Department of Internal Medicine, Washington University School of Medicine, St. Louis, Missouri 63110
Submitted 13 May 2003 ; accepted in final form 5 June 2003
![]() |
ABSTRACT |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
carbohydrate feeding; insulin responsiveness; muscle glucose transport
Previous studies have provided evidence suggesting that prevention of glycogen supercompensation, by not feeding carbohydrate after exercise, results in persistence of an increase in insulin-stimulated glucose transport (5, 9, 46). This raises the possibility that, after glycogen-depleting exercise, muscle cells maintain the adaptations that make possible faster and greater glycogen accumulation until glycogen accumulation actually occurs. Exercise induces an increase in muscle insulin sensitivity (12, 41). It is not clear from available data whether the persistent increase in insulin action in the carbohydrate-depleted state after exercise is due to a persistent increase in insulin sensitivity (5) or also involves enhanced insulin responsiveness mediated by maintenance of the increase in GLUT4. In this context, the present study was undertaken to determine whether persistent increases in GLUT4 and insulin responsiveness are involved in a mechanism that enables trained, glycogen-depleted muscles to maintain their capacity for enhanced glycogen accumulation.
![]() |
MATERIALS AND METHODS |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Animal care. This research was approved by the Animal Studies Committee of Washington University School of Medicine. Male Wistar rats (body wt 165185 g) were obtained from Charles River Laboratories, housed in individual cages, and fed a diet of Purina rodent laboratory chow and water ad libitum. Animals were randomly assigned to either an exercise group or a sedentary control group. Rats in the exercise group were accustomed to swimming for 10 min/day for 2 days. They were then exercised on three successive days using a swimming protocol, described previously (34, 40), that involves two 3-h-long swimming sessions separated by a 45-min-long rest period during which the rats are kept warm and given food and water. After completion of the swimming on the 3rd day, food was withheld from one group of exercised animals, and the remaining exercised animals were fed either chow or lard ad libitum. The exercised, fasted rats and groups of exercised, high-carbohydrate diet and sedentary animals were killed 18 h after the last exercise bout. Groups of chow-fed (high-carbohydrate diet) and lard-fed (carbohydrate-free diet) rats were killed 42 h after exercise. Additional groups of carbohydrate-free diet rats were studied either 66 h after exercise or 18 h after being switched from a lard to a chow diet 66 h after the last bout of exercise. The animals were anesthetized with an intraperitoneal injection of pentobarbital sodium (5 mg/100 g body wt), and the epitrochlearis and triceps muscles were dissected out.
Muscle incubations. Epitrochlearis muscles were incubated with shaking for 60 min at 30°C in 2 ml of oxygenated Krebs-Henseleit buffer (KHB) in Erlenmeyer flasks gassed continuously with 95% O2-5% CO2. The epitrochlearis is a small, thin muscle of the forelimb that, in rats of the size used in this study, is suitable for measurement of sugar transport in vitro (21, 45). The KHB was supplemented with 8 mM glucose, 32 mM mannitol, and 0.1% radioimmunoassay-grade BSA in the presence or absence of 2 mU/ml purified porcine insulin. This concentration of insulin maximally activates glucose transport in this muscle preparation (43). To remove glucose, muscles were then washed for 10 min at 30°C in KHB containing 40 mM mannitol and 0.1% BSA, plus insulin if it was present in the previous incubation, and used for measurement of glucose transport activity.
Measurement of glucose transport activity. Glucose transport activity was measured by using the glucose analog 2-DG as described previously (16, 45). After the wash, epitrochlearis muscles were incubated at 30°C for 20 min in 1.0 ml KHB containing 4 mM [1,2-3H]2-DG (1.5 µCi/ml), 36 mM [14C]mannitol (0.2 µCi/ml), 0.1% BSA, and insulin if present in previous incubations. Extracellular space and intracellular 2-DG concentration were determined as previously described (45).
Analytical methods. Glycogen was measured in perchloric acid extracts of the epitrochlearis muscle by use of the amyloglucosidase method (38).
