The impact of inflammation on bone mass in children

Bone is a dynamic tissue. Skeletal bone integrity is maintained through bone modeling and remodeling. The mechanisms underlying this bone mass regulation are complex and interrelated. An imbalance in the regulation of bone remodeling through bone resorption and bone formation results in bone loss. Chronic inflammation influences bone mass regulation. Inflammation-related bone disorders share many common mechanisms of bone loss. These mechanisms are ultimately mediated through the uncoupling of bone remodeling. Cachexia, physical inactivity, pro-inflammatory cytokines, as well as iatrogenic factors related to effects of immunosuppression are some of the common mechanisms. Recently, cytokine signaling through the central nervous system has been investigated for its potential role in bone mass dysregulation in inflammatory conditions. Growing research on the molecular mechanisms involved in inflammation-induced bone loss may lead to more selective therapeutic targeting of these pathological signaling pathways

Effects of resistance training on fast- and slow-twitch muscles in rats

The purpose of this study was to investigate the effect of resistance training (RT) on muscle strength, the dependence of that on the fast-twitch (FT) and slow-twitch (ST) fibers hypertrophy, nuclear domain size, synthesis and degradation rate of contractile proteins and on the expression of myosin isoforms’. 16 weeks old Wistar rats were trained on a vertical treadmill for six days a week during six weeks. The power of exercise increased 4.9% per session. In RT group the mass of studied muscles increased about 10%, hindlimb grip strength increased from 5.20±0.27 N/100g bw to the 6.05±0.29 N/100g bw (p<0.05). Cross-sectional area and number of myonuclei of FT and ST fibers in plantaris (Pla) and soleus (Sol) muscles increased, myonuclear domain size did not change significantly. RT increased the MyHC IId isoforms relative content and decreased that of IIb and IIa isoforms in Pla muscle, in Sol muscle increased only IIa isoform. In Pla muscle the relative content of myosin light chain (MyLC) 1slow and 2slow isoforms decreased and that of MyLC 2fast isoforms increased during RT. MyLC 3 and MyLC 2 ratio did not change significantly in Pla but increased in Sol muscle by 14.3±3.4�0(p<0.01). The rat RT programme caused hypertrophy of FT and ST muscle fibers, increase of myonuclear number via fusion of satellite cells with damaged fibers or formation of new muscle fibers as a result of myoblast fusion and myotubes formation, maintaining myonuclear domain size

Physiological role of myosin light and heavy chain isoforms in fast- and slow-twitch muscles: effect of exercise

The aims of the present study were to show the distribution of individual myosin light chain (MyLC) isoforms in fast-twitch (FT) and slow-twitch (ST) muscles and between FT muscles in order to find differences between MyLC isoforms in these muscles, to identify similarities with the distribution of myosin heavy chain (MyHC) isoforms and to investigate changes in these relations during adaptation to endurance and resistance training. Male Wistar strain rats were used in this study. One-dimensional electrophoresis was used for separation of MyHC and MyLC isoforms and two-dimensional electrophoresis was used for identification of MyLC different isoforms. A difference in the relative content of MyLC isoforms between FT muscles exists only in the case of MyLC 1slow and 2slow isoforms. Differences in the relative content of MyHC between FT muscles are considerably larger than differences in the MyLC isoforms. MyHC and MyLC isoforms both participate in the remodelling of contractile proteins during exercise training. In conclusion: The present study shows some discrepancy between the modulation of MyHC and MyLC isoforms in muscles with different oxidative potential during adaptation to endurance and resistance training. In ST muscles, there is full agreement between the increase in the relative content of MyHC IIa isoform and MyLC 2fast and 3fast isoforms during resistance training without significant changes during endurance training. The ratio of MyLC 3 and MyLC 2 isoforms increases during both types of exercise training, but it is two times higher during resistance training