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dc.contributor.authorSharples, Adam P.en_GB
dc.contributor.authorAl-Shanti, Nasseren_GB
dc.contributor.authorLewis, Mark P.en_GB
dc.contributor.authorStewart, Claire E.en_GB
dc.date.accessioned2012-05-25T08:53:26Z
dc.date.available2012-05-25T08:53:26Z
dc.date.issued2011-12
dc.identifier.citationSharples A.P., Al-Shanti N., Lewis M.P., and Stewart C.E., (2011) 'Reduction of myoblast differentiation following multiple population doublings in mouse C2 C12 cells: a model to investigate ageing?', Journal of Cellular Biochemistry, 112(12) pp.3773-85.en_GB
dc.identifier.issn1097-4644
dc.identifier.pmid21826704
dc.identifier.doi10.1002/jcb.23308
dc.identifier.urihttp://hdl.handle.net/10547/225932
dc.description.abstractAgeing skeletal muscle displays declines in size, strength, and functional capacity. Given the acknowledged role that the systemic environment plays in reduced regeneration (Conboy et al. [2005] Nature 433: 760-764), the role of resident satellite cells (termed myoblasts upon activation) is relatively dismissed, where, multiple cellular divisions in-vivo throughout the lifespan could also impact on muscular deterioration. Using a model of multiple population doublings (MPD) in-vitro thus provided a system in which to investigate the direct impact of extensive cell duplications on muscle cell behavior. C(2) C(12) mouse skeletal myoblasts (CON) were used fresh or following 58 population doublings (MPD). As a result of multiple divisions, reduced morphological and biochemical (creatine kinase, CK) differentiation were observed. Furthermore, MPD cells had significantly increased cells in the S and decreased cells in the G1 phases of the cell cycle versus CON, following serum withdrawal. These results suggest continued cycling rather than G1 exit and thus reduced differentiation (myotube atrophy) occurs in MPD muscle cells. These changes were underpinned by significant reductions in transcript expression of: IGF-I and myogenic regulatory factors (myoD and myogenin) together with elevated IGFBP5. Signaling studies showed that decreased differentiation in MPD was associated with decreased phosphorylation of Akt, and with later increased phosphorylation of JNK1/2. Chemical inhibition of JNK1/2 (SP600125) in MPD cells increased IGF-I expression (non-significantly), however, did not enhance differentiation. This study provides a potential model and molecular mechanisms for deterioration in differentiation capacity in skeletal muscle cells as a consequence of multiple population doublings that would potentially contribute to the ageing process.
dc.language.isoenen
dc.rightsArchived with thanks to Journal of cellular biochemistryen_GB
dc.subject.meshAging
dc.subject.meshAnimals
dc.subject.meshBase Sequence
dc.subject.meshCell Cycle
dc.subject.meshCell Differentiation
dc.subject.meshCell Line
dc.subject.meshDNA Primers
dc.subject.meshFlow Cytometry
dc.subject.meshMice
dc.subject.meshMicroscopy, Fluorescence
dc.subject.meshMuscle, Skeletal
dc.subject.meshMyoblasts
dc.subject.meshPhosphorylation
dc.subject.meshProtein Kinases
dc.subject.meshRNA, Messenger
dc.subject.meshReal-Time Polymerase Chain Reaction
dc.titleReduction of myoblast differentiation following multiple population doublings in mouse C2 C12 cells: a model to investigate ageing?en
dc.typeArticleen
dc.contributor.departmentUniversity of Bedfordshireen_GB
dc.identifier.journalJournal of Cellular Biochemistryen_GB
html.description.abstractAgeing skeletal muscle displays declines in size, strength, and functional capacity. Given the acknowledged role that the systemic environment plays in reduced regeneration (Conboy et al. [2005] Nature 433: 760-764), the role of resident satellite cells (termed myoblasts upon activation) is relatively dismissed, where, multiple cellular divisions in-vivo throughout the lifespan could also impact on muscular deterioration. Using a model of multiple population doublings (MPD) in-vitro thus provided a system in which to investigate the direct impact of extensive cell duplications on muscle cell behavior. C(2) C(12) mouse skeletal myoblasts (CON) were used fresh or following 58 population doublings (MPD). As a result of multiple divisions, reduced morphological and biochemical (creatine kinase, CK) differentiation were observed. Furthermore, MPD cells had significantly increased cells in the S and decreased cells in the G1 phases of the cell cycle versus CON, following serum withdrawal. These results suggest continued cycling rather than G1 exit and thus reduced differentiation (myotube atrophy) occurs in MPD muscle cells. These changes were underpinned by significant reductions in transcript expression of: IGF-I and myogenic regulatory factors (myoD and myogenin) together with elevated IGFBP5. Signaling studies showed that decreased differentiation in MPD was associated with decreased phosphorylation of Akt, and with later increased phosphorylation of JNK1/2. Chemical inhibition of JNK1/2 (SP600125) in MPD cells increased IGF-I expression (non-significantly), however, did not enhance differentiation. This study provides a potential model and molecular mechanisms for deterioration in differentiation capacity in skeletal muscle cells as a consequence of multiple population doublings that would potentially contribute to the ageing process.


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