mdx小鼠骨骼肌组织成肌、成脂、成骨基因的特异性表达

背景：干细胞移植是治疗肌营养不良症的有效方法之一,但移植的干细胞在病理骨骼肌中成肌表达较低。目的：通过比较mdx小鼠和C57小鼠的骨骼肌形态及成肌、成脂、成骨基因表达的差异,探讨mdx小鼠骨骼肌病理改变的可能机制。方法：取mdx小鼠与C57小鼠的骨骼肌组织行冰冻切片,苏木精-伊红染色和Vonkossa染色观察两种小鼠肌肉组织的形态特征;提取mdx小鼠和C57小鼠骨骼肌组织总RNA,real-timePCR检测成肌、成脂、成骨相关基因的表达。结果与结论：mdx小鼠骨骼肌有肌纤维坏死和再生,伴有轻度脂肪、纤维结缔组织增生,Vonkossa染色可见钙结节沉积,而C57小鼠的骨骼肌细胞形态清晰,核位于细胞周边。与C57小鼠比较,mdx小鼠肌肉组织成骨、成脂基因表达有不同程度的上调（P〈0.05）,而成肌基因表达下调（P〈0.05）。dystrophin基因缺失及成肌基因表达下调、成骨和成脂基因上调是造成mdx小鼠肌肉组织变性坏死的原因。     

Aquaporin 4 mRNA levels in neuromuscular tissues of wild-type and dystrophin-deficient mice

Aquaporin (AQP) 4 is a water-specific channel protein and is abundant in central nervous tissues and skeletal muscles. Recently, the AQP4 molecule has been increasingly highlighted in its pathophysiological role of several neurological diseases, such as stroke, muscular dystrophy and neuromyelitis optica. We therefore measured the levels of AQP4 mRNA and glyceraldehyde-3 phosphate dehydrogenase mRNA (an internal control) in muscle and brain tissues of wild-type mice (C57BL10/ScSn) and age-matched dystrophin-deficient mdx mice (C57BL10/ScSn mdx) by real-time quantitative RT-PCR. The relative AQP4 mRNA level was highest in the spinal cord among the neuromuscular tissues examined in wild-type mice. Among the muscle tissues of wild-type mice, the relative AQP4 mRNA level was higher in extensor digitorum longus (EDL) muscles, and its descending order was EDL, quadriceps femoris, soleus and heart muscles. It is noteworthy that there was no difference in the relative AQP4 mRNA levels in the brain tissues between wild-type mice and age-matched mdx mice. In contrast, the AQP4 mRNA level in the quadriceps femoris muscle was significantly lower in mdx mice than in wild-type mice. The fact that the spinal cord contains the highest AQP4 mRNA may be related to the pathogenesis of neuromyelitis optica, in which AQP4 protein is the target antigen. In addition, the low expression level of AQP4 mRNA in the mdx mouse muscle suggests a functional link between AQP4 and dystrophin in the muscle tissue. We suggest that a similar pathomechanism may underlie the phenotypic consequences of the mdx mouse and Duchenne muscular dystrophy.     

Accumulation of calcium by normal and dystrophin-deficient mouse muscle during contractile activity in vitro.

1. Accumulation of calcium by extensor digitorum longus muscles from dystrophin-deficient mdx and control C57BL/10 mice has been studied in vitro by measurements of total muscle calcium and by following the retention of 45Ca resulting from the incubation of muscles with the isotope for up to 2 h. 2. The rate of influx of calcium, calculated from the retention of 45Ca, was linear over 2 h in muscles at rest with no significant difference between mdx and control muscles. 3. Repetitive tetanic stimuli caused a substantial increase in 45Ca flux into both mdx and control muscles. This elevated rate of influx was maintained by control muscle, but not by mdx muscle after stimulation resulting in a significantly smaller total calcium flux into mdx muscle compared with control muscle by 1 h after stimulation. Similar changes were also seen in the total muscle calcium content of mdx and control muscles. Comparison of these results with those for loss of cytosolic creatine kinase previously reported (McArdle, A., Edwards, R.H.T. & Jackson, M.J. Clin. Sci. 1991; 80, 367-71) [1] indicate that control and dystrophin-deficient muscles release equivalent amounts of intracellular creatine kinase in response to the same accumulation of intracellular calcium. 4. These results therefore do not support the hypotheses that dystrophin deficiency in muscle leads to increased calcium influx during contractile activity, or that dystrophin-deficient muscle shows any inherent increased permeability to cytosolic proteins.     

