The transcription factor p53 guards against tumor and virus replication and is inactivated in almost all cancers. p53 activated transcription of target genes is thought to be synonymous with the stabilization of p53 in response to oncogenes and DNA damage. During adenovirus replication, the degradation of p53 by E1B-55k is considered essential for p53 inactivation, and is the basis for p53 selective viral cancer therapies. Here we reveal a dominant epigenetic mechanism that silences p53-activated transcription, irrespective of p53 phosphorylation and stabilization. We show that another adenoviral protein, E4-ORF3, inactivates p53 independently of E1B-55k by forming a nuclear structure that induces de novo H3K9me3 heterochromatin formation at p53 target promoters, preventing p53 DNA-binding. This suppressive nuclear web is highly selective in silencing p53 promoters and operates in the backdrop of global transcriptional changes that drive oncogenic replication. These findings are important for understanding how high levels of wild-type p53 might also be inactivated in cancer as well as the mechanisms that induce aberrant epigenetic silencing of tumor suppressor loci. Our study changes the longstanding definition of how p53 is inactivated in adenovirus infection and provides key insights that could enable the development of true p53 selective oncolytic viral therapies.
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Forced and maintained expression of four transcription factors OCT4, SOX2, KLF4 and c-MYC (OSKM), can reprogram somatic cells into induced Pluripotent Stem Cells (iPSCs) and a limited OSKM induction is able to rejuvenate the cell physiology without changing the cell identity. We therefore sought to determine if a burst of OSKM might improve tissue fitness and delay age-related pathologies in a whole animal. For this, we used a sensitive model of heterozygous premature aging mice carrying just one mutated Lamin A allele producing progerin. We briefly treated two months-young heterozygotes mice with OSKM and monitored their natural age-related deterioration by various health parameters. Surprisingly, a single two and a half weeks reprogramming was sufficient to improve body composition and functional capacities, over the entire lifespan. Mice treated early in life had improved tissue structures in bone, lung, spleen, kidney and skin, with an increased lifespan of 15%, associated to a differential DNA methylation signature. Altogether, our results indicate that a single short reprogramming early in life might initiate and propagate an epigenetically related rejuvenated cell physiology, to promote a healthy lifespan.
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