Diminished hormonal responses to exercise in trained rats

The glucoregulatory response to high-intensity aerobic exercise following training in rats with insulin-treated type 1 diabetes mellitus

An acute bout of exercise elicits a rapid, potentially deleterious, reduction in blood glucose in patients with type 1 diabetes mellitus (T1DM). In the current study, we examined whether a 10-week aerobic training program could alleviate the rapid exercise-associated reduction in blood glucose through changes in the glucoregulatory hormonal response or increased hepatic glycogen storage in an insulin-treated rat model of T1DM. Thirty-two male Sprague-Dawley rats were divided evenly into 4 groups: non-T1DM sedentary (C) (n = 8), non-T1DM exercised (CX) (n = 8), T1DM sedentary (D) (n = 8), and T1DM exercised (DX) (n = 8). Exercise training consisted of treadmill running for 5 days/week (1 h, 27 m/min, 6% grade) for 10 weeks. T1DM was induced by multiple streptozotocin injections (20 mg/kg) followed by implantation of subcutaneous insulin pellets. At week 1, an acute exercise bout led to a significant reduction in blood glucose in DX (p < 0.05), whereas CX exhibited an increase in blood glucose (p < 0.05). During acute exercise, serum epinephrine was increased in both DX and CX (p < 0.05), whereas serum glucagon was increased during recovery only in CX (p < 0.01). Following aerobic training in DX, the exercise-mediated reduction in blood glucose remained; however, serum glucagon increased to the same extent as in CX (p < 0.05). DX exhibited significantly less hepatic glycogen (p < 0.001) despite elevations in glycogenic proteins in the liver (p < 0.05). Elevated serum epinephrine and decreased hepatic adrenergic receptor expression were also evident in DX (p < 0.05). In summary, despite aerobic training in DX, abrupt blood glucose reductions and hepatic glycogen deficiencies were evident. These data suggest that sympathetic overactivity may contribute to deficiencies in hepatic glycogen storage.

Effect of lactate on insulin action in rats

The aim of the study was to explore the effect of lactate on insulin-stimulated glucose uptake in rats. Thirty Wistar rats, weighing 250 - 300 g. were arbitrarily divided into one of three groups (n =10): insulin (1 IU/kg) treated group, lactate (80 mg/kg), and insulin plus lactate treated groups. Blood glucose levels were measured in venous samples collected from the tail vein over 3 hour period after insulin or/and lactate administration in 30-minute intervals. To estimate the influence of lactate on insulin blood level, a total of 20 rats were divided into 4 groups (n = 5): saline, insulin, lactate, and insulin plus lactate treated group, respectively. Sixty minutes after the appropriate application of the same doses of insulin, lactate, and lactate plus insulin, as in the previous part of the experiment, plasma insulin and blood glucose levels were determined in blood samples drawn from the abdominal aorta. Lactate in combination with insulin, in comparison to insulin application alone, caused a dramatic increase in plasma insulin level (p<0,001) and more profound hypoglicaemia (p<0,001). The results of this investigation indicate that lactate application significantly increases the rate of glucose uptake from peripheral blood caused by exogenous insulin action. The possible involvement of lactate in the mechanism of enhanced glucose uptake due to insulin action after physical exercise is discussed.

Recurrent intermittent restraint delays fed and fasting hyperglycemia and improves glucose return to baseline levels during glucose tolerance tests in the Zucker diabetic fatty rat--role of food intake and corticosterone

Short-term elevations of stress hormones cause an increase in glycemia. However, the effect of intermittent stress on development of type 2 diabetes mellitus is unclear. We hypothesized that recurrent intermittent restraint stress would deteriorate glycemia. Male, prediabetic Zucker diabetic fatty (ZDF) rats were restrained 1 hour per day, 5 days per week for 13 weeks and compared with unstressed, age-matched diabetic controls and lean nondiabetic rats. To differentiate the effects of recurrent restraint stress per se vs restraint-induced inhibition of food intake, a pair-fed group of rats was included. Surprisingly, recurrent restraint and pair feeding delayed fed and fasting hyperglycemia, such that they were lowered 50% by restraint and 30% by pair feeding after 13 weeks. Rats that were previously restrained or pair fed had lower glucose levels during a glucose tolerance test, but restraint further improved the return of glucose to baseline compared to pair feeding (P<.05). This was despite pair-fed rats having slightly lowered food intake and body weights compared with restrained rats. Restraint and pair feeding did not alter insulin responses to an intraperitoneal glucose tolerance test (IPGTT) or fasting insulin, and did not lower plasma lipids. Interestingly, restraint normalized basal corticosterone to one third that in control and pair-fed rats, prevented increases in pretreatment corticosterone seen with pair feeding, and led to habituation of restraint-induced corticosterone responses. After 13 weeks of treatment, multiple regression analysis showed that elevations in basal corticosterone could explain approximately 20% of the variance in fed glucose levels. In summary, intermittent restraint and its adaptations delayed hyperglycemia and improved glucose control in Zucker diabetic fatty rats. These benefits can be partially explained by restraint-induced lowering of food intake, but additional improvements compared to pair feeding may involve lower overall corticosterone exposure with repeated restraint. Paradoxically, these novel investigations suggest some types of occasional stress may limit development of diabetes.

Glucagon Receptors: Effect of Exercise and Fasting

One paradox of hormonal regulation during exercise is the maintenance of glucose homeostasis after endurance training despite a lower increase in plasma glucagon. One explanation could be that liver sensitivity to glucagon is increased by endurance training. Glucagon exerts its effect through a 62 KDa glycoprotein receptor, member of the G protein-coupled receptor. To determine whether changes with exercise in glucagon sensitivity occurred at the level of the glucagon receptor (GR), binding characteristics of hepatic glucagon receptors were ascertained in rat purified plasma membranes. Saturation kinetics indicated no difference in the dissociation constant or affinity of glucagon receptor, but a significantly higher glucagon receptor binding density in liver in endurance trained compared to untrained animals. Along with endurance training, it appears that fasting also changes GR binding characteristics. In animals fasting 24 hrs, a significant increase in glucagon receptor density was also reported. Although the exact mechanism remains unknown, there is no doubt that the liver can adapt to physiological stress through modulation of GR binding characteristics to enhance the hepatic glucose production responsiveness to glucagon. Key words: glucagon sensitivity, liver, endurance training, rats

Swim training increases glucose output from liver perfused in situ with glucagon in fed and fasted rats

The effect of endurance swim training (3 hours per day, 5 days/week, for 10 weeks) on hepatic glucose production (HGP) in liver perfused in situ for 60 minutes with glucagon and insulin was studied in Sprague-Dawley rats. The experiments were performed in fed rats and in rats fasted for 24 hours, but with lactate (8 mmol/L) added to the perfusion medium. Liver glycogen content was significantly lower in fasted than fed rats (fasted untrained and trained: 14 +/- 4 and 11 +/- 3 micromol glycosyl U/g of liver wet weight (WW); fed untrained and trained: 205 +/- 11 and 231 +/- 11 micromol glycosyl U/g of liver WW; not significantly different in trained and untrained rats). Glucagon increased HGP in the 4 experimental groups, but the increases were more rapid and pronounced in trained than in untrained rats in both fed and fasted states. HGP values (area under the curve [AUC] in micromol/g of liver WW) were significantly higher in trained fed (112.1 +/- 7.1 v 85.9 +/- 12.2 in untrained rats) than in trained fasted rats (50.8 +/- 4.4 v 34.7 +/- 3.6 in untrained rats). When compared with untrained rats, the total amount of glucose released by the liver in response to glucagon in trained rats was approximately 30% higher in the fed state and approximately 45% larger in the fasted state. These results indicate that endurance training increases the response of both glycogenolysis and gluconeogenesis to glucagon.