Western blot analysis. Epitrochlearis muscle GLUT4 content was determined by Western blotting, as described previously (18), using a rabbit polyclonal antibody directed against the COOH terminus of GLUT4 followed by horseradish peroxidase-conjugated anti-rabbit IgG. Antibody-bound transporter protein was visualized using ECL. For evaluation of COX-I protein content, triceps muscle was homogenized in a buffer containing 20 mM HEPES, 1 mM EDTA, and 250 mM sucrose, pH 7.4. Protein content was measured using bicinchoninic acid (Pierce). Aliquots of homogenate were solubilized in Laemmli sample buffer and subjected to SDS-polyacrylamide gel electrophoresis. Proteins were transferred to polyvinylidene difluoride membranes. Membranes were blocked in PBS containing 5% nonfat dry milk. Blots were probed with a monoclonal antibody against COX-I. Blots were then incubated with anti-mouse IgG conjugated to horseradish peroxidase. Antibody-bound protein was detected by ECL.
Competitive RT-PCR. The GLUT4 RNA competitors used in our assays were generated using the streamlined PCR-based approach described by Möller and colleagues (32, 33), which uses commercially available kits for most steps of the procedure. In the first round of PCR, a fragment representing the native GLUT4 mRNA was generated by conventional RT-PCR, purified on a gel, and eluted using an extraction kit (Quianx II). The purified first-round product was subjected to a second round of PCR, using a hybrid forward primer, that results in a product in which the forward and reverse primer sites are 100 bp closer to each other, i.e., an
100-bp deletion. The forward and reverse primers and the hybrid forward competitor primers used in this study are listed below. The competitor fragment was cloned into a pGEM-T Easy vector containing T7 promoters. After linearization of the plasmid and Klenow treatment, sense-competitor RNA was transcribed in vitro using a Riboprobe kit (Promega), and the resulting RNA copies were purified from the plasmid template by DNAse 1 digestion. The identity of the RNA and extent of the deletion were verified by sequencing: GLUT4 (D84345
[GenBank]
) forward 5'-GTGTGGTCAATACCGTCTTCACG-3'; reverse 5'-CCATTTTGCCCCTCAGTCATTC-3'; competitor forward 5'-GTGTGGTCAATACCGTCTTCACGATCTTGATGACGGTGGCTCTGC-3'.
Total RNA was isolated from 20 mg of triceps muscle by the method of Chomczynski and Sacchi (6) and suspended in diethyl pyrocarbonate-treated H2O containing 0.1 mM EDTA. For RNA quantitation by competitive RT-PCR, RT reactions were performed with a constant amount of tissue mRNA and different amounts of the competitor mRNA. Once optimal initial concentrations of tissue mRNA and competitor mRNA were established, final RT-PCR was performed. The RT involves the use of the Reverse Transcription System (Promega). Aliquots of each RT reaction were added to a PCR Master Mix (Promega) mixture containing Taq DNA polymerase, dNTPs, MgCl2, reaction buffers at optimal concentrations for efficient amplification of DNA templates by PCR, and 10 pmol of both sense and antisense primers. The reaction medium was subjected to PCR amplification. After the lid was warmed at 105°C and 120 s at 94°C, the PCR mixtures were subjected to 35 cycles of PCR amplification with a cycle profile including denaturation for 60 s at 94°C, hybridization for 60 s at 56.5°C, and elongation for 60 s at 72°C.
The PCR products were separated by electrophoresis on 2% agarose, stained with ethidium bromide, photographed, and analyzed by densitometry. The ratio of sample to competitor band densities was then calculated.
Statistics. Values are expressed as means ± SE. Statistically significant differences were determined using ANOVA. When ANOVA showed significant differences, the Student-Newman-Keuls post hoc test was performed to discern statistically significant differences.
![]() |
RESULTS |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
|
Glucose transport activity. The increase in glucose transport activity in response to a maximal insulin stimulus was approximately twofold higher in epitrochlearis muscles of the exercised rats 18 h after the last bout of exercise than in muscles of sedentary fasted animals (Fig. 2). This enhancement of insulin-stimulated glucose transport activity had reversed completely 42 h after exercise in muscles of rats fed the high-carbohydrate diet. These findings confirm the results of previous studies (26, 29, 30). In contrast, the approximately twofold greater increase in glucose transport activity in response to insulin was still present 66 h after exercise in epitrochlearis muscles of rats fed the carbohydrate-free diet (Fig. 2). The persistence of the increases in GLUT4 protein and insulin-stimulated 2-DG transport were closely correlated (Fig. 2).
