PO-272 Optimisation of hypoxia regulated timed systems for genetic ablation and tracking of hypoxic breast cancer cells to study therapy resistance

Introduction Hypoxia plays a role in many types of cancer, and is linked to metastasis, genetic instability, resistance to therapy and poor prognosis. Hypoxic modification has been tested in clinical trials, but results have been inconclusive, in part due to a knowledge gap into the characterisation and behaviour of hypoxic tumour cells. In this project, hypoxic cells will be lineage traced to investigate their dissemination within the primary tumour and for their presence in circulating tumour cells and distant metastasis. To investigate the contribution of the hypoxic fraction to the tumour resistance, hypoxic cells will be specifically ablated, and the growth and response to treatment of tumours with and without this hypoxic population investigated. Material and methods To accomplish these aims, two complementary systems will be generated in the 4 T1 mouse mammary gland cell line, a model for stage IV metastatic human breast cancer. The first consists of a HIF-1α-CRE-ER TAM ‘hypoxia sensing’ construct coupled with a loxp DsRed loxp DTR-EGFP cassette (Diphtheria Toxin Receptor: DTR). Under normal conditions the HIF-1α-CRE-ER TAM fusion protein is expressed, but immediately degraded, but under hypoxia HIF-1α degradation is inhibited leading to accumulation. 4-OHT Administration translocates HIF-1α-CRE-ER TAM to the nucleus mediating loxp recombination in the coupled cassette. This allows lineage tracing of hypoxic cells and their progeny and selective ablation throught the DTR using Diphthteria toxin. Secondly, a DTR-UnaG-ODDD-HA construct (Oxygen-dependant degradation domain: ODDD), driven by the hypoxia dependent 5XHRE promoter will be used. This system allows ablation of hypoxic cells through the DTR and identification of hypoxic cells through the UnaG fluorescent protein. Only cells that are hypoxic at the time of administration/analysis will be labelled. Both cell lines will be transduced with luciferase to allow identification of distant metastasis. Results and discussions The two systems for this project have been generated and transduced into the 4 T1 cell line. Lineage tracing and selective ablation have been shown to work in vitro and clones are being characterised. In vitro experiments have shown the HIF-1α-CRE-ER TAM system to be extremely tightly regulated in an oxygen and tamoxifen dependant manner. Conclusion Once optimised, both systems will be used in an in vivo orthotopic mouse model to investigate the role of the hypoxic cells in breast cancer, metastasis and response to radiotherapy.