Binding of Intracellular Myeloperoxidase to αV/ß1 Integrin Serves as a Mechanism of Survival in Epithelial Ovarian Cancer.

We were the first to report that epithelial ovarian cancer (EOC) cells and tissues express myeloperoxidase (MPO) that is known to play a role in immune surveillance and inflammation by myeloid cells. Additionally, we reported that MPO is colocalized with inducible nitric oxide synthase (iNOS), a key pro-oxidant enzyme, and plays a key role in regulating apoptosis in EOC cells. Whereas myeloid cells express MPO in a dimeric form, intriguingly, here we report the unique expression of only the monomeric form of MPO in EOC cells, tissues, and blood of an ovarian cancer patient. Additionally, we have identified a cell membrane receptor, αV/ß1 integrin, that is uniquely expressed by both chemosensitive and chemoresistant EOC cells with significantly higher expression in chemoresistant EOC cells. More importantly, we have demonstrated that monoclonal antibodies against αV/ß1 integrin induced cytotoxicity in EOC cells, but not in normal cells, that is also synergistic with conventional chemotherapies. Cytotoxicity of αV/ß1 antibodies is due to conformational changes in αV/ß1 integrin which prevents monomeric MPO binding to αV/ß1 integrin inhibiting the activation of MPO, leading to increased apoptosis. Since normal epithelial cells and macrophages lack monomeric MPO and αV/ß1 integrin system, targeting this unique MPO-dependent survival mechanism will selectively eliminate EOC cells and will be the target for developing specific ovarian cancer therapies.

Epigenetics: new insights into postoperative adhesion development.

BACKGROUND: The link between post-operative adhesion development and epigenetic modifications is important in understanding the mechanism behind their formation. The purpose of this study was to determine whether epigenetic differences exist between primary fibroblasts of normal peritoneum and adhesion tissues isolated from the same patient(s). METHODS: DNA from fibroblasts isolated from normal peritoneum and adhesion tissues was isolated using Qiagen's EZ1 Advanced Kit. Methylation patterns of genes were quantified and compared in both cell lines using the Infinium Human Methylation 27 Beadchip system. RESULTS: A total of 7364 genes had been found to manifest significantly different DNA methylation levels in adhesion fibroblasts as compared to normal peritoneal fibroblasts (p<0.01). A total of 1685 genes were found to have increased DNA methylation by 50% in adhesion compared to peritoneal fibroblasts, and were enriched in Gene Ontology categories, Glycoprotein, and Defense Response. Furthermore, 1287 genes were found to have decreased DNA methylation patterns with enriched Gene Ontology categories, "Homeobox", and Transcription Factor Activity in adhesion fibroblasts. CONCLUSIONS: Epigenetic differences in fibroblasts isolated from normal peritoneum and adhesion tissues were observed. Future studies focusing on the precise role of these genes in the development of post operative adhesions will allow us to more fully appreciate regulatory mechanisms leading to adhesion development, thereby establishing targets for therapeutic interventions to prevent or limit adhesion development.