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Query: UMLS:C0026850 (muscular dystrophy)
 5,870 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Laminin-2 is part of the basement membrane of the skeletal muscle fibers. The laminin alpha 2 chain is absent or drastically reduced in a subgroup of congenital muscular dystrophy patients, and in the severely affected dystrophic dy/dy mouse. We previously reported that heterogeneous primary mouse muscle cell cultures conferred laminin alpha 2 chain expression in dy/dy mice muscles upon cell transplantation. In the present study we investigated whether pure myoblast cell lines were able to confer laminin alpha 2 chain expression in vivo. We observed that: (1) xeno-transplantation of non-immortalized human myoblast in SCID mouse muscles allows human laminin alpha 2 chain expression; (2) allotransplantation of the permanent G8 mouse myoblast cell line in dy/dy muscles allows the expression of the murine laminin alpha 2 chain; and (3) allo-transplantation of the D7 dystrophic dy/dy cell line allows the formation of new and hybrid muscle fibers in dy/dy muscle in the absence of laminin alpha 2 chain expression. We conclude that normal myoblasts are able to restore the expression of an extracellular skeletal muscle protein and that the absence of laminin-2 does not prevent transplanted muscle cells from participating in the formation of myofibers. Myoblasts are, therefore, attractive tools for further exploration of gene complementation strategies in the animal models of congenital muscular dystrophy.
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PMID:Myoblast transplantations lead to the expression of the laminin alpha 2 chain in normal and dystrophic (dy/dy) mouse muscles. 1050 3

Limb girdle muscular dystrophy type 2B form and Miyoshi myopathy are both caused by mutations in the recently cloned gene dysferlin. In the present study, we have investigated whether cell transplantation could permit dysferlin expression in vivo. Two transplantation models were used: SCID mice transplanted with normal human myoblasts, and SJL mice, the mouse model for limb girdle muscular dystrophy type 2B and Miyoshi myopathy, transplanted with allogeneic primary mouse muscle cell cultures expressing the beta-galactosidase gene under control of a muscle promoter of Troponin I. FK506 immunosuppression was used in the non-compatible allogeneic model. One month after transplantation, human and mouse dysferlin proteins were detected in all transplanted SCID and SJL muscles, respectively. Co-localization of dysferlin and human dystrophin or beta-galactosidase-positive fibers was observed following the transplantation of myoblasts. Dysferlin proteins were monitored by immunocytochemistry and Western blot. The number of dysferlin-positive fibers was 40-50% and 20-30% in SCID and SJL muscle sections, respectively. Detection of dysferlin in both SCID mice and dysferlin-deficient SJL mouse shows that myoblast transplantation permits the expression of the donor dysferlin protein.
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PMID:Dysferlin expression after normal myoblast transplantation in SCID and in SJL mice. 1173 59

Duchenne muscular dystrophy (DMD) is a common lethal disease for which no effective treatment is currently available. There exists a mouse model of the disease in which the usefulness of gene therapy was established. However, no progress towards human application was made due to the lack of a proper method for gene delivery. During the past several years, researchers acquired data which led them to believe that bone marrow stem cells are capable of generating not only blood cells, but also liver, heart, skin, muscle, and other tissue. Although the term "stem cell plasticity" became very popular, other studies have suggested that bone marrow might contain different types of stem cells that can produce non-hematopoietic cells. For example, mesenchymal stem cell (MSC) in bone marrow give rise to osteocytes, chondrocytes, adipocytes, and skeletal muscle. Recently, researchers have been able to show that transplanted bone marrow cells can contribute to muscle cells in a human patient who was diagnosed with two genetic diseases: severe combined immunodeficiency (SCID) and Duchenne muscular dystrophy. The odds of this happening is estimated at one in seven million. The results of studying this patient's medical history were reported by collaborating researchers at Children's Hospital, Los Angeles and Children's Hospital, Boston in an article titled "Long-term persistence of donor nuclei in a Duchenne muscular dystrophy (DMD) patient receiving bone marrow transplantation" published in the September 2002 issue of the Journal of Clinical Investigation. This patient was transplanted 15 years ago at Children's Hospital Los Angeles with paternal HLA-haploidentical T cell-depleted bone marrow. He engrafted and became a hematopoietic chimera having T and NK lymphocytes of donor origin. Studies performed on the muscle biopsy from the patient 13 years after transplantation demonstrated that the muscle showed evidence of donor derived nuclei. In addition, analysis of his bone marrow showed that small numbers of MSC were also derived from the transplanted bone marrow. Unfortunately, there was no evidence that the number of new muscle cells from the donor was able to decrease the progression of his muscular dystrophy. The revelation of finding the donor's cells in the muscle of the patient provides new hope for patients with the same disease. In the future it may be possible for mesenchymal cells to be isolated, ex vivo expanded and transplanted into patients with muscle diseases.
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PMID:[Treatment progress of Duchenne Muscular Dystrophy (DMD)]. 1555 94

