Mechanical stretch induces activation of skeletal muscle satellite cells in vitro.

Cultured quiescent satellite cells were subjected to mechanical stretch in a FlexerCell System. In response to stretch, satellite cells entered the cell cycle earlier than if they were under control conditions. Only a brief period of stretch, as short as 2 h, was necessary to stimulate activation. Additionally, conditioned medium from stretched cells could activate unstretched satellite cells. The presence of HGF on c-met-positive myogenic cells was detected by immunofluorescence at 12 h in culture, and immunoblots demonstrated that HGF was released by stretched satellite cells into medium. Also, stretch activation could be abolished by the addition of anti-HGF antibodies to stretched cultures, and activity in conditioned medium from stretched cells could be neutralized by anti-HGF antibodies. In addition, stretch appeared to cause release of preexisting HGF from the extracellular matrix. These experiments suggest that HGF may be involved in linking mechanical perturbation of muscle to satellite cell activation.     

Observations of satellite cells in rat skeletal muscle incubated in vitro

Summary Satellite cells were studied in the peripheral fibres from isolated rat muscles, which had been incubated for various periods of time. The cells were in an activated state with prominent organelles and increased cytoplasm visible. Mitosis of some satellite cells was occasionally observed. It is suggested that when incubated muscle preparations are used as models for physiological systems in vivo, the state of the satellite cell population should be taken into consideration.     

In vitro culture and induced differentiation of sheep skeletal muscle satellite cells

Skeletal muscle satellite cells are adult muscle-derived stem cells receiving increasing attention. Sheep satellite cells have a greater similarity to human satellite cells with regard to metabolism, life span, proliferation and differentiation, than satellite cells of the rat and mouse. We have used 2-step enzymatic digestion and differential adhesion methods to isolate and purify sheep skeletal muscle satellite cells, identified the cells and induced differentiation to examine their pluripotency. The most efficient method for the isolation of sheep skeletal muscle satellite cells was the type I collagenase and trypsin 2-step digestion method, with the best conditions for in vitro culture being in medium containing 20% FBS+10% horse serum. Immunofluorescence staining showed that satellite cells expressed Desmin, α-Sarcomeric Actinin, MyoD1, Myf5 and PAX7. After myogenic induction, multinucleated myotubes formed, as indicated by the expression of MyoG and fast muscle myosin. After osteogenic induction, cells expressed Osteocalcin, with Alizarin Red and ALP (alkaline phosphatase) staining results both being positive. After adipogenic induction, cells expressed PPARγ2 (peroxisome-proliferator-activated receptor γ2) and clear lipid droplets were present around the cells, with Oil Red-O staining giving a positive result. In summary, a successful system has been established for the isolation, purification and identification of sheep skeletal muscle satellite cells.     

Exercise-induced satellite cell activation in growing and mature skeletal muscle

The time course and extent of satellite cell activation were studied in the soleus (m-SOL) and extensor digitorum longus (m-EDL) muscles of untrained growing and mature rats after a single bout of prolonged eccentric treadmill running. At 24, 48, 72, and 120 h postexercise, satellite cell mitotic activity was quantitated in autoradiographs of whole-fiber segments after injection of [3H]thymidine. Fiber damage and localization of labeled cells were also examined in muscle cross sections. Labeling in growing muscles progressively increased to peak levels (approximately 250% of control) at 72 h postexercise, whereas mature muscles exhibited an earlier peak (approximately 250% of control) at 24 (m-SOL) and 48 (m-EDL) h, followed by a more rapid decline to control levels by 120 h postexercise. In all exercised muscles the calculated satellite cell activation was far greater than required to repair the small number (less than 3.0%) of necrotic fibers identified at the light-microscopic level. These results suggest that satellite cells were activated not only on fibers exhibiting overt necrosis but also on those with lesions not discernible with light microscopy.     

