人类胚胎来源成肌细胞的培养和鉴定

背景：人类胚胎骨骼肌含有成肌细胞,其在体外条件下的培养及在体外能否融合形成肌管,以及表达的相应的标志物,目前尚不明确。 目的：验证源于人类胚胎骨骼肌的成肌细胞在体外条件下的培养条件,能否在体外融合形成肌管,能否表达神经细胞的标志物。 方法：采用组织块培养法对人类胚胎肌肉来源的成肌细胞进行原代培养,以免疫细胞化学染色检测培养的细胞肌肉细胞标志物desmin、myogenin、平滑肌肌动蛋白、myosin和神经细胞标志物β-tubulin Ⅲ、nestin、neurofilament 200 (NF200)、胶质纤维酸性蛋白的表达。 结果与结论：从人类胚胎肌肉组织中成功培养出成肌细胞,表达成肌细胞的标志物desmin和myogenin,同时也表达神经元特异性烯醇化酶、nestin和NF200,细胞能够在体外融合形成含有多个细胞核的肌管,融合的肌管可以表达NF200、β-tubulin Ⅲ和胶质纤维酸性蛋白等神经细胞的标志物。结果证实,人类胚胎肌肉来源的成肌细胞能够同时表达神经细胞和肌肉细胞的标志物,培养的成肌细胞和肌管细胞表达神经元特异性烯醇化酶、β-tubulin Ⅲ、nestin、NF 200和胶质纤维酸性蛋白。说明这几种神经细胞标志物不能用于肌肉来源的细胞向神经细胞跨分化的鉴定研究。     

Association of plectin with Z-discs is a prerequisite for the formation of the intermyofibrillar desmin cytoskeleton

Plectin is a high-molecular mass protein (approximately 500 kd) that binds actin, intermediate filaments, and microtubules. Mutations of the plectin gene cause a generalized blistering skin disorder and muscular dystrophy. In adult muscle, plectin is colocalized with desmin at structures forming the intermyofibrillar scaffold and beneath the plasma membrane. To study the involvement of plectin in myofibrillogenesis, we analyzed the spatial and temporal expression patterns of plectin in cultured differentiating human skeletal muscle cells and its relationship to desmin intermediate filaments during this process. Northern and Western blot analyses demonstrated that at least two different plectin isoforms are expressed at all developmental stages from proliferating myoblasts to mature myotubes. Using immunocytochemistry, we show that the localization of plectin dramatically changes from a network-like distribution into a cross-striated distribution during maturation of myocytes. Double immunofluorescence experiments revealed that desmin and plectin are colocalized in premyofibrillar stages and in mature myotubes. Interestingly, plectin was often found to localize to the periphery of Z-discs during the actual alignment of neighboring myofibrils, and an obvious cross-striated plectin staining pattern was observed before desmin was localized in the Z-disc region. We conclude that the association of plectin with Z-discs is an early event in the lateral alignment of myofibrils that precedes the formation of the intermyofibrillar desmin cytoskeleton.     

小鼠Wnt-1基因真核表达载体构建及其在大鼠成肌细胞中的表达

目的：构建p-EGFP-C3-Wnt-1真核表达载体并转染体外培养大鼠成肌细胞,观察Wnt-1在其中的表达。方法：利用RT-PCR方法从小鼠胚脑中扩增获得Wnt-1基因编码区全长序列,克隆到含有增强型绿色荧光蛋白报告基因的真核表达载体p-EGFP-C3上,形成重组载体p-EGFP-C3-Wnt-1。大鼠成肌细胞原代培养及desmin免疫荧光染色鉴定。利用Lipofectamine TM2000脂质体将重组质粒p-EGFP-C3-Wnt-1转染成肌细胞。结果：重组质粒p-EGFP-C3-Wnt-1构建成功;将其转染成肌细胞72 h后,观察到EGFP报告基因和目的基因Wnt-1表达。结论：成功构建了小鼠胚脑Wnt-1基因的真核表达载体p-EGFP-C3-Wnt-1,并可转染成肌细胞。     

Isolation, growth and differentiation of adult rabbit skeletal myoblasts in vitro

