation of glucose transport by these mitogens does not involve protein kinase C. The use of the selective protein kinase C inhibitor, Roche 31-8220, which inhibited PMA-stimulated glucose transport, but was without effect on insulin- and PDGF-stimulated glucose transport further supports this conclusion. Taken together, these data argue against a role for protein kinase C in the stimulation of glucose transport in 3T3-L1 fibroblasts caused by acute exposure to insulin or PDGF.

Metformin ameliorates diabetes but does not normalize the decreased GLUT 4 content in skeletal muscle of obese (fa/fa) Zucker rats

We studied the expression of the glucose transporter GLUT 4 in the soleus and red gastrocnemius muscles from obese, diabetic (fa/fa) Zucker rats compared to their lean littermates (Fa/-), with and without treatment with the antidiabetic drug metformin. In the untreated groups of rats, the GLUT 4 content in a crude membrane fraction of both the soleus and the red gastrocnemius muscles were significantly lower in the obese (fa/fa) rats (3.46 +/- 0.28 vs. 6.04 +/- 0.41, p < 0.001 and 6.0 +/- 0.24 vs. 9.1 +/- 0.48, p < 0.0001, respectively). Differences in GLUT 4 expression in soleus muscle from the same rats were confirmed by quantitative immunofluorescence microscopy, and the results were significantly correlated with the results obtained from quantitative immunoblotting (rho = 0.70, p < 0.0005). The decreased expression of GLUT 4 in fa/fa rats could contribute to the well-established insulin resistance in skeletal muscle of these animals. After 4 weeks of treatment with metformin, weight gain was not affected in either the diabetic (fa/fa) rats or the lean (Fa/-) rats. Improvement of glucose homeostasis by metformin was not associated with normalization of the GLUT 4 expression in the skeletal muscles studied, indicating (1) that the decreased GLUT 4 expression is not directly related to hyperinsulinaemia and diabetes mellitus and (2) that metformin does not normalize the expression of GLUT 4 in skeletal muscle of the diabetic (fa/fa) Zucker rats.

Role of transverse tubules in insulin stimulated muscle glucose transport

Although the strongest evidence for recruitment of glucose transporters in response to insulin comes from studies with adipocytes, studies in muscle seem in general to confirm that glucose transporters are also translocated to the cell membrane in muscle in response to insulin. However, the observation that transverse tubule (T-tubule) membranes contain approximately five times more glucose transporter than sarcolemma raised a question as to where glucose transport occurs in muscle. The T-tubule membrane system is continuous with the surface sarcolemma and is a tubule system in which extracellular fluid is in proximity with the interior of the muscle fiber. The purpose of this Prospects article is to evaluate the possibility that the T-tubule membrane may represent a major site of glucose transport in skeletal muscle. Using immunocytochemical techniques we have located GLUT4 glucose transporters on the T-tubule membrane and in vesicles near T-tubules. Since T-tubules form channels into the interior of the muscle fiber, glucose could diffuse or be moved by some peristaltic-like pumping action into the transverse tubules and then be transported across the membrane deep into the interior of the muscle fiber. This mode of transport directly into the interior of the cell would be advantageous over transport across the sarcolemma and subsequent diffusion around the myofibrils to reach the interior of the muscle. Thus, in addition to the role of the T-tubule in ion fluxes and contraction, this unique membrane system can also provide a pathway for the delivery of substrates into the center of the muscle cell where many glycolytic enzymes and glycogen deposits are located.

The molecular biology of glucose transport: relevance to insulin resistance and non-insulin-dependent diabetes mellitus

The structure of the glucose transporter and the characteristics of the identified members of the facilitative glucose transporter gene family (GLUT1-5) are reviewed. The role of glucose transport in insulin resistance and non-insulin-dependent diabetes mellitus (NIDDM) is discussed. The potential contributions of genetic mutation and disruption of short- or long-term regulation of glucose transporters, particularly GLUT4, in insulin-sensitive tissues to the etiology of NIDDM are examined.

