Effects of UVA light on Xeroderma Pigmentosum Variant patient cells

More than 95% of ultraviolet-light (UV) that reaches the Earth surface corresponds to UVA wavelengths (315-400 nm). UVA-light induces DNA damage through direct and indirect absorption of photons, as well as, intermediated by chromophores and by oxidation mechanisms. Xeroderma Pigmentosum Variant (XP-V) patients are defective in DNA polymerase η (pol eta) that performs translesion synthesis of sunlight induced DNA damage. Absence of pol eta results in increased mutagenesis, which is probably responsible for high frequency of skin cancer in XP-V patients. The goal of this work was to characterize the mechanisms of UVA-induced genome DNA damage and mutagenesis in cells derived from these patients. The results indicate that UVA irradiation increased cell death of XP-V compared to control cell line. The phosphorylation of the histone H2AX (generating γH2AX, an indicator of genotoxic stress) and DNA damage was highly increased in UVA irradiated XP-V cells. Curiously, however, in the absence of pol eta, there was a reduction in the capacity of cells to remove DNA damage from genome. Moreover, UVA irradiation triggered strong DNA synthesis blockage and cell cycle arrest in S phase, resulting in important responses mediated by the ATR/Chk1 pathway in XP-V cells. Interestingly, the antioxidant N-acetyl cysteine (NAC) resulted in decreased cell sensitivity, γH2AX levels, fork stalling and cell cycle arrest, reduced the cytotoxic effect of ATR inhibition, improved DNA repair and prevented the protein carbonylation in XP-V cells irradiated with UVA. The mutagenesis by UVA-light was also investigated by exome DNA sequencing of cellular clones. The data indicated a significative increase of mutagenesis in XP-V irradiated cells compared to control cells, and the identification of mutation types indicated a high increase of C>T transitions, probably as result of error-prone replication of pyrimidine dimers. Nevertheless, the induction of C>A transversions were also detected, probably due to oxidized DNA damage. Curiously, when XP-V and control cells were compared, in the absence of irradiation, these transversions were also detected, maybe due to endogenous oxidation of DNA. In addition, in silico analyses showed that UVA-irradiated XP-V cells had a mutation signature similar to the observed for skin cancer. The data demonstrate XP-V cells are sensitive to UVA-light and DNA damage, including by oxidative stress, trigger cell responses and induce mutagenesis in these patients. Therefore, besides showing that UVA-irradiation may generate deleterious effects in the skin of XP-V patients, the data also contribute to understand how these light wavelengths may damage human cells in general (AU)