Project description:Recently approved cancer drugs remain out-of-reach to most patients due to prohibitive costs and only few produce clinically meaningful benefits. An untapped alternative is to enhance the efficacy and safety of existing cancer treatments. We hypothesized that the response to topoisomerase II poisons, the most successful group of cancer drugs, can be improved by considering treatment-associated transcript levels, taken as surrogates for protein expression. To this end, we analyzed transcriptomes from Acute Myeloid Leukemia (AML) cell lines treated with the topoisomerase II poison etoposide. Using complementary criteria of co-regulation within networks and of essentiality for cell survival, we identified and functionally confirmed 11 druggable drivers of etoposide cytotoxicity. Drivers with pre-treatment expression predicting etoposide response (e.g. PARP9) generally synergized with the drug. Drivers repressed by etoposide (e.g. PLK1) displayed standalone cytotoxicity. Drivers, whose modulation evoked etoposide-like gene expression changes (e.g. mTOR), were cytotoxic both alone and in combination with etoposide. In summary, both pre-treatment gene expression and treatment-driven changes contribute to the cell killing effect of etoposide. Inhibitors of protein products of the involved genes can be used to enhance the efficacy of etoposide. This strategy can be used to identify combination partners or even replacements for other classical anticancer drugs, especially those interfering with DNA integrity and transcription.

Project description:Drivers of topoisomerase II poisoning mimic and complement cytotoxicity in AML cells

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Project description:The cancer target enyzme topoisomerase 1 transiently cleaves one strand of chromosomal DNA to relax accumulated strain that can prevent transcription, replication or chromatin assembly. The topoisomerase 1 poison camptothecin and its synthetic analogs are widely used chemotherapeutics that act by trapping the enzyme on DNA in a ‘covalent complex’, resulting in persistent DNA damage and cell death. The prevailing model, interfacial inhibition, contends that the covalent complex is trapped by drug binding alone. In contrast, here we show that camptothecins produce extensive oxidative stress and that topoisomerase 1 is reactive with electrophilic second messengers of oxidative damage. We show that blocking oxidative stress in cells inhibits covalent complex formation by camptothecin, while electrophiles such as 4-hydroxynonenal are able to induce covalent complex formation in cells on their own. Towards mechanism of action, we show that 4-hydroxynonenal electrophilically modifies a cysteine within the DNA-binding active site of human topoisomerase 1. Taken together, our results suggest a mechanism in which oxidative stress mediates the effects of many topoisomerase 1 poisons, and suggest that this critical DNA-regulating enzyme may have a dual role as a sensor of cellular redox stress, linking oxidative stress to DNA damage response in cancer cells.

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