1 Medical Research Laboratory and Medical Department M (Endocrinology and Diabetes), Aarhus University Hospital, Aarhus, Denmark
2 Department of Clinical Pharmacology, University of Aarhus, Aarhus, Denmark
3 Research Division, Joslin Diabetes Center and Department of Medicine, Brigham and Womens Hospital and Harvard Medical School, Boston, Massachusetts
4 Department of Research and Development, Novo Nordisk, Bagsvaerd, Denmark
![]() |
ABSTRACT |
---|
![]() ![]() ![]() ![]() ![]() ![]() |
---|
The incidence of type 2 diabetes is increasing dramatically throughout the world (1). This increase is due to lifestyle factors such as excessive food intake and a lack of physical activity (2). Recent epidemiological studies demonstrate that lifestyle intervention programs can prevent or delay the onset of type 2 diabetes (35).
One of the main features in the pathogenesis of obesity-related diabetes is the presence of insulin resistance (6). It is well established that regular skeletal muscle contraction enhances insulin action in healthy as well as in insulin-resistant individuals (7,8). It is likely that exercise can prevent the progression from the pre-diabetic insulin-resistant condition to overt diabetes by diminishing peripheral insulin resistance and consequently reducing the work load on the ß-cells in the pancreas. Although a vast amount of research has been conducted, the underlying mechanisms by which exercise alters the development of diabetes are not fully clarified.
The AMP-activated protein kinase (AMPK) is an energy preserving enzyme sensitive to changes in the AMP-to-ATP ratio. AMPK is thought to be an important regulator of glucose and fat metabolism in skeletal muscle during metabolic stress (9) and has been shown to be activated during muscle contraction in both rat (10) and human (11) skeletal muscle. 5-Aminoimidazole-4-carboxamide-1-ß-D-riboruranoside (AICAR) is a known activator of AMPK and can be used as an experimental tool to activate AMPK in vivo. Chronic AICAR administration in rats can result in marked changes in skeletal muscle including increases in glycogen stores, GLUT4, and the activity of hexokinase and mitochondria oxidative enzymes (1214). AICAR can also lead to an increase in maximal insulin-stimulated glucose transport and GLUT4 translocation (15). Thus, it is conceivable that repetitive activation of AMPK may be part of the mechanism leading to improved insulin action after exercise.
A commonly used animal model for the study of diabetes, Zucker diabetic fatty (ZDF) rats, are characterized by a progressive ß-cell dysfunction and a leptin receptor defect, the latter resulting in hyperphagia and obesity. After an initial period of compensatory hyperinsulinemia, the animals develop diabetes at 10 weeks of age due to gradually impaired ß-cell function (16). The present study was performed in order to investigate whether repetitive AMPK activation induced by long-term exercise training or AICAR treatment would be capable of preventing the development of diabetes in ZDF rats.
![]() |
RESEARCH DESIGN AND METHODS |
---|
![]() ![]() ![]() ![]() ![]() ![]() |
---|
Acute study.
A single injection of AICAR or treadmill running was examined in separate groups of rats to see if AMPK activity would increase in response to these acute treatments. Male 5-week-old ZDF rats were either subcutaneously injected with a single dose of AICAR (0.5 mg/g body wt) or underwent a single bout of treadmill (Columbus Instrument; Columbus, OH) running (60 min, speed of 25 m/min at a 5% incline). Untreated ZDF rats served as controls (n = 5 in each group). One hour after the subcutaneous AICAR injection or immediately after treadmill running, rats were killed by cervical dislocation. To avoid any effect of muscle spasm and hypoxia, red and white gastrocnemius muscles were removed within seconds and immediately freeze clamped for later determination of AMPK activity.
Intervention study.
The following four groups were studied (n = 12 per group): ZDF AICAR-treated group (AICAR group), ZDF exercise-trained group (exercise group), ZDF untreated control group (untreated group), and lean untreated control group (lean group). The AICAR group was injected with AICAR (0.5 mg/kg s.c.; Toronto Research Chemicals, Toronto, CA) every morning (between 8:00 A.M. and 10:00 A.M.) as previously described (17). The exercise group was subjected to treadmill running for 60 min (speed of 25 m/min at a 5% incline) 5 days a week (between 3:00 P.M. and 6:00 P.M.). The two control groups (untreated and lean) were left untreated. The intervention study was initiated when the rats were 5 weeks of age and lasted for 8 weeks, until 13 weeks of age. Fasting plasma glucose and insulin as well as body weight and food and water consumption were measured weekly. At the end of the 8-week intervention period, a subgroup of rats from the three ZDF groups (AICAR, exercise, and untreated groups) was subjected to hyperinsulinemic-euglycemic clamp studies. Clamped as well as fasted nonclamped rats were finally killed by cervical dislocation, and various tissues were removed, weighed, frozen in liquid nitrogen, and stored for further biochemical or histological examination.
