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Olaparib Induces RPL5/RPL11-Dependent p53 Activation via Nucleolar Stress

Tao Han, Jing Tong, Mengxin Wang, Yu Gan, Bo Gao, Jiaxiang Chen, Youxun Liu, Qian Hao, Xiang Zhou

2022Frontiers in Oncology13 citationsDOIOpen Access PDF

Abstract

or other DNA repair genes. The anti-tumor activity of Olaparib has been largely attributed to its ability to inhibit PARP enzymes and block DNA single-strand break (SSB) repair, which eventually leads to the most detrimental DNA damage, double-strand breaks (DSB), in HRD cells. Although PARPi was found to induce p53-dependent cell death, the underlying molecular mechanism remains incompletely understood. Here, we report that Olaparib treatment leads to p53 stabilization and activation of its downstream target genes in a dose- and time-dependent manner. Mechanistically, Olaparib triggers nucleolar stress by inhibiting biosynthesis of the precursor of ribosomal RNAs (pre-rRNA), resulting in enhanced interaction between ribosomal proteins (RPs), RPL5 and RPL11, and MDM2. Consistently, knockdown of RPL5 and RPL11 prevents Olaparib-induced p53 activation. More importantly, Olaparib efficiently suppresses breast and colorectal cancer cell survival and proliferation through activation of p53. Altogether, our study demonstrates that Olaparib activates the nucleolar stress-RPs-p53 pathway, suggesting rRNA biogenesis as a novel target for PARPi.

Topics & Concepts

OlaparibSynthetic lethalityGene knockdownDNA damagePARP1Cancer researchDNA repairPoly ADP ribose polymerasePARP inhibitorBiologyRibosome biogenesisCell biologyChemistryMolecular biologyPolymeraseDNAGeneGeneticsRibosomeRNAPARP inhibition in cancer therapyDNA Repair MechanismsCell death mechanisms and regulation