High-grade serous endometrial carcinoma (HGSEC) accounts for just 10% of endometrial cancer (EC) cases but is responsible for at least 40% of all EC-related deaths. It typically arises in post-menopausal women, with 70% of patients presenting with stage III or IV disease, does not respond to hormone therapy unlike the less aggressive forms of EC, and has a lower overall survival rate of just 18-27%, which has not improved over the past two decades. The primary treatment for HGSEC is surgery, followed by a combination of standard chemotherapies (platinum and taxane) with or without localised radiotherapy. However, recurrent HGSEC is less responsive to chemotherapy than are other subtypes of EC and even initial responses to chemotherapy are poor. Therefore, there is a great unmet clinical need to find better treatment options for women with this aggressive cancer. Apart from TP53 (mutated in up to 90% of cases), the other most frequently mutated genes in HGSEC are PPP2R1A (31%), PIK3CA (22%), FBXW7 (28%), CHD4 (17%) and BRCA2 (12%). Focal amplifications of the genes MYC, ERBB2, CCNE1, FGFR3 and SOX17 are also common. The presence of ERBB2 amplification and/or HER2 over-expression in around 30% of HGSEC suggests these patients may respond to HER2-targeting drugs, such as trastuzumab. However, only modest benefit has so far been seen for single-agent HER2-targeted therapies (ie trastuzumab or lapatinib) against HGSEC, suggesting resistance mechanisms are present. Another feature of HGSEC that could be exploited therapeutically is homologous recombination deficiency (HRD), which may be targeted with PARP inhibitors (PARPi). It is not clear what proportion of HGSEC are HRD and neither HER2-targeting drugs or PARPi have been approved for the treatment of HGSEC. Due to its rarity and a lack of pre-clinical models, HGSEC has so far been understudied, resulting in a lack of effective treatment options. We currently have 33 HGSEC patients consented to the WEHI-Stafford Fox Rare Cancer Program and have developed pre-clinical models from fresh patient tumour samples received (4 patient-derived xenograft (PDX) models validated, with 3 pending). Preliminary molecular analysis of whole-genome sequencing (5 samples, one of which gave rise to a PDX model), whole-exome sequencing (4 samples), and cancer panel sequencing (3 samples, 2 of which gave rise to PDX models; one harbouring ERBB2 amplification and one harbouring an AKT mutation) data from our HGSEC cohort has been performed. This has identified potential treatment targets, including ERBB2 amplifications and mutations in HR genes. I am using the PDX models for initial in vivo therapeutic characterization studies and to develop organoid models for use in high-throughput drug assays in vitro. This will guide subsequent novel drug combination testing in our PDX models. By combining specific targeted drugs I hope to overcome de novo resistance mechanisms and prevent acquired resistance. Results from this study will guide future decisions about therapeutic strategies to improve survival of women with HGSEC.

Citation Format: Holly E. Barker, Ratana Lim, Amandine Carmagnac, Cassandra Vandenberg, Gayanie Ratnayake, Genevieve Dall, Briony Milesi, Angela Komiti, Emily O'Grady, Joshua Tram, Kym Pham Stewart, Justin Bedo, Jocelyn Penington, Joep Vissers, Sean Grimmond, Matthew Wakefield, Tony Papenfuss, Clare Scott. Identifying effective combinations of targeted therapies, using novel pre-clinical models, to improve treatment options for high-grade serous endometrial cancer [abstract]. In: Proceedings of the AACR Virtual Special Conference: Endometrial Cancer: New Biology Driving Research and Treatment; 2020 Nov 9-10. Philadelphia (PA): AACR; Clin Cancer Res 2021;27(3_Suppl):Abstract nr PO037.