Cotargeting DNA topoisomerase II enhances efficacy of RAS-targeted therapy in KRAS-mutant cancer models
Rongzhong Xu, Dongsheng Wang, Guangzhi Ma, Xun Yuan, Qian Chu, Songqing Fan, Rener Zhang, Pan Du, Shidong Jia, Ticiana A. Leal, Suresh S. Ramalingam, Zhen Chen, Shi-Yong Sun
Rongzhong Xu, Dongsheng Wang, Guangzhi Ma, Xun Yuan, Qian Chu, Songqing Fan, Rener Zhang, Pan Du, Shidong Jia, Ticiana A. Leal, Suresh S. Ramalingam, Zhen Chen, Shi-Yong Sun
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Research Article Cell biology Oncology

Cotargeting DNA topoisomerase II enhances efficacy of RAS-targeted therapy in KRAS-mutant cancer models

Abstract

The approval of sotorasib and adagrasib as the first KRAS G12C inhibitors has made the RAS oncogene a druggable target. However, they have modest objective response rates and short response durations. Therefore, strategies for improving RAS-targeted cancer therapy are urgently needed. Here, we found that both sotorasib and adagrasib promoted topoisomerase IIα (Topo IIα) proteasomal degradation in KRAS G12C–mutant cancer cells and induced DNA damage and apoptosis. In cell lines with acquired resistance to sotorasib, elevated Topo IIα levels were detected. TOP2A overexpression in sensitive KRAS G12C–mutant cells conferred resistance to sotorasib, whereas TOP2A knockdown in sotorasib-resistant cell lines sensitized the cells to sotorasib. Moreover, the combination of a KRAS G12C inhibitor such as sotorasib with a Topo II inhibitor such as VP-16 synergistically decreased the survival of sotorasib-resistant RAS G12C–mutant cells with augmented induction of DNA damage and apoptosis, effectively inhibited the growth of sotorasib-resistant tumors, and delayed or prevented the emergence of acquired resistance to sotorasib in vivo. Collectively, our results reveal an essential role of Topo IIα inhibition in mediating the therapeutic efficacy of RAS-targeted cancer therapy, providing a strong scientific rationale for targeting Topo II to improve RAS-targeted cancer therapies.

Authors

Rongzhong Xu, Dongsheng Wang, Guangzhi Ma, Xun Yuan, Qian Chu, Songqing Fan, Rener Zhang, Pan Du, Shidong Jia, Ticiana A. Leal, Suresh S. Ramalingam, Zhen Chen, Shi-Yong Sun

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Figure 7

Genetic knockdown of TOP2A expression in sotorasib-resistant NSCLC cell lines sensitizes the cells to sotorasib.

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Genetic knockdown of TOP2A expression in sotorasib-resistant NSCLC cell ...
(AD) Both H358/SR and Calu-1/SR cells expressing pLKO.1 or shTOP2A (A and B) or transfected with scrambled control or TOP2A siRNA for 48 hours (C and D) were exposed to DMSO or 10 μM sotorasib for 48 hours. The levels of Topo IIα and cleavage of PARP were detected with Western blotting (A and C). Annexin V–positive cells were determined with flow cytometry (B and D). Data are shown as the mean ± SD of triplicate determinations. (E) The indicated cell lines described above were exposed to DMSO or 10 μM sotorasib for 48 hours and then IF conducted to stain γ-H2AX foci. Scale bars: 25 μm, 5 μm (zoom). (FI) Mice with the indicated tumors derived from H358/SR cells were treated with vehicle (V) or sotorasib (50 mg/kg, daily, og) for 24 days. Tumor sizes (F) and mouse body weights (I) were measured at the indicated time points, and at the end of the treatment, collected tumors were photographed (G) and weighed (H). Data are shown as the mean ± SEM of 6 tumors from 6 mice. Statistical differences among the treatments were determined by 1-way ANOVA.