Satellite cell
Satellite cells are small mononuclear progenitor cells with virtually no cytoplasm found in mature muscle. They are found sandwiched between the basement membrane and sarcolemma (cell membrane) of individual muscle fibres, and can be difficult to distinguish from the sub-sarcolemmal nuclei of the fibres. Satellite cells are able to differentiate and fuse to augment existing muscle fibres and to form new fibres. These cells represent the oldest known adult stem cell niche, and are involved in the normal growth of muscle, as well as regeneration following injury or disease.
In undamaged muscle, the majority of satellite cells are quiescent; they neither differentiate nor undergo cell division. In response to mechanical strain, satellite cells become activated. Activated satellite cells initially proliferate as skeletal myoblasts before undergoing myogenic differentiation.
Contents [hide]
1 Genetic markers of satellite cells
2 Function in muscular repair
3 Plasticity and therapeutic applications
4 Regulation
5 References
6 External links
[edit] Genetic markers of satellite cells
Satellite cells express a number of distinctive genetic markers. Current thinking is that all satellite cells express PAX7 and PAX3[1]
Activated satellite cells express myogenic transcription factors, such as Myf5 and MyoD. They also begin expressing muscle-specific filament proteins such as desmin as they differentiate.
It should be noted that the field of satellite cell biology suffers from the same technical difficulties as other stem cell fields. Studies rely almost exclusively on Flow cytometry and Fluorescence Activated Cell Sorting (FACS) analysis, which gives no information about cell lineage or behaviour. As such, the satellite cell niche is relatively ill-defined and it is likely that it consists of multiple sub-populations.
[edit] Function in muscular repair
When muscle cells undergo injury, quiescent satellite cells are released from beneath the basement membrane. They become activated and re-enter the cell cycle. These dividing cells are known as the "transit amplifying pool" before undergoing myogenic differentiation to form new (post-mitotic) myotubes. There is also evidence suggesting that these cells are capable of fusing with existing myofibres to facilitate growth and repair.
The process of muscle regeneration involves considerable remodeling of extracellular matrix and, where extensive damage occurs, is incomplete. Fibroblasts within the muscle deposit scar tissue, which can impair muscle function, and is a significant part of the pathology of muscular dystrophies.