Regulation of contraction-stimulated system A amino acid uptake in skeletal muscle: role of vicinal sulfhydryls

Functional vicinal sulfhydryls are essential for insulin-stimulated system A neutral amino acid uptake in the rat epitrochlearis muscle. In skeletal muscle, system A uptake is also activated by contractile activity. Therefore, the purposes of this study were to characterize the stimulation of system A activity by contractions induced by electrical stimulation in vitro, and to assess the role of vicinal sulfhydryls in this process. System A activity in the isolated epitrochlearis muscle was measured using the nonmetabolizable analogue alpha-(methylamino)isobutyric acid (MeAIB). Contractions increased MeAIB uptake by increasing the apparent maximal velocity (Vmax), with no alteration in the apparent Km. The maximal stimulatory effects of insulin and contractions on MeAIB uptake were completely additive, demonstrating that these two stimuli exert their effects via different mechanisms. Phenylarsine oxide (PAO), a vicinal sulfhydryl antagonist, at greater than 20 mumol/L inhibited basal and contraction-stimulated MeAIB uptake by approximately 50% and 70%, respectively, by decreasing Vmax, with no change in Km. Both inhibitory effects were completely prevented by cotreatment with the vicinal dithiol dimercaptopropanol (DMP), indicating the effects were mediated by interactions with vicinal sulfhydryls. Contraction-stimulated MeAIB uptake was rapidly (half-time, approximately 7 minutes) reversed by the addition of PAO. These results (1) define conditions under which contraction-stimulated system A amino acid uptake can be studied in an isolated mammalian skeletal muscle preparation, and (2) indicate that vicinal sulfhydryls are essential for stimulation of system A activity by muscle contractions.

Glucose transporters and glucose transport in skeletal muscles of 1- to 25-mo-old rats

It is widely thought that aging results in development of insulin resistance in skeletal muscle. In this study, we examined the effects of growth and aging on the concentration of the GLUT-4 glucose transporter and on glucose transport activity in skeletal muscles of female Long-Evans rats. Relative amounts of immunoreactive GLUT-4 protein were measured in muscle homogenates of 1-, 10-, and 25-mo-old rats by immunoblotting with a polyclonal antibody directed against GLUT-4. In the epitrochlearis, plantaris, and the red and white regions of the quadriceps muscles, GLUT-4 immunoreactivity decreased by 14-33% between 1 and 10 mo of age and thereafter remained constant. In flexor digitorum brevis (FDB) and soleus muscles, GLUT-4 concentration was similar at all three ages studied. Glucose transport activity was assessed in epitrochlearis and FDB muscles by incubation with 2-deoxyglucose under the following conditions: basal, submaximal insulin, and either maximal insulin or maximal insulin combined with contractile activity. Glucose transport in the epitrochlearis muscle decreased by approximately 60% between 1 and 4 mo of age and then did not decline further between 4 and 25 mo of age. Transport activity in the FDB assessed with a maximally effective insulin concentration decreased only slightly (< 20%) between 1 and 7 mo of age. Aging, i.e., the transition from young adulthood to old age, was not associated with a decrease in glucose transport activity in either the epitrochlearis or the FDB.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of exercise training on skeletal muscle glucose uptake and transport

