| Symposium Participants |
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v | |
| Foreword |
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xvii | |
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Normal and Neoplastic Stem Cells |
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1 | (10) |
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Targeting the Epithelial-to-Mesenchymal Transition: The Case for Differentiation-Based Therapy |
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11 | (10) |
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Trimming the Vascular Tree in Tumors: Metabolic and Immune Adaptations |
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21 | (10) |
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Cell of Origin and Cancer Stem Cells in Tumor Suppressor Mouse Models of Glioblastoma |
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31 | (6) |
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Sheila R. Alcantara Llaguno |
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37 | (4) |
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Alterations in Three-Dimensional Organization of the Cancer Genome and Epigenome |
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41 | (12) |
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Composition and Function of Mammalian SWI/SNF Chromatin Remodeling Complexes in Human Disease |
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53 | (8) |
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The Essential Transcriptional Function of BRD4 in Acute Myeloid Leukemia |
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61 | (6) |
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Reexamining How Cancer Cells Exploit the Body's Metabolic Resources |
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67 | (6) |
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Autophagy, Metabolism, and Cancer |
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73 | (6) |
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A Time for MYC: Metabolism and Therapy |
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79 | (6) |
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Beyond the Oncogene Revolution: Four New Ways to Combat Cancer |
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85 | (8) |
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Lipid Synthesis Is a Metabolic Liability of Non---Small Cell Lung Cancer |
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93 | (12) |
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Targets, Vaccines, and Therapeutics |
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Cancer Immunogenomics: Computational Neoantigen Identification and Vaccine Design |
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105 | (8) |
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Targeting HIF2 in Clear Cell Renal Cell Carcinoma |
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113 | (10) |
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BET Bromodomain Proteins as Cancer Therapeutic Targets |
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123 | (8) |
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To Prime, or Not to Prime: That Is the Question |
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131 | (10) |
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Genetic Dissection of Cancer Development, Therapy Response, and Resistance in Mouse Models of Breast Cancer |
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141 | (10) |
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Microenvironment and Metastasis |
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Tumor---Stroma Interactions in Bone Metastasis: Molecular Mechanisms and Therapeutic Implications |
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151 | (12) |
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Cancer, Oxidative Stress, and Metastasis |
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163 | (14) |
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RON Signaling Is a Key Mediator of Tumor Progression in Many Human Cancers |
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177 | (12) |
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Physical and Chemical Gradients in the Tumor Microenvironment Regulate Tumor Cell Invasion, Migration, and Metastasis |
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189 | (18) |
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Pathways Involved in Formation of Mammary Organoid Architecture Have Keys to Understanding Drug Resistance and to Discovery of Draggable Targets |
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207 | (12) |
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Explaining the Paucity of Intratumoral T Cells: A Construction Out of Known Entities |
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219 | (8) |
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Modeling Breast Cancer Intertumor and Intratumour Heterogeneity Using Xenografts |
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227 | (4) |
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Challenges and Opportunities in Modeling Pancreatic Cancer |
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231 | (6) |
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Cancer Genomics and Tumor Heterogeneity |
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Functional Genomic Characterization of Cancer Genomes |
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237 | (10) |
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How Cancer Genomics Drives Cancer Biology: Does Synthetic Lethality Explain Mutually Exclusive Oncogenic Mutations? |
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247 | (10) |
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A Pipeline for Drag Target Identification and Validation |
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257 | (12) |
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Single-Cell Analysis of Circulating Tumor Cells as a Window into Tumor Heterogeneity |
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269 | (6) |
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Discovery of Double-Stranded Genomic DNA in Circulating Exosomes |
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275 | (6) |
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281 | (8) |
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289 | (8) |
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291 | (6) |
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Conversations at the Symposium |
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297 | (66) |
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299 | (2) |
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301 | (3) |
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304 | (2) |
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306 | (3) |
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309 | (2) |
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311 | (3) |
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314 | (3) |
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317 | (3) |
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320 | (3) |
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Guillermina (Gigi) Lozano |
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323 | (3) |
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326 | (2) |
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328 | (3) |
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331 | (3) |
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334 | (2) |
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336 | (2) |
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338 | (3) |
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341 | (3) |
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344 | (3) |
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347 | (4) |
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351 | (3) |
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354 | (3) |
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357 | (3) |
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360 | (3) |
| Author Index |
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363 | (2) |
| Subject Index |
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365 | |
