Gerrit van Kranenburg

A modified PAS stain combined with immunofluorescence for quantitative analyses of glycogen in muscle sections.

Simultaneous analyses of glycogen in sections with other subcellular constituents within the same section will provide detailed information on glycogen deposition and the processes involved. To date, staining protocols for quantitative glycogen analyses together with immunofluorescence in the same section are lacking. We aimed to: (1) optimise PAS staining for combination with immunofluorescence, (2) perform quantitative glycogen analyses in tissue sections, (3) evaluate the effect of section thickness on PAS-derived data and (4) examine if semiquantitative glycogen data were convertible to genuine glycogen values. Conventional PAS was successfully modified for combined use with immunofluorescence. Transmitted light microscopic examination of glycogen was successfully followed by semiquantification of glycogen using microdensitometry. Semiquantitative data correlated perfectly with glycogen content measured biochemically in the same sample (r2=0.993, P<0.001). Using a calibration curve (r2=0.945, P<0.001) derived from a custom-made external standard with incremental glycogen content, we converted the semiquantitative data to genuine glycogen values. The converted semiquantitative data were comparable with the glycogen values assessed biochemically (P=0.786). In addition we showed that for valid comparison of glycogen content between sections, thickness should remain constant. In conclusion, the novel protocol permits the combined use of PAS with immunofluorescence and shows valid conversion of data obtained by microdensitometry to genuine glycogen data.

Habitual physical activity in daily life correlates positively with markers for mitochondrial capacity

Physical exercise training is a powerful tool to maintain or improve mitochondrial density and function (mitochondrial capacity). This study aims to determine whether mitochondrial capacity is also associated with habitual physical activity in daily life (PADL). The capacity of classic markers for mitochondrial density, i.e., the capacity of citrate synthase (CS) and succinate dehydrogenase (SDH), as well the capacity of cytochrome c oxidase (COX) and beta-hydroxyacyl-CoA dehydrogenase (HAD), was determined in homogenized muscle biopsy samples obtained from the vastus lateralis muscle of nonexercising healthy young (age 20+/-2 yr) subjects (31 women, 7 men). PADL was measured during two periods of 14 days using a triaxial accelerometer for movement registration. CS, SDH, and COX were positively associated with PADL [P<0.05, R=0.36, 95% confidence interval (CI): 1.3.10(-4) to 2.2.10(-3); P<0.05, R=0.39, 95% CI: 1.1.10(-5) to 9.9.10(-5); and P<0.05, R=0.33, 95% CI: 7.5.10(-6) to 3.6.10(-4), respectively], and HAD tended to correlate positively with PADL (P=0.06, R=0.31, 95% CI: -2.2.10(-5) to 1.1.10(-3)). The population was subsequently stratified based on the intensity of the activities performed. CS was only associated with PADL in subjects spending more time on high-intensity physical activity, whereas HAD was only associated with PADL in subjects spending less time on low intensity physical activity. We are the first to report that even within the range of normal daily life activities, mitochondrial capacity is positively associated with the level of habitual physical activity in daily life. Thus an active lifestyle may help to maintain or improve mitochondrial capacity.

4-hydroxycatecholestrogen metabolism responses to exercise and training: Possible implications for menstrual cycle irregularities and breast cancer

