Pericytes of human skeletal muscle are myogenic precursors distinct from satellite cells

Cells derived from blood vessels of human skeletal muscle can regenerate skeletal muscle, similarly to embryonic mesoangioblasts. However, adult cells do not express endothelial markers, but instead express markers of pericytes, such as NG2 proteoglycan and alkaline phosphatase (ALP), and can be prospectively isolated from freshly dissociated ALP(+) cells. Unlike canonical myogenic precursors (satellite cells), pericyte-derived cells express myogenic markers only in differentiated myotubes, which they form spontaneously with high efficiency. When transplanted into severe combined immune deficient-X-linked, mouse muscular dystrophy (scid-mdx) mice, pericyte-derived cells colonize host muscle and generate numerous fibres expressing human dystrophin. Similar cells isolated from Duchenne patients, and engineered to express human mini-dystrophin, also give rise to many dystrophin-positive fibres in vivo. These data show that myogenic precursors, distinct from satellite cells, are associated with microvascular walls in the human skeletal muscle, may represent a correlate of embryonic 'mesoangioblasts' present after birth and may be a promising candidate for future cell-therapy protocols in patients.     

Selection of multipotent cells and enhanced muscle reconstruction by myogenic macrophage-secreted factors

Skeletal muscle regeneration relies on satellite cells, a population of myogenic precursors. Inflammation also plays a determinant role in the process, as upon injury, macrophages are attracted by the damaged myofibers and the activated satellite cells and act as key elements of dynamic muscle supportive stroma. Yet, it is not known how macrophages interact with the more profound stem cells of the satellite cell niche. Here we show that in the presence of a murine macrophage conditioned medium (mMCM) a subpopulation of multipotent cells could be selected and expanded from adult rat muscle. These cells were small, round, poorly adhesive, slow-growing and showed mesenchymal differentiation plasticity. At the same time, mMCM showed clear myogenic capabilities, as experiments with satellite cells mechanically isolated from suspensions of single myofibers showed that the macrophagic factors inhibited their tendency to shift towards adipogenesis. In vivo, intramuscular administrations of concentrated mMCM in a rat model of extensive surgical ablation dramatically improved muscle regeneration. Altogether, these findings suggest that macrophagic factors could be of great help in developing therapeutic protocols with myogenic stem cells.     

Spontaneous myogenic differentiation of Flk-1-positive cells from adult pancreas and other nonmuscle tissues

At the embryonic or fetal stages, autonomously myogenic cells (AMCs), i.e., cells able to spontaneously differentiate into skeletal myotubes, have been identified from several different sites other than skeletal muscle, including the vascular compartment. However, in the adult animal, AMCs from skeletal muscle-devoid tissues have been described in only two cases. One is represented by thymic myoid cells, a restricted population of committed myogenic progenitors of unknown derivation present in the thymic medulla; the other is represented by a small subset of adipose tissue-associated cells, which we recently identified. In the present study we report, for the first time, the presence of spontaneously differentiating myogenic precursors in the pancreas and in other skeletal muscle-devoid organs such as spleen and stomach, as well as in the periaortic tissue of adult mice. Immunomagnetic selection procedures indicate that AMCs derive from Flk-1(+) progenitors. Individual clones of myogenic cells from nonmuscle organs are morphologically and functionally indistinguishable from skeletal muscle-derived primary myoblasts. Moreover, they can be induced to proliferate in vitro and are able to participate in muscle regeneration in vivo. Thus, we provide evidence that fully competent myogenic progenitors can be derived from the Flk-1(+) compartment of several adult tissues that are embryologically unrelated to skeletal muscle.     

Signals from damaged but not undamaged skeletal muscle induce myogenic differentiation of rat bone-marrow-derived mesenchymal stem cells

The regenerative capacity of skeletal muscle has been usually attributed to resident satellite cells, which, upon activation by local or distant stimuli, initiate a myogenic differentiation program. Although recent studies have revealed that bone-marrow-derived progenitor cells may also participate in regenerative myogenesis, the signals and mechanisms involved in this process have not been elucidated. This study was designed to investigate whether signals from injured rat skeletal muscle were competent to induce a program of myogenic differentiation in expanded cultures of rat bone-marrow-derived mesenchymal stem cells (MSC). We observed that the incubation of MSC with a conditioned medium prepared from chemically damaged but not undamaged muscle resulted in a time-dependent change from fibroblast-like into elongated multinucleated cells, a transient increase in the number of MyoD positive cells, and the subsequent onset of myogenin, alpha-actinin, and myosin heavy chain expression. These results show that damaged rat skeletal muscle is endowed with the capacity to induce myogenic differentiation of bone-marrow-derived mesenchymal progenitors.     

