583 results on '"Languino, Lucia R."'
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2. Targeting the αVβ3/NgR2 pathway in neuroendocrine prostate cancer
3. Parkin ubiquitination of Kindlin-2 enables mitochondria-associated metastasis suppression
4. The NOGO receptor NgR2, a novel αVβ3 integrin effector, induces neuroendocrine differentiation in prostate cancer
5. Expression of the αVβ3 integrin affects prostate cancer sEV cargo and density and promotes sEV pro‐tumorigenic activity in vivo through a GPI‐anchored receptor, NgR2.
6. Small Extracellular Vesicle Regulation of Mitochondrial Dynamics Reprograms a Hypoxic Tumor Microenvironment
7. Myc-mediated transcriptional regulation of the mitochondrial chaperone TRAP1 controls primary and metastatic tumor growth
8. Tumor-Derived Extracellular Vesicles Require β1 Integrins to Promote Anchorage-Independent Growth
9. Activated Extracellular Vesicles as New Therapeutic Targets?
10. Prostate cancer sheds the αvβ3 integrin in vivo through exosomes
11. Exosomal αvβ6 integrin is required for monocyte M2 polarization in prostate cancer
12. Selective Modulation of Type 1 Insulin-Like Growth Factor Receptor Signaling and Functions by β 1 Integrins
13. The Launch of the American Journal of Translational Research
14. α v β 3 Integrin Expression Up-Regulates cdc2, Which Modulates Cell Migration
15. Cancer-Associated Fibroblasts Neutralize the Anti-tumor Effect of CSF1 Receptor Blockade by Inducing PMN-MDSC Infiltration of Tumors
16. Neuroendocrine gene subsets are uniquely dysregulated in prostate adenocarcinoma.
17. Unique pattern of neutrophil migration and function during tumor progression
18. Data from NetrinG1+ Cancer-Associated Fibroblasts Generate Unique Extracellular Vesicles that Support the Survival of Pancreatic Cancer Cells Under Nutritional Stress
19. Supplementary Figures S1-S9 from NetrinG1+ Cancer-Associated Fibroblasts Generate Unique Extracellular Vesicles that Support the Survival of Pancreatic Cancer Cells Under Nutritional Stress
20. Supplementary File 1 (proteomics) from NetrinG1+ Cancer-Associated Fibroblasts Generate Unique Extracellular Vesicles that Support the Survival of Pancreatic Cancer Cells Under Nutritional Stress
21. Supplementary File 2 (statistical analyses) from NetrinG1+ Cancer-Associated Fibroblasts Generate Unique Extracellular Vesicles that Support the Survival of Pancreatic Cancer Cells Under Nutritional Stress
22. Supplementary File 3 (metabolomics) from NetrinG1+ Cancer-Associated Fibroblasts Generate Unique Extracellular Vesicles that Support the Survival of Pancreatic Cancer Cells Under Nutritional Stress
23. Figure S5 from αvβ3 Integrin Mediates Radioresistance of Prostate Cancer Cells through Regulation of Survivin
24. Data from αvβ3 Integrin Mediates Radioresistance of Prostate Cancer Cells through Regulation of Survivin
25. Supplementary Data from αvβ3 Integrin Mediates Radioresistance of Prostate Cancer Cells through Regulation of Survivin
26. Transgenic Expression of the Mitochondrial Chaperone TNFR-associated Protein 1 (TRAP1) Accelerates Prostate Cancer Development
27. Mitochondrial Akt Regulation of Hypoxic Tumor Reprogramming
28. CD45 Phosphatase Inhibits STAT3 Transcription Factor Activity in Myeloid Cells and Promotes Tumor-Associated Macrophage Differentiation
29. Supplementary Figure 1 from αvβ6 Integrin Promotes Castrate-Resistant Prostate Cancer through JNK1-Mediated Activation of Androgen Receptor
30. Figure S3 from Syntaphilin Ubiquitination Regulates Mitochondrial Dynamics and Tumor Cell Movements
31. Data from v-Src Oncogene Induces Trop2 Proteolytic Activation via Cyclin D1
32. Supplementary Figure 3 from αvβ6 Integrin Promotes Castrate-Resistant Prostate Cancer through JNK1-Mediated Activation of Androgen Receptor
33. Data from MFF Regulation of Mitochondrial Cell Death Is a Therapeutic Target in Cancer
34. Supplementary Data from MFF Regulation of Mitochondrial Cell Death Is a Therapeutic Target in Cancer
35. Supplemental Methos from v-Src Oncogene Induces Trop2 Proteolytic Activation via Cyclin D1
36. Supplemental Material from αvβ6 Integrin Promotes Castrate-Resistant Prostate Cancer through JNK1-Mediated Activation of Androgen Receptor
37. Supplementary Figure 6 from αvβ6 Integrin Promotes Castrate-Resistant Prostate Cancer through JNK1-Mediated Activation of Androgen Receptor
38. Supplementary Figure 9 from αvβ6 Integrin Promotes Castrate-Resistant Prostate Cancer through JNK1-Mediated Activation of Androgen Receptor
39. Supplementary Figure 4 from αvβ6 Integrin Promotes Castrate-Resistant Prostate Cancer through JNK1-Mediated Activation of Androgen Receptor
40. Figure S5 from MFF Regulation of Mitochondrial Cell Death Is a Therapeutic Target in Cancer
41. Supplementary Figure 7 from αvβ6 Integrin Promotes Castrate-Resistant Prostate Cancer through JNK1-Mediated Activation of Androgen Receptor
42. Supplementary Movie S2 from MFF Regulation of Mitochondrial Cell Death Is a Therapeutic Target in Cancer
43. Table S2 from MFF Regulation of Mitochondrial Cell Death Is a Therapeutic Target in Cancer
44. Supplementary Figure S1 from MFF Regulation of Mitochondrial Cell Death Is a Therapeutic Target in Cancer
45. Table S1 from Syntaphilin Ubiquitination Regulates Mitochondrial Dynamics and Tumor Cell Movements
46. Supplementary Figure 2 from αvβ6 Integrin Promotes Castrate-Resistant Prostate Cancer through JNK1-Mediated Activation of Androgen Receptor
47. Supplemental Figures from v-Src Oncogene Induces Trop2 Proteolytic Activation via Cyclin D1
48. Data from αvβ6 Integrin Promotes Castrate-Resistant Prostate Cancer through JNK1-Mediated Activation of Androgen Receptor
49. Data from Syntaphilin Ubiquitination Regulates Mitochondrial Dynamics and Tumor Cell Movements
50. Supplementary Figure 8 from αvβ6 Integrin Promotes Castrate-Resistant Prostate Cancer through JNK1-Mediated Activation of Androgen Receptor
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