Exercise training increases the concentration of GLUT-4 protein in skeletal muscle that is associated with an increase in maximal insulin-stimulated glucose transport. The purpose of this study was to determine whether exercise training results in a long-lasting increase in insulin-stimulated glucose transport in rat skeletal muscle. Glucose uptake and skeletal muscle 3-O-methyl-D-glucose (3-MG) transport were determined during hindlimb perfusion in the presence of a maximally stimulating concentration of insulin (10 mU/ml). Hindlimb glucose uptake was approximately 29% above sedentary (Sed) levels in rats examined within 24 h (24H) of their last exercise session. However, when rats were examined 48 h (48H) after their last exercise session, hindlimb glucose uptake was not different from Sed levels. Maximal 3-MG transport was enhanced, above Sed levels, in red (RG; 72% increase) and white (WG; 44% increase) gastrocnemius and plantaris (Plan; 67% increase) muscles, but not soleus (Sol), of 24H rats. GLUT-4 protein content was significantly elevated in those muscles that exhibited enhanced 3-MG transport in 24H rats. GLUT-4 protein content was also elevated in RG, WG, and Plan of 48H rats and was not different from 24H rats. Despite the elevated GLUT-4 protein content, 3-MG transport in 48H rats was only slightly, although statistically not significantly, higher than in Sed rats. These results provide evidence that exercise training does not result in a persistent increase in skeletal muscle glucose uptake or transport, despite an increase in GLUT-4 protein content.

Effects of alkaline pH on the stimulation of glucose transport in rat skeletal muscle

Alkaline pH has been reported to cause release of Ca2+ from skeletal muscle sarcoplasmic reticulum (SR). Elevation of sarcoplasmic Ca2+ concentration is thought to stimulate glucose transport in skeletal muscle. In this context, we examined the effect of alkaline pH (extracellular pH of 8.6) on 3-O-methylglucose transport in skeletal muscle. Incubation of rat epitrochlearis muscles at pH 8.6 for 45 min resulted in an approx. 3-fold increase in glucose transport activity, which was not affected by reducing Ca2+ concentration in the incubation medium and essentially completely blocked by 25 microM dantrolene, an inhibitor of SR Ca2+ release. In addition to stimulating glucose transport by itself, alkaline pH may partially inhibit the stimulation of sugar transport by insulin hypoxia and contractions, as the combined effect of alkaline pH and the maximal effect of insulin, contractions, or hypoxia on glucose transport are not different from the maximal effects of insulin, hypoxia, or contractions alone. The maximal effects of insulin and contractions, and of insulin and hypoxia, on glucose transport are normally additive in muscle. Alkaline pH completely prevented this additivity. In summary, our results show that alkaline pH stimulates glucose transport activity in skeletal muscle and provide evidence suggesting that this effect is mediated by Ca2+. They further show that alkaline pH blocks the additivity of the maximal effects of insulin and contractions or hypoxia suggesting that alkaline pH may partially inhibit the stimulation of glucose transport by insulin, contraction and hypoxia.

Effects of wheel running on glucose transporter (GLUT4) concentration in skeletal muscle of young adult and old rats

We examined the effects of voluntary exercise on glucose transporter concentration in skeletal muscle from young adult and old female Long-Evans rats. Rats had free access to voluntary running wheels beginning at 4 months of age or remained sedentary. Exercising rats ran approximately 7.5, 6.2, 5.6 and 5.3 km/day during their 6th, 8th, 9th and 10th month of age, respectively. During the 23rd, 24th and 25th month of age running distance averaged 3.0, 2.8 and 2.4 km/day, respectively. At 10 and 25 months of age, glucose transporter protein concentration was assessed in epitrochlearis and flexor digitorum brevis muscles with a polyclonal antibody directed against the GLUT4 transporter isoform. GLUT4 protein concentration was not altered by the aging process (i.e., comparing 10- and 25-month-old rats) in either muscle type. Wheel running increased GLUT4 protein concentration by 45% in epitrochlearis muscles of 10-month-old rats relative to age-matched sedentary controls. The training-induced adaptation in GLUT4 protein was no longer present at age 25 months, probably because the running distance had declined by 50%. In the flexor digitorum brevis, exercise did not alter GLUT4 concentration at either 10 or 25 months, presumably due to insufficient recruitment of this muscle during wheel running as assessed by measurement of citrate synthase and hexokinase enzyme activities. Wheel running induced cardiac and soleus muscle hypertrophy in 10- and 25-month-old rats. In summary, voluntary wheel running can induce an increase in skeletal muscle GLUT4 protein concentration in adult rats. Older rats that run less exhibit cardiac and soleus muscle hypertrophy, but do not maintain an elevated GLUT4 protein concentration in the epitrochlearis muscle. Aging does not alter GLUT4 protein concentration in the epitrochlearis or FDB muscles.

