Abstract
Transplantable murine models of ovarian high grade serous carcinoma (HGSC) remain an important research tool. We previously showed that ID8, a widely-used syngeneic model of ovarian cancer, lacked any of the frequent mutations in HGSC, and used CRISPR/Cas9 gene editing to generate derivatives with deletions in Trp53 and Brca2. Here we have used one ID8 Trp53−/− clone to generate further mutants, with additional mutations in Brca1, Pten and Nf1, all of which are frequently mutated or deleted in HGSC. We have also generated clones with triple deletions in Trp53, Brca2 and Pten. We show that ID8 Trp53−/−;Brca1−/− and Trp53−/−;Brca2−/− cells have defective homologous recombination and increased sensitivity to both platinum and PARP inhibitor chemotherapy compared to Trp53−/−. By contrast, loss of Pten or Nf1 increases growth rate in vivo, and reduces survival following cisplatin chemotherapy in vivo. Finally, we have also targeted Trp53 in cells isolated from a previous transgenic murine fallopian tube carcinoma model, and confirmed that loss of p53 expression in this second model accelerates intraperitoneal growth. Together, these CRISPR-generated models represent a new and simple tool to investigate the biology of HGSC, and the ID8 cell lines are freely available to researchers.
Highlights
Transplantable murine models of ovarian high grade serous carcinoma (HGSC) remain an important research tool
We show that ID8 Trp53−/−;Brca1−/− and Trp53−/−;Brca2−/− cells have defective homologous recombination and increased sensitivity to both platinum and PARP inhibitor chemotherapy compared to Trp53−/−
CRISPR/Cas[9] Brca[1], Nf1 and Pten editing in ID8 cells
Summary
Transplantable murine models of ovarian high grade serous carcinoma (HGSC) remain an important research tool. We have targeted Trp[53] in cells isolated from a previous transgenic murine fallopian tube carcinoma model, and confirmed that loss of p53 expression in this second model accelerates intraperitoneal growth Together, these CRISPR-generated models represent a new and simple tool to investigate the biology of HGSC, and the ID8 cell lines are freely available to researchers. New genetically engineered mouse models (GEMM) of HGSC have been developed[11,12], in which Trp[53], Brca[1], Brca[2], Pten and Nf1 have been deleted in fallopian tube epithelial cells using Cre-mediated recombination. Using CRISPR/Cas[9] gene editing, we generated four Trp53−/− and two Trp53−/−;Brca2−/− ID8 clones and characterised their intraperitoneal growth[14]
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