Effect of age and endurance training on the capacity for epinephrine-stimulated gluconeogenesis in rat hepatocytes

The effects of endurance training on hepatic glucose production (HGP) from lactate were examined in 24-h-fasted young (4 mo) and old (24 mo) male Fischer 344 rats by using the isolated-hepatocyte technique. The liver cells were incubated for 30 min with 5 mM lactate ([U-14C]lactate; 25000 dpm/ml) and nine different concentrations of epinephrine (Epi). Basal HGP (with lactate only and no Epi) was significantly greater for young trained (T) (99.6 +/- 6.2 nmol/mg protein) compared with young controls (C) (78.2 +/- 6.0 nmol/mg protein). The basal HGP was also significantly greater for old T (97.3 +/- 5.9 nmol/mg protein) compared with old C (72.2 +/- 3.9 nmol/mg protein). After the incubation with the various concentrations of Epi, Hanes-Woolf plots were generated to determine kinetic constants (Vmax and EC50). Maximal Epi-stimulated hepatic glucose production (Vmax) was significantly greater for young T (142.5 +/- 6.5 nmol/mg protein) compared with young C (110.9 +/- 4.8 nmol/mg protein). Similarly, the Vmax was significantly greater for old T (138.2 +/- 5.0 nmol/mg protein) compared with old C (103.9 +/- 2.5 nmol/mg protein). Finally, there was an increase in the EC50 from the hepatocytes of old T (56.2 +/- 6.2 nM) compared with young T (32.6 +/- 4.9 nM). In like manner, there was an increase in the EC50 from the hepatocytes of old C (59.7 +/- 5.8 nM) compared with young C (33.1 +/- 2.7 nM). The results suggest that training elevates HGP in the basal and maximally Epi-stimulated condition, but with age there is a decline in EC50 that is independent of training status.

Effect of exercise training on liver antioxidant status of deoxycorticosterone acetate salt induced hypertensive rats

Several animal models have been developed to study the pathogenesis of hypertension. Deoxycorticosterone acetate (DOCA) salt induced hypertensive rats are adrenal models used to mimic human Conn's syndrome. Because previous studies showed a beneficial effect of chronic exercise (swimming) on the development of arterial hypertension in spontaneously hypertensive rats (which appears similar to human essential hypertension), we decided to evaluate the effects of swimming on DOCA-salt induced hypertension and liver antioxidant status. Therefore, the aim of this experiment was to study whether the swim training would improve hypertension and liver antioxidant status in DOCA-salt rats. DOCA-salt rats and control Sprague-Dawley rats were trained to swim 1 h/day, 5 days/week for 6 weeks and were sacrificed 48 h after the last exercise period. Systolic blood pressure was recorded before the sacrifice, and liver antioxidant status was evaluated in hepatic homogenates after the sacrifice. Swim exercise did not decrease systolic blood pressure in control and DOCA-salt rats but induced changes in liver activities of antioxidant enzymes, showing that exercise provoked liver oxidative stress in control and DOCA-salt rats. In comparison with our previous studies using spontaneously hypertensive rats, we conclude that the beneficial effects of chronic exercise on systolic blood pressure in rats are dependent on strain and the type of experimental hypertension.

Attenuation of age-related declines in glucagon-mediated signal transduction in rat liver by exercise training

This study investigated alterations in glucagon receptor-mediated signal transduction in rat livers from 7- to 25-mo-old animals and examined the effects of exercise training on ameliorating these changes. Sixty-six young (4 mo), middle-aged (12 mo), and old (22 mo) male Fischer 344 rats were divided into sedentary and trained (treadmill running) groups. Isolated hepatic membranes were combined with [(125)I-Tyr(10)]monoiodoglucagon and nine concentrations of glucagon to determine maximal binding capacity (B(max)) and dissociation constant (K(d)). No alterations were found in B(max) among groups; however, middle-aged trained animals had significantly higher glucagon affinity (lower K(d); 21.1 +/- 1.8 nM) than did their untrained counterparts (50.2 +/- 7.1 nM). Second messenger studies were performed by measuring adenylyl cyclase (AC) specific activity under basal conditions and with four pharmacological stimulations to assess changes in receptor-dependent, G protein-dependent, and AC catalyst-dependent cAMP production. Age-related declines were observed in the old animals under all five conditions. Training resulted in increased cAMP production in the old animals when AC was directly stimulated by forskolin. Stimulatory G protein (G(s)) content was reduced with age in the sedentary group; however, training offset this decline. We conclude that age-related declines in glucagon signaling capacity and responsiveness may be attributed, in part, to declines in intrinsic AC activity and changes in G protein [inhibitory G protein (G(i))/G(s)] ratios. These age-related changes occur in the absence of alterations in glucagon receptor content and appear to involve both G protein- and AC-related changes. Endurance training was able to significantly offset these declines through restoration of the G(i)/G(s) ratio and AC activity.

Lipid metabolism during endurance exercise

Endogenous triacylglycerols represent an important source of fuel for endurance exercise. Triacylglycerol oxidation increases progressively during exercise; the specific rate is determined by energy requirements of working muscles, fatty acid delivery to muscle mitochondria, and the oxidation of other substrates. The catecholamine response to exercise increases lipolysis of adipose tissue triacylglycerols and, presumably, intramuscular triacylglycerols. In addition, increases in adipose tissue and muscle blood flow decrease fatty acid reesterification and facilitate the delivery of released fatty acids to skeletal muscle. Alterations in fatty acid mobilization and the relative use of adipose and intramuscular triacylglycerols during exercise depend, in large part, on degree of fitness and exercise intensity. Compared with untrained persons exercising at the same absolute intensity, persons who have undergone endurance training have greater fat oxidation during exercise without increased lipolysis. Available evidence suggests that the training-induced increase in fat oxidation is due primarily to increased oxidation of non-plasma-derived fatty acids, perhaps from intramuscular triacylglycerol stores. Fat oxidation is lower in high-intensity exercise than in moderate-intensity exercise, in part because of decreased fatty acid delivery to exercising muscles. Parenteral lipid supplementation during high-intensity exercise increases fat oxidation, but the effect of ingesting long-chain or medium-chain triacylglycerols on substrate metabolism during exercise is less clear. This review discusses the relation between fatty acid mobilization and oxidation during exercise and the effect of endurance training, exercise intensity, and lipid supplementation on these responses.

Alterations in beta-adrenoceptor mechanisms in the aging heart. Relationship with heart failure

In chronic heart failure substantial and characteristic changes occur in the function of the adrenergic nervous system. Studies in isolated left ventricular muscle and in single cardiomyocytes from experimental models of aging and, recently, from humans show an age-related reduced contractile response to beta-adrenoceptor stimulation. "beta-adrenoceptor desensitization" is thought to be a general and common mechanism to explain the age- and heart failure-related decrease in beta-adrenoceptor response. The aim of this review is to compare alterations in beta-adrenoceptor mechanisms in physiological cardiovascular aging and chronic heart failure. From an analysis of the overall data on the role of aging in beta-adrenoceptor regulation in human and animal hearts, it is possible to conclude that the reduced response to beta-agonists is common to all species and all cardiac tissues. Moreover, the age-related changes are limited to beta-adrenoceptor-G-protein (s)-adenylyl cyclase system abnormalities, while the type and level of abnormalities change with species and tissues. The modifications shown in the aging heart are not very different from some observed in heart failure. In particular, both in aged and failing hearts we may see that the decrease in beta-adrenoceptor responsiveness is related to changes in G-protein function.

Plasma catecholamine response in trained rats following hemorrhage

The purpose of this study was to evaluate the effect of physical training on hemorrhage-induced catecholamine release in rats. The training program consisted of swimming 5 days a week from 15 min in the first week to 2.5 hours in the 14th week. The rats were divided into four groups. Two groups (one trained and the other untrained) were studied during hemorrhage. The third and fourth groups (one trained and the other untrained) were not subjected to hemorrhage. After 14 weeks, trained rats had a lower heart rate than untrained animals at rest (311.86 +/- 8.9 vs. 361.33 +/- 12.13 bpm, p < .002) for a similar body weight. The trained and untrained groups had the same blood pressure, hematocrit, and norepinephrine responses following hemorrhage. However, plasma epinephrine concentration was lower in the trained rats 15 and 25 min following hemorrhage. These results suggest a decrease of the hemorrhage-induced epinephrine secretion in trained rats. An alteration of the relationship of arterial baroreflexes and of their hormonal effectors is a potential mechanism for the reduced plasma epinephrine level in trained hemorrhaged rats.