|
Muscle glycogen concentration. Epitrochlearis muscle glycogen concentration in rats fed the high-carbohydrate diet for 18 h after exercise was increased approximately twofold above that found in the high-carbohydrate diet-fed sedentary control animals (Fig. 3). This increase in muscle glycogen persisted unchanged 42 h after exercise. The postexercise increase in muscle glycogen was prevented by feeding the rats the carbohydrate-free diet for 42 or 66 h after exercise. One of the hypotheses that we were testing in this study was that the exercise-induced increase in the ability of muscle to accumulate glycogen would persist until the glycogen supercompensation actually occurred. This hypothesis appears to be correct, as the increase in epitrochlearis muscle glycogen was as great in rats maintained in the glycogen-depleted state for 66 h and then fed the high-carbohydrate diet as in muscles of rats fed the high-carbohydrate diet for 18 h immediately after exercise (Fig. 3). This increase in glycogen was associated with a decrease in GLUT4 protein back to the control sedentary level (Fig. 1).
|
GLUT4 mRNA. The increase in muscle GLUT4 protein induced by exercise is preceded, and probably mediated, by an increase in GLUT4 mRNA (40). In the present study, GLUT4 mRNA was increased approximately threefold fold 18 h after exercise. This increase in GLUT4 mRNA reversed completely between 18 and 42 h after exercise in the high-carbohydrate-diet rats (Fig. 4). GLUT4 mRNA concentration decreased less rapidly in the carbohydrate-free-diet group and was still elevated 42 h after exercise in the animals fed the carbohydrate-free diet. However, between 42 and 66 h after exercise, GLUT4 mRNA returned to the baseline control level despite prevention of glycogen supercompensation by the carbohydrate-free diet.
|
COX-I. The exercise program used in this study also induces increases in the expression of mitochondrial proteins (2). COX-I, which was used as a mitochondrial marker protein, was increased 18 h after the last exercise bout (Fig. 5). There was no reversal of the increase in COX-I protein in muscles of rats fed carbohydrate for 42 h beginning shortly after the exercise or for 18 h beginning 66 h after exercise. This is in contrast to the rapid reversal of the increase in GLUT4 in response to carbohydrate feeding and muscle glycogen supercompensation.
|
![]() |
DISCUSSION |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
In this context, we tested the hypothesis that muscles maintain their capacity for increased glycogen accumulation after exercise for as long as glycogen supercompensation is prevented after glycogen-depleting exercise. Our findings show that this hypothesis is correct. They provide evidence that maintenance of the capacity for glycogen supercompensation is mediated by persistence of the adaptive increase in GLUT4. As in our previous study (26), the exercise-induced increase in muscle GLUT4 expression reversed completely within 42 h after exercise in rats fed a high-carbohydrate diet that resulted in glycogen supercompensation. In contrast, the increases in GLUT4, insulin responsiveness, and increased capacity for glycogen accumulation persisted unchanged for 66 h, the longest period studied, in muscles of rats fed a carbohydrate-free diet that prevented glycogen supercompensation after exercise. Feeding the glycogen-depleted rats carbohydrate 66 h after exercise resulted in muscle glycogen supercompensation similar in magnitude to that observed in the animals fed chow immediately after exercise. Concomitantly, muscle GLUT4 protein concentration returned to the baseline control level, providing evidence that rapid glucose influx and/or glycogen accumulation are involved in mediating reversal of the exercise-induced increase in GLUT4.
Research interest in the exercise-induced increase in muscle GLUT4 is currently focused on the role that this adaptation can play in ameliorating insulin resistance associated with type 2 diabetes and obesity. However, it seems improbable that countering insulin resistance is the biological function that led to the evolutionary selection of this adaptive response, because obesity and diabetes are extremely rare under natural conditions, i.e., in wild animals. On the other hand, muscle glycogen is necessary for strenuous exercise, and depletion of glycogen stores results in fatigue that makes vigorous exercise impossible (1, 3, 7). Therefore, rapid muscle glycogen repletion can be essential for survival in a fight-or-flight situation that requires prolonged, vigorous exercise. The major factor limiting glycogen accumulation in muscle appears to be the rate of glucose uptake (10, 17, 39, 40). Muscle glucose uptake is limited by both the availability of a high-carbohydrate diet and muscle glucose transport activity. The rate of glucose transport into muscle is limited by glucose transport capacity, which is normally proportional to muscle GLUT4 content (19, 31, 40).
