Abstract 3276: A novel in vivo xenograft mouse model of human high-grade serous ovarian cancer, with clinical, molecular and functional annotation relevant for pre-clinical analysis

Abstract

Abstract Background: The five year survival rate for women with ovarian cancer (OC) is less than 40%. Crucial to improving the outcomes for ovarian cancer patients is the development of accurate pre-clinical models of human epithelial OC, which can be used to unravel the mechanisms underlying its evolution and behaviour. Methods: We have generated a novel xenograft model of human high-grade serous OC (HG-SOC) in order to enable preclinical molecular and drug response assessment of individual HG-SOC: this includes a comparison of standard OC xeno-transplantion approaches (intra-peritoneal, subcutaneous and sub renal capsular), with the novel use of the rodent ovarian bursa, the orthotopic site. Utilising the rodent bursa may better replicate the relevant microenvironment and increase the success of EOC xeno-transplantion. Other aspects designed to optimize the model include the use of NOD-SCID-IL-2rg recipient mice, systemic estrogen supplementation and transplantation of fresh human HG-SOC fragments which have had no prior in vitro culture. Histological, functional and molecular analysis of the novel xenograft cohort (at baseline and following xenotransplantation) includes histological review; documentation of in vitro Homologous Recombination (HR) DNA repair and drug response capabilities (using novel α-irradiation and explant drug assays); classification according to molecular subtype (Tothill classfier); documentation of NHEJ pathway status, BRCA1/2 status and other DNA repair gene status. In vivo drug treatment studies are being performed, with the choice of treatment targeted to the specific molecular characteristics of the HG-SOC in question. Results: Fourteen consecutive chemotherapy naive potentially HG-SOC samples have been collected. Corresponding clinical data has been collected. Data concerning DNA repair capability and response to DNA damaging agents will be presented, including IHC for markers of DNA damage (γH2AX), DNA repair (RAD51) and apoptosis (capsase 3 cleavage). HG-SOC in this cohort have been classified according to Tothilll (Tothill et al 2008). Eight appropriate HG-SOC have been transplanted and 5 of the first 6 have successfully xenografted, with phenotyping of xenografts underway. In vivo analysis of response to cisplatin treatment and other relevant therapeutics will be presented. Conclusions: A novel xenograft model has been developed of human HG-SOC, which includes comparative characterization of important prognostic features both in the baseline panel of fresh human HG-SOC and in subsequent xenografts. This clinically, functionally and molecularly annotated consecutive xenograft cohort of HG-SOC will provide outstanding utility for the development of improved therapeutic approaches. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr 3276. doi:1538-7445.AM2012-3276