posted on 2023-03-31, 02:42authored byChanglong Liu, Carolyn E. Banister, Phillip J. Buckhaults
Table S2. TP53 knockout hESCs resistant drugs
Funding
NIH
History
ARTICLE ABSTRACT
TP53 mutations are common in most human cancers, but few therapeutic options for TP53-mutant tumors exist. To identify potential therapeutic options for cancer patients with TP53 mutations, we profiled 127 FDA-approved chemotherapy drugs against human embryonic stem cells (hESC) in which we engineered TP53 deletion by genome editing. We identified 27 cancer therapeutic drugs for which TP53 mutations conferred resistance; most of these drugs target DNA synthesis or topoisomerase and cause DNA damage. We then performed a genome-wide CRISPR/Cas9 knockout screen in the TP53-null hESC in the presence and absence of sublethal concentrations of cisplatin and identified 137 genes whose loss selectively resensitized the p53-null cells to this chemotherapeutic agent. Gene ontology classification of the resensitizing loci revealed significant overrepresentation of spindle checkpoint pathway genes. Moreover, we confirmed that targeting ZNF207/BuGZ sensitizes p53-null hESC to cisplatin. These data indicate that targeted inhibition of spindle assembly checkpoints (SAC) and chromosomal organizing centers may provide a way to treat p53-deficient cancer cells with standard chemotherapy drugs. Development of small-molecule inhibitors of SAC proteins may be a useful strategy for rescuing DNA-damaging chemotherapeutics in TP53-mutant cancers.
These findings show that inhibition of spindle assembly checkpoints and chromosomal organizing centers may provide a new way to treat p53-deficient cancer cells with standard chemotherapy drugs.