Dystrophin delivery in dystrophin-deficient DMDmdx skeletal muscle by isogenic muscle-derived stem cell transplantation

Duchenne's muscular dystrophy (DMD) is a lethal muscle disease caused by a lack of dystrophin expression at the sarcolemma of muscle fibers. We investigated retroviral vector delivery of dystrophin in dystrophin-deficient DMD(mdx) (hereafter referred to as mdx) mice via an ex vivo approach using mdx muscle-derived stem cells (MDSCs). We generated a retrovirus carrying a functional human mini-dystrophin (RetroDys3999) and used it to stably transduce mdx MDSCs obtained by the preplate technique (MD3999). These MD3999 cells expressed dystrophin and continued to express stem cell markers, including CD34 and Sca-1. MD3999 cells injected into mdx mouse skeletal muscle were able to deliver dystrophin. Though a relatively low number of dystrophin-positive myofibers was generated within the gastrocnemius muscle, these fibers persisted for up to 24 weeks postinjection. The injection of cells from additional MDSC/Dys3999 clones into mdx skeletal muscle resulted in varying numbers of dystrophin-positive myofibers, suggesting a differential regenerating capacity among the clones. At 2 and 4 weeks postinjection, the infiltration of CD4- and CD8-positive lymphocytes and a variety of cytokines was detected within the injected site. These data suggest that the transplantation of retrovirally transduced mdx MDSCs can enable persistent dystrophin restoration in mdx skeletal muscle; however, the differential regenerating capacity observed among the MDSC/Dys3999 clones and the postinjection immune response are potential challenges facing this technology.     

Effects of contractile activity on muscle damage in the dystrophin-deficient mdx mouse.

1. Isolated extensor digitorum longus muscles from control C57BL/10 and mutant dystrophin-deficient C57BL/10 mdx mice have been studied in vitro to determine whether dystrophin deficiency influences the susceptibility of muscle to contractile activity-induced damage. 2. mdx muscles were found to release reduced amounts of intracellular creatine kinase compared with control tissue in response to excessive contractile activity with or without simultaneous stretching of the muscle to 130% of its resting length. 3. In contrast, prostaglandin E2 release from mdx muscle was elevated compared with control tissue in response to either form of contractile activity or to treatment with the calcium ionophore A23187. 4. These results do not support the hypothesis that dystrophin-deficient muscle is more susceptible to damage induced by contractile activity, but suggest that dystrophin deficiency influences the activity of muscle membrane phospholipase enzymes.     

Fast and slow skeletal muscles: effect of ethanol on contractility of muscles from mice.

We examined in vitro the effect of ethanol at four concentrations (0g%, 0.1g%, 0.2g%, and 0.4g%) on contractile parameters of 40 fast extensor digitorum longus (EDL) and 40 slow soleus muscles from healthy mice at 35C. Preparations were curarized to avoid the possible effect of ethanol on the terminal axons or skeletal neuromuscular junction. Contractile parameters measured included: (1) twitch and tetanic tension; (2) rate of tension development; (3) time to peak tension and half relaxation for twitch; (4) time to first evidence of relaxation in the tetanus; and (5) maximum rate of relaxation. The three lower concentrations of ethanol had no significant effect on muscle contractility; however, the 0.4g% dose reduced EDL twitch tension by 9%. High doses of ethanol (2.5g%) reduced the tetanic tension produced by the EDL and soleus muscles 31% and 26%, respectively. Ethanol at 2.5g% also reduced the twitch tension of the EDL and soleus by 50% and 38%, respectively. The data suggested that the 0.4g% is the highest dose of ethanol that should be used to dilute drugs in a solution that will bathe directly stimulated curarized muscle without confounding effects. In addition, it is highly unlikely that a direct effect of ethanol on muscle contractility in humans is related to an impairment in driving.     

Contractile properties and susceptibility to exercise-induced damage of normal and mdx mouse tibialis anterior muscle.