A simple and reliable method is described for the growth and differentiation of myoblasts isolated from adult New Zealand White rabbit fast-twitch (tibialis anterior) and slow-twitch (soleus) skeletal muscle. Cells were dissociated mechanically, and expanded in DMEM supplemented with 20% horse serum. The myoblasts were differentiated by switching to DMEM supplemented with 10% horse serum when the myoblasts were 80–90% confluent. The myoblasts fused into multinucleated myotubes that spontaneously contracted. At the light microscopic level, the myotubes exhibited a striated pattern as revealed by positive immunostaining for sarcomeric proteins such as -actinin, myosin and titin.Electron microscopy demonstrated well ordered sarcomeres with localized mitochondria and sarcoplasmic reticulum. The only notable difference between the fiber types was in the initial response to isolation wherein the myoblast yield was four-fold greater from the soleus than the tibialis anterior, in agreement with satellite cell abundance in predominately slow-twitch vs fast-twitch muscles. These techniques repeatedly (n = 12) produced a population of healthy myoblasts isolated from either fast- or slow-twitch skeletal muscle which can be utilized for studies of skeletal muscle differentiation, assembly and signaling.     

Calpain inhibition and insulin action in cultured human muscle cells

Variation in the calpain 10 gene has been reported to increase susceptibility to type 2 diabetes. Part of this susceptibility appears to be mediated by a decrease in whole body insulin sensitivity. As skeletal muscle is the primary tissue site of the peripheral insulin resistance in type 2 diabetes, the aim of this study was to use a human skeletal muscle cell culture system to explore the effects of calpain inhibition on insulin action. Calpain 10 mRNA and protein expression was examined in cultured myoblasts, myotubes, and whole skeletal muscle from non-diabetic subjects using RT-PCR and Western blotting. Changes in insulin-stimulated glucose uptake and glycogen synthesis in response to the calpain inhibitors ALLN and ALLM were measured. Calpain 10 expression was confirmed in cultured human myoblasts, myotubes, and native skeletal muscle. Insulin-stimulated glucose uptake was significantly decreased following preincubation with ALLN [404+/-40 vs 505+/-55 (mean+/-SEM)pmol/mg/min; with vs without ALLN: p = 0.04] and ALLM [455+/-38 vs 550+/-50 pmol/mg/min; with vs without ALLM: p = 0.025] in day 7 fused myotubes, but not in myoblasts. Neither ALLN nor ALLM affected insulin-stimulated glycogen synthesis in myoblasts or myotubes. These studies confirm calpain 10 expression in cultured human muscle cells and support a role for calpains in insulin-stimulated glucose uptake in human skeletal muscle cells that may be relevant to the pathogenesis of the peripheral insulin resistance in type 2 diabetes.     

Characterization of CMF1 in avian skeletal muscle.

This study reports the identification of the CMF1 protein in somites and embryonic limb muscle. We have previously described CMF1 in developing cardiac muscle. CMF1 is a member of the LEK family of proteins, which are involved in regulating mitosis. Our current data suggest that CMF1 expressed in skeletal and cardiac myocytes is the product of a single gene and that the two proteins are homologous or very highly conserved. Immunohistochemistry shows a dynamic subcellular localization of CMF1 in differentiating skeletal myoblasts: Early myoblasts stain positively for CMF1 antigen in the nucleus, while differentiating myoblasts stain positively in the cytoplasm. CMF1 expression precedes myosin. Later, CMF1 and myosin are detected in the cytoplasm of the same cells. Transfection analysis identifies a functional nuclear localization signal (NLS) in CMF1, whose nuclear transport capability is modified by external sequences. To characterize the function of CMF1 in skeletal muscle, we used antisense oligonucleotides to disrupt CMF1 in myoblast cultures. Expression of CMF1 in early myotubes is reduced by an average of 40% on a cell by cell basis, with a 56% reduction in anti-myosin staining. These data suggest that CMF1 is involved in induction and/or accumulation of myosin in differentiating myocytes.     

Generation of a monoclonal antibody reactive to prefusion myocytes

We established a novel monoclonal antibody, Yaksa that is specific to a subpopulation of myogenic cells. The Yaksa antigen is not expressed on the surface of growing myoblasts but only on a subpopulation of myogenin-positive myocytes. When Yaksa antigen-positive mononucleated cells were freshly prepared from a murine myogenic cell by a cell sorter, they fused with each other and formed multinucleated myotubes shortly after replating while Yaksa antigen-negative cells scarcely generated myotubes. These results suggest that Yaksa could segregate fusion-competent, mononucleated cells from fusion–incompetent cells during muscle differentiation. The Yaksa antigen was also expressed in developing muscle and regenerating muscle in vivo and it was localized at sites of cell–cell contact between mono-nucleated muscle cells and between mono-nucleated muscle cells and myotubes. Thus, Yaksa that marks prefusion myocytes before myotube formation can be a useful tool to elucidate the cellular and molecular mechanisms of myogenic cell fusion.     

