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1. RAS transformation requires CUX1-dependent repair of oxidative DNA damage.

2. Ras effector mutant expression suggest a negative regulator inhibits lung tumor formation.

3. A modular lentiviral and retroviral construction system to rapidly generate vectors for gene expression and gene knockdown in vitro and in vivo.

6. Supplementary Methods Figures 1-7 from Metabolic Regulator IAPP (Amylin) Is Required for BRAF and RAS Oncogene-Induced Senescence

9. Data from Hematopoietic Expression of Oncogenic BRAF Promotes Aberrant Growth of Monocyte-Lineage Cells Resistant to PLX4720

10. Supplementary Figure 5 from A Central Role for RAF→MEK→ERK Signaling in the Genesis of Pancreatic Ductal Adenocarcinoma

12. Data from MOB3A Bypasses BRAF and RAS Oncogene-Induced Senescence by Engaging the Hippo Pathway

18. Supplementary Table 2 from A Central Role for RAF→MEK→ERK Signaling in the Genesis of Pancreatic Ductal Adenocarcinoma

22. Supplementary Figure 1 from A Central Role for RAF→MEK→ERK Signaling in the Genesis of Pancreatic Ductal Adenocarcinoma

23. MOB3A Bypasses BRAF and RAS Oncogene-Induced Senescence by Engaging the Hippo Pathway

26. Supplementary Figures 1-3, Tables 1-3, Table 7, Legends for Figures 1-3, Tables 1-7 from B-Raf Activation Cooperates with PTEN Loss to Drive c-Myc Expression in Advanced Prostate Cancer

28. Data from Characterization of Melanoma Cells Capable of Propagating Tumors from a Single Cell

29. Supplementary Table 4 from B-Raf Activation Cooperates with PTEN Loss to Drive c-Myc Expression in Advanced Prostate Cancer

30. Supplementary Table 8 from B-Raf Activation Cooperates with PTEN Loss to Drive c-Myc Expression in Advanced Prostate Cancer

32. Supplementary Table 6B from B-Raf Activation Cooperates with PTEN Loss to Drive c-Myc Expression in Advanced Prostate Cancer

35. Supplementary Table 5A from B-Raf Activation Cooperates with PTEN Loss to Drive c-Myc Expression in Advanced Prostate Cancer

37. Data from B-Raf Activation Cooperates with PTEN Loss to Drive c-Myc Expression in Advanced Prostate Cancer

39. Supplementary Figure 5B from B-Raf Activation Cooperates with PTEN Loss to Drive c-Myc Expression in Advanced Prostate Cancer

40. Data from TP53 Silencing Bypasses Growth Arrest of BRAFV600E-Induced Lung Tumor Cells in a Two-Switch Model of Lung Tumorigenesis

41. Metabolic Regulator IAPP (Amylin) Is Required for BRAF and RAS Oncogene-Induced Senescence

42. Inhibiting the MNK1/2-eIF4E axis impairs melanoma phenotype switching and potentiates antitumor immune responses

43. The MNK1/2-eIF4E axis drives melanoma plasticity, progression, and resistance to immunotherapy

44. p53 loss does not permit escape from BrafV600E-induced senescence in a mouse model of lung cancer

45. Abstract A53: Phosphorylation of eIF4E promotes phenotype switching and MDSC-mediated immunosuppression in melanoma

46. Construction of Modular Lentiviral Vectors for Effective Gene Expression and Knockdown

47. Construction of Modular Lentiviral Vectors for Effective Gene Expression and Knockdown

48. Oncogene-dependent control of miRNA biogenesis and metastatic progression in a model of undifferentiated pleomorphic sarcoma

49. A Central Role for RAF→MEK→ERK Signaling in the Genesis of Pancreatic Ductal Adenocarcinoma

50. Abrogation of BRAF(V600E)-induced senescence by PI3K pathway activation contributes to melanomagenesis

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