In this context, the rapid increase in GLUT4 expression induced by exercise could provide a survival advantage during prolonged fight-or-flight situations by making possible faster and greater glycogen repletion between exercise bouts or during intervals of less intense exercise. The rapid reversal of the exercise-induced increase in GLUT4 in response to carbohydrate feeding and glycogen supercompensation could serve to prevent glycogen accumulation to the point that it causes muscle stiffness and impaired function. The present results show that additional adaptations are present in glycogen-depleted muscles that prevent this rapid decrease in GLUT4 protein and thus keep the muscles poised for rapid glycogen supercompensation until carbohydrate becomes available.
The increase in GLUT4 expression is a component of an adaptive response to endurance exercise that also involves an increase in mitochondrial biogenesis (2). The signals responsible for this adaptive response appear to be the increases in cytosolic Ca2+, leading to activation of Ca2+-calmodulin-dependent protein kinases, and the decrease in high-energy phosphates, leading to activation of AMP kinase, during contractile activity (24, 3537, 47). After cessation of exercise, the time course of the reversal of the adaptive increase in mitochondrial proteins appears to be determined by the half-lives of the proteins, which, for respiratory chain and citrate cycle enzymes, appears to be 8 days (4). Thus the adaptive increase in mitochondrial enzymes is gradually lost over a period of
1 mo after cessation of training in rats fed a chow diet (4). In the present study, switching rats from a carbohydrate-free to a high-carbohydrate diet that resulted in glycogen supercompensation 66 h after exercise had no effect on COX-I protein level in muscle. In contrast, in rats fed carbohydrate, the increase in GLUT4 protein reversed completely within 40 h (26). The decrease in muscle GLUT4 protein in glycogen-depleted rats fed carbohydrate 66 h after exercise was even more rapid, occurring within 18 h. Two possible explanations for this rapid reversal may be that the GLUT4 protein normally has a short half-life and that rapid glucose influx and glycogen synthesis may be associated with the specific activation of GLUT4 proteolysis.
Our finding in the present study that no decrease in GLUT4 protein occurred over a 66-h period after exercise in glycogen-depleted muscles could, theoretically, be due to either a persistent increase in GLUT4 protein synthesis or an inhibition of GLUT4 proteolysis. Our results suggest that both of these processes may have played a role. Muscle GLUT4 mRNA content had returned to the baseline control value 42 h after exercise in the high-carbohydrate diet-fed rats. However, in the animals fed a carbohydrate-free diet, the persistent decrease in muscle glycogen was associated with maintenance of an increase in GLUT4 mRNA that was still evident 42 h after exercise. Thus the persistent increase in GLUT4 mRNA could have played a role in the maintenance of an exercise-induced increase in GLUT4 protein synthesis. However, an increase in GLUT4 protein content of the glycogen-depleted muscle was still present 66 h after exercise, by which time GLUT4 mRNA had returned to the sedentary control level. This is in contrast to the decline in both GLUT4 mRNA and GLUT4 protein to the sedentary control levels between 18 and 42 h after exercise in the carbohydrate-fed rats. It therefore seems possible that inhibition of GLUT4 proteolysis also played a role in the persistent increase in GLUT4 protein in the glycogen-depleted muscles.
In the high-carbohydrate-diet-fed animals, GLUT4 protein was still elevated 18 h after the onset of muscle glycogen repletion, whereas in the rats maintained in the glycogen-depleted state muscle GLUT4 protein content fell to the sedentary control level within 18 h after the start of glycogen repletion. This difference may be explained by the finding that GLUT4 mRNA was elevated during glycogen repletion starting immediately after exercise, whereas GLUT4 mRNA had fallen to the sedentary control level at the time glycogen repletion was initiated in the rats maintained for 66 h in the glycogen-depleted state.
In conclusion, the results of this study provide evidence that prevention of glycogen supercompensation after exercise results in persistence of the increased capacity for muscle glycogen accumulation after exercise for at least 3 days. The mechanism responsible for this phenomenon appears to be a prolongation of the exercise-induced increase in muscle GLUT4 protein.
![]() |
DISCLOSURES |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
![]() |
ACKNOWLEDGMENTS |
---|
![]() |
FOOTNOTES |
---|
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
![]() |
REFERENCES |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|