Adenovirus mediated transduction of the human DNA polymerase eta cDNA

Keronninn Moreno Lima-Bessa, Vanessa Chiganças, Anne Stary, Patricia Kannouche, Alain Sarasin, Melissa Gava Armelini, Jacqueline de Fátima Jacysyn, Gustavo P. Amarante-Mendes, Marila Cordeiro-Stone, James E. Cleaver, Carlos Frederico Martins Menck

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    Résumé

    Xeroderma pigmentosum (XP) is an autosomal recessive photosensitive disorder with an extremely high incidence of skin cancers. Seven complementation groups, corresponding to seven proteins involved in nucleotide excision repair (NER), are associated with this syndrome. However, in XP variant patients, the disorder is caused by defects in DNA polymerase η; this error prone polymerase, encoded by POLH, is involved in translesion DNA synthesis (TLS) on DNA templates damaged by ultraviolet light (UV). We constructed a recombinant adenovirus carrying the human POLH cDNA linked to the EGFP reporter gene (AdXPV-EGFP) and infected skin fibroblasts from both XPV and XPA patients. Twenty-four hours after infection, the DNA polymerase η-EGFP fusion protein was detected by Western blot analysis, demonstrating successful transduction by the adenoviral vector. Protein expression was accompanied by reduction in the high sensitivity of XPV cells to UV, as determined by cell survival and apoptosis-induction assays. Moreover, the pronounced UV-induced inhibition of DNA synthesis in XPV cells and their arrest in S phase were attenuated in AdXPV-EGFP infected cells, confirming that the transduced polymerase was functional. However, over-expression of polymerase η mediated by AdXPV-EGFP infection did not result in enhancement of cell survival, prevention of apoptosis, or higher rate of nascent DNA strand growth in irradiated XPA cells. These results suggest that TLS by DNA polymerase η is not a limiting factor for recovery from cellular responses induced by UV in excision-repair deficient fibroblasts.

    langue originaleAnglais
    Pages (de - à)925-934
    Nombre de pages10
    journalDNA Repair
    Volume5
    Numéro de publication8
    Les DOIs
    étatPublié - 13 août 2006

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