Muscle glucose transport, GLUT-4 content, and degree of exercise training in obese Zucker rats

The effects of high (HI)- and low (LI)-intensity exercise training were examined on insulin-stimulated 3-O-methyl-D-glucose (3-MG) transport and concentration of insulin-regulatable glucose transporter protein (GLUT-4) in the red (fast-twitch oxidative) and white (fast-twitch glycolytic) quadriceps of the obese Zucker rat. Sedentary obese (SED) and lean (LN) Zucker rats were used as controls. 3-MG transport was determined during hindlimb perfusion in the presence of 8 mM 3-MG, 2 mM mannitol, 0.3 mM pyruvate, and 0.5 mU/ml insulin. HI and LI rats displayed greater rates of red quadriceps 3-MG transport and GLUT-4 concentrations than SED rats. No significant differences in rates of 3-MG transport or GLUT-4 concentrations were observed in the red quadriceps of HI and LI rats. There were no differences found in the rates of 3-MG transport in the white quadriceps of HI, LI, and SED rats although the difference between the HI and SED rats approached significance (P < 0.07). The GLUT-4 concentration and citrate synthase activity of HI rats were significantly greater than SED rats. The 3-MG transport rates of LN rats were twofold greater than SED rats regardless of fiber type, but a difference in GLUT-4 content between the LN and SED rats was observed only in the white quadriceps. GLUT-4 content of the obese rats was significantly correlated with citrate synthase activity (r = 0.93) and 3-MG transport (r = 0.82).(ABSTRACT TRUNCATED AT 250 WORDS)

Insulin-responsive glucose transporter expression in renal microvessels and glomeruli

The insulin-responsive glucose transporter (GLUT4) is expressed at high levels in fat and skeletal muscle, which account for the majority of insulin-stimulated glucose uptake. However, GLUT4 is also expressed at lower levels in kidney and several other tissues. We have used a variety of protein and mRNA detection techniques to determine the sites of renal GLUT4 expression. Indirect immunofluorescence experiments with two specific anti-peptide antisera detected GLUT4 in the smooth muscle cells of the rat renal microvasculature, in renal glomerulus, and in cultured glomerular mesangial and epithelial cells. PCR amplification of cDNA derived from microdissected renal glomeruli, microvessels and tubules corroborated this distribution of GLUT4, and Northern blotting demonstrated GLUT4 mRNA in cultured glomerular mesangial cells. Both the immunofluorescence and PCR data suggested that GLUT4 is most highly expressed in renal microvessels. Our results show that certain renal cells, such as renal microvascular smooth muscle cells, express the insulin-responsive glucose transporter and therefore may demonstrate altered glucose uptake and metabolism in diabetes mellitus.

Distribution of GLUT3 glucose transporter protein in human tissues

To investigate the tissue distribution of the GLUT3 glucose transporter isoform in human tissue we produced affinity purified antibodies to the COOH terminus of the human GLUT3. Both antibodies recognize a specific GLUT3 band in oocytes injected with GLUT3 mRNA but not in those injected with H2O or GLUT1, 2, 4, 5 mRNA. This immunoreactive band in GLUT3 injected oocytes is photolabelled by cytochalasin-B in the presence of L- but not D-glucose indicating that it is a glucose transporter. A high cross reactivity between the human GLUT3 antibodies and a 43 kDa cytoskeletal actin band was identified in all oocyte lysates and many human tissues. However, the specific GLUT3 band could be distinguished from the actin band by carbonate treatment which preferentially solubilized the actin band. Using these antibodies we show that GLUT3 is present as a 45-48 kDa protein in human brain with lower levels detectable in heart, placenta, liver and a barely detectable level in kidney. No GLUT3 was detected in membranes from any of 3 skeletal muscle groups investigated. We conclude that a major role of GLUT3 in humans is as the brain neuronal glucose transporter.