1. The functional properties of tibialis anterior muscles of normal adult (C57BL/10) and age-matched dystrophin-deficient (C57BL/10 mdx) mice have been investigated in situ. Comparisons were made between tibialis anterior muscle strength, rates of force development and relaxation, force-frequency responses and fatiguability. Subjecting mdx and C57 muscles to a regimen of eccentric exercise allowed the hypothesis to be tested that dystrophin-deficient muscles are more susceptible to exercise-induced muscle damage. 2. mdx muscles were, on average, 30% stronger than C57 muscles and almost 80% heavier, but both had similar muscle lengths. Thus, although mdx muscles were stronger in absolute terms, their estimated force per unit cross-sectional area was significantly less than that of C57 muscles. 3. The force-frequency relationships of C57 and mdx muscles differed in that whilst, at 40 Hz, the former developed 70% of the force developed at 100 Hz, the latter developed only 55% of the maximal force. Twitch force was normal in mdx muscles, but contraction time was shortened, and the consequent reduction in fusion frequency probably explains the force-frequency differences observed between the two groups. 4. mdx muscles were less fatiguable than normal muscles when stimulated repeatedly at a frequency of 40 Hz. It is possible that the lower relative force at 40 Hz in mdx muscles entailed a lower energy demand and thus a slower rate of fatigue than seen in normal muscles. 5. Eccentrically exercised C57 muscles showed a large loss of maximal force for up to 12 days after exercise. Maximal force loss occurred 3 days after exercise (55% of non-exercised tibialis anterior muscle), which also corresponded with the period of greatest fibre necrosis. C57 muscles showed a significantly reduced 40 Hz/100 Hz force-frequency ratio at 1 and 3 days after exercise. This was primarily due to a reduced twitch amplitude rather than to a change in the time course of the twitch. It is unlikely, therefore, that the altered contractile characteristics of mdx muscle were a result of the presence of damaged but otherwise normal fibres. 6. C57 and mdx tibialis anterior muscles displayed similar degrees of force loss after exercise. Furthermore, the rate of recovery after the nadir of force loss was very similar for the two groups. By 12 days after exercise, force recovered to 76% and 80% of control in C57 and mdx muscles, respectively. Our findings do not support the hypothesis that dystrophin-deficient muscle is more susceptible to exercise-induced muscle damage.     

Dystrophin gene repair in mdx muscle precursor cells in vitro and in vivo mediated by RNA-DNA chimeric oligonucleotides

Point mutations in the dystrophin gene cause dystrophin deficiency and muscular dystrophy in the mdx mouse and a subset of patients with Duchenne muscular dystrophy. As an approach to gene therapy for muscular dystrophies due to point mutations, we have studied the ability of RNA-DNA chimeric oligonucleotides (chimeraplasts) to induce repair of the dystrophin gene in mdx mice. We have previously demonstrated that targeting chimeraplasts can repair the exon 23 point mutation in differentiated myofibers in vivo after intramuscular injection. For long-term benefit to patients with muscular dystrophy, any gene therapy technology must target not only differentiated myofibers but also undifferentiated muscle precursor cells that are involved in ongoing muscle repair. The focus of the current studies was to test whether chimeraplasts could repair the dystrophin mutation in mdx muscle precursor cells. Initial studies were done by transfecting a targeting chimeraplast into mdx myoblasts in vitro. Gene repair was demonstrated at the DNA, RNA, and protein levels in these cells, whereas treatment of the cells with a control chimeraplast resulted in no gene correction. After differentiation of mdx cells that had been treated with a targeting chimeraplast, immunoblot analysis demonstrated full-length dystrophin expression. By quantitative analysis of independent cultures, the amount of dystrophin expressed ranged from 2 to 15% of that expressed in wild-type cells, providing a measure of the efficacy of gene conversion in vitro. To extend the assessment to muscle precursor cells in vivo, we injected targeting and control chimeraplasts into muscles of mdx mice. When muscle precursor cells were subsequently derived from muscles injected with a targeting chimeraplast, we found that gene repair had occurred in these cells as well. These results, taken together, further demonstrate that chimeraplast-mediated gene repair may be effective as an approach to gene therapy for muscular dystrophies due to point mutations.     

Autologous transplantation of SM/C-2.6(+) satellite cells transduced with micro-dystrophin CS1 cDNA by lentiviral vector into mdx mice.

