Myogenic potential of canine craniofacial satellite cells

The skeletal fibers have different embryological origin; the extraocular and jaw-closer muscles develop from prechordal mesoderm while the limb and trunk muscles from somites. These different origins characterize also the adult muscle stem cells, known as satellite cells (SCs) and responsible for th...

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Bibliographic Details
Published in:Frontiers in aging neuroscience 2014-05, Vol.6, p.90-90
Main Authors: La Rovere, Rita Maria Laura, Quattrocelli, Mattia, Pietrangelo, Tiziana, Di Filippo, Ester Sara, Maccatrozzo, Lisa, Cassano, Marco, Mascarello, Francesco, Barthélémy, Inès, Blot, Stephane, Sampaolesi, Maurilio, Fulle, Stefania
Format: Article
Language:English
Subjects:
Aging
Biopsy
Cell cycle
Cell differentiation
Degeneration
Disease
Dogs
Epigenetics
Gene expression
GRMD canine model
Jaw
Kinases
Life span
Mesoderm
microRNA expression
MicroRNAs
muscle aging
Muscular dystrophy
Muscular Dystrophy, Animal
Musculoskeletal system
MyoD protein
Myogenin
Neuroscience
Oxidative stress
Phenotypes
presomitic and somitic muscles
Progenitor cells
Protein synthesis
Sarcopenia
Satellite cells
Somites
Stem cell transplantation
Stem cells
Telomerase
Veterinary medicine
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Summary:The skeletal fibers have different embryological origin; the extraocular and jaw-closer muscles develop from prechordal mesoderm while the limb and trunk muscles from somites. These different origins characterize also the adult muscle stem cells, known as satellite cells (SCs) and responsible for the fiber growth and regeneration. The physiological properties of presomitic SCs and their epigenetics are poorly studied despite their peculiar characteristics to preserve muscle integrity during chronic muscle degeneration. Here, we isolated SCs from canine somitic [somite-derived muscle (SDM): vastus lateralis, rectus abdominis, gluteus superficialis, biceps femoris, psoas] and presomitic [pre-somite-derived muscle (PSDM): lateral rectus, temporalis, and retractor bulbi] muscles as myogenic progenitor cells from young and old animals. In addition, SDM and PSDM-SCs were obtained also from golden retrievers affected by muscular dystrophy (GRMD). We characterized the lifespan, the myogenic potential and functions, and oxidative stress of both somitic and presomitic SCs with the aim to reveal differences with aging and between healthy and dystrophic animals. The different proliferation rate was consistent with higher telomerase activity in PSDM-SCs compared to SDM-SCs, although restricted at early passages. SDM-SCs express early (Pax7, MyoD) and late (myosin heavy chain, myogenin) myogenic markers differently from PSDM-SCs resulting in a more efficient and faster cell differentiation. Taken together, our results showed that PSDM-SCs elicit a stronger stem cell phenotype compared to SDM ones. Finally, myomiR expression profile reveals a unique epigenetic signature in GRMD SCs and miR-206, highly expressed in dystrophic SCs, seems to play a critical role in muscle degeneration. Thus, miR-206 could represent a potential target for novel therapeutic approaches.
ISSN:1663-4365
1663-4365
DOI:10.3389/fnagi.2014.00090