The satellite cells of normal anuran skeletal muscle

Population counts and size measurements of satellite cell nuclei and myonuclei were carried out on the normal gastrocnemius muscles of adult Rana pipiens and Rana clamitans. Satellite cell profiles occurred with an observed frequency of about 1.3% in the muscles of the R. pipiens, and with an observed frequency of about 1.6% in the muscles of the R. clamitans. These frequencies were not found to be significantly different. The observed frequencies were corrected for the sampling bias introduced by the difference in the mean size of the satellite cell nuclei and myonuclei. This correction suggests that R. pipiens and R. clamitans both have a true satellite cell frequency of approx 2.7%. Analysis of these data indicates that the satellite cells of the normal anuran gastrocnemius occur in sufficient numbers to account for the regeneration seen after injury to this muscle.     

Pepsin can be used to subculture viable mammary epithelial cells

Normal mouse mammary epithelial cells in primary culture can be passaged as viable single cells using 0.5 to 1.0 mg/ml pepsin in Hanks' salt solution. After 5 min the pepsin treatment preferentially removes fibroblasts, leaving a monolayer of purified epithelial cells that can be removed by pipetting and transferred to new culture vessels or injected into animals.     

Pepsin can be used to subculture viable mammary epithelial cells

Summary Normal mouse mammary epithelial cells in primary culture can be passaged as viable single cells using 0.5 to 1.0 mg/ml pepsin in Hanks’ salt solution. After 5 min the pepsin treatment preferentially removes fibroblasts, leaving a monolayer of purified epithelial cells that can be removed by pipetting and transferred to new culture vessels or injected into animals. This study was supported by Contract CB-43907 from the National Institutes of Health.     

Interaction between satellite cells and skeletal muscle fibers

Single myofibers with attached satellite cells isolated from adult rats were used to study the influence of the mature myofiber on the proliferation of satellite cells. The satellite cells remain quiescent when cultured in serum containing medium but proliferate when exposed to mitogen from an extract of crushed adult muscle. The response of satellite cells to mitogen was measured under three situations with respect to cell contact: (1) in contact with a viable myofiber and its basal lamina, (2) detached from the myofiber by centrifugal force and deposited on the substratum and (3) beneath the basal lamina of a Marcaine killed myofiber. The results show that satellite cells in contact with the plasmalemma of a viable myofiber have reduced mitogenic response. Since inhibiting growth may induce differentiation, I tested whether satellite cells proliferating on the surface of a myofiber would fuse. Although the satellite cell progeny were fusion competent, they did not fuse with the myofiber. To determine whether fusion competence of the myofiber changes with time in culture, embryonic myoblasts were challenged to fuse with myofibers that had been stripped of satellite cells and cultured for several days. The myoblasts fused with pseudopodial sprouts growing from the ends of the myofiber, but did not fuse with the original myofiber surface. These results indicate that contact with the surface of a mature myofiber suppresses proliferation of myogenic cells but the cells do not fuse with the myofiber.     

Matrix metalloproteinase-2 mediates stretch-induced activation of skeletal muscle satellite cells in a nitric oxide-dependent manner

