In contrast, an increase in

In contrast, an increase in skeletal muscle insulin-like growth factor-1 (IGF-1) has been observed after HMB treatment of chicken and human myoblasts [76]. Taken together, these results suggest that HMB may affect GH/IGF-1 axis signaling; however, #GW-572016 chemical structure randurls[1|1|,|CHEM1|]# the effect on skeletal muscle protein synthesis requires more investigation. It is possible that the GH/IGF-1 axis signaling may require a large change in plasma HMB levels. At this point, it is not clear whether a threshold response to a specific concentration of plasma HMB exists. This certainly merits further investigation. Skeletal muscle regeneration

In addition to the direct effects on protein synthesis, HMB has been shown to affect satellite cells in skeletal muscle. Kornaiso et al. [76] cultured myoblasts in a serum-starved state to induce apoptosis. When myoblasts were cultured with HMB, the mRNA expression of myogenic regulatory factor D (MyoD), a marker of cell proliferation, was increased in a dose responsive manner. Moreover, the addition of various GSK126 in vitro concentrations of HMB (25–100 μg/ml) to the culture medium for 24 hours resulted in a marked increase of myogenin and myocyte enhancer factor-2 (MEF2) expression, markers of cell differentiation. As a result, there was a significant increase

in the number of cells, suggesting a direct action of HMB upon the proliferation and differentiation of myoblasts. Skeletal muscle proteolysis Skeletal muscle proteolysis is increased in catabolic states such as fasting, immobilization, aging, and disease [77]. HMB has been shown to decrease skeletal muscle protein degradation both in vitro[72, 73] and in vivo[78]. The mechanisms whereby HMB affects skeletal muscle protein degradation are described below. The ubiquitin-proteasome system is an energy-dependent proteolytic system that degrades intracellular proteins. The activity of this pathway

is significantly increased in conditions of exacerbated skeletal muscle catabolism, such as fasting, immobilization, bed rest and disease [77]. Therefore, inhibition of this proteolytic system could explain the attenuation of skeletal learn more muscle protein losses observed during treatment with HMB. Indeed, HMB has been shown to decrease proteasome expression [72] and activity [72, 78–80] during catabolic states, thus attenuating skeletal muscle protein degradation through the ubiquitin-proteasome pathway. Caspase proteases induce skeletal muscle proteolysis through apoptosis of myonuclei and are commonly up-regulated in catabolic states. However, HMB has also been shown to attenuate the up-regulation of caspases, reduce myonuclear apoptosis in catabolic states, such as skeletal muscle cells cultured with large concentrations of inflammatory cytokines [81], and skeletal muscle unloading [82].

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