miR‐24 and its target gene Prdx6 regulate viability and senescence of myogenic progenitors during aging

Satellite cell‐dependent skeletal muscle regeneration declines during aging. Disruptions within the satellite cells and their niche, together with alterations in the myofibrillar environment, contribute to age‐related dysfunction and defective muscle regeneration. In this study, we demonstrated an age‐related decline in satellite cell viability and myogenic potential and an increase in ROS and cellular senescence. We detected a transient upregulation of miR‐24 in regenerating muscle from adult mice and downregulation of miR‐24 during muscle regeneration in old mice. FACS‐sorted satellite cells were characterized by decreased levels of miR‐24 and a concomitant increase in expression of its target: Prdx6. Using GFP reporter constructs, we demonstrated that miR‐24 directly binds to its predicted site within Prdx6 mRNA. Subtle changes in Prdx6 levels following changes in miR‐24 expression indicate miR‐24 plays a role in fine‐tuning Prdx6 expression. Changes in miR‐24 and Prdx6 levels were associated with altered mitochondrial ROS generation, increase in the DNA damage marker: phosphorylated‐H2Ax and changes in viability, senescence, and myogenic potential of myogenic progenitors from mice and humans. The effects of miR‐24 were more pronounced in myogenic progenitors from old mice, suggesting a context‐dependent role of miR‐24 in these cells, with miR‐24 downregulation likely a part of a compensatory response to declining satellite cell function during aging. We propose that downregulation of miR‐24 and subsequent upregulation of Prdx6 in muscle of old mice following injury are an adaptive response to aging, to maintain satellite cell viability and myogenic potential through regulation of mitochondrial ROS and DNA damage pathways.     

Skeletal myogenic progenitors in the endothelium of lung and yolk sac

We previously showed that clonable skeletal myogenic cells can be derived from the embryonic aorta but become very rare in the more mature and structured fetal aorta. The aim of this study was to investigate whether, during fetal and postnatal development, these myogenic progenitors progressively disappear or may rather associate with the microvascular district, being thus distributed to virtually all tissues. To test this hypothesis, we used F1 embryos (or mice) from a transgenic line expressing a striated muscle-specific reporter gene (LacZ) crossed with a transgenic line expressing a different endothelial-specific reporter genes (GFP). Endothelial cells were isolated from yolk sac (at E11) and lung (at E11, E17, P1, P10, and P60), two organs embryologically unrelated to paraxial mesoderm, rich in vessels, and devoid of skeletal muscle. Endothelial cells, purified by magnetic bead selection (CD31/PECAM-1(+)) or cell sorting (Tie2-GFP(+)) were then challenged for their skeletal myogenic potential in vitro and in vivo.The results demonstrated that both yolk sac and lung contain progenitor cells, which express endothelial markers and are endowed with a skeletal myogenic potential that they reveal when in the presence of differentiating myoblasts, in vitro, and regenerating muscle, in vivo.The number (or potency to generate skeletal muscle) of these vessels associated cells decreases rapidly with age and is very low in mature animals, possibly correlating with reduced regenerative capacity of adult mammalian tissues.     

Endoglin is required for myogenic differentiation potential of neural crest stem cells

Genetic studies show that TGFbeta signaling is essential for vascular development, although the mechanism through which this pathway operates is incompletely understood. Here we demonstrate that the TGFbeta auxiliary coreceptor endoglin (eng, CD105) is expressed in a subset of neural crest stem cells (NCSCs) in vivo and is required for their myogenic differentiation. Overexpression of endoglin in the neural crest caused pericardial hemorrhaging, correlating with altered vascular smooth muscle cell investment in the walls of major vessels and upregulation of smooth muscle alpha-actin protein levels. Clonogenic differentiation assay of NCSCs derived from neural tube explants demonstrated that only NCSC expressing high levels of endoglin (NCSC(CD105+)) had myogenic differentiation potential. Furthermore, myogenic potential was deficient in NCSCs obtained from endoglin null embryos. Expression of endoglin in NCSCs declined with age, coinciding with a reduction in both smooth muscle differentiation potential and TGFbeta1 responsiveness. These findings demonstrate a cell autonomous role for endoglin in smooth muscle cell specification contributing to vascular integrity.     