Effects of age and endurance training on beta-adrenergic receptor characteristics in Fischer 344 rats

The purpose of this investigation was to examine changes in beta-adrenergic receptor characteristics in various tissues with age and endurance training. Forty-eight young (6 months), middle-aged (15 months), and old (25 months) male Fischer 344 rats were assigned to either a trained or sedentary running group. Animals were endurance trained by 10 weeks of treadmill running at 75% maximal capacity, 1 h/day, 5 days/week. Animals were sacrificed at rest and the heart, liver, and soleus were removed for analysis. Percent of high and low affinity binding sites were determined by competitive binding experiments. Competition curves were generated using 12 concentrations of ICI-89406 (beta 1 antagonist) and ICI-118551 (beta 2 antagonist) to inhibit the total binding of (-) [125I] pindolol (IPIN). Maximal binding site number (Bmax) and affinity (KD) were determined by Scatchard analysis. Heart Bmax did not differ with age or training. An aging effect was observed in liver such that middle-aged and old animals had greater Bmax compared to young animals. In soleus, Bmax was not altered with training but decreased with age. While training had no affect on affinity in the liver and soleus, heart affinity increased with training in both the middle-aged (21%) and old (27%) animals. In soleus, affinity increased but remained unaltered in heart and liver with age. The ratio of beta 1:beta 2 receptors in the heart and liver did not differ with age or training. The influence of age and training on beta-adrenergic receptor characteristics appear to be tissue specific.

Physical conditioning in rats influences the central and peripheral catecholamine responses to sustained exercise

We have investigated the effect of treadmill running in rats (25m.min-1 using a 3% gradient; for 1 h or 2 h) on the cortical extracellular concentrations of noradrenaline (NA) and its main metabolites-3,4-dihydroxyphenylglycol and 3-methoxy-4-hydroxyphenylglycol- and the plasma adrenaline (A) and NA concentrations in relation to prior physical conditioning (1 or 2-h running.day-1 for 12 days). Cortical microdialysates and peripheral blood were collected during 1-h resting, 1-h or 2-h running and for 1 h after exercise. Catecholamines and their metabolites were quantitated using high performance liquid chromatography with electrochemical detection. Treadmill running stimulated concomitantly peripheral catecholamine secretion and central noradrenergic activity, i.e. NA turnover and release. The effect extended into the recovery period even more as the duration of the run increased. Prior physical conditioning greatly influenced the central and peripheral catecholamine responses: the 1-h trained rats experienced the 2-h run as a stressful new event eliciting great long-lasting catecholamine responses, whereas the 2-h trained rats exhibited a progressive sustained catecholamine increase with an earlier onset of the central NA release. The data are discussed in relation to the psychological and intellectual effects of exercise and physical fitness in humans. In addition, the positive correlation found between the central noradrenergic activation and peripheral A secretion confirmed and extended our previous observations in exercising men and gave support to the hypothesis that the elevation of circulating A can be a relevant factor mediating--directly or indirectly--the exercise-induced central effects.

Effect of age on beta-receptors, Gs alpha- and Gi alpha- proteins in rat heart

beta-adrenoceptors, Gs alpha- and Gi alpha-proteins were investigated in a crude plasma membrane preparation from ventricles of young (2-4 months) and senescent (22-24 months) Wistar rats. Receptor density, ligand affinity and beta 1/beta 2-receptor ratio were independent of the age of the rats. The percentage of beta-receptors coupled to G-proteins increased with age. An age-related increase in the level of Gs alpha (124%) was paralleled by an increase in the ratio between the high and low molecular weight form of Gs alpha. The level of Gi alpha-protein almost doubled (170%) upon aging. We conclude that the age-related differences are small at the level of the beta-adrenoceptor molecule, but that the increase in Gi alpha-proteins could be responsible for the age-related reduction in myocardial inotropic and chronotropic responses. Moreover, we suggest that the changes in degree of high affinity coupling between beta-receptor and Gs-protein are possibly linked to alterations in the ratio between the Gs-molecular weight subtypes.

Chronic dynamic exercise improves a functional abnormality of the G stimulatory protein in cardiomyopathic BIO 53.58 Syrian hamsters

BACKGROUND

The effects of chronic exercise training on myocardial contractility and beta-adrenergic signal transduction in hearts with left ventricular dysfunction have not been determined.

METHODS AND RESULTS

Fourteen-week-old cardiomyopathic BIO 53.58 and normal F1B Syrian hamsters underwent 10 weeks of treadmill training and were compared with 24-week-old BIO 53.58 and F1B untrained controls. Left ventricular isovolumic maximum positive dP/dt and peak developed pressure were significantly lower in BIO 53.58 than in F1B controls. Exercise training improved left ventricular contractile indices in BIO 53.58 but not F1B hamsters. The left ventricular beta-adrenergic receptor number (Bmax) was similar in BIO 53.58 and F1B controls. Basal adenylate cyclase activity (ACA) and ACAs stimulated by isoproterenol, 5'-guanylylimidodiphosphate (GppNHp), sodium fluoride, and forskolin were significantly lower in BIO 53.58 than in F1B controls. The functional activity of stimulatory guanine nucleotide-binding protein (Gs), as determined by reconstitution with S49 lymphoma cyc- cell membranes, was significantly lower in BIO 53.58 controls. After 10 weeks of exercise training, Bmax and basal and isoproterenol-stimulated ACAs were unchanged in either BIO 53.58 or F1B hamsters compared with controls. However, in F1B hamsters, training decreased ACAs stimulated by GppNHp, sodium fluoride, and forskolin, with a reduced functional activity of Gs. In contrast, these ACAs increased significantly in association with an enhanced Gs activity in cardiomyopathic BIO 53.58 hamsters after training.

CONCLUSIONS

Chronic exercise training does not change receptor-mediated beta-adrenergic responsiveness in either F1B or BIO 53.58 hamsters. However, exercise training reduces Gs activity in normal F1B hamsters and improves the functional abnormality of Gs in cardiomyopathic BIO 53.58 hamsters. This improvement may potentially contribute to augmented left ventricular contractility in BIO 53.58 after training.

Impaired glucose tolerance after endurance exercise is associated with reduced insulin secretion rather than altered insulin sensitivity

Paired frequently sampled intravenous glucose tolerance tests (FSIGT) were performed on five highly trained athletes within 2 hours of completing a 6-day ultramarathon run (E) and after 2 weeks of complete rest (R). Severe exercise increased free fatty acid (FFA) levels (E 1.2 +/- 0.16 v 0.42 +/- 0.07 mmol/L, P < .01) and norepinephrine levels (E 573 +/- 141 v 224 +/- 33 pg/mL, P < .01), with only moderate reductions in glucose tolerance (glucose disappearance [Kg] E 1.06 +/- 0.2 v R 1.7 +/- 0.3 min-1 x 10(2), P < .05). The minimal model analysis of FSIGT data using the method of Bergman et al (Endocr Rev 6:45-86, 1985) showed a reduced second-phase insulin secretion ([phi 2] E 5.2 +/- 1.3 v 13 +/- 2.2 microU/mL.min-2 per mg/dL, P < .05) and glucose disposition index ([SI x phi 2] E 33.8 +/- 10 v 73.9 +/- 11 mg-1.dL.min-3 x 10(4), P < .02). Insulin sensitivity (SI) and glucose-mediated glucose disposal (SG) were unchanged (SI E 6.9 +/- 1.0 v 6.0 +/- 0.6 min-1 per microU/mL x 10(4); SG E 1.8 +/- 0.6 v 1.4 +/- 0.3 min-1 x 10(2)). Reduced glucose tolerance after prolonged extreme physical exercise was accompanied by reduced phi 2 and not by alterations of SI or SG, despite the marked increase of FFA levels. Elevated norepinephrine levels, reflecting activation of the sympathetic noradrenergic system, was also associated with the reduction in Kg. The reduction in phi 2 would promote mobilization of FFA, the predominant metabolic substrate in these endurance events.

