A humanized CD 19 antibody, and a chimeric antigen receptor thereof, an immune cell thereof and the use thereof are provided. The humanized CD19 antibody is based on a FMC63 chimeric antibody, which is subjected to humanization modification. A CAR-T and a dual CAR-T cell constructed based on the humanized antibody and the related use thereof are also provided. Compared with a CAR-T cell constructed by using FMC63, the CAR-T cell constructed based on the humanized antibody has higher killing effect and tumor removal ability.

The present disclosure relates to a novel platform for immunotherapy which combines CAR engineered γδ T cells with armoring interleukin IL-18 that can be expressed constitutively or inducibly, or with a chimeric cytokine receptor comprising the endodomain of the IL-18 receptor. The system/platform and the associated methods according to the present disclosure have advantages such as increased immune cell potency and persistence for therapeutic applications.

The present invention provides an engineered immune cell targeting BCMA and use thereof. In particular, the present invention provides a CAR specifically targeting BCMA, the CAR comprising an antigen-binding domain which is an S-derived scFv, an antibody heavy chain variable region as shown in SEQ ID NO: 9 and an antibody light chain variable region as shown in SEQ ID NO: 10. The present invention also provides a CAR-T cell comprising the CAR, a double CAR- and CAR-T cell comprising the S-derived scFv, and related use thereof. Compared to CAR-T cells constructed using other scFvs, the constructed CAR-T cell of the present invention has a better killing effect and tumor elimination capability.

The present disclosure provides ex vivo armed T cell (EAT) compositions that comprise multi-specific (e.g., bispecific) antibodies that bind to CDS and at least one additional target antigen (e.g., antigen that is expressed by tumor cells and/or a DOTA label). The EAT compositions of the present technology are useful for adoptive immunotherapy in a subject in need thereof.

The present invention discloses a nucleic acid molecule for encoding a chimeric antigen receptor targeting CD22 and CD19. The chimeric antigen receptor of the present invention can be used for treatment of CD19.sup.+ and CD22.sup.+ B-cell hematological tumors, as well as combined treatment with CD19 CAR-T cells or CD22 CAR-T cells.

The present invention relates to a cell which comprises a chimeric antigen receptor (CAR) comprising a binding domain which binds a first epitope of a tumour antigen; and a polynucleotide which encodes a bi-specific protein which comprises a first binding domain which binds a second epitope of said tumour antigen; and a second binding domain which binds a cell surface antigen. The present invention also provides CAR systems, nucleic acids, vectors, pharmaceutical compositions and pharmaceutical compositions for use in the treatment and/or prevention of disease.

Provided is a bispecific chimeric antigen receptor targeting CD19 and CD22, which comprises extracellular antigen binding domains of heavy-chain variable regions and light-chain variable regions of anti-CD19 and anti-CD22 antibodies. Further provided is a bispecific CAR-T cell targeting CD19 and CD22.

Aspects of this disclosure relate generally to the use of biomaterials for the in vivo generation of CAR expressing cells. In some embodiments, the biomaterials comprise one or more of a cell recruitment composition, a viral vector, and/or a cell activation agent.

The disclosure relates to an anti-CD133 single-chain antibody. The amino acid sequence of the anti-CD133 single-chain antibody comprises a sequence shown in SEQ ID NO. 1. T lymphocytes expressing the anti-CD133 single-chain antibody can specifically kill CD133-positive tumor cells and have higher specificity and stronger killing ability.

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.