When skeletal muscle is stretched or injured, myogenic satellite cells are activated to enter the cell cycle. This process depends on nitric oxide (NO) production, release of hepatocyte growth factor (HGF) from the extracellular matrix, and presentation of HGF to the c-met receptor. Matrix metalloproteinases (MMPs), a large family of zinc-dependent endopeptidases, mediate HGF release from the matrix and this step in the pathway is downstream from NO synthesis [Yamada, M., Tatsumi, R., Kikuiri, T., Okamoto, S., Nonoshita, S., Mizunoya, W., et al. (2006). Matrix metalloproteinases are involved in mechanical stretch-induced activation of skeletal muscle satellite cells. Muscle Nerve, 34, 313-319]. Experiments reported herein provide evidence that MMP2 may be involved in the NO-dependent release of HGF in vitro. Whole lysate analyses of satellite cells demonstrated the presence of MMP2 mRNA and the protein. When rat satellite cells were treated with 30 microM sodium nitroprusside a NO donor or mechanical cyclic stretch for 2h period, inactive proMMP2 (72 kDa) was converted into 52-kDa form and this processing was abolished by adding a NO synthase inhibitor l-NAME (10 microM) to the stretch culture. The 52-kDa species was also generated by treatment of the recombinant MMP2 protein with 1 microM NOC-7 that can spontaneously release NO under physiological conditions without any cofactor, and its activating activity was demonstrated by applying the NOC-7-treated MMP2 to satellite cell culture. HGF release was detected in NOC-7-MMP2-conditioned media by western blotting; very little HGF was found in media that were generated from cultures receiving NOC-7-treated MMP2 (10 ng/ml) plus 250 ng/ml tissue inhibitor-1 of metalloproteinases. Therefore, results from these experiments provide evidence that NO-activated MMP2 may cause release of HGF from the extracellular matrix of satellite cells and contribute to satellite cell activation.     

Microencapsulated bacterial cells can be used to produce the enzyme feruloyl esterase: preparation and in-vitro analysis

Biotechnological production of ferulic acid, a precursor of vanillin, is an attractive alternative for various industries due to the high price and demand for natural ferulic acid. Feruloyl esterase has been identified as a key enzyme involved in microbial transformations of ferulic acid to vanillin. Several fungal feruloyl esterases have been purified and characterized for their use in the production of ferulic acid. This paper, for the first time, discusses the use of lactic acid bacteria for the production of ferulic acid. Specifically, we have used Lactobacillus cells and microencapsulation so that ferulic acid can be produced continuously using various types of fermentation systems. Bacteria were encapsulated in alginate-poly-l-lysine-alginate (APA) microcapsules, and the production of ferulic acid by lactobacilli was detected using a real-time high-performance liquid chromatography (HPLC)-based assay. Results show that ferulic acid can be produced using microencapsulated Lactobacillus fermentum (ATCC 11976) with significant levels of biological feruloyl esterase activity.     

Adult murine skeletal muscle contains cells that can differentiate into beating cardiomyocytes in vitro

It has long been held as scientific fact that soon after birth, cardiomyocytes cease dividing, thus explaining the limited restoration of cardiac function after a heart attack. Recent demonstrations of cardiac myocyte differentiation observed in vitro or after in vivo transplantation of adult stem cells from blood, fat, skeletal muscle, or heart have challenged this view. Analysis of these studies has been complicated by the large disparity in the magnitude of effects seen by different groups and obscured by the recently appreciated process of in vivo stem-cell fusion. We now show a novel population of nonsatellite cells in adult murine skeletal muscle that progress under standard primary cell-culture conditions to autonomously beating cardiomyocytes. Their differentiation into beating cardiomyocytes is characterized here by video microscopy, confocal-detected calcium transients, electron microscopy, immunofluorescent cardiac-specific markers, and single-cell patch recordings of cardiac action potentials. Within 2 d after tail-vein injection of these marked cells into a mouse model of acute infarction, the marked cells are visible in the heart. By 6 d they begin to differentiate without fusing to recipient cardiac cells. Three months later, the tagged cells are visible as striated heart muscle restricted to the region of the cardiac infarct.     

Constitutive Notch activation upregulates Pax7 and promotes the self-renewal of skeletal muscle satellite cells