Chronic physical activity: hepatic hypertrophy and increased total biotransformation enzyme activity

Does chronic voluntary physical activity alter hepatic or intestinal capacities for xenobiotic biotransformation? This question was investigated by comparing biotransformation enzyme activities in liver and small intestine of active and sedentary rats. Male rats allowed unlimited access to a running wheel and fed ad lib. for 6 weeks were weight-matched to sedentary controls; the active rats ate 22% more food than the sedentary rats (P less than 0.05). Active rats ran 2.8 +/- 0.6 miles/day. Liver weights were higher in the active rats (11.2 +/- 0.2 vs 9.8 +/- 0.2 g; P less than 0.05), as were total liver protein, and liver microsomal and cytosolic protein (P less than 0.05). As a result of liver hypertrophy, the active rats showed higher total liver activity of several biotransformation enzymes, including 2-naphthol sulfotransferase, styrene oxide hydrolase, benzphetamine N-demethylase, ethacrynic acid glutathione S-transferase and morphine UDP-glucuronosyltransferase (P less than 0.05). In contrast, there was no detectable difference in total liver N-acetyltransferase activity toward p-aminobenzoic acid, 2-naphthylamine, and 2-amino-fluorene as well as, relative hepatic enzyme activity (expressed per g liver or per mg protein) and total and relative intestinal enzyme activity. We conclude that chronic voluntary physical activity, accompanied by an increased food intake, results in liver hypertrophy and potentially increases total hepatic capacity to biotransform certain xenobiotic chemicals.

Effects of running training on the blood glucose and lactate in rats during rest and swimming

The purpose of this study was to examine the effect of physical training on the concentrations of glucose and lactate in the blood of rats during rest and after an acute bout of exercise. We used the following types and periods of training; (i) swimming for 4 weeks, (ii) running for 4 weeks, and (iii) running for 10 weeks. The results clearly show that the resting levels of blood glucose was significantly lower in groups trained by either swimming or running than untrained groups. In addition, after the acute exercise of swimming, animals trained by either running or swimming showed a lower increase in the blood lactate than untrained animals. Furthermore, the increases in the blood glucose after swimming were significantly lower in the group trained by swimming for 4 weeks and by running for 10 weeks than in untrained groups. These results suggest that after physical training by running, animals show an adaptation in the changes in the blood glucose and the blood lactate that are induced by a different type of physical stress, swimming.

Adrenodemedullation does not impair the beneficial effect of physical training in streptozotocin-diabetic rats

This study was designed to ascertain if the improvement in glucose homeostasis found in diabetic animals submitted to physical training is due to an increased secretion of epinephrine by the adrenal medullae. Male Wistar rats were surgically adrenodemedullated (ADM group) or sham-operated (SHAM group). After a 3-week recovery period, a bolus of streptozotocin (40 mg/kg) was injected intravenously (IV), and the animals presenting 1 week later with a blood glucose value between 14 and 22 mmol/L were retained in the protocol and randomly assigned to a sedentary (SHAM-DS and ADM-DS) or trained (SHAM-DT and ADM-DT) group. Physical training was done on a treadmill according to a 10-week progressive program. An IV glucose tolerance test (0.5 g/kg) was performed in previously cannulated rats, 64 hours after the last bout of exercise. Pancreatic insulin and glucagon content was also determined. In sedentary diabetic rats, adrenodemedullation had no effect on plasma glucose, insulin, or glucagon levels, neither in the basal state nor following the glucose load. Basal glucose levels were diminished by training in both SHAM (16.1 +/- 1.5 v 21.8 +/- 0.4 mmol/L; P less than .01) and ADM (12.4 +/- 1.7 v 21.1 +/- 1.2 mmol/L; P less than .01) groups, with values lower in ADM-DT than in SHAM-DT rats (P less than .05). After glucose loading, the glucose levels were significantly lower (P less than .01) throughout the test in both SHAM-DT and ADM-DT rats than in their sedentary counterparts.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of short-term exercise training on muscle glycogen in resting conditions in rats fed a high fat diet

It has been reported that exercise training increases muscle glycogen storage in rats fed a high carbohydrate (CHO) diet in resting conditions. The purpose of this study was to examine whether a 3-week swimming training programme would increase muscle glycogen stores in rats fed a high-fat (FAT) diet in resting conditions. Rats were fed either the FAT or CHO diet for 7 days ad libitum, and then were fed regularly twice a day (between 0800 and 0830 hours and 1800 and 1830 hours) for 32 days. During this period of regular feeding, half of the rats in both dietary groups had swimming training for 3 weeks and the other half were sedentary. The rats were not exercised for 48 h before sacrifice. All rats were killed 2 h after their final meal (2030 hours). The glycogen contents in red gastrocnemius muscle, heart and liver were significantly higher in sedentary rats fed the CHO diet than in those fed the FAT diet. Exercise training clearly increased glycogen content in soleus, red gastrocnemius and heart muscle in rats fed the CHO diet. In rats fed the FAT diet, however, training did not increase glycogen content in these muscles or the heart. Exercise training resulted in an 87% increase of total glycogen synthase activity in the gastrocnemius muscle of rats fed the CHO diet. However, this was not observed in rats fed the FAT diet. The total glycogen phosphorylase activity in the gastrocnemius muscle of the rats of both dietary groups was increased approximately twofold by training.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of acute exercise and prolonged exercise training on blood pressure, vasopressin and plasma renin activity in spontaneously hypertensive rats

The purpose of this study was to investigate the effect of swimming training on systolic blood pressure (BPs), plasma and brain vasopressin (AVP), and plasma renin activity (PRA) in spontaneously hypertensive rats (SHR) during rest and after exercise. Resting and postexercise heart rate, as well as blood parameters such as packed cell volume (PCV), haemoglobin concentration (Hb), plasma sodium and potassium concentrations ([Na+], [K+]) osmolality and proteins were also studied. Hypophyseal AVP had reduced significantly after exercise in the SHR, whereas PRA had increased significantly in the Wistar-Kyoto (WKY) strain used as normotensive controls. Plasma AVP concentration increased in both strains. By the end of the experiment, training had reduced body mass and BPs by only 10% and 6%, respectively. Maximal oxygen uptake was increased 10% and plasma osmolality 2% by training. The postexercise elevation of heart rate was not significantly attenuated by training. A statistically significant reduction in postexercise plasma osmolality (10%) and [Na+] (4%) was observed. These results suggested that swimming training reduced BPs. Plasma and brain AVP played a small role in the hypertensive process of SHR in basal conditions because changes in AVP contents did not correlate with those of BPs. Moreover, there were no differences between SHR and WKY in plasma, hypophyseal and hypothalamic AVP content in these basal conditions. Finally, during moderate exercise a haemodilution probably occurred with an increase of plasma protein content. This was confirmed by the exercise-induced increase of plasma AVP and the reduction of hypophyseal AVP content, suggesting a release of this hormone, which probably contributed to the water retention and haemodilution.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of norepinephrine infusion on in vivo insulin sensitivity and responsiveness

The effect of a continuous infusion of norepinephrine (NE) on glucose disposal in vivo was examined in conscious restrained rats using the euglycemic-hyperinsulinemic clamp technique. NE, 1,000 micrograms.kg-1.day-1 (130 nmol.kg-1.h-1) or vehicle (CO) was infused for 10 days in adult male Sprague-Dawley rats using subcutaneously implanted osmotic minipumps. Body weight and food intake were similar in both groups of animals throughout the study. Fasting basal plasma glucose and insulin concentrations were similar in both groups. However, basal hepatic glucose production (HGP) was increased by NE treatment (9.03 +/- 0.63 vs. 13.20 +/- 1.15 mg.kg-1.min-1, P less than 0.05, CO vs. NE, respectively). Insulin infusions of 2, 6, and 200 mU.kg-1.min-1 suppressed HGP to the same degree in both groups. During 2, 6, and 200 mU.kg-1.h-1 insulin infusions the glucose disposal rate was 65, 60, and 13% greater in NE-treated animals than in controls. Acute beta-adrenergic blockade with propranolol infused at 405 nmol.kg-1.h-1 during the glucose clamps did not normalize glucose disposal. These results demonstrate that chronic NE infusion is associated with increased basal glucose turnover and increased insulin sensitivity of peripheral tissues.