Duchenne muscular dystrophy (DMD) is a lethal muscle disorder caused by mutations in the dystrophin gene. Transplantation of autologous myogenic cells genetically corrected ex vivo is a possible treatment for this disorder. In order to test the regenerative efficiency of freshly isolated satellite cells, we purified quiescent satellite cells from limb muscles of 8-12-week-old green fluorescent protein-transgenic (GFP-Tg) mice using SM/C-2.6 (a recently developed monoclonal antibody) and flow cytometry. Freshly isolated satellite cells were shown to participate in muscle regeneration more efficiently than satellite cell-derived myoblasts passaged in vitro do, when transplanted into tibialis anterior (TA) muscles of 8-12-week-old cardiotoxin-injected C57BL/6 mice and 5-week-old dystrophin-deficient mdx mice, and analyzed at 4 weeks after injection. Importantly, expansion of freshly isolated satellite cells in vitro without passaging had no detrimental effects on their regenerative capacity. Therefore we directly isolated satellite cells from 5-week-old mdx mice using SM/C-2.6 antibody and cultured them with lentiviral vectors expressing micro-dystrophin CS1. The transduced cells were injected into TA muscles of 5-week-old mdx mice. At 4 weeks after transplantation, the grafted cells efficiently contributed to regeneration of mdx dystrophic muscles and expressed micro-dystrophin at the sarcolemma. These results suggest that there is potential for lentiviral vector-mediated ex vivo gene therapy for DMD.     

Parvalbumin gene transfer impairs skeletal muscle contractility in old mice

Abstract Sarcopenia is the progressive age-related loss of skeletal muscle mass associated with functional impairments that reduce mobility and quality of life. Overt muscle wasting with sarcopenia is usually preceded by a slowing of the rate of relaxation and a reduction in maximum force production. Parvalbumin (PV) is a cytosolic Ca(2+) buffer thought to facilitate relaxation in muscle. We tested the hypothesis that restoration of PV levels in muscles of old mice would increase the magnitude and hasten relaxation of submaximal and maximal force responses. The tibialis anterior (TA) muscles of young (6 month), adult (13 month), and old (26 month) C57BL/6 mice received electroporation-assisted gene transfer of plasmid encoding PV or empty plasmid (pcDNA3.1). Contractile properties of TA muscles were assessed in situ 14 days after transfer. In old mice, muscles with increased PV expression had a 40% slower rate of tetanic force development (p<0.01), and maximum twitch and tetanic force were 22% and 16% lower than control values, respectively (p<0.05). Muscles with increased PV expression from old mice had an 18% lower maximum specific (normalized) force than controls, and absolute force was ～26% lower at higher stimulation frequencies (150-300?Hz, p<0.05). In contrast, there was no effect of increased PV expression on TA muscle contractile properties in young and adult mice. The impairments in skeletal muscle function in old mice argue against PV overexpression as a therapeutic strategy for ameliorating aspects of contractile dysfunction with sarcopenia and help clarify directions for therapeutic interventions for age-related changes in skeletal muscle structure and function.     

Targeted expression of insulin-like growth factor-I reduces early myofiber necrosis in dystrophic mdx mice.

Necrosis of dystrophic myofibers in Duchenne muscular dystrophy and mdx mice results from defects in the subsarcolemmal protein dystrophin that cause membrane fragility and tears in the sarcolemma, and these lead to the destruction of the myofibers. The present study specifically tests whether overexpression of mIGF-1 in mdx/mIGF-1 transgenic mice reduces myofiber breakdown during the acute onset phase of dystrophy (at 21 days). The extent of muscle damage and Evans blue dye (EBD) staining of myofibers was quantitated histologically for mdx/mIGF-1 and their mdx littermates from 15 to 30 days of age. Overexpression of mIGF-1 strikingly reduced the extent of myofiber damage (histology and EBD staining) by up to 97% in tibialis anterior and quadriceps muscles at 21-22 days after birth. In the mdx diaphragm, the onset of muscle breakdown was earlier (by 15 days after birth) but no significant protective effect of IGF-1 was apparent within the first month of age in mdx/IGF-1 mice. These novel observations show that increased mIGF-1 within mdx myofibers specifically reduces the breakdown of dystrophic muscle during the acute onset of muscle degeneration. This mechanism of action can account for the long-term reduced severity of the dystropathology in mdx mice that overexpress mIGF-1 and provides promising opportunities for therapeutic strategies.     

Intramuscular Transplantation of Human Postnatal Myoblasts Generates Functional Donor-Derived Satellite Cells

Myogenic cell transplantation is an experimental approach for the treatment of myopathies. In this approach, transplanted cells need to fuse with pre-existing myofibers, form new myofibers, and generate new muscle precursor cells (MPCs). The last property was fully reported following myoblast transplantation in mice but remains poorly studied with human myoblasts. In this study, we provide evidence that the intramuscular transplantation of postnatal human myoblasts in immunodeficient mice generates donor-derived MPCs and specifically donor-derived satellite cells. In a first experiment, cells isolated from mouse muscles 1 month after the transplantation of human myoblasts proliferated in vitro as human myoblasts. These cells were retransplanted in mice and formed myofibers expressing human dystrophin. In a second experiment, we observed that inducing muscle regeneration 2 months following transplantation of human myoblasts led to myofiber regeneration by human-derived MPCs. In a third experiment, we detected by immunohistochemistry abundant human-derived satellite cells in mouse muscles 1 month after transplantation of postnatal human myoblasts. These human-derived satellite cells may correspond totally or partially to the human-derived MPCs evidenced in the first two experiments. Finally, we present evidence that donor-derived satellite cells may be produced in patients that received myoblast transplantation.     

