Induction and peak gene expression of insulin-like growth factor II follow that of myogenin during differentiation of BC3H-1 muscle cells.

Acting through hormonal and/or autocrine/paracrine mechanisms, the insulin-like growth factors (IGFs) stimulate the differentiation of muscle cells. Previous studies have suggested that one mechanism by which IGFs stimulate muscle cell differentiation is by increasing the expression of myogenin, a DNA binding protein that regulates the expression of muscle-specific genes. While exogenous IGF peptides increase myogenin mRNA, the role of endogenously produced IGF peptides in myogenin expression has not been established. In addition, the potential role of IGFs in regulating the expression of Id, a protein in myoblasts that can inhibit the action of myogenin-like peptides, is also unknown. In the present study, we have examined the kinetics of accumulation of myogenin and IGF-II mRNAs during differentiation of BC3H-1 mouse muscle cells and have explored the potential role of IGFs in regulating Id expression. During differentiation induced by serum withdrawal, induction of myogenin expression preceded that of IGF-II, the principal IGF peptide expressed by these cells. In addition, Id expression decreased within two hours in serum-free medium and was not affected by IGF treatment. Thus, these studies suggest that endogenously-produced IGF-II may stimulate muscle cell differentiation after both the decrease in Id and the induction of myogenin gene expression have occurred.     

高表达FoxO1抑制猪骨骼肌成肌细胞的分化

FoxO1(Forkhead box O1)是调控肌肉生长、代谢和细胞分化的重要转录因子,但其在成肌细胞分化中的作用还不甚清楚。为了研究FoxO1对哺乳动物成肌细胞分化的影响,以原代培养的长白仔猪成肌细胞作为实验材料,用2%马血清诱导分化,采用实时荧光定量PCR、Western blotting和脂质体转染等方法检测FoxO1及早期和晚期生肌调节因子MyoD和myogenin在猪成肌细胞分化过程中的表达变化。结果显示,在猪成肌细胞分化过程中,FoxO1mRNA表达量显著增加,但总蛋白量变化不显著,其磷酸化水平显著上调。同时,高表达FoxO1的猪成肌细胞中,生肌调节因子MyoD和myogenin mRNA表达受到显著抑制,而MyoD蛋白变化不显著,myogenin却显著下调(P0.05)。以上结果表明,FoxO1能够推迟猪成肌细胞的分化时间并抑制分化;同时推测,FoxO1可能通过抑制生肌调节因子的表达控制骨骼肌纤维类型的终末分化。     

Myoblast migration is prevented by a calpain-dependent accumulation of MARCKS

Calpains, also called calcium activated neutral cysteine proteases are presently known to play pivotal roles in physiological and biological phenomena such as signal transduction, cell spreading and motility, apoptosis, regulation of cell cycle and regulation of muscle cell differentiation. Concerning this last point, calpains have been shown to play a crucial role during the earlier myogenesis. In this study we have analyzed the involvement of calpains during an important step of myogenesis: myoblast migration. Our findings show that myoblast migration was drastically reduced when the expression of micro- and m-calpain was decreased. We have also observed that MARCKS (myristoylated alanine rich C kinase substrate), a protein localized at focal adhesion sites, was significantly accumulated when the expression levels of calpains were decreased. Also, using phorbol myristate acetate, (an activator of PKC) and plasmids carrying the full-length cDNA of MARCKS or a cDNA fragment lacking the phosphorylation site domain, we demonstrated that normal myoblast migration is dependent on MARCKS phosphorylation and localization.     

Crystal structure of a micro-like calpain reveals a partially activated conformation with low Ca2+ requirement

The two Ca2+-dependent cysteine proteases, micro- and m-calpain, are involved in various Ca2+-linked signal pathways but differ markedly in their Ca2+ requirements for activation. We have determined the structure of a micro-like calpain, which has 85% micro-calpain sequence (the first 48 and the last 62 residues of the large subunit are those from m-calpain) and a low Ca2+ requirement. This construct was used because micro-calpain itself is too poorly expressed. The structure of micro-like calpain is very similar in overall fold to that of m-calpain as expected, but differs significantly in two aspects. In comparison with m-calpain, the catalytic triad residues in micro-like calpain, His and Cys, are much closer together in the absence of Ca2+, and significant portions of the Ca2+ binding EF-hand motifs are disordered and more flexible. These structural differences imply that Ca2+-free micro-calpain may represent a partially activated structure, requiring lower Ca2+ concentration to trigger its activation.