Although cytokine-induced nuclear factor kappaB (NF-kappaB) pathways are involved in muscle wasting subsequent to disease, their potential role in disuse muscle atrophy has not been characterized. Seven days of hind limb unloading led to a 10-fold activation of an NF-kappaB-dependent reporter in rat soleus muscle but not the atrophy-resistant extensor digitorum longus muscle. Nuclear levels of p50 were markedly up-regulated, c-Rel was moderately up-regulated, Rel B was down-regulated, and p52 and p65 were unchanged in unloaded solei. The nuclear IkappaB protein Bcl-3 was increased. There was increased binding to an NF-kappaB consensus oligonucleotide, and this complex bound antibodies to p50, c-Rel, and Bcl-3 but not other NF-kappaB family members. Tumor necrosis factor alpha (TNF-alpha) and TNF receptor-associated factor 2 protein were moderately down-regulated. There was no difference in p38, c-Jun NH(2)-terminal kinase or Akt activity, nor were activator protein 1 or nuclear factor of activated T cell-dependent reporters activated. Thus, whereas several NF-kappaB family members are up-regulated, the prototypical markers of cytokine-induced activation of NF-kappaB seen with disease-related wasting are not evident during disuse atrophy. Levels of an anti-apoptotic NF-kappaB target, Bcl-2, were increased fourfold whereas proapoptotic proteins Bax and Bak decreased. The evidence presented here suggests that disuse muscle atrophy is associated with activation of an alternative NF-kappaB pathway that involves the activation of p50 but not p65.
The intracellular signals that mediate skeletal muscle protein loss and functional deficits due to muscular disuse are just beginning to be elucidated. Previously we showed that the activity of an NF-κB-dependent reporter gene was markedly increased in unloaded muscles, and p50 and Bcl-3 proteins were implicated in this induction. In the present study, mice with a knockout of the p105/p50 (Nfkb1) gene are shown to be resistant to the decrease in soleus fiber cross-sectional area that results from 10 days of hindlimb unloading. Furthermore, the marked unloading-induced activation of the NF-κB reporter gene in soleus muscles from WT mice was completely abolished in soleus muscles from Nfkb1 knockout mice. Knockout of the B cell lymphoma 3 (Bcl3) gene also showed an inhibition of fiber atrophy and an abolition of NF-κB reporter activity. With unloading, fast fibers from WT mice atrophied to a greater extent than slow fibers. Resistance to atrophy in both strains of knockout mice was demonstrated clearly in fast fibers, while slow fibers from only the Bcl3 -/-mice showed atrophy inhibition. The slow-to-fast shift in myosin isoform expression due to unloading was also abolished in both Nfkb1 and Bcl3 knockout mice. Like the soleus muscles, plantaris muscles from Nfkb1 -/-and Bcl3 -/-mice also showed inhibition of atrophy with unloading. Thus both the Nfkb1 and the Bcl3 genes are necessary for unloading-induced atrophy and the associated phenotype transition. IntroductionReduced muscular activity due to bed rest, limb immobilization, sedentary lifestyles, or space flight is a widespread phenomenon that leads to significant muscle atrophy, weakness, fatigue, and insulin resistance (reviewed in ref. 1). While it has been known for some time that the loss in muscle protein due to disuse results from decreases in protein synthesis and increases in protein degradation rates (2), we are just beginning to learn about the upstream triggers and signaling pathways that regulate the changes in these target systems that determine protein content. While myostatin (3, 4) and glucocorticoids (5) have been studied for a role in atrophy, and both can induce atrophy in normal muscle, neither is required for disuse atrophy in vivo (5, 6). Recent work suggests that inhibition of the Akt growth pathway in muscle may be involved in the progression of disuse atrophy. Proteins of the Akt cascade of kinases involved in growth control are dephosphorylated with unloading (7-9). This is consistent with the decrease in protein synthesis rate.Work from our laboratory has implicated additional regulatory molecules in unloading-induced muscle atrophy: the NF-κB and inhibitory κB (IκB) family of transcriptional regulators (10). We showed marked transactivation of injected NF-κB reporter plasmids in soleus muscles from non-weight-bearing (i.e., hindlimb-unloaded) rats. Gel-shift and immunoblot data using nuclear extracts of these muscles showed that likely NF-κB/IκB candidates for involvement in disuse atrophy were p50 and Bcl-3, but not p65. The cano...
