Oncogenic stress sensitizes murine cancers to hypomorphic suppression of ATR
David W. Schoppy, Ryan L. Ragland, Oren Gilad, Nishita Shastri, Ashley A. Peters, Matilde Murga, Oscar Fernandez-Capetillo, J. Alan Diehl, Eric J. Brown
David W. Schoppy, Ryan L. Ragland, Oren Gilad, Nishita Shastri, Ashley A. Peters, Matilde Murga, Oscar Fernandez-Capetillo, J. Alan Diehl, Eric J. Brown
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Research Article

Oncogenic stress sensitizes murine cancers to hypomorphic suppression of ATR

Abstract

Oncogenic Ras and p53 loss-of-function mutations are common in many advanced sporadic malignancies and together predict a limited responsiveness to conventional chemotherapy. Notably, studies in cultured cells have indicated that each of these genetic alterations creates a selective sensitivity to ataxia telangiectasia and Rad3-related (ATR) pathway inhibition. Here, we describe a genetic system to conditionally reduce ATR expression to 10% of normal levels in adult mice to compare the impact of this suppression on normal tissues and cancers in vivo. Hypomorphic suppression of ATR minimally affected normal bone marrow and intestinal homeostasis, indicating that this level of ATR expression was sufficient for highly proliferative adult tissues. In contrast, hypomorphic ATR reduction potently inhibited the growth of both p53-deficient fibrosarcomas expressing H-rasG12V and acute myeloid leukemias (AMLs) driven by MLL-ENL and N-rasG12D. Notably, DNA damage increased in a greater-than-additive fashion upon combining ATR suppression with oncogenic stress (H-rasG12V, K-rasG12D, or c-Myc overexpression), indicating that this cooperative genome-destabilizing interaction may contribute to tumor selectivity in vivo. This toxic interaction between ATR suppression and oncogenic stress occurred without regard to p53 status. These studies define a level of ATR pathway inhibition in which the growth of malignancies harboring oncogenic mutations can be suppressed with minimal impact on normal tissue homeostasis, highlighting ATR inhibition as a promising therapeutic strategy.

Authors

David W. Schoppy, Ryan L. Ragland, Oren Gilad, Nishita Shastri, Ashley A. Peters, Matilde Murga, Oscar Fernandez-Capetillo, J. Alan Diehl, Eric J. Brown

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Figure 2

ATR hypomorphic suppression has a minimal impact on normal tissue homeostasis.

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ATR hypomorphic suppression has a minimal impact on normal tissue homeos...
(A) H&E-stained sections of humeral bones from tamoxifen-treated mice at the indicated time points after initial treatment. Original magnification, ×200. (B) Absolute number of myeloid cells (Mac1+Gr1+) obtained from 4 hind limb bones of mice at the indicated time points (n = 5–15 mice per genotype, per time point). (C) H&E-stained sections of intestines from tamoxifen-treated mice at the indicated time points after initial treatment. Original magnification, ×200. (D) Weight of mice at the indicated time points. (E and F) Abundance of the ATRfl-recombined allele (ATRΔ) in the bone marrow (E) and intestines (F) of tamoxifen-treated mice. Time points represent the number of days after tamoxifen treatment. The frequency of ATRfl recombination was determined by qPCR amplification of the ATRfl allele from genomic DNA isolated from each tissue (n = 5–15 mice per genotype, per time point). Data show mean ± SEM.