83 results on '"DeNicola, Gina"'
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2. Figure S3 from Distinct Nrf2 Signaling Thresholds Mediate Lung Tumor Initiation and Progression
3. Figure S5 from Distinct Nrf2 Signaling Thresholds Mediate Lung Tumor Initiation and Progression
4. Figure S4 from Distinct Nrf2 Signaling Thresholds Mediate Lung Tumor Initiation and Progression
5. Figure S2 from Distinct Nrf2 Signaling Thresholds Mediate Lung Tumor Initiation and Progression
6. Figure S2 from Distinct Nrf2 Signaling Thresholds Mediate Lung Tumor Initiation and Progression
7. Figure S1 from Comprehensive Metabolic Tracing Reveals the Origin and Catabolism of Cysteine in Mammalian Tissues and Tumors
8. Figure S4 from Comprehensive Metabolic Tracing Reveals the Origin and Catabolism of Cysteine in Mammalian Tissues and Tumors
9. Figure S6 from Comprehensive Metabolic Tracing Reveals the Origin and Catabolism of Cysteine in Mammalian Tissues and Tumors
10. Figure S7 from Comprehensive Metabolic Tracing Reveals the Origin and Catabolism of Cysteine in Mammalian Tissues and Tumors
11. Figure S4 from Comprehensive Metabolic Tracing Reveals the Origin and Catabolism of Cysteine in Mammalian Tissues and Tumors
12. Figure S6 from Comprehensive Metabolic Tracing Reveals the Origin and Catabolism of Cysteine in Mammalian Tissues and Tumors
13. Figure S3 from Comprehensive Metabolic Tracing Reveals the Origin and Catabolism of Cysteine in Mammalian Tissues and Tumors
14. Figure S7 from Comprehensive Metabolic Tracing Reveals the Origin and Catabolism of Cysteine in Mammalian Tissues and Tumors
15. Data from Comprehensive Metabolic Tracing Reveals the Origin and Catabolism of Cysteine in Mammalian Tissues and Tumors
16. Figure S5 from Comprehensive Metabolic Tracing Reveals the Origin and Catabolism of Cysteine in Mammalian Tissues and Tumors
17. Figure S3 from Comprehensive Metabolic Tracing Reveals the Origin and Catabolism of Cysteine in Mammalian Tissues and Tumors
18. Figure S5 from Comprehensive Metabolic Tracing Reveals the Origin and Catabolism of Cysteine in Mammalian Tissues and Tumors
19. Figure S1 from Comprehensive Metabolic Tracing Reveals the Origin and Catabolism of Cysteine in Mammalian Tissues and Tumors
20. Data from Comprehensive Metabolic Tracing Reveals the Origin and Catabolism of Cysteine in Mammalian Tissues and Tumors
21. Figure S2 from Comprehensive Metabolic Tracing Reveals the Origin and Catabolism of Cysteine in Mammalian Tissues and Tumors
22. Figure S2 from Comprehensive Metabolic Tracing Reveals the Origin and Catabolism of Cysteine in Mammalian Tissues and Tumors
23. Distinct Nrf2 Signaling Thresholds Mediate Lung Tumor Initiation and Progression
24. Abstract 2161: Quinolinic acid phosphoribosyl transferase (QPRT) is an essential liability of non-small cell lung cancer
25. Supplementary Data from Coordinated Transcriptional and Catabolic Programs Support Iron-Dependent Adaptation to RAS–MAPK Pathway Inhibition in Pancreatic Cancer
26. Abstract 6029: Multi-omic landscape of squamous cell lung cancer
27. Data from Coordinated Transcriptional and Catabolic Programs Support Iron-Dependent Adaptation to RAS–MAPK Pathway Inhibition in Pancreatic Cancer
28. Supplementary Figure from Coordinated Transcriptional and Catabolic Programs Support Iron-Dependent Adaptation to RAS–MAPK Pathway Inhibition in Pancreatic Cancer
29. Supplementary Figure from Coordinated Transcriptional and Catabolic Programs Support Iron-Dependent Adaptation to RAS–MAPK Pathway Inhibition in Pancreatic Cancer
30. Data from Coordinated Transcriptional and Catabolic Programs Support Iron-Dependent Adaptation to RAS–MAPK Pathway Inhibition in Pancreatic Cancer
31. Supplementary Data from Coordinated Transcriptional and Catabolic Programs Support Iron-Dependent Adaptation to RAS–MAPK Pathway Inhibition in Pancreatic Cancer
32. Supplementary Figure Legends 1-4 from C-Raf Is Required for the Initiation of Lung Cancer by K-RasG12D
33. Figure S7 from Oncogenic KRAS Induces NIX-Mediated Mitophagy to Promote Pancreatic Cancer
34. Figure S6 from Oncogenic KRAS Induces NIX-Mediated Mitophagy to Promote Pancreatic Cancer
35. Supplementary Figure 4 from C-Raf Is Required for the Initiation of Lung Cancer by K-RasG12D
36. Data from Oncogenic KRAS Induces NIX-Mediated Mitophagy to Promote Pancreatic Cancer
37. Supplementary Figure 4 from C-Raf Is Required for the Initiation of Lung Cancer by K-RasG12D
38. Figure S1 from Oncogenic KRAS Induces NIX-Mediated Mitophagy to Promote Pancreatic Cancer
39. Figure S7 from Oncogenic KRAS Induces NIX-Mediated Mitophagy to Promote Pancreatic Cancer
40. Supplementary Figure 3 from C-Raf Is Required for the Initiation of Lung Cancer by K-RasG12D
41. Supplementary Figure 2 from C-Raf Is Required for the Initiation of Lung Cancer by K-RasG12D
42. Supplementary Figure 2 from C-Raf Is Required for the Initiation of Lung Cancer by K-RasG12D
43. Data from Oncogenic KRAS Induces NIX-Mediated Mitophagy to Promote Pancreatic Cancer
44. Data from C-Raf Is Required for the Initiation of Lung Cancer by K-RasG12D
45. Figure S8 from Oncogenic KRAS Induces NIX-Mediated Mitophagy to Promote Pancreatic Cancer
46. Figure S4 from Oncogenic KRAS Induces NIX-Mediated Mitophagy to Promote Pancreatic Cancer
47. Supplementary Figure 3 from C-Raf Is Required for the Initiation of Lung Cancer by K-RasG12D
48. Figure S5 from Oncogenic KRAS Induces NIX-Mediated Mitophagy to Promote Pancreatic Cancer
49. Supplementary Figure 1 from C-Raf Is Required for the Initiation of Lung Cancer by K-RasG12D
50. Figure S2 from Oncogenic KRAS Induces NIX-Mediated Mitophagy to Promote Pancreatic Cancer
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