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D. Carney

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    PL02 - Will Personalised Therapies Ever “Cure” Metastatic NSCLC? (ID 73)

    • Event: WCLC 2013
    • Type: Plenary Session
    • Track: Medical Oncology
    • Presentations: 5
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      PL02.0 - Chair Intro (ID 632)

      08:15 - 09:45  |  Author(s): D. Gandara

      • Abstract
      • Slides

      Abstract not provided

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      PL02.1 - Identifying Druggable Targets Through Whole Genome Sequencing: TCGA (ID 633)

      08:15 - 09:45  |  Author(s): M. Meyerson

      • Abstract
      • Slides

      Abstract not provided

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      PL02.2 - Dark Matter: Defining Oncogenic Drivers in the Epigenome (ID 634)

      08:15 - 09:45  |  Author(s): C.M. Rudin

      • Abstract
      • Slides

      Abstract
      The single most important advance in the approach to lung cancer treatment in the past decade has been the iterative identification and targeting of subsets of lung cancer defined by distinct oncogenic driver mutations. This has changed the way we think about these diseases, and is accelerating the development of driver-targeted therapies that are improving multiple measures of clinical outcome, most dramatically documented by waterfall plots of tumor response, for patients with advanced lung cancer. Despite the clinically meaningful benefits provided by selective inhibition of mutated oncogenic drivers, however, none of these treatments have changed the fundamental incurability of metastatic lung cancer. Hence the impetus for this series of talks: we have markedly improved the short-term prognosis for select subsets of our patients, but the survival curves even for these subsets go to ground. This observation, entirely consistent with the clinical experience of targeted inhibitor development in other malignancies, has prompted focused research in a number of directions, including inhibiting secondary mutations and escape pathways implicated in acquired resistance, priming the immune system to effectively respond to advanced cancer, and defining and targeting non-mutational (epigenetic) mechanisms contributing to oncogenesis and disease persistence. Epigenetics refers to the somatically heritable differences in gene expression not attributable to intrinsic alterations in the primary sequence of DNA. In general, the cells that comprise an individual have identical genomes, but have many entirely different epigenomes that dictate tissue specificity and cellular function. The past decade has seen remarkable expansion of our understanding of how epigenetic control influences the patterns of gene expression, how these controls can be manipulated, and how such manipulation can influence cell fate. These emerging insights have clear translational implications for therapeutic targeting epigenetic abnormalities in cancer. Cancers of all types demonstrate extensive and biologically significant changes in the epigenetic code; these changes collectively can be termed the “cancer epigenome.” Clonally heritable alterations in the cancer epigenome include important oncogenic drivers, entirely analogous to somatic mutations in the cancer genome. One nice example demonstrating the complementary nature of genetic and epigenetic alterations in cancer has emerged from The Cancer Genome Atlas sequencing efforts in lung cancer, revealing key tumor suppressors affected by mutational inactivation or epigenetic silencing in non-overlapping sets of cases. There is a key difference between genetic and epigenetic changes in cancer-causing genes. Mutation is in general irreversible, while epigenetic changes are not: these could be reversed with appropriately directed therapy. This plasticity may represent both an opportunity and a limitation for epigenetic therapy approaches. The existence of intermediate states of gene silencing or activation can further complicate identification of epigenetically dysregulated “driver” and “passenger” genes in cancer. I will review our recent progress in epigenetic profiling of small cell lung cancer. The development of epigenetically targeted anti-cancer drugs has lagged behind the recent explosive expansion of mutant kinase inhibitors. In part, this may be because many key components of epigenetic dysregulation in cancer are only now being described. Currently available epigenetically targeted drugs include the DNA methyltransferase inhibitors azacitidine and decitabine and the histone deacetylase inhibitors romidepsin and vorinostat; a much larger portfolio of both of these classes of drugs, particularly the HDAC inhibitors, are now in development. These classes of drugs both induce broad changes in gene expression. Our experience in combining azacitidine with the HDAC inhibitor entinostat in patients with advanced lung cancer will be discussed in another presentation at this meeting. An additional development with translational implications for drug development that has emerged from recent genomic sequencing efforts is the recognition that virtually all tumors harbor mutations in critical regulators of the epigenome. Novel agents targeting other epigenetic factors, including multiple chromatin modifiers, are now in development. Bromodomain inhibitors targeting the BET family proteins may be of particular interest in blocking activation of MYC target genes, of central relevance in small cell lung cancer. If cancer-specific epigenetic alterations were just an alternative to mutation in heritably affecting specific oncogenic drivers, one might not expect epigenetically directed therapy to lead to durable responses. However, several preclinical observations that suggest that effective epigenetic therapy could have very different, and potentially complementary, effects. One set of observations, first noted by the Settleman laboratory, suggests a strategy to convert excellent responses to targeted therapy to durable responses. These investigators define drug-tolerant “persisters” among driver-oncogene dependent tumor cells treated with supratherapeutic doses of tyrosine kinase inhibitors – these persisters are clonogenic but are dependent on a particular histone demethylase (KDM5A) and can be eliminated by exposure to any of multiple HDAC inhibitors. A second set of observations, from the Baylin laboratory and others, demonstrates that low dose exposure to demethylating agents alone, below the level of substantial cytotoxicity, can alter the long-term clonogenic and tumorigenic potential of cancer cells. A final set of observations concerns the extensive array of cancer-relevant pathways and processes that can be concomitantly affected by epigenetically targeted therapy; of particular note are multiple immunologically relevant pathways in both tumor cells and immunologic effectors. Induced re-expression of silenced tumor antigens together with stimulation of immune response pathways may enhance tumor susceptibility to immunotherapy. These recent observations define clinically testable hypotheses using currently available investigational agents that could affect the long-term survival of patients with lung cancer.

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      PL02.3 - Tumour Heterogeneity as an Obstacle to Cure (ID 635)

      08:15 - 09:45  |  Author(s): C. Swanton

      • Abstract
      • Slides

      Abstract
      Despite advances in cancer genomics, most advanced solid tumors remain incurable and drug resistance is almost inevitable. Two important lessons have emerged, which may provide an explanation for difficulties that have been encountered in improving cancer survival outcomes. First, each tumor contains an individual assortment of multiple genomic aberrations, few of which are shared between patients with the same histopathological tumor subtype. Second, evidence suggests that these anomalies appear to vary within individual tumors, both spatially and temporally during the disease course, indicating substantial intratumor heterogeneity. Branched evolutionary growth and intratumor heterogeneity results in coexisting cancer cell subclones with variegated genotypes and phenotypes that may be regionally separated within the same tumor and alter in dominance over time. Variegated phenotypes, resulting from intratumoral genetic heterogeneity and the emergence of new subclones at relapse, are likely to have important implications for developing novel targeted therapies and for preventing the emergence of drug resistance. Intratumor heterogeneity and sampling bias, resulting from single biopsy-driven biomarker discovery and validation approaches, may also contribute to the recently reported failures in implementation of robust biomarkers in the clinical setting. In this talk, the two fundamental principles of Darwinian Evolution, diversity and selection, will be discussed in relation to achieving better cancer survival outcomes.

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      PL02.4 - What is Cure and How Can We Achieve This With Targeted Therapies? (ID 636)

      08:15 - 09:45  |  Author(s): T. Mok

      • Abstract
      • Slides

      Abstract not provided

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