Notch-mediated restoration of regenerative potential to aged muscle
A hallmark of aging is diminished regenerative potential of tissues, but the mechanism of this
decline is unknown. Analysis of injured muscle revealed that, with age, resident precursor
cells (satellite cells) had a markedly impaired propensity to proliferate and to produce
myoblasts necessary for muscle regeneration. This was due to insufficient up-regulation of
the Notch ligand Delta and, thus, diminished activation of Notch in aged, regenerating
muscle. Inhibition of Notch impaired regeneration of young muscle, whereas forced …
decline is unknown. Analysis of injured muscle revealed that, with age, resident precursor
cells (satellite cells) had a markedly impaired propensity to proliferate and to produce
myoblasts necessary for muscle regeneration. This was due to insufficient up-regulation of
the Notch ligand Delta and, thus, diminished activation of Notch in aged, regenerating
muscle. Inhibition of Notch impaired regeneration of young muscle, whereas forced …
A hallmark of aging is diminished regenerative potential of tissues, but the mechanism of this decline is unknown. Analysis of injured muscle revealed that, with age, resident precursor cells (satellite cells) had a markedly impaired propensity to proliferate and to produce myoblasts necessary for muscle regeneration. This was due to insufficient up-regulation of the Notch ligand Delta and, thus, diminished activation of Notch in aged, regenerating muscle. Inhibition of Notch impaired regeneration of young muscle, whereas forced activation of Notch restored regenerative potential to old muscle. Thus, Notch signaling is a key determinant of muscle regenerative potential that declines with age.
AAAS