Immunomodulatory alpha neutrophils: The first-in-class neutrophil progenitor-based allogeneic immuno-cell therapy with cytotoxic and immunomodulatory functionality for the treatment of solid tumours.

Abstract

e14523 Background: Adoptive cell therapy for the treatment of cancer has largely focused on the administration of autologous engineered αβ T cells. Although successful in some haematological malignancies, the solid tumour microenvironment (TME) poses significant challenges to the efficacy of CAR-T cells, including physical barriers, heterogeneous antigen expression or antigen escape and immunosuppressive mediators. Remodeling the immunosuppressive solid TME is pivotal to the success of immunotherapies. Recent studies have highlighted key roles for neutrophils in tumour control and in facilitating successful responses to cancer immunotherapy, with neutrophil functional heterogeneity within the TME becoming increasingly appreciated. Methods: At LIfT Biosciences we have developed the first-in-class, stem cell-derived immuno-cell therapy with anti-cancer neutrophil properties called Immunomodulatory Alpha Neutrophils (IMANs). IMANs are derived from CD34+ stem cells expanded and differentiated in proprietary media compositions in a simple and scalable GMP-compliant manufacturing process. IMANs are designed to recapitulate those neutrophil states that are both cytotoxic and capable of immunomodulating the solid TME for long-lasting tumour control. Off-the-shelf, allogeneic, innate IMANs have the potential to provide major clinical benefits in the treatment of multiple solid tumours. Results: IMANs multimodal mechanisms of action (MoA) have been demonstrated in different state-of-the-art solid tumour models, including co-culture with patient-derived xenograft organoids (PDX-O) and with 3D ex vivo patient tissues (tumour-on-a-chip). Direct antigen-independent cytotoxicity towards PDX-O from a range of solid tumour indications has been demonstrated. Additionally, and fundamental to IMANs MoA is their ability to migrate to the solid TME and recruit and activate recipients’ anti-tumour immune responses. We have demonstrated IMANs ability to rapidly migrate into the solid TME and promote recruitment of patients’ immune cells leading to enhanced tumour cell death using tumour-on-a-chip technology accompanied by daily live cell imaging. Mechanistically, co-culture with IMANs enhanced expression of co-stimulatory receptors on T and NK cells, such as OX40 and 4-1BB, as well as promoting secretion of TME-modulating factors, such as CXCL10. Furthermore, co-culture with IMANs enhanced secretion of IFN-γ by activated tumour-infiltrating lymphocytes. Conclusions: These cytotoxic and immunomodulatory functions enable IMANs to remodel the TME, leaving the solid tumour more susceptible to host immune responses.