Hyperinsulinemic-euglycemic glucose clamp studies.
To recover before the clamp, a subgroup of rats was instrumented with chronic catheters in the carotid artery (blood sampling) and jugular vein (infusions) 710 days before the clamp study in week 8 of the intervention period. Antibiotic (Tribessen, 24%, 0.2 ml s.c. per rat) and analgesic (Anorphin 0.06 mg s.c. per rat and Rimadyl 2.02.5 mg/kg s.c. per rat) treatments were employed for 3 days after surgery. Diabetic untreated rats were given insulin (Actrapid 25 units/kg s.c.; Novo Nordisk) on the day of surgery and the following day in order to improve their postsurgical recovery. Exercised rats were allowed to rest the day after surgery. During the following days we observed no change in their exercise capacity due to the operation. The clamp studies were done 2024 h after the last AICAR injection or treadmill run, and rats were fasted overnight for 12 h before the clamp. After catheters had been connected to the infusion system, the rats were placed in clamp cages allowing unrestricted behavior. A hyperinsulinemic-euglycemic clamp (60 min tracer equilibration, 30 min basal, and 180 min clamp) was performed in conscious, unrestricted rats as previously described (18). Insulin was infused at a rate of 7.5 mU · kg1 · min1, and plasma glucose levels were clamped close to 7 mmol/l by adjusting an exogenous glucose infusion at 10-min intervals. During the 1st hour of the clamp, plasma glucose in the untreated rats was gradually lowered to the same level as in the two intervention groups. Endogenous glucose appearance and disappearance rates were measured using constant and variable infusions of [3-3H]glucose as described previously (18).
Analytical procedures.
Plasma glucose and insulin were determined using plasma obtained by tail-vein bleeding from rats fasted overnight (10 h). Blood sampling took place 2024 h after the last AICAR injection or treadmill run. Plasma glucose was measured in duplicate immediately after sampling on a Beckmann Glucose Analyzer II (Beckman Instruments, Palo Alto, CA). Insulin levels were determined using an ultrasensitive rat insulin enzyme-linked immunosorbent assay kit (DRG Diagnostics, Marburg, Germany). Glucose concentrations during the clamp experiments were analyzed by the glucose oxidase method using a YSI 2500 STAT (Yellow Springs Instruments, Yellow Springs, OH). Insulin during the clamp and 3H counts in plasma samples were measured as described by Brand et al. (18).
Plasma cholesterol, HDL cholesterol, and triglycerides were determined in a subgroup (n = 5) of fasted nonclamped rats from the three ZDF groups as previously described (17). To minimize stress in rats used in the clamp study, no blood samples were drawn from these rats before they were clamped.
Total crude membrane GLUT4 contents and AMPK subunit isoform and activities.
Twenty micrograms of protein from cardiac and red and white gastrocnemius muscles was used for determination of total GLUT4 content, and AMPK subunit isoform expression was determined by Western blotting as previously described (15,19). Isoform-specific AMPK-1 and -
2 activities were measured in red and white gastrocnemius muscles according to Jessen et al. (20).
Islets histology.
After the animals were killed, the pancreas was removed en bloc, fixed in 4% paraformaldehyde for 48 days, dissected free of surrounding tissue, weighed, and fractionated by the smooth fractionator method (21,22). Each capsule contained 811 randomly picked pancreas cubes, systematically, uniformly representing one-fourth of the total pancreas. These were postfixed, dehydrated, and embedded in paraffin, and 3-µmthick sections were cut from five different levels 600 µm apart, with the depth of the first level selected from a table of random numbers (23). The deparaffinized sections were stained for insulin and a mixture of antibodies to glucagon, somatostatin, and pancreatic polypeptide to visualize ß and non-ß endocrine cells as described (23,24). Furthermore, sections were counterstained with Mayers hematoxyline. Endocrine cell mass (ß and non-ß) was evaluated stereologically in five sections with the origin of the sections blinded to the observer. Area-weighted mean values were calculated from the five sections. The mass of endocrine cells is expressed as milligrams per kilogram of body weight.
Statistics.
Data are presented as the mean ± SE. Statistical significance was assessed by group comparison with the use of one-way ANOVA followed by Tukeys post hoc test. Significance was accepted at P < 0.05.
![]() |
RESULTS |
---|
![]() ![]() ![]() ![]() ![]() ![]() |
---|
Intervention study
Plasma glucose, insulin levels, and food intake during the intervention period.
