Age-Associated Activation of Epigenetically Repressed Genes in the Mouse

Age-Associated Activation of Epigenetically Repressed Genes in the Mouse

Pamela E. Bennett-Baker^a, Jodi Wilkowski^a, and David T. Burke^a
^a Department of Human Genetics, University of Michigan School of Medicine, Ann Arbor, Michigan 48109-0618

Corresponding author: David T. Burke, University of Michigan School of Medicine, 1241 E. Catherine St., Ann Arbor, MI 48109-0618., dtburke{at}umich.edu (E-mail)

Communicating editor: L. PILLUS

Epigenetic control of gene expression is a consistent featureof differentiated mammalian cell types. Epigenetic expressionpatterns are mitotically heritable and are stably maintainedin adult cells. However, unlike somatic DNA mutation, littleis known about the occurrence of epigenetic change, or epimutation,during normal adult life. We have monitored the age-associatedmaintenance of two epigenetic systems—X inactivation andgenomic imprinting—using the genes Atp7a and Igf2, respectively.Quantitative measurements of RNA transcripts from the inactiveand active alleles were performed in mice from 2 to 24 monthsof age. For both genes, older animal cohorts showed reproducibleincreases in transcripts expressed from the silenced alleles.Loss of X chromosome silencing showed cohort mean increasesof up to 2.2%, while imprinted-gene activation increased upto 6.7%. The results support the hypothesis that epigeneticloss of gene repression occurs in normal tissues and may bea contributing factor in progressive physiological dysfunctionseen during mammalian aging. Quantitatively, the loss of epigeneticcontrol may be one to two orders of magnitude greater than previouslydetermined somatic DNA mutation.

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