Abstract 1481: Srx-Prx IV axis is required for human lung cancer cell maintenance, migration, and invasion

Abstract

Abstract Sulfiredoxin (Srx) is a novel antioxidant protein that has been shown to reduce the hyper oxidized Peroxiredoxins (Prxs). Our previous study has demonstrated that Srx is required for tumor promoter induced cell transformation and is highly expressed in certain types of human skin cancers (Wei et al PNAS 2008). In this study, our goal is to further examine the expression of Srx in a broad range of human tumors and to explore its functional significance and molecular mechanisms in human cancer development. We found that Srx is highly expressed in several types of human lung cancers and its level is correlated with cancer malignancy and metastasis. Using human lung cancer A549 cell in culture, we found that knockdown of Srx significantly reduces anchorage independent growth in soft agar, cell migration in a wound-healing assay and cell invasiveness in a matrigel invasion assay. In an effort to discover downstream mediators of Srx-signaling pathway, we used affinity-based pull down and mass spectrometry methods to identify proteins that interact with Srx. To our surprise, Prx IV was found to be the most abundant protein that interacts with Srx in at least three different cell lines and the preferential interaction occurs independently of its expression levels. To characterize the Srx-Prx IV interaction, bacterial expressed recombinant Srx, Prx I, II, III and IV were individually purified. In an in vitro binding assay using Surface Plasmon Resonance technique, we confirmed that purified Srx has a much higher binding affinity to Prx IV than to Prx I, II or III. With a lentiviral based shRNA technology, each individual Prx was specifically knocked down in A549 cells. The phenotypic changes of these cells were compared to the Srx knockdown cells. We found that knockdown of Prx IV, but not other Prxs, was sufficient to recapitulate the attenuation of tumor phenotype and progression of Srx knockdown cells. In addition, we also confirmed that Prx IV undergoes rapid hyperoxidation in the presence of oxidative stress and is preferentially reduced by Srx in A549 cells. Overall our data indicate that Srx is highly expressed in human lung cancers and Srx-Prx IV axis is critical for human lung cancer cell maintenance, migration and invasion. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr 1481.