The field of gene therapy, delivering genes to directly treat diseases, has had a remarkable year. This is no more evident than in the scope of the third annual meeting of the American Society of Gene Therapy (ASGT). Clear progress has been made in both ex vivo clinical protocols and in vivo administration. The meeting covered every major method of gene delivery, from injection of naked DNA to advanced synthetic gene delivery systems, as well as the major viral-based vectors. The optimism of the society was tempered, however, by the much-publicized death of a patient in a clinical trial at the University of Pennsylvania last year. There was a correspondingly high regulatory presence at the meeting, with several presentations by representatives of the US FDA and National Institutes of Health (NIH). Major clinical advances in gene therapy have been in genetic diseases, including hemophilia, severe combined immunodeficiency, and cystic fibrosis. Therapies are in later-stage clinical trials, and evidence of efficacy has been demonstrated, most notably by the apparent cure of SCID-affected children in Paris by ex vivo gene therapy with cytokine receptor subunit genes. Cancer gene therapy is also making significant headway, with many products entering phase II and III trials. Basic technology development is proceeding in vector targeting, enhancement of gene transfer efficiency, and regulating expression of therapeutic genes. In addition, basic research demonstrates the promise of new combined modes for treating diseases such as muscular dystrophy, lysosomal storage diseases and cardiovascular disease.
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PMID:American Society of Gene Therapy - Third Annual Meeting. 1604 54

We have isolated and cultured human primordial germ cells (PGCs) from early embryos. The PGCs expressed embryonic germ (EG) cell-specific surface markers, including Oct4 and Nanos. We derived a cell population from these PGCs that we termed embryoid body-derived (EBD) cells. EBD cells can be extensively expanded in vitro for more than 50 passages and express lineage markers from all three primary germ layers. The myogenic potential of the EBD cells was examined both in vitro and in vivo.In vitro, the EBD cells can be induced to form multinucleated myotubes, which express late skeletal muscle-specific markers, including MHC and dystrophin, when exposed to human galectin-1. In vivo, the EBD cells gave rise to all the myogenic lineages, including the skeletal muscle stem cells known as satellite cells. Strikingly, these cells were able to partially restore degenerated muscles in the SCID/mdx mouse, an animal model of the Duchenne's muscular dystrophy. These results indicate the EBD cells may be a promising source of myogenic stem cells for cell-based therapies for muscle degenerative disorders.
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PMID:Skeletal myogenesis by human primordial germ cell-derived progenitors. 1907 Oct 88