OBJECTIVE To investigate the behavior of C4-substituted estrogens, the so-called catecholestrogens, in response to acute exercise and training. The 4-hydroxyestrogens are known to have both a strong estrogenic potency and affinity for catechol-O-methyltransferase (COMT), the enzyme that deactivates catecholamines. DESIGN A prospective trial covering three menstrual cycles: a control cycle, a moderate training cycle, and a heavy training cycle. PARTICIPANT(S) Six untrained, healthy, eumenorrheic women (mean pretraining maximum oxygen uptake: 40.9 +/- 4.9 mL/kg per minute, body fat: 27.9% +/- 3.6%) volunteered for this study. INTERVENTION(S) An incremental exercise test to exhaustion on a cycle ergometer, in the follicular and luteal phases, before and after a brief but exhaustive training program. MAIN OUTCOME MEASURE(S) Hormone measurements included follicular and luteal phase plasma E2, LH, catecholamines, PRL, total unconjugated and conjugated estrogens, total 4-hydroxyestrogens (4-OHE), and 4-hydroxyestrogen-monomethylethers (4-MeOE). RESULT(S) Pretraining baseline 4-OHE levels were significantly higher in the luteal phase (66 +/- 9 pg/mL; mean +/- SEM) than in the follicular phase (51 +/- 7 pg/mL). Pretraining and post-training baseline 4-MeOE values were below minimal detection limits (< 35 pg/mL). During incremental exercise, catecholamines, PRL, E2, unconjugated and conjugated estrogens, 4-OHE, and 4-MeOE always increased (the increases in 4-OHE during exercise were more pronounced before training, contrary to the 4-MeOE being most increased after training). The baseline 4-MeOE:4-OHE ratio (a measure of catecholestrogen activity) significantly increased with progressive training. CONCLUSION(S) Because 4-OHE have been shown to be able to control the hypothalamic gonadotropin oscillator and to stimulate the luteolytic prostaglandin PGF2 alpha, the acute exercise-induced increases of 4-OHE and their positive correlation with lactate levels may indicate a key process in the pathogenesis of exercise-associated menstrual irregularities. In addition, 4-OHE, when insufficiently O-methylated, are known to be capable of raising mutagenic superoxide free radicals and causing DNA damage that may lead to breast cancer. The results of the present study also may be of significance for the apparent protective effects of sports participation against cancer of the breast.

Modulation of glycogen metabolism of rat skeletal muscles by endurance training and testosterone treatment

The effects of training and/or testosterone treatment on glycogen content and the activities of glycogen synthase, glycogen phosphorylase, and fructose-6-phosphate kinase were studied in extensor digitorum longus (EDL) and soleus muscles of intact adult female rats. One group of rats remained sedentary, whereas another group was trained for 7 weeks. Thereafter, both the sedentary and trained rats were subdivided into two control and four testosterone-treated subgroups. Testosterone was administered by a silastic implant. Training was continued for 2 weeks. On the final day of the experiment rats from one trained control and one trained testosterone-treated subgroup ran for 60 min submaximally. Upon testosterone treatment of sedentary rats the glycogen concentration was not changed. However, in the soleus, but not in the EDL, the glycogen content was increased by training (P<0.05) which could, at least partly, be explained by a decrease in activity of active glycogen phosphorylase (P < 0.05). In the EDL of trained rats testosterone treatment increased glycogen content significantly by both an increase in activity of active glycogen synthase and a decrease in activity of active glycogen phosphorylase (P<0.05). In the EDL and soleus of testosterone-treated animals from the exercised subgroup a significant sparing of glycogen was observed, which could be explained by an increase in activity of active glycogen synthase and, in the soleus, could also be explained by a concerted decrease in active glycogen phosphorylase (P<0.05). In the two muscles studied, we also found that testosterone treatment in trained animals shifted the fibre type distribution towards more oxidative fibres in both types of muscle in comparison with the control animals. We conclude that testosterone, at a pharmacological dose, potentiates the training-induced increase in glycogen content of skeletal muscle and induces a glycogen-sparing effect after submaximal exercise.