A modified enrichment protocol for adult caprine skeletal muscle stem cell

To establish an adequate model to study the proliferation and differentiation of adult caprine skeletal muscle in response to bioactive compounds, a pool of satellite cells (SC) was derived from the rectus abdominis muscle of adult goat. Skeletal muscle contains a population of adult stem cells, named as satellite cells that reside beneath the basal lamina of skeletal muscle fiber and other populations of cells. These SC are multipotent stem cells, since cells cultured in the presence of specific cell lineage inducing cocktails can differentiate into several types of mesenchymal lineage, such as osteocytes and adipocytes. In the present study, we have developed a modified protocol for isolating satellite cells (>90%) and examined their myogenic and contractile properties in vitro.     

Insulin-like growth factor-1 (IGF-1) and leucine activate pig myogenic satellite cells through mammalian target of rapamycin (mTOR) pathway

Myogenic satellite cells are adult stem cells and have important roles in skeletal muscle growth, repair, and regeneration. Both insulin-like growth factor-1 (IGF-1) and leucine stimulate skeletal muscle growth, which link to the activation and proliferation of myogenic satellite cells in skeletal muscle. Mammalian target of rapamycin (mTOR) signaling is one of the main signaling pathways controlling protein synthesis and cell proliferation. Thus, IGF-1 and leucine may stimulate activation of myogenic satellite cells through mTOR signaling. In this study, myogenic satellite cells were isolated from 6-month-old pigs and subjected to IGF-1 and leucine treatments. Both IGF-1 and leucine upregulated mTOR signaling in myogenic satellite cells. The phosphorylation of mTOR at Ser(2448) increased 83.8 +/- 7.7% by IGF-1 (P < 0.05) and 83.4 +/- 5.7% by leucine (P < 0.05). The downstream targets of mTOR, S6 kinase, and 4E-binding protein 1 (4EBP1) were also phosphorylated due to IGF-1 and leucine treatments. Treatment with IGF-1 and leucine induced the phosphorylation of tuburin (TSC2), a key mediator upstream of mTOR signaling, by 272.8 +/- 26.4% and 94.2 +/- 28.7%, respectively. Treatment of cells with both IGF-1 and leucine did not show synergistic effect on mTOR signaling. Inhibition of mTOR by rapamycin abolished the protein synthesis and cell proliferation stimulated by both IGF-1 and leucine. In summary, our data showed that in preliminary cultured myogenic satellite cells mTOR signaling was activated due to IGF-1 and leucine treatments, and this mTOR activation is necessary for the activation of myogenic satellite cells.     

Harnessing the therapeutic potential of myogenic stem cells

The potential clinical use of stem cells for cell transplantation therapies to replace defective genes in myopathies is an area of intense investigation. Precursor cells derived from non-muscle tissue with myogenic potential have been identified in many tissues, including bone marrow and dermis, although the status of these putative stem cells requires clarification. The incorporation of circulating bone-marrow derived stem cells into regenerating adult skeletal muscle has been demonstrated in mice but the contribution of donor cells is so minimal that it would appear clinically irrelevant at this stage. The possibility of a true stem cell subpopulation within skeletal muscle that replenishes the satellite cells (conventional muscle precursors on the surface of myofibres) is also very attractive as a superior source of myoblasts for muscle construction. A full understanding of the intrinsic factors (i.e. gene expression within the stem cell) and extrinsic factors (i.e. signals from the external environment) which control the commitment of stem cells to the myogenic lineage, and the conditions which favour stem cell expansion in vivo is required before stem cells can be seriously considered for clinical cell therapy. This revised version was published online in July 2006 with corrections to the Cover Date.     

