| Project Detail |
Engineered B cell immunotherapy in cancer treatment
In vivo B cell engineering to express therapeutic antibodies represents a safe and efficient method for the treatment of many conditions, including cancer. The presence of the tumour-specific B cells and anti-tumour antibodies in the plasma correlate with a favourable prognosis and response to treatment with checkpoint inhibitors in sarcomas and carcinomas. The EU-funded EngineerBcells project will develop a novel engineered B cell-based cancer immunotherapy using CRISPR/Cas9 and adeno-associated viral vectors to integrate the anti-tumour antibody genes into the IgH locus. The localised activation of engineered B cells will be demonstrated and evaluated in diverse tumour models. B cells will be co-engineered to secrete additional immune effectors upon activation.
B cells have an important role in the immune response against cancer. Tumor specific B cells in tertiary lymphoid structures and anti-tumor antibodies in the plasma are associated with a favorable prognosis and with an improved response to checkpoint inhibition in different sarcomas and carcinomas. Antigen specific B cells home to tumors and prolong survival in mice, while B cell based vaccines allow durable anti-tumor activity in cervical cancer patients. We have recently demonstrated both ex vivo and in vivo B cell engineering for the expression of anti-HIV antibodies. Here, we propose a novel cancer immunotherapy approach based on engineered B cells. In particular, we use CRISPR/Cas9 and AAV to target the integration of anti-tumor antibody genes into the IgH locus. In diverse tumor models, we plan to demonstrate localized B cell activation upon antigen engagement. The B cells will exert multiple anti-tumor effects. Secreted antibodies will induce ADCC, CDC and ADCP. In addition, a polyclonal T cell response with epitope spreading will be facilitated by engineered B cells acting as APCs as well as by antibodies forming immune complexes to be taken up by dendritic cells and macrophages for cross-presentation. The B cell will be co-engineered to locally secrete additional immune effectors upon activation. These include: stimulatory cytokines, BiTEs, checkpoint inhibitors, CD40/27 agonists and cell penetrating nanobodies. Localized secretion is predicted to increase efficacy while reducing systemic toxicities. When targeting self-antigens, B cells will be engineered to co-express a CAR, relaying CD40 or TLR signals for T cell independent B cell activation and allowing allogeneic therapy. We will further demonstrate in vivo B cell engineering for increased scalability, and ensure safety using a suicide cassette for inducible B cell elimination. B cell engineering is thus a flexible and robust platform technology that may revolutionize cancer immunotherapy. |
