Although skeletal muscle accounts for a large fraction of the body mass, it is one of the least regenerative of tissues. Satellite cells, which reside within the basal lamina of mature skeletal muscle fibers, are capable of mitotic expansion thereby generating new adult myoblasts to effect local repair of injured or diseased muscle. Such adult myoblasts, however, are not capable of replacing large losses of muscle tissue that occur through injury or as a consequence of chronic muscle disease, such as Duchenne's muscular dystrophy. Even after in vitro enrichment and implantation into injured muscle sites, such adult myoblasts evidence little incorporation and integration into organized muscle tissue. Ideal cells that could be used in muscle replacement therapy should be capable of: (1) large mitotic expansion potential through stem cell activity; (2) morphogenetic capacity (involving complex intra-tissue and extra-tissue interactions); (3) migratory capacity (short and long distance). At present, neither a source of such cells nor an effective muscle replacement strategy is available. These qualities are possessed by the embryonic cells that build the muscle primordia of the body. During the previous 3 years of this project we have identified, Isolated and otherwise analyzed a novel class of embryonic muscle stem cells that we name mvogenic progenitor cells (MP cells). MP cells are distinct from satellite cells in their ability to undergo migration and morphogenetic movements. MP cells are distinct from their earlier embryonic counterparts, typically referred to as """"""""embryonic stem cells,"""""""" in that they are not multipotent but are developmentally restricted to the formation of skeletal muscle tissue only. Most importantly, after transplantation from one embryo to another, MP cells act in a semiautonomous fashion to generate organized muscle tissue, even under non-permissive conditons. Thus, MP cells retain intrinsic determined qualities that allow them to form muscle tissues even in localities that are inappropriate or even hostile. Thus, embryonic MP cells possess the qualities required for cells to be used for muscle replacement therapy. In the present proposal, we will isolate MP cells from avian embryos and analyze their cellular, tissue, and molecular properties. These studies will lead to a deeper understanding of the processes by which muscle tissue is formed in both normal and abnormal development. More important from a potential therapeutic point of view however, the properties discovered about MP cells from this study will provide a foundation for the engineering of their essential properties into other cells, such as satellite cells, for their potential use in myoblast transfer or other therapies.

Agency
National Institute of Health (NIH)
Institute
National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS)
Type
Research Project (R01)
Project #
5R01AR044483-05
Application #
6497368
Study Section
Cell Development and Function Integrated Review Group (CDF)
Program Officer
Lymn, Richard W
Project Start
1997-04-01
Project End
2006-01-31
Budget Start
2002-02-01
Budget End
2003-01-31
Support Year
5
Fiscal Year
2002
Total Cost
$338,805
Indirect Cost
Name
University of California San Francisco
Department
Anatomy/Cell Biology
Type
Schools of Medicine
DUNS #
073133571
City
San Francisco
State
CA
Country
United States
Zip Code
94143
Yang, Yagai; Ordahl, Charles P (2006) The pattern of MyoD and contractile protein localization in primary epaxial myotome reflects the dynamic progression of nascent myoblast differentiation. Dev Dyn 235:382-94
Towler, Mhairi C; Gleeson, Paul A; Hoshino, Sachiko et al. (2004) Clathrin isoform CHC22, a component of neuromuscular and myotendinous junctions, binds sorting nexin 5 and has increased expression during myogenesis and muscle regeneration. Mol Biol Cell 15:3181-95
Kirsten, Eva; Kun, Ernest; Mendeleyev, Jerome et al. (2004) Activity assays for poly-ADP ribose polymerase. Methods Mol Biol 287:137-49
Venters, Sara J; Ordahl, Charles P (2002) Persistent myogenic capacity of the dermomyotome dorsomedial lip and restriction of myogenic competence. Development 129:3873-85
Denetclaw Jr, W F; Berdougo, E; Venters, S J et al. (2001) Morphogenetic cell movements in the middle region of the dermomyotome dorsomedial lip associated with patterning and growth of the primary epaxial myotome. Development 128:1745-55
Ordahl, C P; Berdougo, E; Venters, S J et al. (2001) The dermomyotome dorsomedial lip drives growth and morphogenesis of both the primary myotome and dermomyotome epithelium. Development 128:1731-44
Dockter, J; Ordahl, C P (2000) Dorsoventral axis determination in the somite: a re-examination. Development 127:2201-6
Denetclaw, W F; Ordahl, C P (2000) The growth of the dermomyotome and formation of early myotome lineages in thoracolumbar somites of chicken embryos. Development 127:893-905
Williams, B A; Ordahl, C P (2000) Fate restriction in limb muscle precursor cells precedes high-level expression of MyoD family member genes. Development 127:2523-36
Ordahl, C P; Williams, B A (1998) Knowing chops from chuck: roasting myoD redundancy. Bioessays 20:357-62