YAP/TAZ mediates resistance to KRAS inhibitors through inhibiting proapoptosis and activating the SLC7A5/mTOR axis
Wang Yang, … , Jiuwei Cui, Xin Zhou
Wang Yang, … , Jiuwei Cui, Xin Zhou
Published December 20, 2024
Citation Information: JCI Insight. 2024;9(24):e178535. https://doi.org/10.1172/jci.insight.178535.
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Research Article Oncology Therapeutics

YAP/TAZ mediates resistance to KRAS inhibitors through inhibiting proapoptosis and activating the SLC7A5/mTOR axis

Abstract

KRAS mutations are frequent in various human cancers. The development of selective inhibitors targeting KRAS mutations has opened a new era for targeted therapy. However, intrinsic and acquired resistance to these inhibitors remains a major challenge. Here, we found that cancer cells resistant to KRAS G12C inhibitors also display cross-resistance to other targeted therapies, such as inhibitors of RTKs or SHP2. Transcriptomic analyses revealed that the Hippo-YAP/TAZ pathway is activated in intrinsically resistant and acquired-resistance cells. Constitutive activation of YAP/TAZ conferred resistance to KRAS G12C inhibitors, while knockdown of YAP/TAZ or TEADs sensitized resistant cells to these inhibitors. This scenario was also observed in KRAS G12D–mutant cancer cells. Mechanistically, YAP/TAZ protects cells from KRAS inhibitor–induced apoptosis by downregulating the expression of proapoptotic genes such as BMF, BCL2L11, and PUMA, and YAP/TAZ reverses KRAS inhibitor–induced proliferation retardation by activating the SLC7A5/mTORC1 axis. We further demonstrated that dasatinib and MYF-03-176 notably enhance the efficacy of KRAS inhibitors by reducing SRC kinase activity and TEAD activity. Overall, targeting the Hippo-YAP/TAZ pathway has the potential to overcome resistance to KRAS inhibitors.

Authors

Wang Yang, Ming Zhang, Tian-Xing Zhang, Jia-Hui Liu, Man-Wei Hao, Xu Yan, Haicheng Gao, Qun-Ying Lei, Jiuwei Cui, Xin Zhou

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Figure 1

Cancer cells resistant to KRAS G12C inhibitors also display cross-resistance to other inhibitors targeting upstream or downstream components of the RAS signaling pathway.

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Cancer cells resistant to KRAS G12C inhibitors also display cross-resist...
(A) Dose-response curves of AMG510 displaying the relative viability (top) and viability (bottom) of H358, H1373, MIAPACA2, H2030, and SW1573 cells following combination treatment with buparlisib (1 μM), linsitinib (0.5 μM), gefitinib (2 μM), trametinib (0.1 μM), or SHP099 (4 μM) for 3 days. (B) Dot plots displaying the quantitative results of the clonogenic assay evaluating the growth of H358, H1373, MIAPACA2, H2030, and SW1573 cells upon treatment with buparlisib, linsitinib, gefitinib, trametinib, or SHP099 alone, as well as in combination with AMG510 as in Supplemental Figure 1A. (C) Scatter plots depicting the correlation between the IC50 values of KRAS (G12C) Inhibitor-12 and the IC50 values of buparlisib, linsitinib, gefitinib, or trametinib in 12 KRAS G12C–mutant cell lines. Data were analyzed using Spearman’s rank correlation coefficient. (D) Left: Lollipop chart showing Spearman’s correlation coefficient (R values) between the IC50 values of KRAS (G12C) Inhibitor-12 and the IC50 values of 54 individual inhibitors targeting MAPK signaling, PI3K/mTOR signaling, or RTKs in 12 KRAS G12C–mutant cell lines. The dots with a black outline indicate significant correlations. Right: Stacked bar chart presenting the proportion of inhibitors with a significant R value in different targeted pathways. (E and F) Dose-response curves presenting the relative viability of parental H358 cells and acquired-resistance H358R and H358R N20 cells upon treatment with the indicated inhibitors for 5 days. Data are presented as mean ± SEM (A, E, and F) or mean ± SD (B).