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Literature DB >> 32727735

Combined Proteomic and Genetic Interaction Mapping Reveals New RAS Effector Pathways and Susceptibilities.

Marcus R Kelly^1,2, Kaja Kostyrko³, Kyuho Han⁴, Nancie A Mooney¹, Edwin E Jeng⁴, Kaitlyn Spees⁴, Phuong T Dinh³, Keene L Abbott¹, Dana M Gwinn³, E Alejandro Sweet-Cordero⁵, Michael C Bassik^6,7, Peter K Jackson^8,7,9.

Abstract

Activating mutations in RAS GTPases drive many cancers, but limited understanding of less-studied RAS interactors, and of the specific roles of different RAS interactor paralogs, continues to limit target discovery. We developed a multistage discovery and screening process to systematically identify genes conferring RAS-related susceptibilities in lung adenocarcinoma. Using affinity purification mass spectrometry, we generated a protein-protein interaction map of RAS interactors and pathway components containing hundreds of interactions. From this network, we constructed a CRISPR dual knockout library targeting 119 RAS-related genes that we screened for KRAS-dependent genetic interactions (GI). This approach identified new RAS effectors, including the adhesion controller RADIL and the endocytosis regulator RIN1, and >250 synthetic lethal GIs, including a potent KRAS-dependent interaction between RAP1GDS1 and RHOA. Many GIs link specific paralogs within and between gene families. These findings illustrate the power of multiomic approaches to uncover synthetic lethal combinations specific for hitherto untreatable cancer genotypes. SIGNIFICANCE: We establish a deep network of protein-protein and genetic interactions in the RAS pathway. Many interactions validated here demonstrate important specificities and redundancies among paralogous RAS regulators and effectors. By comparing synthetic lethal interactions across KRAS-dependent and KRAS-independent cell lines, we identify several new combination therapy targets for RAS-driven cancers.This article is highlighted in the In This Issue feature, p. 1775. ©2020 American Association for Cancer Research.

Entities: Chemical

Mesh：

Substances：
ras Proteins

Year: 2020 PMID： 32727735 PMCID： PMC7710624 DOI： 10.1158/2159-8290.CD-19-1274

Source DB: PubMed Journal: Cancer Discov ISSN： 2159-8274 Impact factor: 38.272

61 in total

1. Selective Inhibition of Oncogenic KRAS Output with Small Molecules Targeting the Inactive State.

Authors: Matthew P Patricelli; Matthew R Janes; Lian-Sheng Li; Rasmus Hansen; Ulf Peters; Linda V Kessler; Yuching Chen; Jeff M Kucharski; Jun Feng; Tess Ely; Jeffrey H Chen; Sarah J Firdaus; Anjali Babbar; Pingda Ren; Yi Liu
Journal: Cancer Discov Date: 2016-01-06 Impact factor: 39.397

2. Scratch-wound assay.

Authors: Giles Cory
Journal: Methods Mol Biol Date: 2011

3. RalGDS is required for tumor formation in a model of skin carcinogenesis.

Authors: Ana González-García; Catrin A Pritchard; Hugh F Paterson; Georgia Mavria; Gordon Stamp; Christopher J Marshall
Journal: Cancer Cell Date: 2005-03 Impact factor: 31.743

4. High-Resolution CRISPR Screens Reveal Fitness Genes and Genotype-Specific Cancer Liabilities.

Authors: Traver Hart; Megha Chandrashekhar; Michael Aregger; Zachary Steinhart; Kevin R Brown; Graham MacLeod; Monika Mis; Michal Zimmermann; Amelie Fradet-Turcotte; Song Sun; Patricia Mero; Peter Dirks; Sachdev Sidhu; Frederick P Roth; Olivia S Rissland; Daniel Durocher; Stephane Angers; Jason Moffat
Journal: Cell Date: 2015-11-25 Impact factor: 41.582

5. Mapping the NPHP-JBTS-MKS protein network reveals ciliopathy disease genes and pathways.

Authors: Liyun Sang; Julie J Miller; Kevin C Corbit; Rachel H Giles; Matthew J Brauer; Edgar A Otto; Lisa M Baye; Xiaohui Wen; Suzie J Scales; Mandy Kwong; Erik G Huntzicker; Mindan K Sfakianos; Wendy Sandoval; J Fernando Bazan; Priya Kulkarni; Francesc R Garcia-Gonzalo; Allen D Seol; John F O'Toole; Susanne Held; Heiko M Reutter; William S Lane; Muhammad Arshad Rafiq; Abdul Noor; Muhammad Ansar; Akella Radha Rama Devi; Val C Sheffield; Diane C Slusarski; John B Vincent; Daniel A Doherty; Friedhelm Hildebrandt; Jeremy F Reiter; Peter K Jackson
Journal: Cell Date: 2011-05-13 Impact factor: 41.582

6. A human protein selected for interference with Ras function interacts directly with Ras and competes with Raf1.

Authors: L Han; J Colicelli
Journal: Mol Cell Biol Date: 1995-03 Impact factor: 4.272

7. An ARL3-UNC119-RP2 GTPase cycle targets myristoylated NPHP3 to the primary cilium.

Authors: Kevin J Wright; Lisa M Baye; Anique Olivier-Mason; Saikat Mukhopadhyay; Liyun Sang; Mandy Kwong; Weiru Wang; Pamela R Pretorius; Val C Sheffield; Piali Sengupta; Diane C Slusarski; Peter K Jackson
Journal: Genes Dev Date: 2011-11-15 Impact factor: 11.361

8. The Canonical Wnt Pathway Drives Macropinocytosis in Cancer.

Authors: Gil Redelman-Sidi; Anna Binyamin; Isabella Gaeta; Wilhelm Palm; Craig B Thompson; Paul B Romesser; Scott W Lowe; Mukta Bagul; John G Doench; David E Root; Michael S Glickman
Journal: Cancer Res Date: 2018-06-05 Impact factor: 13.312

9. Comparative Proteomics Reveals Strain-Specific β-TrCP Degradation via Rotavirus NSP1 Hijacking a Host Cullin-3-Rbx1 Complex.