骨髓间充质干细胞成肌分化在骨骼肌再生中的应用

骨骼肌良好的再生能力是由于肌卫星细胞的存在,然而肌卫星细胞的数量仅占骨骼肌细胞数量的1%~ 5%,当肌肉损伤时,仅依靠这些卫星细胞还不足以促进骨骼肌修复与再生,并且这种再生能力会随着年龄的增大而衰减,并不能修复损伤严重的骨骼肌。骨髓间充质干细胞（BMSC）因其多向分化潜能,旁分泌潜能,免疫调节能力及容易获取等特点广泛用于损伤骨骼肌的修复与再生。但在某种程度上,仅仅采用BMSC治疗损伤的骨骼肌仍不能达到满意的效果。因此,大量研究采用药物、生物材料、细胞及细胞因子对BMSC进行预处理不仅可改善它的移植率,还可显著促进其向骨骼肌分化,从而最大限度的发掘骨骼肌间充质干细胞的成肌分化潜能以促进骨骼肌的修复。因此,本篇综述旨在概括BMSC成肌分化在骨骼肌再生中的应用。     

Differential response among cells in the chick embryo myogenic lineage to photosensitization by Merocyanine 540

Primary cultures of myogenic cells from progressively older embryonic and adult chickens were incubated in medium containing Merocyanine 540 (MC540) and were exposed to white light during the incubation period. After exposure, the cultures were followed to determine cell survival and differentiation. MC540 attached to the surface membranes of all cells. In cultures from 10-day embryos (E10 cells), concentrations of MC540 greater than or equal to 60 micrograms/ml resulted in death of nearly all myogenic cells upon exposure to light, but non-myogenic cells survived and replicated. Below 60 micrograms/ml, there was a dose-dependent reduction in muscle differentiation. At concentrations less than 40 micrograms/ml, there was no effect on myogenesis. Cultures of cells from 18-day (E18) embryos (myogenic stem cells) and from adult muscle (satellite cells) were resistant to doses of MC540 that killed E10 cells. E14 myogenic cell populations contained both resistant and sensitive sub-populations. Terminally differentiated muscle cells were more sensitive to MC540 than precursor cells from any age embryo. Progeny of E18 cells acquired sensitivity to MC540 as differentiation proceeded. In clonal cultures, cells that normally give rise to small muscle clones (committed cells) were selectively destroyed by exposure to the dye. These observations demonstrate that an MC540-resistant myogenic population is present in low numbers in 10-day embryonic pectoral muscle. As development proceeds, this population increases such that, by 18 days of gestation, most of the myogenic cells are resistant to MC540. The results also suggest that embryonic chick myogenic stem cells and adult satellite cells have surface membrane properties which differ from those of their committed progeny.     

Syndecan-3 and syndecan-4 specifically mark skeletal muscle satellite cells and are implicated in satellite cell maintenance and muscle regeneration.

Myogenesis in the embryo and the adult mammal consists of a highly organized and regulated sequence of cellular processes to form or repair muscle tissue that include cell proliferation, migration, and differentiation. Data from cell culture and in vivo experiments implicate both FGFs and HGF as critical regulators of these processes. Both factors require heparan sulfate glycosaminoglycans for signaling from their respective receptors. Since syndecans, a family of cell-surface transmembrane heparan sulfate proteoglycans (HSPGs) are implicated in FGF signaling and skeletal muscle differentiation, we examined the expression of syndecans 1-4 in embryonic, fetal, postnatal, and adult muscle tissue, as well as on primary adult muscle fiber cultures. We show that syndecan-1, -3, and -4 are expressed in developing skeletal muscle tissue and that syndecan-3 and -4 expression is highly restricted in adult skeletal muscle to cells retaining myogenic capacity. These two HSPGs appear to be expressed exclusively and universally on quiescent adult satellite cells in adult skeletal muscle tissue, suggesting a role for HSPGs in satellite cell maintenance or activation. Once activated, all satellite cells maintain expression of syndecan-3 and syndecan-4 for at least 96 h, also implicating these HSPGs in muscle regeneration. Inhibition of HSPG sulfation by treatment of intact myofibers with chlorate results in delayed proliferation and altered MyoD expression, demonstrating that heparan sulfate is required for proper progression of the early satellite cell myogenic program. These data suggest that, in addition to providing potentially useful new markers for satellite cells, syndecan-3 and syndecan-4 may play important regulatory roles in satellite cell maintenance, activation, proliferation, and differentiation during skeletal muscle regeneration.     

