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      Hedgehog Signaling Regulates MyoD Expression and Activity*

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          Abstract

          Background: Hedgehog (Hh) signaling regulates skeletal myogenesis; however, the molecular mechanisms involved are not fully understood.

          Results: Gli2, a transactivator of Hh signaling, associates with MyoD gene elements, regulating MyoD expression, and binds to MyoD protein, regulating its ability to induce myogenesis.

          Conclusion: Hh signaling is linked to MyoD gene expression and MyoD protein function.

          Significance: Novel mechanistic insight is gained into the Hh-regulated myogenesis.

          Abstract

          The inhibition of MyoD expression is important for obtaining muscle progenitors that can replenish the satellite cell niche during muscle repair. Progenitors could be derived from either embryonic stem cells or satellite cells. Hedgehog (Hh) signaling is important for MyoD expression during embryogenesis and adult muscle regeneration. To date, the mechanistic understanding of MyoD regulation by Hh signaling is unclear. Here, we demonstrate that the Hh effector, Gli2, regulates MyoD expression and associates with MyoD gene elements. Gain- and loss-of-function experiments in pluripotent P19 cells show that Gli2 activity is sufficient and required for efficient MyoD expression during skeletal myogenesis. Inhibition of Hh signaling reduces MyoD expression during satellite cell activation in vitro. In addition to regulating MyoD expression, Hh signaling regulates MyoD transcriptional activity, and MyoD activates Hh signaling in myogenic conversion assays. Finally, Gli2, MyoD, and MEF2C form a protein complex, which enhances MyoD activity on skeletal muscle-related promoters. We therefore link Hh signaling to the function and expression of MyoD protein during myogenesis in stem cells.

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          Embryonic stem cell differentiation: emergence of a new era in biology and medicine.

          Gordon Keller (2005)
          The discovery of mouse embryonic stem (ES) cells >20 years ago represented a major advance in biology and experimental medicine, as it enabled the routine manipulation of the mouse genome. Along with the capacity to induce genetic modifications, ES cells provided the basis for establishing an in vitro model of early mammalian development and represented a putative new source of differentiated cell types for cell replacement therapy. While ES cells have been used extensively for creating mouse mutants for more than a decade, their application as a model for developmental biology has been limited and their use in cell replacement therapy remains a goal for many in the field. Recent advances in our understanding of ES cell differentiation, detailed in this review, have provided new insights essential for establishing ES cell-based developmental models and for the generation of clinically relevant populations for cell therapy.
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            The circuitry of a master switch: Myod and the regulation of skeletal muscle gene transcription.

            Stephen Tapscott (2005)
            The expression of Myod is sufficient to convert a fibroblast to a skeletal muscle cell, and, as such, is a model system in developmental biology for studying how a single initiating event can orchestrate a highly complex and predictable response. Recent findings indicate that Myod functions in an instructive chromatin context and directly regulates genes that are expressed throughout the myogenic program, achieving promoter-specific regulation of its own binding and activity through a feed-forward mechanism. These studies are beginning to merge our understanding of how lineage-specific information is encoded in chromatin with how master regulatory factors drive programs of cell differentiation.
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              Human ES- and iPS-derived myogenic progenitors restore DYSTROPHIN and improve contractility upon transplantation in dystrophic mice.

              Radbod Darabi, Robert W. Arpke, Stefan Irion (2012)
              A major obstacle in the application of cell-based therapies for the treatment of neuromuscular disorders is obtaining the appropriate number of stem/progenitor cells to produce effective engraftment. The use of embryonic stem (ES) or induced pluripotent stem (iPS) cells could overcome this hurdle. However, to date, derivation of engraftable skeletal muscle precursors that can restore muscle function from human pluripotent cells has not been achieved. Here we applied conditional expression of PAX7 in human ES/iPS cells to successfully derive large quantities of myogenic precursors, which, upon transplantation into dystrophic muscle, are able to engraft efficiently, producing abundant human-derived DYSTROPHIN-positive myofibers that exhibit superior strength. Importantly, transplanted cells also seed the muscle satellite cell compartment, and engraftment is present over 11 months posttransplant. This study provides the proof of principle for the derivation of functional skeletal myogenic progenitors from human ES/iPS cells and highlights their potential for future therapeutic application in muscular dystrophies. Copyright © 2012 Elsevier Inc. All rights reserved.
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                Author and article information

                Journal
                Journal ID (nlm-ta): J Biol Chem
                Journal ID (iso-abbrev): J. Biol. Chem
                Journal ID (hwp): jbc
                Journal ID (pmc): jbc
                Journal ID (publisher-id): JBC
                Title: The Journal of Biological Chemistry
                Publisher: American Society for Biochemistry and Molecular Biology (9650 Rockville Pike, Bethesda, MD 20814, U.S.A. )
                ISSN (Print): 0021-9258
                ISSN (Electronic): 1083-351X
                Publication date (Print): 8 February 2013
                Publication date (Electronic): 24 December 2012
                Publication date PMC-release: 24 December 2012
                Volume: 288
                Issue: 6
                Pages: 4389-4404
                Affiliations
                From the []Department of Biochemistry, Microbiology, and Immunology and
                [§ ]Pancreatic Islet Biology and Transplantation Unit, Dasman Diabetes Institute, Dasman 15462, Kuwait and
                the []Department of Cellular and Molecular Medicine, Faculty of Medicine, University of Ottawa and
                []Ottawa Hospital Research Institute, Ottawa K1H 8M5, Canada
                Author notes
                [3 ] To whom correspondence should be addressed. Tel.: 613-562-5800 (Ext. 8669); E-mail: iskerjan@ 123456uottawa.ca .
                [1]

                Supported by a doctoral research award from the Heart and Stroke Foundation of Canada.

                [2]

                Supported by an Ontario Graduate Scholarship.

                Article
                Publisher ID: M112.400184
                DOI: 10.1074/jbc.M112.400184
                PMC ID: 3567689
                PubMed ID: 23266826
                SO-VID: 8d695d01-5282-4ab6-ade7-ce9295a5170d
                Copyright © © 2013 by The American Society for Biochemistry and Molecular Biology, Inc.
                License:

                Author's Choice—Final version full access.

                Creative Commons Attribution Non-Commercial License applies to Author Choice Articles

                History
                Date received : 11 July 2012
                Date revision received : 12 December 2012
                Categories
                Subject: Gene Regulation

                ScienceOpen disciplines: Biochemistry
                Keywords: development,embryonic stem cell,gene expression,gli,hedgehog signaling,mef2,myod,myogenesis,skeletal muscle,transcription
                Data availability:
                ScienceOpen disciplines: Biochemistry
                Keywords: development, embryonic stem cell, gene expression, gli, hedgehog signaling, mef2, myod, myogenesis, skeletal muscle, transcription

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