Thioredoxin system-mediated regulation of mutant Kras associated pancreatic neoplasia and cancer.

Peroxiredoxin-1 (Prdx1), a member of the thioredoxin (Txn) system, is overexpressed and correlates with poor prognosis in pancreatic cancer patients and can suppress Kras signaling through redox-mediated inhibition of ERK and AKT in lung and breast cancer. Its redox function is maintained by Txn and sulfiredoxin (Srxn), and its tumor promoting functions are activated by post-translational modification. We studied the role of the Txn system in pancreatic neoplasia and cancer by determining how it regulates the phosphorylation of Kras effectors and by determining its association with patient survival. We found that elevated Prdx1 nuclear localization significantly correlated with better patient survival. Our data also demonstrate that the expression of the Txn system is dysregulated, with elevated Prdx1 expression and significantly decreased Txn and Srxn expression in pancreatic lesions of targeted mutant Kras mouse models. This correlated with distinct differences in the interconversion of Prdx1 oligomers that affect its ability to regulate ERK and AKT phosphorylation. Our data also suggest that Prdx1 post-translational modification and oligomerization suppress Prdx1 mediated redox regulation of ERK phosphorylation. We observed distinct differences in Txn expression and in the ability of pTyr-Prdx1 to bind to pERK in a PanIN model of pancreatic neoplasia as compared to an IPMN model, indicating a distinct difference in the function of post-translationally modified Prdx1 in cells with less Txn expression. Modified Txn system function and post-translational regulation may therefore play a significant role in pancreatic tumorigenesis by altering Kras effector phosphorylation and inhibiting the tumor suppressive redox functions of Prdx1.

Nrf1 and Nrf2 transcription factors regulate androgen receptor transactivation in prostate cancer cells.

Despite androgen deprivation therapy (ADT), persistent androgen receptor (AR) signaling enables outgrowth of castration resistant prostate cancer (CRPC). In prostate cancer (PCa) cells, ADT may enhance AR activity through induction of oxidative stress. Herein, we investigated the roles of Nrf1 and Nrf2, transcription factors that regulate antioxidant gene expression, on hormone-mediated AR transactivation using a syngeneic in vitro model of androgen dependent (LNCaP) and castration resistant (C4-2B) PCa cells. Dihydrotestosterone (DHT) stimulated transactivation of the androgen response element (ARE) was significantly greater in C4-2B cells than in LNCaP cells. DHT-induced AR transactivation was coupled with higher nuclear translocation of p65-Nrf1 in C4-2B cells, as compared to LNCaP cells. Conversely, DHT stimulation suppressed total Nrf2 levels in C4-2B cells but elevated total Nrf2 levels in LNCaP cells. Interestingly, siRNA mediated silencing of Nrf1 attenuated AR transactivation while p65-Nrf1 overexpression enhanced AR transactivation. Subsequent studies showed that Nrf1 physically interacts with AR and enhances AR's DNA-binding activity, suggesting that the p65-Nrf1 isoform is a potential AR coactivator. In contrast, Nrf2 suppressed AR-mediated transactivation by stimulating the nuclear accumulation of the p120-Nrf1 which suppressed AR transactivation. Quantitative RT-PCR studies further validated the inductive effects of p65-Nrf1 isoform on the androgen regulated genes, PSA and TMPRSS2. Therefore, our findings implicate differential roles of Nrf1 and Nrf2 in regulating AR transactivation in PCa cells. Our findings also indicate that the DHT-stimulated increase in p65-Nrf1 and the simultaneous suppression of both Nrf2 and p120-Nrf1 ultimately facilitates AR transactivation in CRPC cells.

Loss of Nrf2 accelerates ionizing radiation-induced bone loss by upregulating RANKL.

Radiation therapy is an integral part of treatment for cancer patients; however, major side effects of this modality include aberrant bone remodeling and bone loss. Ionizing radiation (IR) is a major external factor that contributes to a significant increase in oxidative stress such as reactive oxygen species (ROS), has been implicated in osteoporotic phenotypes, and has been implicated in osteoporotic phenotypes, bone loss, and fracture risk. One of the major cellular defenses against heightened oxidative stress is mediated by nuclear factor (erythroid-derived 2)-like 2 (Nrf2), a master transcription factor that regulates induction of antioxidant gene expression and phase II antioxidant enzymes. Our objective was to test the hypothesis that loss of functional Nrf2 increases radiation-induced bone loss. We irradiated (single dose, 20Gy) the hindlegs of age- and sex-matched Nrf2(+/+) and Nrf2(-/-) mice. After 1 month, microCT analysis and histology revealed a drastic overall decrease in the bone volume after irradiation of mice lacking Nrf2. Although radiation exposure led to bone loss in mice with intact Nrf2, it was dramatically enhanced by loss of Nrf2. Furthermore, in the absence of Nrf2, a decrease in osteoblast mineralization was noted in calvarial osteoblasts compared with wild-type controls, and treatment with a common antioxidant, N-acetyl-l-cysteine (NAC), was able to rescue the mineralization. As expected, we observed a higher number of osteoclasts in Nrf2(-/-) mice compared to Nrf2(+/+) mice, and after irradiation, the trend remained the same. RT-PCR analysis of calvarial osteoblasts revealed that in the absence of Nrf2, the expression of RANKL was increased after irradiation. Interestingly, RANKL expression was suppressed when the calvarial osteoblasts were treated with NAC before IR exposure. Taken together, our data suggest that loss of Nrf2 leads to heightened oxidative stress and increased susceptibility to radiation-induced bone loss.

The nrf1 and nrf2 balance in oxidative stress regulation and androgen signaling in prostate cancer cells.

Reactive oxygen species (ROS) signaling has recently sparked a surge of interest as being the molecular underpinning for cancer cell survival, but the precise mechanisms involved have not been completely elucidated. This review covers the possible roles of two ROS-induced transcription factors, Nrf1 and Nrf2, and the antioxidant proteins peroxiredoxin-1 (Prx-1) and Thioredoxin-1 (Txn-1) in modulating AR expression and signaling in aggressive prostate cancer (PCa) cells. In androgen independent (AI) C4-2B cells, in comparison to the parental androgen dependent (AD) LNCaP cells, we present evidence of high Nrf1 and Prx-1 expression and low Nrf2 expression in these aggressive PCa cells. Furthermore, in DHT treated C4-2B cells, increased expression of the p65 (active) isoform of Nrf1 correlated with enhanced AR transactivation. Our findings implicate a crucial balance of Nrf1 and Nrf2 signaling in regulating AR activity in AI-PCa cells. Here we will discuss how understanding the mechanisms by which oxidative stress may affect AR signaling may aid in developing novel therapies for AI-PCa.