BACKGROUND: It is unclear how DNA-damaging agents target cancer cells over normal somatic cells. RESULTS: Arf/p53-dependent down-regulation of H2AX enables normal cells to survive after DNA damage. CONCLUSION: Transformed cells, which harbor mutations in either Arf or p53, are more sensitive to DNA-damaging agents. SIGNIFICANCE: Cellular transformation renders cells more susceptible to some DNA-damaging agents. Anti-cancer drugs generally target cancer cells rather than normal somatic cells. However, the factors that determine this differential sensitivity are poorly understood. Here we show that Arf/p53-dependent down-regulation of H2AX induced the selective survival of normal cells after drug treatment, resulting in the preferential targeting of cancer cells. Treatment with camptothecin, a topoisomerase I inhibitor, caused normal cells to down-regulate H2AX and become quiescent, a process mediated by both Arf and p53. In contrast, transformed cells that harbor mutations in either Arf or p53 do not down-regulate H2AX and are more sensitive to drugs unless they have developed drug resistance. Such transformation-associated changes in H2AX expression rendered cancer cells more susceptible to drug-induced damage (by two orders of magnitude). Thus, the expression of H2AX and γH2AX (phosphorylated form of H2AX at Ser-139) is a critical factor that determines drug sensitivity and should be considered when administering chemotherapy.
BACKGROUND: It is unclear how DNA-damaging agents target cancer cells over normal somatic cells. RESULTS: Arf/p53-dependent down-regulation of H2AX enables normal cells to survive after DNA damage. CONCLUSION: Transformed cells, which harbor mutations in either Arf or p53, are more sensitive to DNA-damaging agents. SIGNIFICANCE: Cellular transformation renders cells more susceptible to some DNA-damaging agents. Anti-cancer drugs generally target cancer cells rather than normal somatic cells. However, the factors that determine this differential sensitivity are poorly understood. Here we show that Arf/p53-dependent down-regulation of H2AX induced the selective survival of normal cells after drug treatment, resulting in the preferential targeting of cancer cells. Treatment with camptothecin, a topoisomerase I inhibitor, caused normal cells to down-regulate H2AX and become quiescent, a process mediated by both Arf and p53. In contrast, transformed cells that harbor mutations in either Arf or p53 do not down-regulate H2AX and are more sensitive to drugs unless they have developed drug resistance. Such transformation-associated changes in H2AX expression rendered cancer cells more susceptible to drug-induced damage (by two orders of magnitude). Thus, the expression of H2AX and γH2AX (phosphorylated form of H2AX at Ser-139) is a critical factor that determines drug sensitivity and should be considered when administering chemotherapy.
Entities:
Keywords:
ARF; Arf/p53 Module; Camptothecin; Cancer Chemotherapy; Cancer Therapy; Cell Biology; DNA Damage Response; H2AX; p53; γH2AX
Authors: Ander Matheu; Antonio Maraver; Peter Klatt; Ignacio Flores; Isabel Garcia-Cao; Consuelo Borras; Juana M Flores; Jose Viña; Maria A Blasco; Manuel Serrano Journal: Nature Date: 2007-07-19 Impact factor: 49.962
Authors: Jaclyn Quin; Keefe T Chan; Jennifer R Devlin; Donald P Cameron; Jeannine Diesch; Carleen Cullinane; Jessica Ahern; Amit Khot; Nadine Hein; Amee J George; Katherine M Hannan; Gretchen Poortinga; Karen E Sheppard; Kum Kum Khanna; Ricky W Johnstone; Denis Drygin; Grant A McArthur; Richard B Pearson; Elaine Sanij; Ross D Hannan Journal: Oncotarget Date: 2016-08-02