The role of Nrf2 in increased reactive oxygen species and DNA damage in prostate tumorigenesis.

The impact of oxidative stress in human cancer has been extensively studied. It is accepted that elevated reactive oxygen species (ROS) promote mutagenic DNA damage. Even with an extensive armament of cellular antioxidants and detoxification enzymes, alterations to DNA occur that initiate cellular transformation. Erythroid 2p45 (NF-E2)-related factor 2 (Nrf2) is a basic-region leucine zipper transcription factor that mediates the expression of key protective enzymes through the antioxidant-response element (ARE). By analysing 10 human prostate cancer microarray data sets, we have determined that Nrf2 and members of the glutathione-S-transferase (GST) mu family are extensively decreased in human prostate cancer. Using the TRAMP transgene and Rb and Nrf2 knockout murine models, we demonstrated that the loss of Nrf2 initiates a detrimental cascade of reduced GST expression, elevated ROS levels and ultimately DNA damage associated with tumorigenesis. Based on overwhelming data from clinical samples and the current functional analysis, we propose that the disruption of the Nrf2-antioxidant axis leads to increased oxidative stress and DNA damage in the initiation of cellular transformation in the prostate gland.

Human polyomavirus BKV transcriptionally activates DNA methyltransferase 1 through the pRb/E2F pathway.

Many DNA tumor virus oncogenes are capable of activating and highjacking the host cell's DNA replication machinery for its own reproduction purposes through targeting and inactivation of the retinoblastoma pocket protein family. Pocket proteins function to regulate cell cycle progression and DNA synthesis through inhibitory interactions with the E2F transcription factors. The interaction of viral oncogenes with the pocket proteins is crucial for their transforming activity. We recently demonstrated that the DNA methyltransferase 1 (DNMT1) gene is an E2F target gene that is transcriptionally activated in cells lacking the retinoblastoma gene (Rb-/-). Overexpression of DNMT1 is implicated in tumor suppressor gene hypermethylation which is associated with tumorigenesis. Given that viral oncogenes potently stimulate E2F activity, we hypothesized that viral infection might activate DNMT1 and thereby promote transformation. Herein, we demonstrate that DNMT1 is strongly activated by the human polyomavirus BKV large T antigen (TAg) and adenovirus E1a. Viral oncogene mutants incapable of binding the pocket proteins are ineffective at activating DNMT1 compared to their wild-type counterparts. Additionally, mutation of the E2F sites within the DNMT1 promoters dramatically abrogates transcriptional activation. These data suggest that viral induction of DNMT1 through modulation of the pRB/E2F pathway may be involved in viral transformation.