The transplantation of stem cells and viruses in utero has tremendous potential for treating congenital disorders in the human fetus. For example, in utero transplantation (IUT) of hematopoietic stem cells has been used to successfully treat patients with severe combined immunodeficiency. In several other conditions, however, IUT has been attempted without success. Given these mixed results, the availability of an efficient non-human model to study the biological sequelae of stem cell transplantation and gene therapy is critical to advance this field. We and others have used the mouse model of IUT to study factors affecting successful engraftment of in utero transplanted hematopoietic stem cells in both wild-type mice and those with genetic diseases. The fetal environment also offers considerable advantages for the success of in utero gene therapy. For example, the delivery of adenoviral, adeno-associated viral, retroviral, and lentiviral vectors into the fetus has resulted in the transduction of multiple organs distant from the site of injection with long-term gene expression. in utero gene therapy may therefore be considered as a possible treatment strategy for single gene disorders such as muscular dystrophy or cystic fibrosis. Another potential advantage of IUT is the ability to induce immune tolerance to a specific antigen. As seen in mice with hemophilia, the introduction of Factor IX early in development results in tolerance to this protein. In addition to its use in investigating potential human therapies, the mouse model of IUT can be a powerful tool to study basic questions in developmental and stem cell biology. For example, one can deliver various small molecules to induce or inhibit specific gene expression at defined gestational stages and manipulate developmental pathways. The impact of these alterations can be assessed at various timepoints after the initial transplantation. Furthermore, one can transplant pluripotent or lineage specific progenitor cells into the fetal environment to study stem cell differentiation in a non-irradiated and unperturbed host environment. The mouse model of IUT has already provided numerous insights within the fields of immunology, and developmental and stem cell biology. In this video-based protocol, we describe a step-by-step approach to performing IUT in mouse fetuses and outline the critical steps and potential pitfalls of this technique.
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PMID:A mouse model of in utero transplantation. 2130 29

Dysferlin deficiency leads to a peculiar form of muscular dystrophy due to a defect in sarcolemma repair and currently lacks a therapy. We developed a cell therapy protocol with wild-type adult murine mesoangioblasts. These cells differentiate with high efficiency into skeletal muscle in vitro but differ from satellite cells because they do not express Pax7. After intramuscular or intra-arterial administration to SCID/BlAJ mice, a novel model of dysferlinopathy, wild-type mesoangioblasts efficiently colonized dystrophic muscles and partially restored dysferlin expression. Nevertheless, functional assays performed on isolated single fibers from transplanted muscles showed a normal repairing ability of the membrane after laser-induced lesions; this result, which reflects gene correction of an enzymatic rather than a structural deficit, suggests that this myopathy may be easier to treat with cell or gene therapy than other forms of muscular dystrophies.
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PMID:Partial dysferlin reconstitution by adult murine mesoangioblasts is sufficient for full functional recovery in a murine model of dysferlinopathy. 2136 66

Transplantation of a myogenic cell population into an immunodeficient recipient is an excellent way of assessing the in vivo muscle-generating capacity of that cell population. To facilitate both allogeneic and xenogeneic transplantations of muscle-forming cells in mice, we have developed a novel immunodeficient muscular dystrophy model, the NSG-mdx(4Cv) mouse. The IL2Rg mutation, which is linked to the Dmd gene on the X chromosome, simultaneously depletes NK cells and suppresses thymic lymphomas, issues that limit the utility of the SCID/mdx model. The NSG-mdx(4Cv) mouse presents a muscular dystrophy of similar severity to the conventional mdx mouse. We show that this animal supports robust engraftment of both pig and dog muscle mononuclear cells. The question of whether satellite cells prospectively isolated by flow cytometry can confer a functional benefit upon transplantation has been controversial. Using allogeneic Pax7-ZsGreen donors and NSG-mdx(4Cv) recipients, we demonstrate definitively that as few as 900 FACS-isolated satellite cells can provide functional regeneration in vivo, in the form of an increased mean maximal force-generation capacity in cell-transplanted muscles, compared to a sham-injected control group. These studies highlight the potency of satellite cells to improve muscle function and the utility of the NSG-mdx(4Cv) model for studies on muscle regeneration and Duchenne muscular dystrophy therapy.
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PMID:A new immuno-, dystrophin-deficient model, the NSG-mdx(4Cv) mouse, provides evidence for functional improvement following allogeneic satellite cell transplantation. 2360