MMP-9 overexpression improves myogenic cell migration and engraftment.

Myoblast migration requires matrix metalloproteinase (MMP) activity but the contribution of individual MMPs or tissue inhibitors of matrix metalloproteinase (TIMPs), particularly MMP-9 and TIMP-1, is lacking. Using two clones derived for differential regulation of MMP-2, MMP-9, and TIMP-1, we correlated protein expression with cell migration. MMP/TIMP regulation was determined by zymography, western blots, and quantitative reverse transcriptase-polymerase chain reaction (qRT-PCR). Cell migration was compared in vitro and after grafting into nude-mdx mouse muscles. C2M9 clones produced high MMP-9 and low MMP-2, and migrated better than C2F clones, which secreted low MMP-9, but overexpressed MMP-2 and TIMP-1. Improvement of C2F invasion by MMP-9 and inhibition of C2M9 migration by MMP-9 inhibitor I confirmed the role of MMP-9 and pointed to potential inhibition by TIMP-1. Higher complementation achieved by C2M9 grafts corroborated the beneficial effect of MMP-9 overexpression. Modulation of MMP-9 expression opens perspectives for improved efficacy of cell therapy for muscular dystrophies.

Regeneration of skeletal muscle from transplanted immortalised myoblasts is oligoclonal.

Myoblasts transplanted into muscles of recipient mice mostly die, only a minor stem cell-like subpopulation surviving and participating in muscle regeneration. To investigate this phenomenon further, we used a retrovirus expressing beta-galactosidase to provide a unique marker for satellite-cell-derived muscle precursor cells, before transplanting them into myopathic mdx nu/nu mouse muscle. We employed inverse polymerase chain reaction to identify viral integrations, to follow the fate of clones present within the injected cells. Mass-infected cultures contained many marked clones, some of which contributed disproportionately to muscle regeneration. Although no particular clones showed overall predominance, some were present in more than one injected muscle, an eventuality unlikely to arise by chance. Conversely, in grafts of muscle precursor cells that had either been labelled as sparse satellite-cell derived cultures, or had been cloned, all clones were shown to be able to survive and form muscle in vivo. Moreover, all clones contributed to further generations of new-formed muscle fibres following a series of injuries administered to injected muscles, demonstrating that some cells of each clone had been retained as stem-cell-like muscle precursors. Furthermore, retrovirally marked satellite-cell-derived clones were derived from muscles that had been injected with marked muscle precursor cells. These cells formed muscle following their transplantation into a new host mouse, confirming their stem cell properties.

Myogenic cell proliferation and generation of a reversible tumorigenic phenotype are triggered by preirradiation of the recipient site.

Environmental influences have profound yet reversible effects on the behavior of resident cells. Earlier data have indicated that the amount of muscle formed from implanted myogenic cells is greatly augmented by prior irradiation (18 Gy) of the host mouse muscle. Here we confirm this phenomenon, showing that it varies between host mouse strains. However, it is unclear whether it is due to secretion of proliferative factors or reduction of antiproliferative agents. To investigate this further, we have exploited the observation that the immortal myogenic C2 C12 cell line forms tumors far more rapidly in irradiated than in nonirradiated host muscle. We show that the effect of preirradiation on tumor formation is persistent and dose dependent. However, C2 C12 cells are not irreversibly compelled to form undifferentiated tumor cells by the irradiated muscle environment and are still capable of forming large amounts of muscle when reimplanted into a nonirradiated muscle. In a clonal analysis of this effect, we discovered that C2 C12 cells have a bimodal propensity to form tumors; some clones form no tumors even after extensive periods in irradiated graft sites, whereas others rapidly form extensive tumors. This illustrates the subtle interplay between the phenotype of implanted cells and the factors in the muscle environment.

Low-energy laser irradiation promotes the survival and cell cycle entry of skeletal muscle satellite cells.

Low energy laser irradiation (LELI) has been shown to promote skeletal muscle cell activation and proliferation in primary cultures of satellite cells as well as in myogenic cell lines. Here, we have extended these studies to isolated myofibers. These constitute the minimum viable functional unit of the skeletal muscle, thus providing a close model of in vivo regeneration of muscle tissue. We show that LELI stimulates cell cycle entry and the accumulation of satellite cells around isolated single fibers grown under serum-free conditions and that these effects act synergistically with the addition of serum. Moreover, for the first time we show that LELI promotes the survival of fibers and their adjacent cells, as well as cultured myogenic cells, under serum-free conditions that normally lead to apoptosis. In both systems, expression of the anti-apoptotic protein Bcl-2 was markedly increased, whereas expression of the pro-apoptotic protein BAX was reduced. In culture, these changes were accompanied by a reduction in the expression of p53 and the cyclin-dependent kinase inhibitor p21, reflecting the small decrease in viable cells 24 hours after irradiation. These findings implicate regulation of these factors as part of the protective role of LELI against apoptosis. Taken together, our findings are of critical importance in attempts to improve muscle regeneration following injury.