Conceptual skills and verbal abilities were better in children aged six to seven years who were from more highly educated families and attended sports clubs.

AIM: We explored the cognitive abilities, health behaviour and cardiorespiratory fitness of preschool Estonian children aged 6-7 and any association with parental education, attending sports clubs and gender. METHODS: Data were obtained from 256 children recruited from 13 randomly chosen kindergartens in Tartu, Estonia. Cognitive abilities were assessed using the modified Boehm Test of Basic Concepts - Third Edition. Objective physical activity (PA) intensity and sedentary levels were measured over seven days by accelerometry. To assess cardiorespiratory fitness, we used the 20-m shuttle run from the PREFIT test battery. Parents reported their educational attainment, together with their child's sports club attendance, sleep duration and screen time. RESULTS: Children from more highly educated families had significantly better test results for conceptual skills, verbal abilities and cardiorespiratory fitness. PA levels, cardiorespiratory fitness and perception and conceptual skills test results were better in children who attended sports clubs. Higher cardiorespiratory fitness level, shorter screen time and sleep duration were associated with better conceptual skills. CONCLUSION: Conceptual skills and verbal abilities were better in the children of more highly educated families and if they attended sports clubs. Children's cognitive abilities may benefit from better cardiorespiratory fitness, reduced sedentary activity and less screen time.

Extracellular matrix and myofibrils during unloading and reloading of skeletal muscle.

The aim of the study was to elucidate the effect of unloading and reloading on the collagen expression and synthesis rate of myofibrillar proteins in fast-twitch (FT) muscle in relation to changes in muscle strength and motor activity. Northern blot analysis was used for testing the specificity of cDNA probes and protein synthesis rate was measured according to incorporation of radioactive leucine into different protein fractions. Unloading depresses collagen type I and III (p<0.001), type IV (p<0.05) and reloading enhances collagen expression in fast-twitch skeletal muscle in comparison with unloading. Enhanced expression of matrix metalloproteinase-2 continued during the first week of reloading (p<0.01) and tissue inhibitor of metalloproteinase-2 during reloading (p<0.05). Changes in collagen expression in FT muscle are in good agreement with changes in myofibrillar protein synthesis during unloading and reloading. In conclusion alterations in extracellular matrix and myofibrillar apparatus in FT skeletal muscle are related to changes in muscle strength and motor activity, are significant in exercise training and determination of recovery periods in the training process as well as in athletes' rehabilitation.

Composition and turnover of contractile proteins in volume-overtrained skeletal muscle.

The purpose of this study was to find the composition shift of myosin heavy chain (MyHC) isoforms in overtraining in fast- and slow-twitch skeletal muscles and different changes in MyHC isofom composition, synthesis and turnover rate between 4-week and 6-week overtraining. Male Wistar rats were randomly assigned to 4-week and 6-week endurance training, 4-week and 6-week overtraining groups. Plantaris (Pla), extensor digitorum longus (EDL), and soleus (Sol) muscles were studied. Daily excretion of 3-methylhistidine (3-MeHis) pool as an indicator for protein degradation increased in the 4-week and 6-week overtraining group to 4.04 +/- 0.21 and 4.32 +/- 0.23 %/day subsequently in comparison with the control group (2.16 +/- 14 %/day, p < 0.001). In Pla muscle MyHC I isoform synthesis rate was 33 200 +/- 2150 (after 6-week overtraining 27 100 +/- 1800, p < 0.05), IIa 32 600 +/- 2100; IId 27 300 +/- 1890 and IIb isoform 20 100 +/- 1600 (after 6-week overtraining 15 500 +/- 1400, p < 0.05) dpm/M leucine/min. Actin synthesis rate increased in fast-twitch muscles during 4- and 6-week overtraining, and in soleus muscle during 6-week overtraining. In EDL and Sol muscle MyHC isoform composition during 6-week overtraining did not change significantly. During the 6-week overtraining the relative content of MyHC I and IIb isoforms decreased and IIa and IId isoforms increased in Pla muscle. The initial increase of MyHC IIb isoform after 4-week overtraining shows the higher stability of this isoform in comparison with MyHC I isoform in fast-twitch muscles during high volume exercise.

Regulation of type IV collagen gene expression and degradation in fast and slow muscles during dexamethasone treatment and exercise.

Glucocorticoids have anti-anabolic effects on many tissues and can cause muscle atrophy. However, their effects on type IV collagen gene expression and degradation in skeletal muscle have not been studied previously. Rats were treated daily with dexamethasone or saline. Half the groups of experimental and control animals were also subjected to daily endurance or uphill running exercise to determine the possible preventive effects of exercise. After an experimental period of 3 or 10 days, the extensor digitorum longus, soleus and tibialis anterior muscles were studied. Dexamethasone treatment for 10 days reduced muscle weight and type IV collagen mRNA abundance in all muscles. Gene expression of matrix metalloproteinase-2 (MMP-2) was decreased in fast muscles. However, the effects of this decrease were possibly attenuated by the simultaneous decrease in the activity of tissue inhibitor of metalloproteinases (TIMP-2). The amount of type IV collagen was not changed during dexamethasone treatment or exercise. The regulation of type IV collagen degradation during dexamethasone treatment varied between slow and fast muscles. Although endurance running prevented muscle atrophy, exercise could not compensate the changes observed in the regulation of type IV collagen gene expression and degradation during dexamethasone treatment.