Endurance training, not acute exercise, differentially alters beta-receptors and cyclase in skeletal fiber types

beta-Adrenergic receptor binding characteristics and adenylate cyclase activity were examined in rat skeletal muscle membranes to determine if acute exercise or endurance training altered beta-receptors or adenylate cyclase activity in different muscle fiber types. Binding characteristics and adenylate cyclase activity were examined in type IIA [red fast-twitch, red vastus (RV)], type IIB [white fast-twitch, white vastus (WV)], and type I [red slow-twitch, soleus (S)] muscles. Acute exercise involved a 20-min run on a treadmill at 20 m/min and did not alter beta-receptor density or adenylate cyclase activity in any of the fiber types examined. Endurance training consisted of a progressive treadmill protocol that involved increasing intensity and duration of exercise for 18 wk. beta-Adrenergic receptor density increased in skeletal muscle fiber types primarily recruited during submaximal training (types I and IIA), whereas nonreceptor-mediated adenylate cyclase activity was altered in the three fiber types. Endurance training significantly increased beta-receptor density in RV by 25% and in S by 19% (P less than 0.05), whereas in WV beta-receptor density was not altered. Basal adenylate cyclase activity in RV was increased approximately 2.5 fold by endurance training. Nonreceptor-mediated adenylate cyclase activity, stimulated by NaF and forskolin, increased by approximately twofold in both RV and WV as a result of endurance training. The data support and extend previous observations to show greater effects of endurance training in types I and IIA fibers with respect to alterations in beta-receptor density and alterations in adenylate cyclase activity in each fiber type. Acute exercise did not alter these parameters either in trained or untrained rats.

Adrenaline-mediated glycogenolysis in different skeletal muscle fibre types in the anaesthetized rat

The effect of adrenaline infusion on glycogen breakdown in different muscle fibres types in resting extensor digitorum longus (EDL) and soleus was investigated with histochemical methods. During adrenaline infusion the glycogen content in type IIB and type IIA fibres in EDL, as measured in PAS-stained sections, decreased 24.5% and 11.5% respectively. The glycogen content in type I fibres in EDL and in type I, type IIA and T-fibres in soleus did not change during adrenaline infusion. The present study shows that adrenaline infusion has different effects on glycogen breakdown in the different fibre types in EDL and a different effect on type IIA fibres in EDL and soleus. So far, the reason for these differences is unknown.

Norepinephrine turnover in various tissues at rest and during exercise: evidence for a training effect

This study quantitates the sympathetic response to an acute bout of exercise in specific tissues recruited during exercise in Fischer 344 rats (National Institute on Aging, Bethesda, MD), as well as determining any associated training adaptations. After 10 weeks of treadmill running, significant improvements were found for both endurance time and running speed eliciting maximal response in trained animals compared to controls (477% and 57%, respectively). Norepinephrine turnover (NEt) was determined by the administration of alpha-methyl tyrosine (250 mg/kg), a competitive inhibitor of tyrosine hydroxylase. Animals were killed at rest, after 30 minutes of submaximal (75% max) and at maximal exercise. Cardiac NEt values were 36.3, 141.5 and 528.1 ng/g/h for trained (Tr), 37.2, 134.5 and 638.7 ng/g/h for untrained (Un) animals at rest, submax and max, respectively. A similar response was found in the adrenals. However, the opposite was found with training in the liver. NEt values in Tr animals were greater (6.4, 80.5 and 161.8 ng/g/h) compared with Un (5.8, 25.5 and 75.8 ng/g/h) at rest, submax and max, respectively. It was concluded that training elicits a diminished sympathetic response in the heart and adrenals in response to an acute bout of exercise. Such a training effect was not found in the liver.

Recent advances in hormonal response to exercise

1. This is an article concerning the maintenance of homeostasis during varying metabolic responses to different forms of physical stress. This can be considered the task of the nervous and endocrine systems. 2. Research during the past decade in the field of hormonal response to exercise (as a form of stress) in both exercise-trained and untrained subjects (mostly in the human and rat) is discussed. 3. The responses of the various hormones are discussed in three categories according to the broad chemical classification of the hormones, viz. the polypeptides, the amines and the steroids, although of course, these responses are highly integrated. 4. From the literature it is evident that exercise-trained individuals maintain homeostasis more efficiently than untrained individuals because of an improved integrated endocrine response to changes in homeostatic balance. 5. There seems to be insufficient research being conducted into the steroid hormones--especially in view of the increasing misuse of anabolic steroids in enhancing sports performance these days.

Carbohydrate homeostasis and post-exercise ketosis in trained and untrained rats

1. Experiments were carried out to establish what relationship there is between the concentration of ketone bodies in the blood and the concentrations of glycogen in muscle and liver of thirty-six trained and thirty-six untrained rats exercised at the same absolute load. There were, in addition, non-exercised control animals (of which thirty-six were trained and thirty-six untrained) which were studied on the same day. 2. Training occurred on a level treadmill at 0.2 m/s for 1 h/day, 5 days a week, for 6 weeks. The untrained animals ran on the treadmill every 3rd day for 5 min to maintain familiarity with treadmill running without training them. 3. At the end of the 6th week, the experimental animals ran for 1 h at 0.2 m/s on a level treadmill. Blood 3-hydroxybutyrate and tissue glycogen concentrations were measured at the beginning and immediately after exercise, and then every 30 min for 2 h. 4. Physically trained rats had higher pre- and immediate post-exercise liver glycogen concentrations than untrained rats: 413 +/- 15 and 300 +/- 8 mumol/g before exercise in trained and untrained rats respectively, and 225 +/- 8 and 166 +/- 3 mumol/g immediately after (P less than 0.05). 5. Muscle glycogen, which was also higher in trained than in untrained rats, was resynthesized at approximately the same rate in the two groups of animals (9 and 11 mumol/(g h), but the trained animals were able to achieve this without further depletion of liver glycogen beyond that which had occurred during exercise. In untrained animals liver glycogen concentrations continued to drop for 60 min beyond the end of exercise.(ABSTRACT TRUNCATED AT 250 WORDS)

Demonstration of a different sensitivity to epinephrine in isolated and in vivo hearts

Studies in isolated preparations dealing with myocardial effects of catecholamines usually employ epinephrine concentrations 10-1,000 times higher (10(-7)-10(-5) M) than those observed during maximal cardiac adrenoceptor activation in vivo (10(-9)-5 x 10(-8) M) to obtain measurable cardiac responses. The reason for this discrepancy is still unclear, but it may reflect a diminished sensitivity to catecholamines in vitro. The main purpose of this study was to evaluate if a different myocardial sensitivity to epinephrine in vivo and in vitro does exist and to investigate which epinephrine concentrations in vitro mimic the effect of cardiac adrenoceptor activation in vivo. We compared concentration-response curves to cumulative increasing concentrations of of epinephrine, measured by high pressure liquid chromatography, in chloralose anesthetized or pithed rats (in vivo) and in isolated Langendorff perfused rat hearts (in vitro). We found that the amplitude of response to epinephrine was significantly higher in vivo at all concentrations. For example, an increase of 50 beats/min was observed at an epinephrine concentration of 29 +/- 6 nM in chloralose anesthetized, 25 +/- 4 nM in pithed rats and 149 +/- 52 nM in isolated hearts (P less than 0.05 vs. in vivo). Data on contractility closely parallel those on heart rate. These data indicate that, when methodological differences are minimized, there is a marked reduction in the amplitude of the response to epinephrine in vitro.(ABSTRACT TRUNCATED AT 250 WORDS)