Epinephrine administration stimulates GLUT4 translocation but reduces glucose transport in muscle

Epinephrine opposes glucose transport in muscle. Therefore, we investigated the effects of epinephrine administration (25 micrograms/100g body weight) on glucose transport and glucose transporters in rat muscle. Ninety minutes after epinephrine injection 3-O-methyl glucose transport was reduced (approximately 47%) in perfused muscles of the rat hindlimb. Translocation of the insulin-regulatable glucose transporter (GLUT4) in the epinephrine-injected animals was confirmed by the marked increments in the GLUT-4 in the plasma membranes and their concomitant reduction in the intracellular membranes. We speculate a) that it is epinephrine which translocated GLUT4 via a cAMP-linked pathway, and b) that the intrinsic activity reductions are caused either by the glycation of the transporter by the persistent hyperglycemia and/or by epinephrine via the phosphorylation of the GLUT4 transporter protein in muscle.

Peripheral glucose uptake and skeletal muscle GLUT4 content in man: effect of insulin and free fatty acids

To investigate the relationship between glucose uptake and the content of the insulin regulatable glucose transporter, GLUT4, in skeletal muscle at near physiological insulin concentrations in vivo, we measured the effect of a 3h euglycemic insulin-infusion (40 mU m-2 min-1) on glucose uptake and skeletal muscle GLUT4 content in 10 healthy subjects. We found no correlation (r approximately 0.1) between individual muscle GLUT4 content and insulin-stimulated glucose uptake. Mean GLUT4 content in skeletal muscle was reduced by 19 +/- 6.3% (mean +/- SE, p less than 0.02) after insulin infusion. However, when the same subjects were made insulin resistant by infusion of lipid, as evidenced by a reduction of 16 +/- 7.2% (mean +/- SE, p less than 0.05), in insulin-stimulated glucose uptake, the effect of insulin on GLUT4 content was attenuated and no change in GLUT4 content was observed. Our results show that the total content of skeletal muscle GLUT4 is a poor predictor for in vivo response to near physiological insulin concentrations in healthy human subjects.

Abundance, localization, and insulin-induced translocation of glucose transporters in red and white muscle

D-Glucose protectable cytochalasin B (CB) binding to subcellular membrane fractions was used to determine glucose transporter number in red (quadriceps-gastrocnemius-soleus) and white (quadriceps-gastrocnemius) rat muscle. CB binding was twofold higher in isolated plasma membranes of red than of white muscle. In contrast, the number of transporters in an isolated insulin-sensitive intracellular membrane organelle was similar in the two muscle groups. Immunoblotting and immunofluorescence microscopy with anti-GLUT4 and anti-GLUT1 antibodies indicated that both GLUT1 and GLUT4 transporter isoforms account for the higher abundance of CB binding sites in plasma membranes of red than of white muscle. Immunofluorescence localized GLUT4 to both the surface and the interior of the muscle cell and demonstrated that type I (slow twitch oxidative) and type IIa (fast twitch oxidative-glycolytic) fibers are enriched in GLUT4 protein compared with type IIb (fast twitch glycolytic) fibers. In contrast, GLUT1 reactivity was restricted to the surface of the muscle cell and was also highly enriched in the perineurial sheaths of peripheral nerves and the capsules of muscle spindles present in both red and white muscles. Insulin caused a twofold increase in CB binding in isolated plasma membranes of red or white muscles with a corresponding 40-50% decrease in CB binding in isolated intracellular membranes. These changes in CB binding were paralleled by similar changes in the membrane distribution of the GLUT4 glucose transporter isoform and in glucose transport activity measured after insulin perfusion of hindquarter muscles. In contrast, insulin did not change the distribution of either GLUT1 glucose transporters or Na(+)-K(+)-ATPase alpha 1-subunits. The molar ratio of GLUT4 to GLUT1 in red and white muscle plasma membranes was found to be 4:1 in the basal state and 7:1 in the insulin-stimulated state. These results indicate that red muscle contains a higher amount of GLUT1 and GLUT4 transporters at the plasma membrane than white muscle in the basal and insulin-stimulated states but that GLUT4 translocation does not differ between muscle types. In addition, GLUT4 expression correlates with the metabolic nature (oxidative vs. glycolytic) of skeletal muscle fibers, rather than with their contractile properties (slow twitch vs. fast twitch).

