Posttranslational modification of transcription factors controlling oocyte growth and differentiation
Role of SUMOylation in mammalian meiosis
Function of the BMP family in ovary development
Mouse models of female infertility
Development of novel non-invasive diagnostics for early ovarian cancer detection
Novel Non-Invasive Detection of Ovarian Cancer
Ovarian cancer is the fifth most common cancer in women and is responsible for the most gynecological disease-related deaths. The majority of cases are not detected until late stage disease when prognosis is poor, partly due to vague and subtle symptoms such as bloating, constipation, feeling full quickly, abdominal and pelvic pain. Current biomarkers used clinically have been largely ineffective at detecting early stage ovarian cancer. Therefore, the discovery of novel early detection methods are greatly needed. Our lab is currently exploring different methodologies to detect ovarian cancer biomarkers in multiple biofluids and tissues. We hope that such techniques will not only reduce the morbidity and mortality of this disease, but also decrease stress and concern for women undergoing evaluation for common symptoms of ovarian cancer.
TGFbeta Signaling in Juvenile Granulosa Cell Tumors of the Ovary
Juvenile granulosa cell tumors of the ovary are sex cord-stromal tumors that are poorly understood and treatment regimes are not well defined. The majority of juvenile granulosa cell tumors affect girls younger than 20 years of age. Our lab utilizes mouse models of the disease, as well as human cell lines, to investigate aberrations in the transforming growth factor beta (TGFbeta) signaling pathway that drive the development and growth of these tumors. By understanding the mechanisms of tumorigenesis, we can develop better targeted therapies for the treatment of this cancer.
Determine the Expression Pattern of BMP Signaling in the Developing and Adult Reproductive Tract
Bone morphogenetic protein signaling is an essential pathway for the development of many organisms. BMPs have also been identified to regulate fertility. However, the exact patterning of BMP signaling in the developing reproductive tract is unknown. We are using a GFP promoter mouse to monitor BMP activity in the developing reproductive tract. By knowing which cells respond to BMPs, we will be better positioned to determine the normal versus pathologic roles of BMPs in our other mouse mutants that have defective BMP signaling.
Also, we will be able to design specific interventions for particular cell targets as novel therapeutics or to assist with artificial reproductive technologies.