Decorin expression in quiescent myogenic cells

Satellite cells are quiescent muscle stem cells that promote postnatal muscle growth and repair. When satellite cells are activated by myotrauma, they proliferate, migrate, differentiate, and ultimately fuse to existing myofibers. The remainder of these cells do not differentiate, but instead return to quiescence and remain in a quiescent state until activation begins the process again. This ability to maintain their own population is important for skeletal muscle to maintain the capability to repair during postnatal life. However, the mechanisms by which satellite cells return to quiescence and maintain the quiescent state are still unclear. Here, we demonstrated that decorin mRNA expression was high in cell cultures containing a higher ratio of quiescent satellite cells when satellite cells were stimulated with various concentrations of hepatocyte growth factor. This result suggests that quiescent satellite cells express decorin at a high level compared to activated satellite cells. Furthermore, we examined the expression of decorin in reserve cells, which were undifferentiated myoblasts remaining after induction of differentiation by serum-deprivation. Decorin mRNA levels in reserve cells were higher than those in differentiated myotubes and growing myoblasts. These results suggest that decorin participates in the quiescence of myogenic cells.     

Isolation of adult mouse myogenic progenitors: functional heterogeneity of cells within and engrafting skeletal muscle

Skeletal muscle regeneration in adults is thought to occur through the action of myogenic satellite cells located in close association with mature muscle fibers; however, these precursor cells have not been prospectively isolated, and recent studies have suggested that additional muscle progenitors, including cells of bone marrow or hematopoietic origin, may exist. To clarify the origin(s) of adult myogenic cells, we used phenotypic, morphological, and functional criteria to identify and prospectively isolate a subset of myofiber-associated cells capable at the single cell level of generating myogenic colonies at high frequency. Importantly, although muscle-engrafted cells from marrow and/or circulation localized to the same anatomic compartment as myogenic satellite cells and expressed some though not all satellite cell markers, they displayed no intrinsic myogenicity. Together, these studies describe the clonal isolation of functional adult myogenic progenitors and demonstrate that these cells do not arise from hematopoietic or other bone marrow or circulating precursors.     

A new look at the origin, function, and "stem-cell" status of muscle satellite cells

Muscle satellite cells have long been considered a distinct myogenic lineage responsible for postnatal growth, repair, and maintenance of skeletal muscle. Recent studies in mice, however, have revealed the potential for highly purified hematopoietic stem cells from bone marrow to participate in muscle regeneration. Perhaps more significantly, a population of putative stem cells isolated directly from skeletal muscle efficiently reconstitutes the hematopoietic compartment and participates in muscle regeneration following intravenous injection in mice. The plasticity of muscle stem cells has raised important questions regarding the relationship between the muscle-derived stem cells and the skeletal muscle satellite cells. Furthermore, the ability of hematopoietic cells to undergo myogenesis has prompted new investigations into the embryonic origin of satellite cells. Recent developmental studies suggest that a population of satellite cells is derived from progenitors in the embryonic vasculature. Taken together, these studies provide the first evidence that pluripotential stem cells are present within adult skeletal muscle. Tissue-specific stem cells, including satellite cells, may share a common embryonic origin and possess the capacity to activate diverse genetic programs in response to environmental stimuli. Manipulation of such tissue-specific stem cells may eventually revolutionize therapies for degenerative diseases, including muscular dystrophy.     

Notch pathway: from development to regeneration of skeletal muscle

In vertebrates, skeletal muscle is derived from mesodermal structures called somites. Myogenic progenitor cells that form skeletal muscles of the trunk and limbs are derived from the dermomyotome, the dorsal region of the somite. These cells enter the myogenic program by activating a set of four myogenic regulatory factors. During embryonic and fetal growth, muscle progenitor cells provide the source for muscle growth. Around birth, the muscle progenitor enters quiescence, and adopts a satellite cell position on muscle fibers, providing a pool of adult muscle stem cells. They are essential for the growth and regeneration of muscles. Among the mechanisms that control the maintenance of satellite cells properties, the Notch pathway plays a crucial role. In facts, this pathway is implicated from the early steps of somitogenesis and the development of skeletal muscles in the embryo. Furthermore, during ageing, Notch activity decreases which results in decreased muscle regeneration. Thus, the Notch pathway is a key regulator of muscle plasticity.