Changes in proliferation,differentiation, fibroblast growth factor 2 responsiveness and expression of syndecan‐4 and glypican‐1 with turkey satellite cell age

Myogenic satellite cells are heterogeneous multipotential stem cells that are required for muscle repair, maintenance, and growth. The membrane‐associated heparan sulfate proteoglycans syndecan‐4 and glypican‐1 differentially regulate satellite cell proliferation, differentiation, fibroblast growth factor 2 (FGF2) signal transduction, and expression of the myogenic regulatory factors MyoD and myogenin. The objective of the current study was to determine the effect of age on syndecan‐4 and glypican‐1 satellite cell populations, proliferation, differentiation, FGF2 responsiveness, and expression of syndecan‐4, glypican‐1, MyoD, and myogenin using satellite cells isolated from the pectoralis major muscle of 1‐day‐old, 7‐week‐old and 16‐week‐old turkeys. Proliferation was significantly reduced in the 16‐week‐old satellite cells, while differentiation was decreased in the 7‐week‐old and the 16‐week‐old cells beginning at 48 h of differentiation. Fibroblast growth factor 2 responsiveness was highest in the 1‐day‐old and 7‐week‐old cells during proliferation; during differentiation there was an age‐dependent response to FGF2. Syndecan‐4 and glypican‐1 satellite cell populations decreased with age, but syndecan‐4 and glypican‐1 were differentially expressed with age during proliferation and differentiation. MyoD and myogenin mRNA expression was significantly decreased in 16‐week‐old cells compared to the 1‐day‐old and 7‐week‐old cells. MyoD and myogenin protein expression was higher during proliferation in the 16‐week‐old cells and decreased with differentiation. These data demonstrate an age‐dependent effect on syndecan‐4 and glypican‐1 satellite cell subpopulations, which may be associated with age‐related changes in proliferation, differentiation, FGF2 responsiveness, and the expression of the myogenic regulatory factors MyoD and myogenin.     

BTB-Kelch protein Krp1 regulates proliferation and differentiation of myoblasts

The BTB-Kelch protein Krp1 is highly and specifically expressed in skeletal muscle, where it is proposed to have a role in myofibril formation. We observed significant upregulation of Krp1 in C2 cells early in myoblast differentiation, well before myofibrillogenesis. Krp1 has a role in cytoskeletal organization and cell motility; since myoblast migration and elongation/alignment are important events in early myogenesis, we hypothesized that Krp1 is involved with earlier regulation of differentiation. Krp1 protein levels were detectable by 24 h after induction of differentiation in C2 cells and were significantly upregulated by 48 h, i.e., following the onset myogenin expression and preceding myosin heavy chain (MHC) upregulation. Upregulation of Krp1 required a myogenic stimulus as signaling derived from increased myoblast cell density was insufficient to activate Krp1 expression. Examination of putative Krp1 proximal promoter regions revealed consensus E box elements associated with myogenic basic helix-loop-helix binding. The activity of a luciferase promoter-reporter construct encompassing this 2,000-bp region increased in differentiating C2 myoblasts and in C2 cells transfected with myogenin and/or MyoD. Knockdown of Krp1 via short hairpin RNA resulted in increased C2 cell number and proliferation rate as assessed by bromodeoxyuridine incorporation, whereas overexpression of Krp1-myc had the opposite effect; apoptosis was unchanged. No effects of changed Krp1 protein levels on cell migration were observed, either by scratch wound assay or live cell imaging. Paradoxically, both knockdown and overexpression of Krp1 inhibited myoblast differentiation assessed by expression of myogenin, MEF2C, MHC, and cell fusion.     

Effects of low-intensity pulsed ultrasound on the differentiation of C2C12 cells

Low-intensity pulsed ultrasound (LIPUS) is known to accelerate bone regeneration, but the precise cellular mechanism is still unclear. The purpose of this study was to determine the effect of LIPUS on the differentiation of pluripotent mesenchymal cell line C2C12. The cells were cultured in differentiation medium with or without the addition of LIPUS stimulation. The ultrasound signal consisted of 1.5 MHz at an intensity of 70 mW/cm2 for 20 min for all cultures. To verify the cell lineage after LIPUS stimulation, mRNA expression of cellular phenotype-specific markers characterizing osteoblasts (Runx2, Msx2, Dlx5, AJ18), chondroblasts (Sox9), myoblasts (MyoD), and adipocytes (C/EBP, PPARgamma) was studied using real-time polymerase chain reaction analysis. The protein expression of Runx2 and activated phosphorylation of extracellular signal-regulated kinase 1/2 (ERK1/2) and p38 mitogen-activated protein kinase (p38 MAPK) were performed using Western blotting. The mRNA expression of Runx2, Msx2, Dlx5, AJ18, and Sox9 was increased markedly by the LIPUS stimulation, whereas the expression of MyoD, C/EBP, and PPARgamma was drastically decreased. In the Western blot analysis, LIPUS stimulation increased Runx2 protein expression and phosphorylation of ERK1/2 and p38 MAPK. Our study demonstrated that LIPUS stimulation converts the differentiation pathway of C2C12 cells into the osteoblast and/or chondroblast lineage via activated phosphorylation of ERK1/2 and p38 MAPK.     

