Abstract
The LKB1 tumor suppressor encodes a key metabolic sensor that integrates cell growth and metabolism. LKB1 is mutationally inactivated in multiple adult malignancies, including >20% of lung cancers, often simultaneously with activating KRAS mutations. LKB1 mutations are an important predictor of poor outcome and resistance to current therapeutic approaches. We employed an integrative approach to define novel therapeutic targets in Lkb1 mutant lung cancers. Matched cell lines from genetically engineered mouse models of cancer driven by activated Kras alone or in combination with Lkb1 deletion, were employed in high-throughput RNAi, kinase inhibitor, and metabolite screens. These screens identified knockdown of either Dtymk (deoxythymidylate kinase) or Chek1 (checkpoint kinase 1) as synthetically lethal with Lkb1 deficiency in both mouse and human lung cancer cell lines, and revealed that Lkb1 inactivation conferred marked sensitivity to treatment with CHEK1 inhibitors. Lkb1 deficient cells had a distinct metabolic profile, characterized by striking decreases in multiple nucleotide metabolites. Knockdown of DTYMK inhibited dTTP biosynthesis and, consequently, DNA synthesis, and knockdown of CHEK1 caused accumulation of DNA damage. We hypothesize that Lkb1 loss enhances dependence on these enzymes due to broad defects in nucleotide metabolism. Our studies support the development of therapies target DTYMK and CHEK1 in LKB1 mutant non-small cell lung cancer.
Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr LB-260. doi:1538-7445.AM2012-LB-260