Abstract
Diversity in the genetic lesions that cause cancer is extreme. In consequence, a pressing challenge is the development of drugs that target patient-specific disease mechanisms. To address this challenge, we employed a chemistry-first discovery paradigm for de novo identification of druggable targets linked to robust patient selection hypotheses. In particular, a 200,000 compound diversity-oriented chemical library was profiled across a heavily annotated test-bed of >100 cellular models representative of the diverse and characteristic somatic lesions for lung cancer. This approach led to the delineation of 171 chemical-genetic associations, shedding light on the targetability of mechanistic vulnerabilities corresponding to a range of oncogenotypes present in patient populations lacking effective therapy. Chemically addressable addictions to ciliogenesis in TTC21B mutants and GLUT8-dependent serine biosynthesis in KRAS/KEAP1 double mutants are prominent examples. These observations indicate a wealth of actionable opportunities within the complex molecular etiology of cancer. Application of a chemistry-first approach matches chemicals with targetable, diverse genetic lesions and cancer-promoting mechanisms in human lung cancer, providing guidance for development of personalized cancer treatment.
Original language | English (US) |
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Pages (from-to) | 864-878.e29 |
Journal | Cell |
Volume | 173 |
Issue number | 4 |
DOIs | |
State | Published - May 3 2018 |
Bibliographical note
Funding Information:This work was supported by grants from the NIH (CA197717, CA176284, CA70907, CA142543), CPRIT (RP120732, RP110708, RP110708), Robert Welch Foundation (I-1414), the Korea Health Technology R & D project through the Korea Health Industry Development Institute (HI14C1324), and the National R&D Program for Cancer Control (1420100), funded by the Ministry of Health & Welfare, Republic of Korea. E.A.M. was supported by NIH training grant 5T32GM8203-27, C.D. and R.M.V were supported by CPRIT training grant RP140110, and R.M.V was supported by NIH training grant 5T32CA124334-09. We would like to thank Hanspeter Niederstrasser, Melissa McCoy, Shuguang Wei, Hong Chen, and Anwu Zhou in the UT Southwestern High-throughput Screening Core for their support of the large-scale screening and dose-response experiments described herein.
Funding Information:
This work was supported by grants from the NIH ( CA197717 , CA176284 , CA70907 , CA142543 ), CPRIT ( RP120732 , RP110708 , RP110708 ), Robert Welch Foundation ( I-1414 ), the Korea Health Technology R & D project through the Korea Health Industry Development Institute ( HI14C1324 ), and the National R&D Program for Cancer Control ( 1420100 ), funded by the Ministry of Health & Welfare, Republic of Korea . E.A.M. was supported by NIH training grant 5T32GM8203-27 , C.D. and R.M.V were supported by CPRIT training grant RP140110 , and R.M.V was supported by NIH training grant 5T32CA124334-09 . We would like to thank Hanspeter Niederstrasser, Melissa McCoy, Shuguang Wei, Hong Chen, and Anwu Zhou in the UT Southwestern High-throughput Screening Core for their support of the large-scale screening and dose-response experiments described herein.
Publisher Copyright:
© 2018 Elsevier Inc.
Keywords
- KRAS mutant
- NRF2 signaling
- cancer target identification
- chemical biology
- ciliogenesis
- glucocorticoid therapies
- lung cancer
- serine biosynthesis