Pan-cancer analysis of non-oncogene addiction to DNA repair.

Sci Rep

Robotic Radiosurgery Center, International Cancer Center, San José, Costa Rica.

Published: December 2021

AI Article Synopsis

  • - Cancer cells can become reliant on both driver genes (oncogene addiction) and the normal functions of certain non-oncogenes (non-oncogene addiction) to survive and thrive, particularly through DNA repair mechanisms.
  • - A study analyzed DNA repair gene dependency across various cancers and found 59 essential genes, with contrasting dependency scores across 423 cell lines and different cancer types.
  • - Among these essential genes, some were linked to better or worse patient survival, revealing a particular pattern in which certain genes with weak dependency scores and high expression were associated with poorer outcomes, highlighting potential new targets for cancer therapy.

Article Abstract

Cancer cells usually depend on the aberrant function of one or few driver genes to initiate and promote their malignancy, an attribute known as oncogene addiction. However, cancer cells might become dependent on the normal cellular functions of certain genes that are not oncogenes but ensure cell survival (non-oncogene addiction). The downregulation or silencing of DNA repair genes and the consequent genetic and epigenetic instability is key to promote malignancy, but the activation of the DNA-damage response (DDR) has been shown to become a type of non-oncogene addiction that critically supports tumour survival. In the present study, a systematic evaluation of DNA repair addiction at the pan-cancer level was performed using data derived from The Cancer Dependency Map and The Cancer Genome Atlas (TCGA). From 241 DDR genes, 59 were identified as commonly essential in cancer cell lines. However, large differences were observed in terms of dependency scores in 423 cell lines and transcriptomic alterations across 18 cancer types. Among these 59 commonly essential genes, 14 genes were exclusively associated with better overall patient survival and 19 with worse overall survival. Notably, a specific molecular signature among the latter, characterized by DDR genes like UBE2T, RFC4, POLQ, BRIP1, and H2AFX showing the weakest dependency scores, but significant upregulation was strongly associated with worse survival. The present study supports the existence and importance of non-oncogenic addiction to DNA repair in cancer and may facilitate the identification of prognostic biomarkers and therapeutic opportunities.

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Source
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC8636604PMC
http://dx.doi.org/10.1038/s41598-021-02773-3DOI Listing

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