Abstract: The present application relates to the field of immunotherapy, more particularly to the field of chimeric antigen receptors (CARs). Currently, second and third generation CAR designs are quite rigid in that they combine fixed costimulatory domains in cis on the same intracellular protein domain. Trans signaling is not equivalent as costimulatory receptors have different expression levels or stoichiometry. Here, a ‘mix and match’ approach is proposed where different signaling and costimulatory domains are present on separate chains within the same CAR complex, allowing increased flexibility and control of the nature and strength of the CAR-generated signal. Also proposed are polynucleotides, vectors encoding the transmembrane polypeptide chains and cells expressing such CARs. These cells are particularly suitable for use in immunotherapy, and strategies to treat diseases such as cancer using these cells are also provided.

Abstract: The present application relates to the field of immunotherapy, more particularly to the field of chimeric antigen receptors (CARs). Currently, second and third generation CAR designs are quite rigid in that they combine fixed costimulatory domains in cis on the same intracellular protein domain. Trans signaling is not equivalent as costimulatory receptors have different expression levels or stoichiometry. Here, a ‘mix and match’ approach is proposed where different signaling and costimulatory domains are present on separate chains within the same CAR complex, allowing increased flexibility and control of the nature and strength of the CAR-generated signal. Also proposed are polynucleotides, vectors encoding the transmembrane polypeptide chains and cells expressing such CARs. These cells are particularly suitable for use in immunotherapy, and strategies to treat diseases such as cancer using these cells are also provided.

Abstract: The present application relates to the field of immunotherapy, more particularly to the field of chimeric antigen receptors (CARs). Here, CARs are proposed that are directed against B-cell Maturation Antigen (BCMA, also known as CD269). Also proposed are polynucleotides, vectors encoding the transmembrane polypeptide chains and cells expressing such CARs. These cells are particularly suitable for use in immunotherapy, and strategies to treat diseases such as cancer using these cells are also provided. The engineered immune cells, such as T-cells or natural killer (NK) cells, expressing such CARs are particularly suitable for treating lymphomas, multiple myeloma and leukemia.

Abstract: The present application relates to the field of immunotherapy, more particularly to the field of chimeric antigen receptors (CARs). Currently, second and third generation CAR designs are quite rigid in that they combine fixed costimulatory domains in cis on the same intracellular protein domain. Trans signaling is not equivalent as costimulatory receptors have different expression levels or stoichiometry. Here, a ‘mix and match’ approach is proposed where different signaling and costimulatory domains are present on separate chains within the same CAR complex, allowing increased flexibility and control of the nature and strength of the CAR-generated signal. Also proposed are polynucleotides, vectors encoding the transmembrane polypeptide chains and cells expressing such CARs. These cells are particularly suitable for use in immunotherapy, and strategies to treat diseases such as cancer using these cells are also provided.