Authors: Siyuan Ding; Nancie Mooney; Bin Li; Marcus R Kelly; Ningguo Feng; Alexander V Loktev; Adrish Sen; John T Patton; Peter K Jackson; Harry B Greenberg
Journal: PLoS Pathog Date: 2016-10-05 Impact factor: 6.823

10. Ras functional proximity proteomics establishes mTORC2 as new direct ras effector.

Authors: Joanna R Kovalski; Ronald L Shanderson; Paul A Khavari
Journal: Oncotarget Date: 2019-08-27

12 in total

1. Paralog knockout profiling identifies DUSP4 and DUSP6 as a digenic dependence in MAPK pathway-driven cancers.

Authors: Takahiro Ito; Michael J Young; Ruitong Li; Sidharth Jain; Andreas Wernitznig; John M Krill-Burger; Christopher T Lemke; Davide Monducci; Diego J Rodriguez; Liang Chang; Sanjukta Dutta; Debjani Pal; Brenton R Paolella; Michael V Rothberg; David E Root; Cory M Johannessen; Laxmi Parida; Gad Getz; Francisca Vazquez; John G Doench; Mahdi Zamanighomi; William R Sellers
Journal: Nat Genet Date: 2021-12-02 Impact factor: 38.330

Review 2. KRAS^G12R-Independent Macropinocytosis in Pancreatic Cancer.

Authors: G Aaron Hobbs; Channing J Der
Journal: Subcell Biochem Date: 2022

Review 3. Synthetic Vulnerabilities in the KRAS Pathway.

Authors: Marta Roman; Elizabeth Hwang; E Alejandro Sweet-Cordero
Journal: Cancers (Basel) Date: 2022-06-08 Impact factor: 6.575

4. Interpretation of cancer mutations using a multiscale map of protein systems.

Authors: Fan Zheng; Marcus R Kelly; Dana J Ramms; Marissa L Heintschel; Kai Tao; Beril Tutuncuoglu; John J Lee; Keiichiro Ono; Helene Foussard; Michael Chen; Kari A Herrington; Erica Silva; Sophie N Liu; Jing Chen; Christopher Churas; Nicholas Wilson; Anton Kratz; Rudolf T Pillich; Devin N Patel; Jisoo Park; Brent Kuenzi; Michael K Yu; Katherine Licon; Dexter Pratt; Jason F Kreisberg; Minkyu Kim; Danielle L Swaney; Xiaolin Nan; Stephanie I Fraley; J Silvio Gutkind; Nevan J Krogan; Trey Ideker
Journal: Science Date: 2021-10-01 Impact factor: 63.714

Combined Proteomic and Genetic Interaction Mapping Reveals New RAS Effector Pathways and Susceptibilities.

1. Selective Inhibition of Oncogenic KRAS Output with Small Molecules Targeting the Inactive State.

2. Scratch-wound assay.

3. RalGDS is required for tumor formation in a model of skin carcinogenesis.

4. High-Resolution CRISPR Screens Reveal Fitness Genes and Genotype-Specific Cancer Liabilities.

5. Mapping the NPHP-JBTS-MKS protein network reveals ciliopathy disease genes and pathways.

6. A human protein selected for interference with Ras function interacts directly with Ras and competes with Raf1.

7. An ARL3-UNC119-RP2 GTPase cycle targets myristoylated NPHP3 to the primary cilium.

8. The Canonical Wnt Pathway Drives Macropinocytosis in Cancer.

9. Comparative Proteomics Reveals Strain-Specific β-TrCP Degradation via Rotavirus NSP1 Hijacking a Host Cullin-3-Rbx1 Complex.

10. Ras functional proximity proteomics establishes mTORC2 as new direct ras effector.

1. Paralog knockout profiling identifies DUSP4 and DUSP6 as a digenic dependence in MAPK pathway-driven cancers.

Review 2. KRAS^G12R-Independent Macropinocytosis in Pancreatic Cancer.

Review 3. Synthetic Vulnerabilities in the KRAS Pathway.

4. Interpretation of cancer mutations using a multiscale map of protein systems.

Review 5. The Ins and Outs of RAS Effector Complexes.

Review 6. The Metabolic Landscape of RAS-Driven Cancers from biology to therapy.

Review 7. KRAS mutation: from undruggable to druggable in cancer.

Review 8. Synthetic Lethality in Cancer Therapeutics: The Next Generation.

Review 9. CRISPR Screens in Synthetic Lethality and Combinatorial Therapies for Cancer.

Review 10. Targeting KRAS mutant lung cancer: light at the end of the tunnel.

Review 2. KRASG12R-Independent Macropinocytosis in Pancreatic Cancer.

Review 3. Synthetic Vulnerabilities in the KRAS Pathway.

Review 5. The Ins and Outs of RAS Effector Complexes.

Review 6. The Metabolic Landscape of RAS-Driven Cancers from biology to therapy.

Review 7. KRAS mutation: from undruggable to druggable in cancer.

Review 8. Synthetic Lethality in Cancer Therapeutics: The Next Generation.

Review 9. CRISPR Screens in Synthetic Lethality and Combinatorial Therapies for Cancer.

Review 10. Targeting KRAS mutant lung cancer: light at the end of the tunnel.

Review 2. KRAS^G12R-Independent Macropinocytosis in Pancreatic Cancer.