The present invention provides a pharmaceutical composition comprising cells expressing a chimeric receptor, for use in combination with administration of an antigen-binding molecule, wherein the chimeric receptor comprises an extracellular domain, the extracellular domain comprises an extracellular domain of an immunoreceptor, an extracellular domain variant of an immunoreceptor, or a portion thereof, and the antigen-binding molecule is a multispecific antigen-binding molecule having a target antigen recognition site and an immunoreceptor recognition site which recognizes the immunoreceptor.

A method of generating a population of genetically modified veto cells is disclosed. The method comprising: (a) providing a population of cells comprising T cells, the T cells comprising at least 40% memory CD8.sup.+ T cells; (b) culturing the population of cells comprising T cells with an antigen or antigens under conditions which allow enrichment of tolerance-inducing antigen-specific cells having a central memory T-lymphocyte (Tcm) phenotype, the cells being depleted of graft versus host (GVH) reactivity; and (c) transducing the cells with a polynucleotide encoding a heterologous cell surface receptor comprising a T cell receptor signaling module, thereby generating the population of genetically modified veto cells.

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.

A population of genetically engineered T cells, comprising a nucleic acid encoding an anti-CD83 CAR, a disrupted Reg1 gene, and/or a disrupted TGFBRII gene. Such genetically engineered T cells may comprise further genetic modifications, for example, a disrupted CD83 gene. The population of genetically engineered T cells exhibit one or more of (a) improved cell growth activity; (b) enhanced persistence; and (c) reduced T cell exhaustion, (d) enhanced cytotoxicity activity, (e) resistant to inhibitory effects induced by TGF-β, and (f) resistant to inhibitory effects by fibroblasts and/or inhibitory factors secreted thereby, as compared to non-engineered T cell counterparts.

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 disclosure relates to an anti-TIM3 single-chain antibody. The amino acid sequence of the anti-TIM3 single-chain antibody is a sequence shown in SEQ ID NO. 1. T lymphocytes expressing the anti-TIM3 single-chain antibody can effectively kill tumor cells.

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.