Immunocytochemical study of dystrophin in muscle cultures from patients with Duchenne muscular dystrophy and unaffected control patients.

Using immunocytochemical methods, the localization of dystrophin, the gene product affected in Duchenne muscular dystrophy (DMD) in aneural, differentiating human muscle cultures, was studied. Dystrophin was not demonstrable in undifferentiated myoblasts from control patients and from two patients with DMD. After myoblast fusion, the protein was found in circumscribed sarcoplasmic patches, in the perinuclear area, and along the surface of all normal multinucleate myotubes, with more mature myotubes showing predominantly sarcolemmal distribution. There was no staining in myotubes from one DMD patient and only faint diffuse fluorescence in myotubes from the second affected boy, however. These data provide further evidence that dystrophin is a sarcolemma-associated protein, that it is developmentally regulated, and that it is absent or greatly reduced in quantity in skeletal muscle cultures from patients with DMD.     

mRNA transfection of CXCR4-GFP fusion--simply generated by PCR-results in efficient migration of primary human mesenchymal stem cells

We present a general, entirely PCR-based strategy to construct mRNAs coding for green fluorescent protein (GFP) fusion proteins from a cDNA pool. We exemplify our approach for the chemokine receptor CXCR4. mRNA transfection of the PCR-generated fusion of CXCR4-GFP into K562 cells or primary mesenchymal stem cells (MSCs) resulted in excellent viability (> 90%) with more than 90% of target cells expressing easily detectable CXCR4-GFP for > 72 h. The fusion protein was localized in the plasma membrane and was rapidly internalized upon incubation with the CXCR4 ligand stromal cell-derived factor-1 (SDF-1). Transwell migration experiments showed significantly increased migration of CXCR4-GFP mRNA-transfected MSCs toward a gradient of SDF-1, demonstrating that mRNA-mediated chemokine receptor overexpression allows for transient initiation of chemotaxis. The presented strategy to construct a PCR-based fluorescent fusion protein can be generally applied to other genes of interest to study their function by simple overexpression and easy detection in primary cells.     

Myofibrillogenesis in primary tissue cultures of adult human skeletal muscle: expression of desmin,titin, and nebulin

To investigate the in vitro development of myofibrils in skeletal muscle cells derived from adult human muscle biopsies, immunohistochemical analysis was performed using monoclonal antibodies against desmin, titin, and nebulin. Diffuse desmin reactivity was detected 48 h after plating in about 60% of all mononucleated cells. This supports the use of desmin as a marker for undifferentiated rhabdomyosarcomas in man. Titin was visible from day 4 onwards, while nebulin was not found in mononucleated cells. After 1 week polynucleated myotubes appeared, and grew up to 30 days. Desmin was distributed diffusely throughout the cytoplasm until day 21, when the pattern became patchy. Titin began to be organized in a predominantly longitudinal orientation at day 15, while nebulin, which appeared for the first time in fusing myoblasts on the fifth to the seventh day, was almost immediately organized in a dotted longitudinal pattern, which became a Z line connected striation in matured myotubes.Abbreviations FCS fetal calf serum - mAb monoclonal antibody - TBS Tris-buffered saline Correspondence to: T. Behr     

Rapid purification of transfected porcine muscle cells

A detailed methodology is described for fluorescence-activated cell sorting (FACS) of porcine muscle cells that have been transfected to express green fluorescent protein (GFP). Cells are liberated from porcine skeletal muscle and primary cultures are transfected with DNA encoding GFP. Primary cultures are subjected to immunocytochemistry using a primary muscle-specific monoclonal antibody followed by incubation with a phycoerythrin-conjugated second antibody. Transfected myoblasts aresorted from fibroblasts using forward angle light scatter and ninety degree light scatter, phycoerythrin fluorescence, and GFP fluorescence. These procedures allow for isolation of genetically-engineered porcine muscle cells more rapidly than traditional clonal selection procedures. Consequently, FACS provides porcine myoblast populations that retain the majority of their replicative capacity and are not contaminated with non-myogenic cells.     

