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Juan Sandoval



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    P2.03 - Biology (ID 162)

    • Event: WCLC 2019
    • Type: Poster Viewing in the Exhibit Hall
    • Track: Biology
    • Presentations: 1
    • Moderators:
    • Coordinates: 9/09/2019, 10:15 - 18:15, Exhibit Hall
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      P2.03-38 - Identification of a Novel Synthetic Lethal Vulnerability in Non-Small Cell Lung Cancer by Co-Targeting TMPRSS4 and DDR1 (ID 2191)

      10:15 - 18:15  |  Author(s): Juan Sandoval

      • Abstract
      • Slides

      Background

      Synthetic lethality has been defined as the inability of cells to proliferate when co-targeting two genes, with a synergistically superior inhibition than that found for each individual gene. Consistent co-expression of two genes involved in a similar function is a predictor of synthetic lethality, a strategy that is being applied to find out novel cancer vulnerabilities.

      Method

      Large-scale bioinformatics analyses across 5 public databases were used to identify genes consistently co-expressed with TMPRSS4, a novel therapeutic target that we have previously identified in NSCLC. Pyrosequencing was used to evaluate methylation levels in patients and cell lines. Functional in vitro experiments and animal models were used to assess synthetic lethality of TMPRSS4 and DDR1 in NSCLC.

      Result

      Consistent co-expression between TMPRSS4 and DDR1 was found in all NSCLC databases evaluated. Similar to TMPRSS4, DDR1 promoter was hypomethylated in NSCLC in 3 independent cohorts and hypomethylation was an independent prognostic factor of disease-free survival. Treatment with 5-azacitidine increased DDR1 levels in cell lines, suggesting an epigenetic regulation. Cells lacking TMPRSS4 were highly sensitive to the cytotoxic effect of the DDR1 inhibitor dasatinib. TMPRSS4/DDR1 double knock-down cells, but not single knock-out cells suffered a G0/G1 cell cycle arrest with loss of E2F1 and cyclins A and B, increased p21 levels and apoptosis. Moreover, double knock-down cells were highly sensitized to cisplatin, which caused massive apoptosis (~40%). In vivo studies demonstrated tumor regression in mice injected with double knock-down-injected cells and lack of 18FDG-uptake by microPET analysis.

      Conclusion

      We have identified a novel vulnerability in NSCLC resulting from a synthetic lethal interaction between DDR1 and TMPRSS4. This may help designing therapeutic strategies to impair NSCLC growth by co-targeting both genes.

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