Motor training and physical fitness: possible short- and long-term influences on the development of individual differences in behavior

Individual differences in the behavior of young and adult animals have been documented in diverse species. Possible sources of such variation are of interest to scientists representing many disciplines, including behavior, genetics, and population and evolutionary biology. Two variables that may be important in the ontogeny and maintenance of behavioral differences are (1) individual physical (aerobic and anaerobic) fitness and (2) possible genetic variations underlying individual abilities to engage in, and to benefit from, motor training early in life. The differential development of aerobic and anaerobic capacities may play a significant role in the ontogeny of individual differences in the performance of various motor skills. There also may be short- and long-term consequences of variations in physical fitness that influence individual abilities to perform energy demanding acts during aggressive encounters, interactions with prey or predators, and courtship and breeding. Genetic studies of a limited number of species indicate that specific genotypes are correlated with individual variations in motor performance, even among conspecifics. Multidisciplinary research concerning possible relationships among the ontogeny of physical fitness, genetics, and variations in behavior is needed. Recent work on the relationship between individual differences in physical fitness and variations in the behavior of adult cold-blooded vertebrates provides a good model for comparative research on warm-blooded species.

Effects of training on blood glucose kinetics during glucose challenge in rats

We hypothesized that endurance training would alter blood glucose kinetics in rats given an exogenous glucose challenge. Primed-continuous infusion of H14CO3- and [3-3H]glucose were given to fasted rats during an intravenous glucose load of approximately 150% of the normal endogenous appearance rate for 3 h. In all rats blood glucose concentrations increased with loading, but in trained animals glucose stabilized at significantly lower levels. Trained animals had lower blood glucose turnover rates than the controls (75 +/- 2.3 vs. 120 +/- 6.3 mumoles/kg x min, respectively). Glucose metabolic clearance rates in trained rats (11.5 +/- 1.7) were not different from those in controls (11.6 +/- 1.2 ml/kg x min). Gluconeogenic rates estimated from incorporation of 14C into blood glucose did not differ between trained and untrained groups. However, the rate of hepatic glucose release estimated from the difference between tracer measured and exogenous appearance rate was lower in the trained group. These findings support the concept that when resting trained animals are challenged with an exogenous load, more glucose is diverted to anabolic processes as opposed to increased turnover.

Regulation of skeletal muscle myofibrillar protein degradation: relationships to fatigue and exercise

1. Exercise results in large alterations in cellular metabolic homeostasis and protein turnovers. Exhaustive exercise (as well as starvation, dystrophy, motor nerve disease) results in myofibrillar degradation and has been associated with the decreased force generating capabilities of muscle at fatigue. 2. Complete protein degradation is accomplished by the combined actions of non-lysosomal and lysosomal proteases and the initial breakdown of myofibrillar protein appears to be non-lysosomal mediated. 3. Current evidence suggests that covalent modification (mixed-function oxidation, formation of mixed disulfides, oxidation of methionine residues and phosphorylation) of proteins may mark them for degradation by rendering them more susceptible to proteolytic attack. 4. The rate of covalent modification can be controlled by the level of stabilizing and destabilizing ligands and by factors affecting the activity of the marking reaction. 5. The activities of individual proteases may be controlled by activators and inhibitors. 6. It is suggested that the large alterations in metabolism (hormonal profiles, energy status, redox status and Ca2+ levels) which accompany exercise serve to activate specific proteases and/or induce covalent modifications which mark specific myofibrillar proteins for subsequent proteolytic attack.

Effects of exercise training on plasma catecholamines and blood pressure in labile hypertensive subjects

Plasma catecholamine concentrations (norepinephrine, NE; epinephrine, E) were measured along with heart rate (HR) and blood pressure (BP) at rest in supine (20 min) and standing (10 min) positions and in response to cycle ergometer exercise (5 min; 60% estimated maximal aerobic power) in 12 hypertensive patients before and after 20 weeks of aerobic training on cycle ergometer (six males, one female) or by jogging (five males). In a control group of labile hypertensive patients (five males, two females), estimated maximal aerobic power as well as HR and BP at rest in the supine and standing positions and in response to exercise were not modified from the first to the second evaluation (43 +/- 4 vs 43 +/- 5 ml.kg-1.min-1). In comparison estimated maximal aerobic power significantly increased in both training groups (cycle: 38 +/- 4 to 43 +/- 4; jogging: 38 +/- 3 to 46 +/- 4 ml.kg-1.min-1). However HR and BP were not modified following training, except for small reductions in systolic (18.9 to 18 kPa: 142 to 135 mmHg) and diastolic pressures (13.3 to 12 kPa: 100 to 90 mmHg) (p less than 0.05) at standing rest in the cycle group.(ABSTRACT TRUNCATED AT 250 WORDS)

Amphetamine and alpha-methyl-p-tyrosine affect the exercise-induced imbalance between the availability of tryptophan and synthesis of serotonin in the brain of the rat

This study was performed to investigate the effects of exercise on the synthesis of dopamine (DA) and 5-hydroxytryptamine (5-HT) in the brain of the trained rat. The consequences on the relationships between these two systems were also examined. The sum of the levels of free 3,4-dihydroxyphenyl acetic acid (DOPAC) plus homovanillic acid (HVA) was increased by running and remained elevated throughout the first hour of recovery. Regional studies indicated that the levels of DA were increased in the midbrain, hypothalamus and hippocampus. In these areas, DOPAC showed little variation whereas HVA was largely increased. Administration of pargyline confirmed this increase in the metabolism of DA in hypothalamus and midbrain during running. Food deprivation and administration of tryptophan clearly revealed that running, despite increasing levels of tryptophan and 5-hydroxyindoleacetic acid in brain, reduced the central control of synthesis of 5-HT by tryptophan, probably by inhibiting tryptophan hydroxylase. To examine if such an alteration was caused by the running-induced activation of metabolism of DA in brain, compounds known to affect the activity of DA were used. Administration of amphetamine potentiated the relative inhibition of synthesis of 5-HT induced by running, while alpha-methyl-p-tyrosine prevented this effect of exercise. Haloperidol did not produce any significant change. It is concluded that the control of the synthesis of 5-HT in brain by the availability of tryptophan is altered during exercise and that the increased central catecholaminergic activity participates in such an alteration.

Effects of propranolol and swim-training on blood pressure, plasma electrolytes, and vasopressin in spontaneously hypertensive and normotensive rats

The aim of this work was to study the influence of beta-adrenoreceptor blockade on the adaptation to exercise of one of the hormonal systems (arginine vasopressin) involved in the regulation of blood volume and pressure in spontaneously hypertensive rats (SHR). Systolic blood pressure (SBP) was measured in SHR and WKY rats during 11 wk of swim training. At the end of the training program we determined post-exercise values of plasma arginine-vasopressin (pAVP), osmolality (pOsm), K+ (pK+), Na+ (pNa+), hemoglobin (Hgb), and hematocrit (Hct) in SHR and WKY rats. The following groups were studied: control (C), propranolol treated (PC), swim trained (S), and propranolol-treated and swim-treated (PS). SBP was significantly reduced by swim training or propranolol, bu these beneficial effects on SBP were attenuated when propranolol and swim training were combined. pNa+ and pOsm were significantly reduced by training alone in SHR. This reduction of pNa+ and, consequently, of pOsmol without any modification of other parameters could suggest an Na+ loss. In contrast, the SHR group treated with propranolol alone showed a significant reduction in Hct, suggesting an increased plasma volume without Na+ loss. PS SHR showed a significant reduction of Hgb, Hct, proteins, pNa+, and pOsmol, probably as a consequence of the additive effects of swimming- and propranolol-induced hypervolemia with Na+ loss. The slight and nonsignificant reduction in pAVP observed with either training or propranolol treatment alone became much more pronounced and statistically significant when the 2 treatments were combined. WKY rats showed a much smaller response to exercise and beta-adrenoreceptor blockade than SHR. We conclude that the hypervolemia suggested in PS SHR could be a possible cause of attenuation of the beneficial effects of either swimming or propranolol on SBP.