Preintervention fasting glucose levels were similar among the three pre-diabetic ZDF groups but were elevated as compared with the lean ZDF rats (Fig. 1). At week 5 of the intervention period, fasting plasma glucose increased sharply in the untreated group and remained high throughout the study period. In contrast, plasma glucose was almost unchanged in the AICAR and exercise groups. Before initiation of the intervention study, the pre-diabetic ZDF rats were hyperinsulinemic compared with the lean ZDF rats. In the untreated group, insulinemia increased gradually when compared with the two intervention groups and was already significantly elevated after 3 weeks of the study. Hyperinsulinemia increased until week 5 of the intervention period, after which a decline was observed. As expected, the latter occurred concomitantly with the marked increase in plasma glucose. In contrast, plasma insulin in the AICAR and exercise groups exhibited a sluggish and almost superimposable increase. During the first 3 weeks, rats in the untreated group consumed 3 and 9% more chow than the exercise and AICAR groups, respectively. This difference increased even more during the last 5 weeks of the intervention study, when rats in the untreated group had glucosuria and hyperglycemia. During these weeks, rats in the untreated group consumed 9 and 28% more chow than rats in the exercise and AICAR, respectively.
|
|
|
|
|
|
|
![]() |
DISCUSSION |
---|
![]() ![]() ![]() ![]() ![]() ![]() |
---|
Circulating insulin during the intervention period in the untreated group exhibited a bell-shaped form with initially increasing insulin values until the rats were 910 weeks of age. After the age of 910 weeks, fasting plasma glucose increased sharply with a concomitant decrease in insulin secretion, emphasizing a progressive ß-cell dysfunction in the untreated group. In contrast, in the treated groups, plasma glucose was almost unchanged and circulating insulin was only gradually increased during the entire intervention period. The improved glucose homeostasis of the two intervention groups was further underlined by the hyperinsulinemic-euglycemic clamp data, demonstrating an increase in glucose infusion rate in these groups and especially in the AICAR group. The incremental insulin-stimulated increase in glucose disposal from basal was found to be higher in the two intervention groups when compared with the untreated group. Insulin sensitivity of the liver was apparently also improved in both intervention groups but was predominantly pronounced in the AICAR group. However, the latter should be interpreted cautiously, as the glucose rate of appearance was not reduced in all groups.
Through its conversion to 5-amino-4-imidazole carboxamide riboside 5-monophosphate (ZMP) and probably also the triphosphorylated 5-amino-4-imidazole carboxamide riboside 5'-triphosphate (ZTP), AICAR injection might result in stimulation of other enzyme systems in the cells other than AMPK (25,26). One of these is fructose 1-6-bisphosphatase, which is involved in gluconeogenesis in the liver. Inhibition of this enzyme by ZMP will result in decreased hepatic glucose release. As the present study was undertaken 2024 h after the last AICAR injection, and as no detectable amount of ZMP was found in the liver at this time (data not shown), the insulin-mediated suppression of endogenous glucose release was not likely due to a direct effect of ZMP. Instead, decreased hepatic glucose production with chronic AICAR treatment may be due to the downregulation of several of the key enzymes in the gluconeogenic pathways, a finding observed with AICAR treatment of cultured hepatoma cells (27).
In the current study, both AICAR administration and exercise training augmented peripheral insulin action, and the changes exhibited by either of the treatment groups were nearly identical. Previous studies have shown that both long-term AICAR treatment and exercise training are capable of enhancing GLUT4 protein expression in skeletal muscle (12,28). The present experiment shows a rise in GLUT4 expression in skeletal muscle tissue as a consequence of both AICAR treatment and exercise training. Therefore, one can speculate that the increased whole-body insulin sensitivity demonstrated in the present study, at least partly, might be due to an increased GLUT4 protein level in skeletal muscle tissue.
Rats in the untreated group had a slight but significant increase in kidney weight when compared with those in the exercise and AICAR groups. Increase in kidney weight is often seen as the initial sign of an early diabetic kidney disease in animals (29), and it seems that both exercise training and AICAR administration ameliorate this increase. In the present study, no significant difference in triglycerides and cholesterol was found between rats in the exercise, AICAR, and untreated groups. We have previously reported that in obese Zucker rats, AICAR treatment was associated with a lower level of triglycerides and an increase in HDL cholesterol (17). However, these animals were more obese than in the present study and exhibited considerably higher levels of triglycerides.
Rats in the AICAR group had a slight decrease in food intake during the 1st week of treatment when compared with those in the untreated group. The excessive food intake by the rats in the untreated group increased quite dramatically during the last 5 weeks of the study, when the rats first had glucosuria and then later hyperglycemia. This difference in food intake could be attributed to the fact that 2530% of the intake of calories by a ZDF rat is excreted due to glucosuria (C.L.B., unpublished data). The difference in food intake in the exercise and AICAR groups is explained by the increased calorie consumption due to the daily exercise training and also to the fact that the exercised rats had a larger increase in body weight at the end of the intervention period.