The homeodomain protein Barx2 promotes myogenic differentiation and is regulated by myogenic regulatory factors

The homeobox protein Barx2 is expressed in both smooth and skeletal muscle and is up-regulated during differentiation of skeletal myotubes. Here we use antisense-oligonucleotide inhibition of Barx2 expression in limb bud cell culture to show that Barx2 is required for myotube formation. Moreover, overexpression of Barx2 accelerates the fusion of MyoD-positive limb bud cells and C2C12 myoblasts. However, overexpression of Barx2 does not induce ectopic MyoD expression in either limb bud cultures or in multipotent C3H10T1/2 mesenchymal cells, and does not induce fusion of C3H10T1/2 cells. These results suggest that Barx2 acts downstream of MyoD. To test this hypothesis, we isolated the Barx2 gene promoter and identified DNA regulatory elements that might control Barx2 expression during myogenesis. The proximal promoter of the Barx2 gene contained binding sites for several factors involved in myoblast differentiation including MyoD, myogenin, serum response factor, and myocyte enhancer factor 2. Co-transfection experiments showed that binding sites for both MyoD and serum response factor are necessary for activation of the promoter by MyoD and myogenin. Taken together, these studies indicate that Barx2 is a key regulator of myogenic differentiation that acts downstream of muscle regulatory factors.     

The myostatin gene is a downstream target gene of basic helix-loop-helix transcription factor MyoD

Myostatin is a negative regulator of myogenesis, and inactivation of myostatin leads to heavy muscle growth. Here we have cloned and characterized the bovine myostatin gene promoter. Alignment of the upstream sequences shows that the myostatin promoter is highly conserved during evolution. Sequence analysis of 1.6 kb of the bovine myostatin gene upstream region revealed that it contains 10 E-box motifs (E1 to E10), arranged in three clusters, and a single MEF2 site. Deletion and mutation analysis of the myostatin gene promoter showed that out of three important E boxes (E3, E4, and E6) of the proximal cluster, E6 plays a significant role in the regulation of a reporter gene in C(2)C(12) cells. We also demonstrate by band shift and chromatin immunoprecipitation assay that the E6 E-box motif binds to MyoD in vitro and in vivo. Furthermore, cotransfection experiments indicate that among the myogenic regulatory factors, MyoD preferentially up-regulates myostatin promoter activity. Since MyoD expression varies during the myoblast cell cycle, we analyzed the myostatin promoter activity in synchronized myoblasts and quiescent "reserve" cells. Our results suggest that myostatin promoter activity is relatively higher during the G(1) phase of the cell cycle, when MyoD expression levels are maximal. However, in the reserve cells, which lack MyoD expression, a significant reduction in the myostatin promoter activity is observed. Taken together, these results suggest that the myostatin gene is a downstream target gene of MyoD. Since the myostatin gene is implicated in controlling G(1)-to-S progression of myoblasts, MyoD could be triggering myoblast withdrawal from the cell cycle by regulating myostatin gene expression.     

干扰Sirt2促进C2C12成肌细胞分化

Sirt2是组蛋白去乙酰化酶(HDAC III)家族成员之一, 对细胞周期、自噬、脂肪细胞分化、神经细胞存活等生物学过程的调节发挥重要作用. 目前,Sirt2在肌肉发育过程中的研究尚未见报道.本文通过构建Sirt2慢病毒干扰载体,侵染C2C12成肌细胞,并用细胞免疫荧光化学、real-time PCR 和Western印迹方法,检测其对成肌分化标志基因及相关信号通路因子的影响. 结果显示,干扰质粒shRNA 663处理C2C12细胞后,Sirt2 mRNA及蛋白质表达水平与对照相比显著下调(P<0.01);C2C12细胞分化第4 d,MyoD,MyoG,MyHC mRNA及蛋白质表达均显著增加(P<0.01); PI3K,AKT,FoxO1磷酸化水平明显升高. 结果表明,Sirt2可通过PI3K/AKT/FOXO1信号通路来促进成肌细胞分化,是肌生成的一个潜在调节因子.