The present disclosure provides compositions and methods for delivering a nucleic acid sequence encoding a chimeric antigen receptor (CAR) to an immune cell using a retroviral vector comprising an optimized Cocal vesiculovirus envelope protein.

The present disclosure provides hybrid promoter sequences comprising an MND promoter and HTLV enhancer capable of driving high levels of sustained expression of a heterologous sequence in immune cells, particularly Natural Killer (NK) cells. The disclosure also provides compositions comprising such vectors, immune cells which have been genetically modified to contain the vectors, as well as methods of using the same for inducing immune responses and treating cancer and other conditions.

Provided herein is a chimeric antigen receptor (CAR) and CAR-expressing immune cells that target human RORI expressed aberrantly on a tumor cancers. Described herein are chimeric antigen receptors that target human ROR-1, cell compositions expressing the chimeric antigen receptors, and methods and uses of the chimeric antigen receptors and/or the cell compositions. The chimeric antigen receptors described herein can be expressed by the T lymphocytes isolated from an individual afflicted with cancer and re-administered to the individual.

Herein, we provide genetically engineered immune effector cells, among other cells, which express CAR and secret a bispecific “trap” protein co-targeting a checkpoint protein and TGF-β or TGF-β receptor, so as to improve the antitumor immunity of the immune effector cells. Compared with conventional CAR-T cells and CAR-T cells secreting a polypeptide checkpoint inhibitor, the provided genetically engineered immune effector cells CAR-T cells with “trap” protein secretion attenuate inhibitory T cell signaling, enhance T cell persistence and expansion, and improve effector functionalities and resistance to exhaustion. In a xenograft mouse model, CAR-T cells with “trap” protein secretion significantly enhanced antitumor immunity and efficacy. Methods of using these genetically engineered cells, as well as using polynucleotides encoding the CAR and the “trap” protein, are also provided, for example, as a therapy against solid tumors.

The present disclosure relates to compositions and methods for treating a subject having cancer associated with melanoma-associated antigen 4 (MAGE-A4) peptide. The disclosure includes the embodiments relate to a chimeric antigen receptor (CAR) that binds MAGE-A4 peptide, a polynucleotide encoding a CAR that binds the MAGE-A4 peptide, a modified cell comprising a CAR that binds the MAGE-A4 peptide, and a population of modified cells comprising a CAR that binds the MAGE-A4 peptide.

Provided a chimeric anti-drug antibody receptor (CADAR) specific for anti-drug-antibody-based B cell receptor (BCR), the anti-drug antibody is induced by a therapeutic anti-TNF-alpha monoclonal antibody. Also provided compositions comprising the CADAR, polynucleotides encoding the CADAR, vectors comprising a polynucleotide encoding the CADAR, engineered cells comprising the CADAR, and method using the same.

Provided are a technique for preparing universal humanised CAR19-DNT cells and an application therefor. Specifically provided are universal CAR-T cells targeting CD19, the universal CAR-T cells expressing an exogenous CAR construct, and the CAR construct having the structure shown in formula I: L-scFv-H-TM-C-CD3ζ (formula I); in the formula, L is nothing or a signal peptide sequence; scFv is an antibody single-chain fragment variable region sequence targeting CD19; H is nothing or a hinge area; TM is a transmembrane domain; C is a costimulatory signal molecule; and CD3ζ is a cytoplasmic signal conduction sequence derived from CD3ζ. The provided universal humanised CAR19-DNT cells have the advantages of low immunogenicity, not requiring gene editing to avoid GvHD, high safety, high specificity, and obvious tumour killing effects, and the provided construction method can be implemented in large-scale production, the production costs being low.

Provided herein are chimeric switch receptors (CSRs) comprising an ectodomain and/or transmembrane domain derived from an inhibitory receptor (e.g. PD1 or TGFβR2) fused to the transmembrane domain and/or intracellular signaling domain derived from one or more costimulatory proteins (e.g. CD2, CD28, MyD88, DAP10 or ICOS), or variants thereof. The chimeric switch receptors are designed to convert a signal e.g. an inhibitory signal such as an immunosuppressive signal in the form of PD-L1 or TGFβ into a costimulatory signal. Also provided are engineered immune cells engineered to functionally express a chimeric switch receptor and/or a CAR and optionally also a chimeric cytokine receptor (CCR), and populations thereof, methods of making and using the engineered cells, compositions and kits comprising them, and methods of treating e.g. cancer (e.g. solid or hematologic tumors) by administering the cells and the compositions.

Among the various aspects of the present disclosure is the provision of compositions and methods of making modified chimeric antigen receptor dendritic cells (CAR-DCs) and methods of use thereof. CAR-DCs can be used for the treatment of tumors and cancers, particularly solid tumors (as well as liquid tumors, blood cancer, and metastatic cancer).

Aspects of the present disclosure relate to compositions comprising a population of genetically engineered T cells that expresses a chimeric antigen receptor (CAR) that binds CD70, and methods of using such for the treatment of CD70+ solid tumors.