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Deregulation of oncogene-induced senescence and p53 translational control in X-linked dyskeratosis congenita.

ABSTRACT: Defects in ribosome biogenesis and function are present in a growing list of human syndromes associated with cancer susceptibility. One example is X-linked dyskeratosis congenita (X-DC) in which the DKC1 gene, encoding for an enzyme that modifies ribosomal RNA, is found to be mutated. How ribosome dysfunction leads to cancer remains poorly understood. A critical cellular response that counteracts cellular transformation is oncogene-induced senescence (OIS). Here, we show that during OIS, a switch between cap- and internal ribosome entry site (IRES)-dependent translation occurs. During this switch, an IRES element positioned in the 5'untranslated region of p53 is engaged and facilitates p53 translation. We further show that in DKC1(m) cells, p53 IRES-dependent translation is impaired during OIS ex vivo and on DNA damage in vivo. This defect in p53 translation perturbs the cellular response that counteracts oncogenic insult. We extend these findings to X-DC human patient cells in which similar impairments in p53 IRES-dependent translation are observed. Importantly, re-introduction of wild-type DKC1 restores p53 expression in these cells. These results provide insight into the basis for cancer susceptibility in human syndromes associated with ribosome dysfunction.

SUBMITTER: Bellodi C

PROVIDER: S-EPMC2885924 | biostudies-literature |

REPOSITORIES: biostudies-literature

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Project description:Aging is the consequence of intra- and extracellular events that promote cellular senescence. Dyskeratosis congenita (DC) is an example of a premature aging disorder caused by underlying telomere/telomerase-related mutations. Cells from these patients offer an opportunity to study telomere-related aging and senescence. Our previous work has found that telomere shortening stimulates DNA damage responses (DDR) and increases reactive oxygen species (ROS), thereby promoting entry into senescence. This work also found that telomere elongation via TERT expression, the catalytic component of the telomere-elongating enzyme telomerase, or p53 shRNA could decrease ROS by disrupting this telomere-DDR-ROS pathway. To further characterize this pathway, we performed a CRISPR/Cas9 knockout screen to identify genes that extend lifespan in DC cells. Of the cellular clones isolated due to increased lifespan, 34% had a guide RNA (gRNA) targeting CEBPB while gRNAs targeting WSB1, MED28 and p73 were observed multiple times. CEBPB is a transcription factor associated with activation of proinflammatory response genes suggesting that inflammation may be present in DC cells. The inflammatory response was investigated using RNA-Seq to compare DC and control cells. Expression of inflammatory genes were found to be significantly elevated (p<0.0001) in addition to a key subset of these inflammation-related genes (IL1B, IL6, IL8, IL12A, CXCL1 (GROa), CXCL2 (GROb), and CXCL5) which are regulated by CEBPB. Exogenous TERT expression led to downregulation of RNA/protein CEBPB expression and the inflammatory response genes suggesting a telomere-length dependent mechanism to regulate CEBPB. Furthermore, unlike exogenous TERT and p53 shRNA, CEBPB shRNA did not significantly decrease ROS suggesting that CEBPB’s contribution in DC cells’ senescence is ROS-independent. Our findings demonstrate a key role for CEBPB in engaging senescence by mobilizing an inflammatory response within DC cells.

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Deregulation of oncogene-induced senescence and p53 translational control in X-linked dyskeratosis congenita.

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