A recent study has indicated that the 3 subunits might be several-fold increased after several weeks of very intense exercise training in rats (30). This increase was found in red quadriceps muscles but not in soleus or white quadriceps muscles. In the present study, we used a more moderate form of exercise training and did not find a change in the
3 subunit protein expression, neither in red nor in white gastrocnemius muscles after the 8-week training period. Nevertheless, we demonstrated markedly improved peripheral insulin sensitivity in these trained rats. This might indicate that the observed increase in
3 subunit expression is only seen after very intense exercise training or is restricted to very specific muscles, e.g., red quadriceps muscles, but may also indicate that an increased
3 subunit expression is not a major contributor to increased insulin sensitivity, as seen after exercise training. Indeed, it should be noticed that a recent report in human muscles demonstrates that training leads to a decrease in the content of the regulatory
3 subunits (31).
In the present study, only the AMPK-1 subunit protein level was found to be increased after exercise training in red muscles when compared with sedentary untreated and AICAR-treated rats.
It has been shown that prolonged, sustained activation of AMPK by AICAR in ß-cell lines induces apoptosis in insulin-producing cells (32,33). This implies that future pharmaceutical approaches to activate AMPK might lead to a devastating damage of pancreatic ß-cells. When AICAR was injected daily subcutaneously as a single dose, ß-cell mass was preserved in the AICAR-treated animals, and morphologically the islet cells in the AICAR-treated group had the most similar appearance as compared with islet cells of lean ZDF rats. This clearly indicates that no serious ß-cell damage had occurred in these rats. In this study, which to our knowledge is the first in vivo study to examine the effect of AICAR on ß-cells, it seems that AICAR treatment preserved ß-cell function close to nearly normal. This could be secondary, of course, to the improved insulin sensitivity observed in these rats and, consequently, less stress on the ß-cell. However, a possible direct protective effect of daily AICAR injection, and therefore repetitive activation of AMPK in the ß-cells, on the function and survival of pancreatic ß-cells cannot be excluded. Further studies in animal models that are predisposed to developing diabetes, but characterized by a developing ß-cell dysfunction rather than by peripheral insulin resistance like the ZDF rats, are needed to explore whether repetitive activation of AMPK in ß-cells in contrast to prolonged sustained activation might directly have a positive effect on ß-cell function and survival. The ß-cell mass in ZDF rats initially increases in size due to the peripheral insulin resistance when the rats grow older. At this point, the rats are able to maintain a slightly elevated plasma glucose level as compared with lean ZDF rats. When the rats grow older, the structure of the islet cells in the ZDF rats starts to degenerate with increasing amounts of connective tissue and the ß-cell mass dramatically decreases as seen in the untreated group in the present study. The enhanced ß-cell mass in the exercised rats compared with the AICAR-treated rats might be due to the fact that the ß-cells in the exercised animals were more stressed, as they were found to be less insulin sensitive than the AICAR-treated animals. It is possible that a more vigorous exercise program would have improved insulin sensitivity more than the exercise protocol used in the present study, therefore preventing the expansion in ß-cell mass.
The present study is the first to show that long-term AICAR administration, like exercise, can prevent the development of hyperglycemia in an animal model predisposed to developing diabetes. This is partly due to an improved peripheral insulin sensitivity in skeletal muscles, apparently also due to an increase in insulin-mediated suppression of endogenous glucose release and partly due to the fact that long-term AICAR administration and exercise training maintain ß-cell function. To our knowledge, this is the first in vivo study to demonstrate how long-term AICAR administration can preserve nearly normal islet morphology in the pancreas of animals predisposed to developing diabetes. As AMPK has been suggested to play an important role in muscle metabolism during exercise (26), and as both exercise training and AICAR administration activate AMPK, it is obvious to speculate that at least part of the beneficial effects of the two stimuli in preventing the development of hyperglycemia in the treated rats might be mediated through this kinase.
![]() |
ACKNOWLEDGMENTS |
---|
We thank H. Petersen, E. Hornemann, B. Hansen, S. Gronemann, and J. Hansen for excellent technical assistance and Prof. H. Ørskov and Dr. J. Sturis for stimulating discussion.
Address correspondence and reprint requests to Sten Lund, MD, DMSc, Medical Department M (Endocrinology and Diabetes), Aarhus University Hospital, Aarhus Sygehus, DK-8000 Aarhus C, Denmark. E-mail: sl{at}dadlnet.dk
Received for publication August 10, 2004 and accepted in revised form January 1, 2005
AICAR, 5-aminoimidazole-4-carboxamide-1-ß-D-riboruranoside; AMPK, AMP-activated protein kinase; ZMP, 5-amino-4-imidazole carboxamide riboside 5'-monophosphate
![]() |
REFERENCES |
---|
![]() ![]() ![]() ![]() ![]() ![]() |
---|