Age-related decline in muscle strength and power output in acid 1-4 alpha-glucosidase knockout mice

A hallmark of glycogen storage disease type II, caused by defective α‐glucosidase (AGLU) activity, is a progressive decline in muscle performance. The objective of this study was to determine the relative contribution to this decline in muscle performance of (1) decline in muscle mass; (2) decline in muscle protein content per unit mass; and (3) accumulation of glycogen. To this end, isometric torque and power in AGLU−/− mice at 7, 13, and 20 months were assessed in situ. Power (∼24 mW) and torque (∼2.45 Nmm) did not change with age in control animals, but declined significantly in AGLU−/− mice, in the three age groups. No decline in protein content per unit muscle mass was observed. Muscle atrophy explained one third of the decline in muscle performance; the remaining part was attributed to a decrease in muscle quality—a decrease in mechanical performance per unit muscle mass. Mechanical effects of glycogen inclusions could not fully explain this decrease. Additional factors must therefore play a role. Muscle Nerve, 2005

Effect of testosterone and endurance training on glycogen metabolism in skeletal muscle of chronic hyperglycaemic female rats

Objectives: To investigate in glycolytic and oxidative muscles of trained (nine weeks) and untrained hyperglycaemic female rats the effect of hyperandrogenicity and/or endurance training on energy metabolic properties. Methods: Glycogen content and activity of muscle enzymes with regulatory functions in glycogen synthesis were examined. Results: Testosterone treatment increased glycogen content of extensor digitorum longus (EDL) and soleus muscles of hyperglycaemic sedentary (18% and 84% respectively) and hyperglycaemic trained (7% and 16% respectively) rats. In both types of muscle of the hyperglycaemic testosterone treated exercised subgroup, less depletion of glycogen was found than in the untreated group (38% and 87% for EDL and soleus respectively). Conclusions: The mechanisms by which training and/or hyperandrogenism alone or in combination elicits their specific effects are complex. Differences in sex, surgery, levels of hormones administered, and exercise model used may be the main reasons for the observed discrepancies. Conclusions from the results: (a) hyperandrogenism is not a primary cause of the development of insulin resistance; (b) glycogen content of slow and fast twitch muscle is increased by training through increased glycogen synthase activity. The most plausible explanation for differences between different muscle fibre types is the different levels of expression of androgen receptors in these fibres. Hyperandrogenicity therefore acts on energy metabolic variables of hyperglycaemic animals by different mechanisms in glycolytic and oxidative muscle fibres.

Exercise-induced changes in enzymatic O-methylation of catecholestrogens by erythrocytes of eumenorrheic women.

The present study was designed to assess the effects of acute exercise and short-term intensive training on catechol-O-methyltransferase (COMT) activity. COMT inactivates catecholamines and converts primary catecholestrogens (CE) into their O-methylated form yielding the 2- (2-MeOE) and 4-methoxyestrogens (4-MeOE). Blood samples were obtained from 15 previously untrained eumenorrheic women (mean +/- SE, VO2max: 43.8 mL x kg-1 x min-1 +/- 0.6) before and after a 5-d intensive training period, at rest and during incremental exercise. COMT activity was determined in the erythrocytes (RBC-COMT) after incubation of blood lysate with primary CE. The formation of both 2- and 4-MeOE was significantly higher (P < 0.05) during the luteal (LPh) than during the follicular phase (FPh). The amount of 2-MeOE formed (FPh: 4.2 +/- 0.2%; LPh: 4.9 +/- 0.2%) was significantly greater than the produced amount of 4-MeOE (FPh: 1.4 +/- 0.1%; LPh: 1.5 +/- 0.1%) (P < 0.05). Both before and after training, incremental exercise did not significantly alter RBC-COMT activity although we observed a trend for RBC-COMT activity increasing proportionally with the exercise intensity. After a brief period of exhaustive training, during rest the formation of 2-MeOE (FPh: +16.7%, LPh: +15.7%) and 4-MeOE (FPh: +28.6%; LPh: +40%) was significantly (P < 0.05) increased. The results of the present study are consistent with earlier findings reporting increased plasma concentrations of O-methylated CE following training. It is concluded that RBC-COMT activity is increased by brief intensive training, but not by acute exercise. We speculate that an increase in COMT-catalyzed O-methylation of CE may indicate that less COMT is available to deactivate norepinephrine.