Notch signaling is a conserved cell fate regulator during development and postnatal tissue regeneration. Using skeletal muscle satellite cells as a model and through myogenic cell lineage-specific NICD(OE) (overexpression of constitutively activated Notch 1 intracellular domain), here we investigate how Notch signaling regulates the cell fate choice of muscle stem cells. We show that in addition to inhibiting MyoD and myogenic differentiation, NICD(OE) upregulates Pax7 and promotes the self-renewal of satellite cell-derived primary myoblasts in culture. Using MyoD(-/-) myoblasts, we further show that NICD(OE) upregulates Pax7 independently of MyoD inhibition. In striking contrast to previous observations, NICD(OE) also inhibits S-phase entry and Ki67 expression and thus reduces the proliferation of primary myoblasts. Overexpression of canonical Notch target genes mimics the inhibitory effects of NICD(OE) on MyoD and Ki67 but not the stimulatory effect on Pax7. Instead, NICD regulates Pax7 through interaction with RBP-Jκ, which binds to two consensus sites upstream of the Pax7 gene. Importantly, satellite cell-specific NICD(OE) results in impaired regeneration of skeletal muscles along with increased Pax7(+) mononuclear cells. Our results establish a role of Notch signaling in actively promoting the self-renewal of muscle stem cells through direct regulation of Pax7.     

Membrane currents of rat satellite cells attached to intact skeletal muscle fibers

Muscle satellite cells play an important role in the postnatal growth of skeletal muscle and in the regeneration of damaged muscle during adult life. Little is known about the physiological properties of satellite cells in their dormant state as they lie adjacent to the intact muscle fibers, underneath the basement membrane. Our recent experiments, using patch clamp techniques, indicate that no tight electrical coupling is present between satellite cells and the muscle fiber dissociated from rat flexor digitorum brevis. Satellite cells possess sodium channels with low sensitivity to tetrodotoxin and at a much lower density than muscle. In addition, satellite cells are insensitive to acetylcholine (ACh) for at least 24 hr after having been removed from the animal, even when detached from their muscle fiber. However, we could measure ACh-evoked currents from satellite cells 48-72 hr in culture, indicating that ACh sensitivity develops with time.     

Myogenic skeletal muscle satellite cells communicate by tunnelling nanotubes

Quiescent satellite cells sit on the surface of the muscle fibres under the basal lamina and are activated by a variety of stimuli to disengage, divide and differentiate into myoblasts that can regenerate or repair muscle fibres. Satellite cells adopt their parent's fibre type and must have some means of communication with the parent fibre. The mechanisms behind this communication are not known. We show here that satellite cells form dynamic connections with muscle fibres and other satellite cells by F‐actin based tunnelling nanotubes (TNTs). Our results show that TNTs readily develop between satellite cells and muscle fibres. Once developed, TNTs permit transport of intracellular material, and even cellular organelles such as mitochondria between the muscle fibre and satellite cells. The onset of satellite cell differentiation markers Pax‐7 and MyoD expression was slower in satellite cells cultured in the absence than in the presence of muscle cells. Furthermore physical contact between myofibre and satellite cell progeny is required to maintain subtype identity. Our data establish that TNTs constitute an integral part of myogenic cell communication and that physical cellular interaction control myogenic cell fate determination. J. Cell. Physiol. 223: 376–383, 2010. © 2010 Wiley‐Liss, Inc.     

Regulation of satellite cells during skeletal muscle growth and development

Satellite cells are myogenic cells attributed with the role of postnatal growth and regeneration in skeletal muscle. Following proliferation and subsequent differentiation, these cells will fuse with one another or with the adjacent muscle fiber, thereby increasing myonuclei numbers for fiber growth and repair. The potential factors which could regulate this process are many, including exercise, trauma, passive stretch, innervation, and soluble growth factors. Three classes of growth factors in particular (fibroblast growth factor, insulin-like growth factor, and transforming growth factor-beta) have been studied extensively with respect to their effects on satellite cell proliferation and differentiation in culture. Fibroblast growth factor has been shown to stimulate proliferation but depress differentiation. Insulin-like growth factor stimulates both proliferation and differentiation, although the latter to a much greater degree. Transforming growth factor-beta slightly depresses proliferation but inhibits differentiation. When administered in combination, these factors can induce satellite cell activities in culture which mimic those typical of satellite cells found in vivo in growing, regenerating, or healthy mature muscle. Alterations in the concentrations of these growth factors in the muscle environment as well as alterations in the cell's sensitivity or responsiveness to these factors represent potential mechanisms for regulating satellite cell activity in situ.     

