The present invention provides a chimeric cytokine receptor (CCR) comprising: (i) an exodomain which binds to a ligand selected from a tumour secreted factor, a chemokine and a cell-surface antigen; and (ii) a cytokine receptor endodomain.

The present invention provides a cell which comprises a first chimeric antigen receptor (CAR) and a second CAR, wherein the first and second CARs bind different epitopes on the same ligand. The cell may be used in a method for treating a disease, such as cancer.

The present disclosure provides compositions, including modified peripheral blood mononuclear cells (PBMCs) with reduced expression of Slc16a11 and/or reduced activity of MCT11. Also provided are siRNAs and gRNAs targeting Slc16a11. Methods of using the disclosed compositions in the treatment of cancer are also provided.

The present invention provides a chimeric cytokine receptor (CCR) comprising: (i) an exodomain which binds to a ligand selected from a tumour secreted factor, a chemokine and a cell-surface antigen; and (ii) a cytokine receptor endodomain.

Compositions and methods are disclosed herein for producing one or more immunoglobulins in an isolated cytotoxic B lymphocyte cell line. An isolated cell line includes an isolated B lymphocyte cell line capable of expressing at least one exogenously incorporated membrane immunoglobulin capable of binding to a first antigen and at least one endogenous secreted immunoglobulin capable of binding to a second antigen, and further capable of expressing at least one exogenously incorporated recombinant B cell receptor that signals for expression of cytotoxic effector molecules.

The present invention relates to the field of cancer. More specifically, the present invention provides compositions and methods for using synthetically enhanced T-cells to treat cancer. The present invention also provides a T-cell engineered (a) to express at least one CAR that binds tumor antigens; and (b) to inducibly express a prostate-specific antigen (PSA)-activated pro-aerolysin (PA) upon tumor antigen recognition by CAR.

Described herein is a reliable method for preparing a potent vaccine useful for immunotherapy comprising the step of cryopreserving a population of cells undergoing immunogenic cell death, and using such cells to activate dendritic cells for use in immunotherapy. In a specific embodiment, the method comprises cryopreserving cancer cells undergoing cell death, which can be used to prepare a pharmaceutical composition for immunotherapy against cancer.

Compositions and methods are disclosed herein for producing one or more immunoglobulins in an isolated B lymphocyte cell line. An isolated recombinant cell line includes an isolated B lymphocyte cell line capable of expressing at least one endogenous membrane immunoglobulin reactive to a first antigen and at least one exogenously incorporated nucleic acid encoding at least one secreted immunoglobulin reactive to a second antigen.

Described herein is a reliable method for preparing a potent vaccine useful for immunotherapy comprising the step of cryopreserving a population of cells undergoing immunogenic cell death, and using such cells to activate dendritic cells for use in immunotherapy. In a specific embodiment, the method comprises cryopreserving cancer cells undergoing cell death, which can be used to prepare a pharmaceutical composition for immunotherapy against cancer.

Disclosed herein are genetically engineered T cell receptors, and methods, vectors, and genetically engineered T cells related to genetically engineered T cell receptors.