Skeletal muscle possesses a remarkable ability for its regeneration and injured tissue repair. This ability depends on the activity and contributions of muscle satellite cells. Proliferating satellite cells, termed myogenic precursor cells or myoblasts, are activated and driven out of their quiescent state upon muscle injury. In this summary, we present a review to summarize the molecular regulation in skeletal satellite cells to light on the satellite cells' self-renewal mechanism.
Cell Proliferation ; Humans ; Muscle, Skeletal ; Regeneration ; Satellite Cells, Skeletal Muscle ; cytology ; Soft Tissue Injuries

OBJECTIVETo establish the methods for purification, culture, and identification of adult human skeletal muscle stem cells in vitro and to explore the biological properties of the cells.

METHODSMuscle stem cells were obtained by reformed enzymatic digestion of muscle tissue from the consenting donors and cultured in serum-free medium. The morphology was inspected by an inverted phase contrast microscope. Phenotypic characteristics of the cells and expression of cell-specific markers were determined using reverse transcription-polymerase chain reaction (RT-PCR) and immunocytochemistry. The growth of single cells in suspension culture was observed and recorded continuously. The cells were analyzed for their multi-lineage differentiation potential into osteoblastic, adipocyte, and smooth muscle cell lineages.

RESULTSPrimary cultured human skeletal muscle stem cells proliferated and formed the big spheres when cultured with serum free medium. Immunofluorescence staining displayed Pax7 and ALDH1 positive expression in the cell spheres. Furthermore, Myod and Desmin showed positive expression in the monolayer cells derived from the spheres. The gene expressions of Oct3/4, Nanog, Sox2 and Pax7 in the cells were determined by RT-PCR. The cell clones formed from single cells grew well. In addition, they were capable of spontaneous differentiation into myotubes in differentiation medium and into other mesodermal cell lineages in induction medium.

CONCLUSIONSHuman muscle stem cells with properties of self-renewal capacity and multi-differentiation could be successfully isolated and expanded in vitro.

Cell Culture Techniques ; methods ; Cell Differentiation ; Cell Proliferation ; Cells, Cultured ; Humans ; Muscle, Skeletal ; cytology ; Satellite Cells, Skeletal Muscle ; cytology ; Stem Cells ; cytology

OBJECTIVETo study the effects of skeletal muscle satellite cells implanted into infarcted myocardium on the volume of remnant myocytes.

METHODSThirty-six adult mongrel canines were divided randomly into implantation group and control group. In the implantation group, skeletal muscle satellite cells taken from the gluteus maximus muscles of the dogs were cultured, proliferated and labeled with 4',6-diamidino-2-phenylindone (DAPI) in vitro. In both groups, a model of acute myocardial infarction was established in every dog. In the implantation group, each dog was injected with M199 solution containing autologous skeletal muscle satellite cells. The dogs in the control group received M199 solution without skeletal muscle satellite cells. The dogs of both groups were killed 2, 4 and 8 weeks after implantation (six dogs in a separate group each time). Both infarcted myocardium and normal myocytes distal from the infracted regions isolated were observed under optical and fluorescent microscope. Their volumes were determined using a confocal microscopy image analysis system and analyzed using SAS. A P < 0.05 was considered significant.

RESULTSA portion of the implanted cells differentiated into muscle fiber with striations and were connected with intercalated discs. Cross-sectional area and cell volume were increased in normal myocardium. Hypertrophy of remnant myocytes in the infarcted site after skeletal muscle cell implantation was much more evident than in the control group. Cross-sectional area, cell area and cell volume differed significantly from those of the control group (P < 0.05). Hypertrophy of the cells occurred predominantly in terms of width and thickness, whereas cell length remained unchanged.

CONCLUSIONSkeletal muscle satellite cells implanted into infarct myocardium, could induce the hypertrophy of remnant myocyte cells in the infarcted site and could also aid in the recovery of the contractile force of the infarcted myocardium.

Animals ; Cell Size ; Dogs ; Myocardial Infarction ; pathology ; Myocardium ; pathology ; Myocytes, Cardiac ; cytology ; Random Allocation ; Satellite Cells, Skeletal Muscle ; cytology ; physiology

OBJECTIVETo study the effect of different access routes on autologous satellite cell implantation to stimulate myocardial regeneration.

METHODSSatellite cells were procured from skeletal muscle (gluteus max) of adult mongrel canine, cultured, proliferated and labeled with 4', 6-diamidino-2-phenylindone (DAPI) in vitro. The cells were autologously implanted into the site of acute myocardial infarction by local injection or perfusion through the ligated distal left anterior descending coronary artery. Specimens were harvested 2, 4 and 8 weeks later for histological study.

RESULTSThe labeling efficiency of satellite cells with DAPI was close to 100%. Fluorescent cells were found at the infarcted zone, papillary muscle and local injection site. Some of these cells had progressively differentiated into striated muscle fibers connected to intercalated discs. The infant cells appeared different from the mature myocardium under an electron microscope. Satellite cells implanted by perfusion through the coronary artery were arranged in order of consistency with host myocardial fibers. The satellite cells, implanted by local injection, were found growing in a disordered way.