Effect of aging and endurance training on tissue catecholamine response to strenuous exercise in Fischer 344 rats

The purpose of the present investigation was to determine the catecholamine response in various tissues to a bout of strenuous exercise in young, adult, and old Fischer 344 rats. Further, to study the effect of endurance training on this response, animals from each age group underwent ten weeks of treadmill running at 75% of their functional capacity. On completion of the training program, all animals demonstrated significant increases (P less than 0.05) in VO2max and endurance capacity. At rest or immediately after an acute bout of strenuous exercise, animals were killed, and the heart, liver, kidney, and adrenals were removed for subsequent catecholamine analysis. Resting cardiac catecholamine levels declined significantly with age. In response to an acute exercise bout, epinephrine (E) levels in the heart were greatly reduced with age averaging 141.8, 62.3, and 21.7 ng/g for the 6-, 15-, and 27-month-old untrained group, respectively. The 15- and 27-month-old trained animals demonstrated significantly higher E levels (33% and 91%) than controls. A similar trend was found for norepinephrine (NE) content in the heart in response to acute exercise, with a marked reduction occurring with advancing age (904.6, 580.1, and 400.8 ng/g heart for 6-, 15-, and 27-month-old untrained groups, respectively). Again, training induced a greater NE response in the older trained animals compared to age-matched controls. In contrast, adrenal catecholamine levels showed a tendency to increase with age. It was concluded that when challenged with strenuous physical stress, cardiac catecholamine content is markedly diminished with age. Further, ten weeks of endurance training can attenuate this functional decline.

Beta-adrenergic modulation of insulin binding in skeletal muscle

Both a high physiological concentration (13.1 nM) of epinephrine (E) and acute exercise (AEx) have previously been shown to increase 125I-insulin binding in skeletal muscle. To investigate the site and mechanism of the effect of epinephrine on binding and the possible link between epinephrine- and AEx-enhanced insulin binding, we measured insulin binding in three different preparations: 1) crude membranes derived from whole soleus muscle incubated in vitro with 13.1 nM E, 2) crude membranes with E present in the binding assay, and 3) purified plasma membranes with E present. Epinephrine enhanced binding in all three preparations by 169, 144, and 164%, respectively, at low concentrations of insulin but had little effect at high concentrations. Epinephrine, therefore appears to have its effect at the plasma membrane. Propranolol (10 microM), a beta-adrenergic antagonist, blocked E-enhanced insulin binding and when added to crude membranes made from soleus and extensor digitorum longus muscle of AEx rats reversed the increase in binding seen with exercise. This indicates that E-enhanced insulin binding is mediated by beta-adrenergic receptors and that AEx enhances insulin binding via beta-adrenergic receptors. Sodium orthovanadate (3 mM), a phosphotyrosyl-protein phosphatase inhibitor, also inhibited the increase in insulin binding due to E, implying that E may increase insulin binding by activating a phosphotyrosyl-protein phosphatase which decreases the phosphorylation of a plasma membrane protein, presumably the insulin receptor.

Acute exercise, epinephrine, and diabetes enhance insulin binding to skeletal muscle

We measured insulin binding to crude membranes from rat skeletal muscle, with binding expressed relative to the sarcolemmal marker, cholesterol ester (CE). The amount of CE in the sarcolemma remained constant after streptozotocin-induced diabetes and acute exercise (swam for 90 min). Soleus (predominantly slow-twitch fibers) had higher insulin binding capacity than extensor digitorum longus (predominantly fast twitch). Both diabetes and acute exercise enhanced insulin binding. The shape of the enhanced insulin binding curve differed, however, between diabetes and acute exercise. Diabetes elicited a uniform increase in binding across the insulin concentrations measured (0.04-166 nM); acute exercise elicited the largest increase at the lower concentrations, suggesting different mechanisms cause the enhanced binding. Addition of 13.1 nM epinephrine to the perfusate in a rat hindlimb preparation increased insulin binding in a pattern similar to acute exercise. In contrast, muscular contraction stimulated by the sciatic nerve (1 Hz) or reduction of perfusate insulin from 100 to 40 pM, two additional correlates of acute exercise, had no effect. The increased insulin binding after acute exercise, therefore, appears to be mediated through elevated levels of catecholamines and not upregulation of the insulin receptor.

Plasma catecholamine measurements in resting and stressed conscious rats, using high performance liquid chromatography with electrochemical detection

Plasma epinephrine (EPI) and norepinephrine (NE) were measured in conscious, unrestrained rats at rest, and following exercise, cold stress and hemorrhage. Heart rate and mean arterial pressure were monitored at all points. Minor modifications of a standard, commercially available methodology achieved good chromatographic separation of both EPI and NE. Sensitivity was sufficient for all NE measurements and for EPI measurements in the stress conditions. Estimates of EPI by this procedure were somewhat higher than those in other reports. Absolute values of NE, as well as the selective, qualitative changes found in both EPI and NE under each stress condition, were consistent with those found in other studies which used the radioenzymatic method. Blood withdrawal of two 1.5 ml samples, 3 hours apart, had no detectable effect on EPI, NE, mean arterial pressure or heart rate in otherwise non-stressed rats.

Skeletal muscle and hormonal adaptation to physical training in the rat: role of the sympatho-adrenal system

The main purpose of the present study was to test the hypothesis that adrenergic stimulation of muscle fibres during exercise is a major stimulus for the training-induced enhancement of skeletal muscle respiratory capacity. Therefore, Sprague-Dawley rats either underwent bilateral surgical ablation of the adrenal medulla or were sham-operated. Furthermore, unilateral surgical extirpation of the lumbar sympathetic chain was performed. Half of the rats were then trained for 12 weeks by swimming (up to 5.5 h X day-1, 4 days X week-1) and the remaining rats were sedentary controls. In the gastrocnemius muscle, training significantly increased the mitochondrial enzymes citrate synthase, succinate dehydrogenase, cytochrome c oxidase, and 3-hydroxyacyl-CoA dehydrogenase. In sham-operated rats, the increases were 40%, 43%, 66%, and 25%, respectively, in legs with intact sympathetic innervation. The training-induced enzyme adaptation after adrenodemedullation and/or sympathectomy was not significantly lower than these control values. In sham-operated rats, training decreased resting plasma insulin and glucagon levels and increased liver glycogen content. Similar changes were induced by adrenodemedullation, but training did not augment these changes in adrenodemedullated rats. In conclusion, the data suggest that neither adrenomedullary hormones nor local sympathetic nerves are prerequisites for the training-induced increase in muscle mitochondrial enzymes. The training-induced decline in resting plasma insulin and glucagon levels in intact rats may be mediated by adrenomedullary hormones.

Decrease in ventricular beta-adrenergic receptors in trained diabetic rats

The effects of physical training on beta-adrenergic receptors were evaluated in heart ventricular tissue of diabetic rats. Mild diabetes mellitus was induced in rats with streptozotocin (45 mg/kg, iv). They were then submitted to a progressive 10-week running programme on a treadmill. Binding studies were done at six different concentrations of (-) [3H]dihydroalprenolol (0.5 to 14.4 nM) with ventricular membrane preparations from control (n = 13), sedentary diabetic (n = 9) and trained diabetic rats (n = 10). Direct linear plot analysis of the data revealed that the total number of beta-adrenoceptors was reduced in sedentary diabetic rats as compared to control (2231 +/- 207 vs 2922 +/- 211 fmol/ventricles; P less than 0.05); however, there was no significant change in the receptor density expressed as fmol/mg of membrane protein (40 +/- 3 vs 43 +/- 3; P greater than 0.05). On the other hand, the beta-adrenergic binding sites were decreased in training diabetic rats, either expressed as the total number of receptors (1920 +/- 179 vs 2922 +/- 211; P less than 0.01), or as fmol/mg of membrane protein (30 +/- 3 vs 43 +/- 3; P less than 0.01). There was no significant change in the dissociation constant (KD) of these receptors between groups (KD = 4.08 +/- 0.51, 4.69 +/- 0.93 and 2.88 +/- 0.39 nM respectively for control, sedentary diabetic and diabetic trained animals). The basal epinephrine concentration was significantly increased in trained diabetic rats (102 +/- 21 pg/ml vs 47 +/- 7 for control (P less than 0.05) and vs 49 +/- 9 for sedentary diabetic (P less than 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)