Role for IκBα, but not c-Rel, in skeletal muscle atrophy
Skeletal muscle atrophy is associated with a marked and sustained activation of nuclear factor-kappaB (NF-kappaB) activity. Previous work showed that p50 is one of the NF-kappaB family members required for this activation and for muscle atrophy. In this work, we tested whether another NF-kappaB family member, c-Rel, is required for atrophy. Because endogenous inhibitory factor kappaBalpha (IkappaBalpha) was activated (i.e., decreased) at 3 and 7 days of muscle disuse (i.e., hindlimb unloading), we also tested if IkappaBalpha, which binds and retains Rel proteins in the cytosol, is required for atrophy and intermediates of the atrophy process. To do this, we electrotransferred a dominant negative IkappaBalpha (IkappaBalphaDeltaN) in soleus muscles, which were either unloaded or weight bearing. IkappaBalphaDeltaN expression abolished the unloading-induced increase in both NF-kappaB activation and total ubiquitinated protein. IkappaBalphaDeltaN inhibited unloading-induced fiber atrophy by 40%. The expression of certain genes known to be upregulated with atrophy were significantly inhibited by IkappaBalphaDeltaN expression during unloading, including MAFbx/atrogin-1, Nedd4, IEX, 4E-BP1, FOXO3a, and cathepsin L, suggesting these genes may be targets of NF-kappaB transcription factors. In contrast, c-Rel was not required for atrophy because the unloading-induced markers of atrophy were the same in c-rel(-/-) and wild-type mice. Thus IkappaBalpha degradation is required for the unloading-induced decrease in fiber size, the increase in protein ubiquitination, activation of NF-kappaB signaling, and the expression of specific atrophy genes, but c-Rel is not. These data represent a significant advance in our understanding of the role of NF-kappaB/IkappaB family members in skeletal muscle atrophy, and they provide new candidate NF-kappaB target genes for further study.
To test for a role of the calcineurin-NFAT (nuclear factor of activated T cells) pathway in the regulation of fiber type-specific gene expression, slow and fast muscle-specific promoters were examined in C2C12 myotubes and in slow and fast muscle in the presence of calcineurin or NFAT2 expression plasmids. Overexpression of active calcineurin in myotubes induced both fast and slow muscle-specific promoters but not non-muscle-specific reporters. Overexpression of NFAT2 in myotubes did not activate muscle-specific promoters, although it strongly activated an NFAT reporter. Thus overexpression of active calcineurin activates transcription of muscle-specific promoters in vitro but likely not via the NFAT2 transcription factor. Slow myosin light chain 2 (MLC2) and fast sarco(endo)plasmic reticulum Ca(2+)-ATPase (SERCA1) reporter genes injected into rat soleus (slow) and extensor digitorum longus (EDL) (fast) muscles were not activated by coinjection of activated calcineurin or NFAT2 expression plasmids. However, an NFAT reporter was strongly activated by overexpression of NFAT2 in both muscle types. Calcineurin and NFAT protein expression and binding activity to NFAT oligonucleotides were different in slow vs. fast muscle. Taken together, these results indicate that neither calcineurin nor NFAT appear to have dominant roles in the induction and/or maintenance of slow or fast fiber type in adult skeletal muscle. Furthermore, different pathways may be involved in muscle-specific gene expression in vitro vs. in vivo.
In the rat, denervation and hindlimb unloading are two commonly employed models used to study skeletal muscle atrophy. In these models, muscle atrophy is generally produced by a decrease in protein synthesis and an increase in protein degradation. The decrease in protein synthesis has been suggested to occur by an inhibition at the level of protein translation. To better characterize the regulation of protein translation, we investigated the changes that occur in various translation initiation and elongation factors. We demonstrated that both hindlimb unloading and denervation produce alterations in the phosphorylation and/or total amount of the 70-kDa ribosomal S6 kinase, eukaryotic initiation factor 2 alpha-subunit, and eukaryotic elongation factor 2. Our findings indicate that the regulation of these protein translation factors differs between the models of atrophy studied and between the muscles evaluated (e.g., soleus vs. extensor digitorum longus).
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