Local and distant transfection of mdx muscle fibers with dystrophin and LacZ genes delivered in vivo by synthetic microspheres.

Patterns of dystrophin and beta-galactosidase expression were examined in mdx mice after i.m. injections of synthetic microspheres (MF-2) loaded with full-length (pHSADy) or mini-dystrophin gene (pSG5dys) cDNA plasmid constructs or with LacZ marker gene (pCMV-LacZ). A single injection of 25 microg pHSADy into quadriceps femoris muscle resulted in 6.8% of dystrophin positive myofibers (DPM) in a given muscle; 8.4% of DPM in glutaeus muscle and 4.3% of DPM in quadriceps femoris muscle of contralateral limb on day 21 after exposure compared with only 0.6% DPM in intact (non-injected) mdx mice. A high proportion of DPM (17.6% and 10.8%, respectively) was registered in both injected and contralateral muscles after mini- gene cDNA administration. MF-2/dystrophin cDNA particles were detected by FISH analysis in about 60-70% of myofiber nuclei in muscles of injected and contralateral limbs 7 days after application. The presence of human dystrophin cDNA and its products in all skeletal muscles and in different internal organs was proven by PCR and RT-PCR analysis. Patches of beta-galactosidase expression were abundant in injected muscle, and frequent in the contralateral and other skeletal muscles as well as in diaphragm, heart and lungs. High levels of dystrophin cDNA expression, and an efficient distant transfection effect with preferential intranuclei inclusion of MF-2 vehicle, are very encouraging for the development of a new constructive strategy in gene therapy trials of DMD.     

Immune rejection of human dystrophin following intramuscular injections of naked DNA in mdx mice

Intramuscular administration of plasmid expressing full-length human dystrophin in dystrophin-deficient adult mdx mice resulted in humoral and weak specific T cell responses against the human dystrophin protein. Following plasmid injection, human dystrophin was detected in the injected muscles at 7 days, but decreased thereafter. Anti-dystrophin antibodies were found 21 days following plasmid injection, which coincided with transient myositis. This immune rejection prevented the mice from expressing human dystrophin after a second plasmid injection. No anti-DNA antibodies were found. Anti-dystrophin antibodies were seen in a smaller proportion of plasmid-injected dystrophin-competent C57BL/10 mice, suggesting that the immune rejection of dystrophin may be explained partially by species differences in the dystrophin protein.     

Phenotypic improvement of dystrophic muscles by rAAV/microdystrophin vectors is augmented by Igf1 codelivery.

The absence of dystrophin in Duchenne muscular dystrophy (DMD) leads to sarcolemmal instability and enhances the susceptibility of muscle fibers to contraction-induced injury. Various viral vectors have been used to deliver mini- and microdystrophin expression cassettes to muscles of dystrophin-deficient mdx mice, significantly increasing both the morphological and the functional properties of the muscles. However, dystrophin delivery to adult mdx mice has not yielded a complete rescue of the dystrophic phenotype. Here we investigated a novel strategy involving dual gene transfer of recombinant adeno-associated viral vectors expressing either microdystrophin (rAAV-muDys) or a muscle-specific isoform of Igf-1 (rAAV-mIgf-1). Injection of mdx muscles with rAAV-muDys reduced myofiber degeneration and turnover and increased their resistance to mechanical injury, but did not increase muscle mass or force generation. Injection of mdx muscles with rAAV-mIgf-1 led to increased muscle mass, but did not provide protection against mechanical injury or halt myofiber degeneration, leading to loss of the vector over time. In contrast, co-injection of the rAAV-muDys and rAAV-mIgf-1 vectors resulted in increased muscle mass and strength, reduced myofiber degeneration, and increased protection against contraction-induced injury. These results suggest that a dual-gene, combinatorial strategy could enhance the efficacy of gene therapy of DMD.     