Effects of maturation and aging on the skeletal muscle glucose transport system

Insulin resistance in old, compared with young, humans and animals has been well documented. The resistance is due primarily to defects in skeletal muscle. In the present study, skeletal muscle sarcolemmal membranes were purified from five age groups of female Fischer rats ranging from 2 to 24 mo. Basal specific D-glucose transport was not significantly different among any of the groups. Maximum insulin-stimulated transport was progressively decreased from 96.4 +/- 5.0 pmol.mg-1.15 s-1 in the 2-mo-old animals to 70.8 +/- 8.9 pmol.mg-1.15 s-1 in the 24-mo-old animals. Most of the decrease occurred during maturation, and in fact there was no significant difference in maximum transport among the 8-, 16-, and 24-mo-old rats. The decrease in insulin-stimulated transport in the 24-mo-old animals was due to a reduction in the number of glucose transporters translocated into the sarcolemma membrane (9.8 +/- 0.6 vs. 7.8 +/- 0.6 pmol/mg protein). The intracellular or microsomal pool of glucose transporters was not significantly different between the 2- and 24-mo-old animals (8.8 +/- 0.6 vs. 8.5 +/- 0.9/mg protein). Western blotting revealed no differences in the cellular GLUT-4 contents between the 2- and 24-mo-old rats. The number of insulin receptors (2.3 +/- 0.4 vs. 2.1 +/- 0.5 pmol/mg protein) was not significantly different. Tyrosine kinase activity of the insulin receptor was, however, significantly reduced in the 24-mo-old compared with the 2-mo-old animals.(ABSTRACT TRUNCATED AT 250 WORDS)

Regulation of glucose transport and GLUT1 glucose transporter expression by O2 in muscle cells in culture

The effect of varying cellular oxygenation on L6 muscle cell 2-deoxy-D-glucose transport, glucose utilization, lactate production, and expression of GLUT1 and GLUT4 transport proteins was investigated. Incubation of L6 myotubes in 3% O2 (mimicking a state of hypoxia) elevated glucose uptake by 6.5-fold over 48 h relative to cells incubated in 21% O2 (normoxia). Incubation of L6 cells in hyperoxic conditions (50% O2) significantly depressed glucose uptake by 0.4-fold. These effects were fully reversible. Incubation in 3% O2 also caused lactate accumulation and enhanced glucose consumption from the medium. Hypoxia elevated 2-deoxy-D-glucose transport even when the concentration of glucose in the medium was kept constant, suggesting that glucose deprivation alone was not responsible for increased cellular glucose uptake. Incubation in 3% O2 also elevated 3-O-methylglucose uptake but not amino acid uptake. Cycloheximide prevented the hypoxia-induced increase in glucose uptake, indicating that de novo synthesis of glucose transport-related proteins was the major means by which cells increased glucose uptake. The content of GLUT1 glucose transporter was significantly elevated in total membranes of cells incubated in 3% O2 and depressed in membranes from cells incubated in hyperoxic conditions, whereas GLUT4 expression was not affected. These results indicate that hypoxia induces an adaptive response of increasing cellular glucose uptake through elevated expression of GLUT1 in an attempt to maintain supply of glucose for utilization by nonoxidative pathways.