CONCLUSIONSatellite cells, implanted by coronary artery perfusion, can progressively differentiate into striated muscle fibers, arranging in order and disseminating over the infarcted zone. This approach seems more favorable for the recovery of myocardial contractile function than that of local injection.

Animals ; Cell Differentiation ; physiology ; Dogs ; Myocardial Infarction ; pathology ; therapy ; Myocardium ; cytology ; Regeneration ; Satellite Cells, Skeletal Muscle ; cytology ; transplantation ; Transplantation, Autologous

BACKGROUNDMyocardial infarction results in tissue necrosis, leading to cell loss and ultimately to cardiac failure. Implantation of skeletal muscle satellite cells into the scar area may compensate for the cell loss and provides a new strategy for infarct therapy. Vascular endothelial growth factor (VEGF) is a promising reagent for inducing myocardial angiogenesis. Skeletal myoblast transplantation has been shown to improve cardiac function in chronic heart failure models by regenerating muscle. We hypothesized that VEGF expression and vascular regeneration increased in infarcted myocardium by skeletal muscle satellite cells, which can promote vascular producing and improve survival environment in infarcted myocardium.

METHODSThe skeletal muscle satellite cells were implanted into the infarcted myocardium in a model through ligated left anterior artery in Louis Inbrad Strain rat. Specimens were got for identifying the expression of VEGF and the density of vascular by immunochemical method at two weeks after implantation.

RESULTSThe proliferation and differentiation of the skeletal muscle satellite cell was very well. The expression of VEGF was higher in the implanted group (146.83 +/- 2.49) than that in the control group (134.26 +/- 6.84) (P < 0.05). The vascular density in the implanted group (13.00 +/- 1.51) was also higher than that in the control (10.68 +/- 1.79) (P < 0.05).

CONCLUSIONThe implanted satellite cell could excrete growth factor that would induce angiogenesis and improve cell survival environment in infarcted myocardium.

Animals ; Cell Proliferation ; Cells, Cultured ; Myocardial Infarction ; physiopathology ; therapy ; Neovascularization, Physiologic ; RNA, Messenger ; analysis ; Rats ; Regeneration ; Satellite Cells, Skeletal Muscle ; cytology ; transplantation ; Vascular Endothelial Growth Factor A ; genetics

OBJECTIVETo investigate separation and purification of skeletal muscle satellite cells with improved incontinuous density Percoll gradient centrifugation technique.

METHODSThe primary skeletal muscle satellite cells of New Zealand white rabbits were cultured with different adhesion time method and incontinuous density Percoll gradient centrifugation technique. The cells were observed under invert microscope and scanning electron microscope. The degree of purification was examined by celluar immunochemical stain. The growth curve was tested by thiazolyl blue assay.

RESULTSOver 90% satellite cells were harvested by incontinuous density Percoll gradient centrifugation technique, in contrast to which, only 30%-40% cells were harvested by different adhesion time. Morphological observation accorded with satellite cells. The growth curve indicated that the cells grew in a good status.

CONCLUSIONThe high purification satellite cells can be obtained by incontinuous density Percoll gradient centrifugation technique. It is a good method to culture seed cells for tissue engineering applications.

Animals ; Bioartificial Organs ; Cell Culture Techniques ; methods ; Cell Separation ; methods ; Centrifugation, Density Gradient ; Male ; Povidone ; Rabbits ; Satellite Cells, Skeletal Muscle ; cytology ; Silicon Dioxide ; Tissue Engineering ; Urinary Bladder

We examined the effect of a combination of astaxanthin (AX) supplementation, repeated heat stress, and intermittent reloading (IR) on satellite cells in unloaded rat soleus muscles. Forty-nine male Wistar rats (8-week-old) were divided into control, hind-limb unweighting (HU), IR during HU, IR with AX supplementation, IR with repeated heat stress (41.0-41.5 °C for 30 min), and IR with AX supplementation and repeated heat stress groups. After the experimental period, the antigravitational soleus muscle was analyzed using an immunohistochemical technique. Our results revealed that the combination of dietary AX supplementation and heat stress resulted in protection against disuse muscle atrophy in the soleus muscle. This protective effect may be partially due to a higher satellite cell number in the atrophied soleus muscle in the IR/AX/heat stress group compared with the numbers found in the other groups. We concluded that the combination treatment with dietary AX supplementation and repeated heat stress attenuates soleus muscle atrophy, in part by increasing the number of satellite cells.
Animals ; Body Weight ; Dietary Supplements ; Fibrinolytic Agents/pharmacology* ; Heat-Shock Response ; Hindlimb ; Hot Temperature ; Immunohistochemistry ; Male ; Muscle, Skeletal ; Muscular Atrophy/drug therapy* ; Oxidative Stress ; Rats ; Rats, Wistar ; Satellite Cells, Skeletal Muscle/cytology* ; Xanthophylls/pharmacology*