Immune response to adenovirus-delivered antigens upregulates utrophin and results in mitigation of muscle pathology in mdx mice

The upregulation of endogenous utrophin in skeletal muscle may lead to a new approach to the treatment of Duchenne muscular dystrophy (DMD). We found that injection of an E1, E3-deleted adenovirus vector expressing beta-galactosidase (beta-Gal) or green fluorescent protein (GFP) into the skeletal muscle of neonatal dystrophin-deficient mdx mice alleviated dystrophic pathology. In the adenovirus-infected muscles, an evaluation of sarcolemma stability showed low permeability and immunohistochemistry revealed utrophin upregulation at the extrasynaptic sarcolemma of mature muscle fibers. This utrophin upregulation was concomitant with endomysial cellular infiltration from a host immune reaction. There was no evidence of active muscle regeneration. In normal C57BL/10 mice, utrophin was also upregulated in adenovirus-injected skeletal muscles, where upregulated utrophin often coexisted with dystrophin. FK506 and anti-CD4 antibody administration decreased utrophin expression in adenovirus-injected mdx muscles and prevented the dystrophic phenotype from being mitigated, suggesting that an immune reaction is involved in utrophin upregulation. This is the first report demonstrating the improvement of the dystrophic phenotype as a result of the acquired overexpression of endogenous utrophin. Our findings provide an important clue to understanding the mechanism of utrophin expression and the development of an effective treatment for DMD.     

Intraarterial delivery of naked plasmid DNA expressing full-length mouse dystrophin in the mdx mouse model of duchenne muscular dystrophy

Our previous studies have demonstrated that the intraarterial delivery of naked plasmid DNA leads to high levels of foreign gene expression throughout the muscles of the targeted limb. Although the procedure was first developed in rats and then extended to nonhuman primates, the present study has successfully implemented the procedure in normal mice and the mdx mouse model for Duchenne muscular dystrophy. After intraarterial delivery of plasmid DNA expressing the normal, full-length mouse dystrophin from either the cytomegalovirus promoter or a muscle-specific human desmin gene control region, mdx mouse muscle stably expressed dystrophin in 1-5% of the myofibers of the injected hind limb for at least 6 months. This expression generated an antibody response but no apparent cellular response.     

Matching host muscle and donor myoblasts for myosin heavy chain improves myoblast transfer therapy

Intensive efforts have been made to develop an effective therapy for Duchenne muscular dystrophy (DMD). Although myoblast transplantation has been found capable of transiently delivering dystrophin and improving the strength of the injected dystrophic muscle, this approach has been hindered by the immune rejection problems as well as the poor survival and limited spread of the injected cells. In the present study, we have investigated whether the careful selection of donor myoblasts and host muscle for the myosin heavy chain expression (MyHCs) plays a role in the success of myoblast transfer. Highly purified normal myoblasts derived from the m. soleus and m. gastrocnemius white of normal mice were transplanted into the m. soleus (containing 70% of type I fibers) and gastrocnemius white (100% of type II fibers) of dystrophin deficient mdx mice. At several time-points after injection (10, 20 and 30 days), the number of dystrophin-positive fibers was monitored and compared among the different groups. A significantly higher number and better persistence of dystrophin-positive myofibers were observed when the injected muscle and donor myoblasts expressed a similar MyHC in comparison with myoblast transfer between host muscle and donor myoblasts that were not matched for MyHC. These results suggest that careful matching between the injected myoblasts and injected muscle for the MyHC expression can improve the efficiency of myoblast-mediated gene transfer to skeletal muscle. Gene Therapy (2000) 7, 428-437.     

骨髓间充质干细胞移植治疗mdx鼠：3个月疗效

背景：干细胞移植治疗肌营养不良症是目前的研究热点,相对造血干细胞移植,间充质干细胞移植风险较小。目的：观察骨髓间充质干细胞移植治疗Duchenne型肌营养不良鼠（mdx鼠）的疗效。方法：4周龄mdx鼠16只,随机分为治疗组与对照组,每组8只,经静脉移植及肌肉局部注射C57BL/6小鼠的骨髓间充质干细胞或等量生理盐水。结果与结论：移植3个月后,治疗组较对照组血清肌酸激酶水平下降,骨骼肌肌膜部分有dystrophin蛋白表达,而对照组检测不到dystrophin蛋白表达。但是两组的运动功能无明显改善。结果初步表明骨髓间充质干细胞移植对mdx鼠有一定的治疗作用,可能使肌细胞膜破坏减少,延缓病情发展。