Abstract
Skeletal myoblast transplantation has therapeutic potential for repairing damaged heart. However, the optimal conditions for this transplantation are still unclear. Recently, we demonstrated that satellite cell-derived myoblasts lacking the MyoD gene (MyoD−/−), a master transcription factor for skeletal muscle myogenesis, display increased survival and engraftment compared to wild-type controls following transplantation into murine skeletal muscle. In this study, we compare cell survival between wild-type and MyoD−/− myoblasts after transplantation into infarcted heart. We demonstrate that MyoD−/− myoblasts display greater resistance to hypoxia, engraft with higher efficacy, and show a larger improvement in ejection fraction than wild-type controls. Following transplantation, the majority of MyoD−/− and wild-type myoblasts form skeletal muscle fibers while cardiomyocytes do not. Importantly, the transplantation of MyoD−/− myoblasts induces a high degree of angiogenesis in the area of injury. DNA microarray data demonstrate that paracrine angiogenic factors, such as stromal cell-derived factor-1 (SDF-1) and placental growth factor (PlGF), are up-regulated in MyoD−/− myoblasts. In addition, over-expression and gene knockdown experiments demonstrate that MyoD negatively regulates gene expression of these angiogenic factors. These results indicate that MyoD−/− myoblasts impart beneficial effects after transplantation into an infarcted heart, potentially due to the secretion of paracrine angiogenic factors and enhanced angiogenesis in the area of injury. Therefore, our data provide evidence that a genetically engineered myoblast cell type with suppressed MyoD function is useful for therapeutic stem cell transplantation.
Highlights
Stem cells have extensive proliferative potential and differentiate into several cell lineages
We investigate whether (1) MyoD2/2 myoblasts display significantly higher engraftment in infarcted mouse heart compared to wild-type myoblasts; (2) engrafted MyoD2/2 myoblasts improve cardiac function in the infarcted heart; (3) MyoD2/2 myoblasts can differentiate into cardiomyocytes; and (4) MyoD2/2 myoblasts can induce angiogenesis in the injured area of the heart
Isolation of Wild-type and MyoD2/2 Myoblasts for Cardiac Repair Recently, we reported that MyoD2/2 myoblasts display remarkable resistance to apoptosis and increased cell survival compared to wild-type myoblasts after injection into injured skeletal muscle [29], [30]
Summary
Stem cells have extensive proliferative potential and differentiate into several cell lineages. Stem cell transplantation remains an attractive approach for myocardial repair. The transplantation of skeletal muscle myoblasts has been used both experimentally and clinically in an attempt to restore cardiac function [13], [14], [15], [16], [17]. Advantages to this approach include a readily available cell source and the biochemical and functional similarities between skeletal and cardiac muscle [18]. The production of new cardiomyocytes and vasculature by means of stem cell transplantation is an attractive approach to heart therapy
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