Midkine and its receptor in regenerating rat skeletal muscle after bupivacaine injection

Midkine (MK) is a multifunctional cytokine and heparin-binding growth factor with neurotrophic activity. MK and its receptor were examined for up to 14 days in a chemically injured rat muscle regeneration process caused by the injection of bupivacaine using immunohistochemical and Western blot analysis. Although MK immunoreactivity was not detectable in the mature uninjured skeletal muscle, MK was strongly detected in the regenerating muscle cells. MK immunoreactivity was observed in the myoblast-like cells and myotubes, which were desmin-positive cells, whereas it was not detectable in the surviving normal muscle fibers. Most myotubes labeling for desmin showed MK immunoreactivity 5-7days after the injury. However, MK immunoreactivity was not detected 14 days after the injury. Immunoreactivity of low-density lipoprotein receptor-related protein (LRP), a cell membrane receptor of MK, was detected in the regenerating muscle cells, whereas it was not detected in the normal adult skeletal muscle and surviving muscle. These findings suggested that MK was involved. MK may have a role for differentiation during skeletal muscle regeneration and may be taken up in an autocrine fashion with LRP.     

Transduction of Aedes aegypti mosquitoes with vectors derived from Aedes densovirus

Aedes densovirus (AeDNV)-based constructs that express green fluorescent protein (GFP) from either the P7 or the P61 promoter were made. The construct in which GFP protein was expressed as a fusion protein to the C-terminus of NS1 (NS1-GFP) showed the highest level of GFP expression. This hybrid NS1-GFP protein preserved the biological functions of the parental proteins: it showed GFP fluorescence, it stimulated expression from the virus promoters, and it facilitated rescue and replication of the cloned AeDNV genome. Similar to NS1, the hybrid NS1-GFP localized in the nucleus predominantly in a punctate pattern. Transducing virus particles carrying the NS1-GFP gene infected mosquito larvae. Expression of GFP was detected as early as 48 h postinfection and in larval and pupal stages. Midgut, hindgut, and Malpighian tubule cells expressed GFP soon after transduction. However, the anal papillae were the most commonly infected organ system. The anal papillae are syncytia and regulate ion concentration in the hemolymph of mosquito larvae, and they might be a novel route of mosquito larvae infection with densoviruses.     

Desmin-lacZ transgene expression and regeneration within skeletal muscle transplants

The purpose of this study was to investigate the initiation and time course of the regeneration process in fragments of skeletal muscle transplants as a function of muscle tissue age at implantation. The appearance of desmin occurs at the very beginning of myogenesis. The transgenic desminnls lacZ mice used in the study bear a transgene in which the 1 kb DNA 5′ regulatory sequence of the desmin gene is linked to a reporter gene coding for Escherichia coliβ-galactosidase. The desmin lacZ transgene labels muscle cells in which the desmin synthesis programme has commenced. We implanted pectoralis muscle fragments from fetal transgenic embryos and mature and old transgenic mice into mature non-transgenic mice. Early events of myogenesis occurring during regeneration started sooner in transplants from 4-month-old (day 3 post-implantation) muscle than in those from 24-month-old (day 5-6 post-implantation) muscle, and they lasted longer in those from young (day 17 post-implantation) than in those from old (day 14 post-implantation) muscle fragments. In adult muscle, transgene activation proceeded from the periphery toward the centre of the transplant. In transplants from fetal 18-day-old pectoralis, myotubes with transgene activity were observed from day 1 to day 19. Desmin immunoreactivity, which appeared about one day after transgene activation, was followed by myosin expression. In adult transplants, the continuity of laminin labelling was disrupted around degenerative fibres, illustrating alteration of the extracellular matrix. Our data suggest that satellite cells from old muscle tissue have lower proliferative capacity and/or less access to trophic substances released by the host (damaged fibres, vascularization) than those from fetal or young adult muscle This revised version was published online in July 2006 with corrections to the Cover Date.     

An ultrastructural study of the dufferentiation of skeletal muscle in the bovine fetus

Summary The differentiation of skeletal muscle was studied by electron microscopy in bovine fetuses from 47 days gestation to neonatal calves 3 days of age.Initally, the muscle was composed of clusters of myotubes with mononucleated myoblasts between them. In 2-month-old fetuses these myoblasts became apposed to the differentiating muscle cells and were enclosed within the rudimentary basal lamina of the myotubes. At this stage the clusters of myotubes consisted of central, larger diameter, more differentiated myotubes and also the mononucleated satellite cells. The differentiated myotubes separated from the clusters accompanied by satellite cells which continued proliferating and fused together to form new generations of satellite myotubes. In this manner new clusters of myotubes were formed. By 4–5 months some of the separating myotubes began to form individual myotubes and independent myofibers were prominent in fetuses of 5–8 months of age.The myofibers in the 8-month-old fetuses showed diversification into fiber types by differences in the thickness of the Z-line, the prominence of the sarcotubular system, the amount of glycogen and lipid droplets and also the number of mitochondria.