Exercise-induced alterations of hepatic mitochondrial function

In order to examine the effect of a single bout of exercise on hepatic mitochondrial function, starved untrained male rats swam at 34-35 degrees C with a tail weight (5% of body wt.) for 100 min. The rates of ADP-stimulated and uncoupled respiration were higher in the mitochondria isolated from the exercised rats regardless of the substrate utilized. Succinate-linked Ca2+ uptake was 48% greater in the exercised group; however, Ca2+ efflux was markedly depressed. The inhibition of Ca2+ uptake by Mg2+ was higher in the control group, so that the difference in Ca2+ uptake between the two groups was greater in the presence of Mg2+ than in its absence. The response of phosphorylating respiration and Ca2+ fluxes to exogenous phosphate and the pH of the assay medium differed in the exercise group. These observations with the exercised group were not related to non-specific stress. The exercise-induced mitochondrial-functional alterations are reminiscent of those obtained from mitochondria isolated from glucagon- or catecholamine-treated sedentary rats. Thus, adrenergic stimulation as well as other factors may be operating during exercise, leading to an alteration of mitochondrial function in vitro.

Enhanced receptor-cyclase coupling and augmented catecholamine-stimulated lipolysis in exercising rats

To test the hypothesis that alterations of adipocyte beta-adrenergic receptors provide a molecular mechanism for enhanced catecholamine-stimulated lipolysis in physically trained animals, we studied adipocytes derived from rats subjected to 14 wk of swimming and from sedentary controls. Peak glycerol release and peak adenylate cyclase activity in response to epinephrine were increased in swimmers to 255% (P less than 0.01) and 156% (P less than 0.01) of control values, respectively, but neither basal glycerol release, basal cyclase activity, NaF-stimulated cyclase activity, beta-receptor number, nor receptor affinity for [3H]dihydroalprenolol were altered. Epinephrine-stimulated adenylate cyclase activity remained increased in adipocytes from swimmers in the presence of theophylline or adenosine. In the absence of exogenous guanine nucleotide, we observed no differences in the dissociation constants for either the high-affinity (KD = 0.025 microM) or the low-affinity (KL = 11 microM) classes of binding sites for (-)-epinephrine, but the proportion of high-affinity sites was greater in membrane preparations from swimmers than from controls (74 vs. 42%; P less than 0.01). We conclude that receptor-cyclase coupling is enhanced in adipocytes from exercising rats, perhaps due to an improved ability of adrenergic agonists to form the guanine nucleotide reversible high-affinity agonist-receptor complex.

Alpha and beta adrenergic effects on metabolism in contracting, perfused muscle

The role of alpha- and beta-adrenergic receptor stimulation for the effect of epinephrine on muscle glycogenolysis, glucose- and oxygen uptake and muscle performance was studied in the perfused rat hindquarter at rest and during electrical stimulation (60 contractions/min). Adrenergic stimulation was obtained by epinephrine in a physiological concentration (2.4 X 10(-8) M) and alpha- and beta-adrenergic blockade by 10(-5) M phentolamine and propranolol, respectively. Epinephrine enhanced net glycogenolysis during contractions most markedly in slow-twitch red fibers. In these fibers the effect was mediated by alpha- as well as by beta-adrenergic stimulation, the latter involving production of cAMP, phosphorylase activation and synthase inactivation. In contrast, in fast-twitch fibers only beta-adrenergic mechanisms were involved in the glycogenolytic effect of epinephrine. Moreover, inactivation of synthase was less in these fibers. Epinephrine also increased the net release of lactate from the hindquarter, an effect abolished by combined alpha- and beta-adrenergic blockade but by neither alpha- nor beta-adrenergic blockade alone. Epinephrine increased uptake of oxygen and glucose by stimulation of alpha-adrenergic receptors and had a positive inotropic effect during contractions which was abolished by alpha- as well as by beta-adrenergic blockade. The results indicate that epinephrine has profound effects on contracting muscle, and that these effects are elicited through different combinations of alpha- and beta-adrenergic receptor stimulation.

Treadmill training improves intravenous glucose tolerance and insulin sensitivity in fatty Zucker rats

The effect of treadmill training on intravenous glucose tolerance and insulin sensitivity was investigated in Zucker rats (fafa). In 25-week-old fafa animals with the typical metabolic syndrome of massive obesity, glucose intolerance, hypertriglyceridaemia and insulin resistance, treadmill exercise of only very mild intensity was carried out for 6 weeks. The training programme induced a marked reduction in basal and post-glucose challenge plasma insulin levels and a slight but significant improvement of intravenous glucose tolerance. No alteration in insulin sensitivity of the isolated perfused hindquarter was demonstrable. In another study a 9-week training programme was started in 7-week-old fafa rats before the development of their metabolic syndrome. In the sedentary control animals glucose intolerance and insulin resistance developed during the study period; in the training group, both the deterioration of glucose tolerance and the decrease of insulin sensitivity were prevented. This study demonstrates in fafa rats that (a) in young animals physical training may prevent a genetically predisposed deterioration of glucose tolerance and insulin sensitivity and (b) in adult animals mild physical training may improve intravenous glucose tolerance and insulin sensitivity.

Effects of exercise and time elapsed after exercise on VO2, VCO2 and R responses to norepinephrine in rats

The effects of norepinephrine (NE) injection (300 microgram . kg-1 of body weight) on oxygen consumption (VO2), carbon dioxide production (VCO2) and respiratory exchange ratio (R) were investigated in female rats after 1 h of running on a treadmill (21.5 m . min-1) at 10% inclination. Six groups of animals were injected respectively at various times after the exercise (1, 3, 6, 9, 21, and 47 h), and were compared to six non-exercised groups injected at corresponding times. VO2 and VCO2 were monitored continuously during the 20 min preceding injection and for the 60 min following it. The increases in VO2 and VCO2, and the decrease in R were of similar magnitude in both exercised and non-exercised rats (about 30% and 20% for VO2 and VCO2, respectively, and -12% for R). Peak VO2 and R values attained after NE injection varied however with time of injection, specially in exercised animals 1 and 9 h after the run. Exercise significantly delayed time of response to NE for VO2 and VCO2 particularly 1 and 9 h after the running bout. It is concluded that time of day, exercise, and time elapsed after exercise are important factors to consider when studying metabolic responses to catecholamines. Furthermore, it is suggested that such experimental controls might be meaningful in human studies as well.

Muscle glycogenolysis during exercise: dual control by epinephrine and contractions

The interaction of epinephrine and contractions on muscle metabolism was studied in the isolated perfused rat hindquarter. Subtetanic contractions (180/min) through 20 min elicited glycogenolysis and increased phosphorylase a activity. In the soleus, a slow-twitch red muscle, these effects were transient, but when epinephrine at a physiological concentration (2.4 X 10(-8) M) was added to the perfusate, glycogenolysis and phosphorylase activity were sustained throughout contractions. At this high frequency of contractions, the effect of epinephrine was much smaller in the fast-twitch red fibers and not significant in the fast-twitch white fibers of the gastrocnemius muscle. However, during less frequent contractions (30/min) epinephrine increased glycogenolysis and phosphorylase a activity in fast-twitch muscle. The data suggest that epinephrine and muscle contractions exert a dual control of muscle glycogenolysis during exercise: contractions principally stimulate glycogenolysis early in exercise, and a direct effect of epinephrine on muscle is needed for continued glycogenolysis. In addition, epinephrine increased oxygen consumption and glucose uptake in both resting and electrically stimulated hindquarters and, under some conditions, it had a positive inotropic effect on contracting muscle.