Development of a low-cost epigenetic screening assay for Pap specimen-based detection of early-stage ovarian cancer in high-risk women

PROJECT SUMMARY With a 5-year survival rate of only 47%, high-grade serous carcinoma (HGSC) remains the most lethal of all types of ovarian cancer. This is a particular concern for women with familial histories or BRCA mutations, who exhibit 20 to 35-fold higher risk of developing HGSC in their lifetime. The high mortality of the disease is largely

attributable to the fact that HGSC almost always remains undiagnosed until advanced stages when curative surgery is no longer feasible. Recently, numerous studies have demonstrated that most HGSCs likely originate in the fallopian tubes as precursor lesions called serous tubal intraepithelial carcinomas (STICs) that progress

over a period of 6-7-years before rapidly metastasizing to the ovary and surrounding tissues. This suggests there exists a critical window of time in which STIC lesions and early-stage tumors might be detected so that tumor progression can be effectively intercepted before reaching an incurable stage. Recent studies have held

out hope by showing that STIC and tumor cells are able to freely travel from the fallopian tubes to the cervix where they can be readily-detected in routinely-collected Pap specimens. Nonetheless, two notable challenges to this approach remain: (1) issues associated with the sensitivity and specificity of current biomarkers that

undermine test performance and (2) a cost-effective diagnostic technology with sufficient sensitivity to detect exceedingly-rare copies of biomarkers from early-stage HGSC in complex samples such as Pap specimens. In the present proposal, we seek to address both of these challenges by developing a new type of HGSC

screening assay called PapDREAM that is based on the sensitive, cost-effective detection of a novel set of epigenetic biomarkers that we have recently shown to be prevalently and specifically hypermethylated in both early, precursor (STIC) lesions and later-stage HGSC tumors. The PapDREAM assay will employ a unique,

digital methylation analysis technique called µ-DREAMing (microfluidic Discrimination of Rare EpiAlleles by Melt) that provides a simple, but highly-effective means of detecting and quantifying rare, aberrantly- methylated DNA, even in challenging samples such as stool, liquid biopsies and Pap specimens. A user-

friendly workflow based on common laboratory instrumentation will be developed to enable PapDREAM to be readily translated and performed in various research and clinical settings at a cost of only a few dollars per assay. Ultimately, the PapDREAM assay can be used alone or in combination with other assays to provide an

ideal screening method for women at high risk for developing HGSC. We have assembled a multi-disciplinary team with complementary expertise in gynecologic pathology, assay development and DNA methylation bioinformatics to accomplish this goal by achieving the following aims: (1) Evaluate and prioritize methylation biomarkers to be included in the PapDREAM assay, (2) Incorporate µ-

DREAMing assays into PapDREAM: a simple, multiplexed digital methylation assay for the detection of early- stage HGSC, and (3) Assess the clinical performance of the PapDREAM assay in Pap specimens.