大鼠骨骼肌卫星细胞诱导分化为胰岛素生成细胞的研究

目的探讨大鼠骨骼肌卫星细胞（MDSCs）定向诱导分化为胰岛素生成细胞（IPCs）,为1型糖尿病的干细胞治疗提供一种新的研究思路。 方法通过二次酶消化法和差速贴壁培养法分离、培养大鼠MDSCs,利用不同的诱导培养液使MDSCs定向分化为IPCs,并对诱导后细胞进行形态观察,通过双硫腙染色和免疫组化染色对MDSCs-IPCs形态进行鉴定,采用Q-PCR和Western Blot方法检测MDSCs-IPCs中C-peptide和Insulin的表达,通过胰岛素释放实验检测MDSCs-IPCs的生物学功能,β细胞和MDSCs-IPCs两组间比较采用t检验。 结果MDSCs在接种4 h后开始贴壁部分细胞伸出小的突起,48 h后绝大多数细胞贴壁呈梭形、胞浆丰富、折光度高。随着培养时间的延长,细胞的梭形形状更为明显且生长迅速。免疫组化结果显示细胞表达Desmin、α-Sarcomeric Actinin、MyoD1、Myf5和PAX7。成胰诱导后MDSCs形成胰岛样的圆形细胞团,双硫腙染色呈猩红色,Insulin免疫组化染色阳性。Q-PCR结果显示MDSCs-IPCs中C-peptide和Insulin mRNA表达量分别是β细胞的0.73倍（P > 0.05）和0.79倍（P > 0.05）。胰岛素释放实验显示,5.6 mmol/L和16.7 nmlol/L葡萄糖刺激培养2 h后,β细胞和MDSCs-IPCs分泌胰岛素量分别为[（20.3±4.2）mU/L]、[（16.1±3.7）mU/L]、[（60.5±9.3）mU/L]和[（40.9±7.3）mU/L],葡萄糖可调节MDSCs-IPCs胰岛素的分泌。 结论MDSCs易于分离培养、增殖能力强,体外可诱导分化为有功能的IPCs,适合作为再生医学的种子细胞。     

Hepatocyte growth factor affects satellite cell activation and differentiation in regenerating skeletal muscle

Hepatocyte growth factor (HGF) is the onlyknown growth factor that activates quiescent satellite cells inskeletal muscle. We hypothesized that local delivery of HGF may enhanceregeneration after trauma by increasing the number of myoblastsavailable for restoring normal tissue architecture. Injection of HGFinto muscle at the time of injury increases myoblast number but doesnot enhance tissue repair as determined using quantitative histologicalanalyses. Rather, depending on the dose and the timing of HGFadministration relative to the injury, regeneration can be inhibited.The greatest inhibitory effect is observed when HGF is administered onthe day of injury and continued for 3 days, corresponding to the time when satellite cell activation, proliferation, and earlydifferentiation normally occur. To establish a mechanism for thisinhibition, we show that HGF can act directly on primary muscle cellsto block differentiation. These results demonstrate that1) exogenous HGF synergizes withfactors in damaged muscle to increase myoblast number,2) regeneration is not regulatedsolely by myoblast number, and 3)HGF inhibits muscle differentiation both in vitro and in vivo.

     

Metabolic switching of human skeletal muscle cells in vitro

In this review we will focus on external factors that may modify energy metabolism in human skeletal muscle cells (myotubes) and the ability of the myotubes to switch between lipid and glucose oxidation. We describe the metabolic parameters suppressibility, adaptability and substrate-regulated flexibility, and show the influence of nutrients such as fatty acids and glucose (chronic hyperglycemia), and some pharmacological agents modifying nuclear receptors (PPAR and LXR), on these parameters in human myotubes. Possible cellular mechanisms for changes in these parameters will also be highlighted.