YB-1 gene expression is kept constant during myocyte differentiation through replacement of different transcription factors and then falls gradually under the control of neural activity.

We have previously reported that translation of acetylcholine receptor α-subunit (AChR α) mRNA in skeletal muscle cells is regulated by Y-box binding protein 1 (YB-1) in response to neural activity, and that in the postnatal mouse developmental changes in the amount of YB-1 mRNA are similar to those of AChR α mRNA, which is known to be regulated by myogenic transcription factors. Here, we examined transcriptional regulation of the YB-1 gene in mouse skeletal muscle and differentiating C2C12 myocytes. Although neither YB-1 nor AChR α was detected at either the mRNA or protein level in adult hind limb muscle, YB-1 expression was transiently activated in response to denervation of the sciatic nerve and completely paralleled that of AChR α, suggesting that these genes are regulated by the same transcription factors. However, during differentiation of C2C12 cells to myotubes, the level of YB-1 remained constant even though the level of AChR α increased markedly. Reporter gene, gel mobility shift and ChIP assays revealed that in the initial stage of myocyte differentiation, transcription of the YB-1 gene was regulated by E2F1 and Sp1, and was then gradually replaced under the control of both MyoD and myogenin through an E-box sequence in the proximal region of the YB-1 gene promoter. These results suggest that transcription factors for the YB-1 gene are exchanged during skeletal muscle cell differentiation, perhaps playing a role in translational control of mRNAs by YB-1 in both myotube formation and the response of skeletal muscle tissues to neural stimulation.

Mechanism of YB-1-mediated translational induction of GluR2 mRNA in response to neural activity through nAChR.

BACKGROUND: We have reported previously that YB-1 induces translation of GluR2 mRNA in response to neural activity, and that HSP60 affects the association of YB-1 with polysomes. Here we examined the mechanism of YB-1-mediated translational activation of GluR2 mRNA through the nAChR. METHODS: Expression of nAChRs in NG108-15 cells was verified. Translation of GluR2 mRNA and YB-1/HSP60 interaction were examined in nicotine-treated NG108-15 cells. Effects of inhibition of α7-nAChR and the PI3K/Akt pathway were investigated. The ratios of YB-1 to GluR2 mRNA and to HSP60 were explored in polysomal and non-polysomal fractions, respectively, and the role of HSP60 in cytoplasmic retention of YB-1 was evaluated. RESULTS: Nicotine treatment transiently induced translation of GluR2 mRNA and Akt phosphorylation with a concomitant increase of YB-1/HSP60 interaction. Both α-bungarotoxin and LY294002 abolished the effects of nicotine. On a sucrose gradient, nicotine treatment shifted the distribution of YB-1 to much heavier-sedimenting polysome fractions. In these fractions, the ratio of YB-1 to its binding GluR2 mRNA was decreased, and ribosome association with the YB-1-bound GluR2 mRNA was increased. HSP60 was distributed only in the non-polysomal fractions as its binding to YB-1 increased. In HSP60-depleted cells, nicotine treatment induced nuclear localization of YB-1. CONCLUSION: YB-1 is released from GluR2 mRNA during α7-nAChR-mediated neurotransmission, causing the PI3K/Akt pathway to recruit ribosomes into the translational machinery, and HSP60 is involved in cytoplasmic retention of polysome-free YB-1. GENERAL SIGNIFICANCE: Activation of the PI3K/Akt pathway through the α7-nAChR and YB-1/HSP60 interaction are important for YB-1-mediated translational activation of GluR2 mRNA.

Translational level of acetylcholine receptor α mRNA in mouse skeletal muscle is regulated by YB-1 in response to neural activity.

Y-box-binding protein 1 (YB-1) binds to mRNAs and affects translation. In this study, we focused on skeletal muscle, in which YB-1 expression is restricted to the early postnatal period, and found that YB-1 binds to acetylcholine receptor α-subunit (AChR α) mRNA. Although transcription of the AChR α gene is known to be regulated by myogenic transcription factors, translational control of the mRNA in response to neuromuscular transmission has not been examined. In undifferentiated C2C12 myoblasts, expression of AChR α remained at a low level. However, translation of the mRNA was increased by knockdown of YB-1. Continued overexpression of YB-1 prevented the cells from differentiating. In myotubes, which show clustering of AChRs, translation of the mRNA was induced within 3h after treatment with nicotine. The effect of nicotine was inhibited by α-bungarotoxin, and in the presence of cycloheximide the level of AChR α was reduced, even after nicotine treatment. Sucrose gradient analysis revealed that in nicotine-treated myotubes, YB-1-containing polysomes were shifted to the heavier-sedimenting fractions, and showed an apparent decrease in the amount of YB-1 bound to AChR α mRNA. These results suggest that in skeletal muscle cells, neural activity reduces the molar ratio of YB-1 relative to its binding AChR α mRNA, leading to an increase of ribosome binding to the mRNA, and thus activating translation. Furthermore, in postnatal growing mice, as has already been shown, the level of AChR α mRNA declined during the early period with maturation of neuromuscular synapses, but the translation level was found to increase transiently at postnatal day 10, when the level of YB-1 was markedly reduced. It is suggested that although the level of AChR α mRNA is reduced, the translation can be induced by alteration of the ratio of YB-1 protein to the mRNA.