Herein are provided anti-EGFR single domain antibodies (sdAb) prepared by immunizing a llama with recombinant human EGFRvIII. VHH antibodies specific to EGFR were isolated. The example antibodies initially produced comprise CDR1, CDR2, and CDR3 sequences corresponding, respectively to SEQ NOs: 1-3, 4-6, 7-9, 10-12, 13-15, 16-18, 19-21, 22-24, 25-27, 28-30, 31-33, 34-36, 37-39, 40-42, 43-45, and 46-48; and related sequences, including humanized variants. Also provided are multivalent antibodies comprising any one of the sdAbs, including bispecific T-cell engagers, bispecific killer cell engagers (BiKEs), and trispecific killer cell engagers (TriKEs). Also described are chimeric antigen receptors (CARs) for CAR-T therapy comprising any one of the aforementioned sdAbs. Uses of these molecules in the treatment of cancer are also described, in particularly EGFR-high cancers. Hinge lengths may be selected to achieve desired activities, such as high activity or high selectivity for target vs. non-target cells.

Provided herein are chimeric antigen receptors (CARs) for cancer therapy, and more particularly, CARs containing a scFv from an anti-MUC16 monoclonal antibody. Provided are immune effector cells containing such CARs, and methods of treating proliferative disorders.

The present application is directed to bispecific polypeptides comprising a first domain binding an antigen on an antigen presenting cell (ARC) and a second domain binding an antigen on an immune cell expressing a chimeric antigen receptor (CAR). Nucleic acids, vectors and host cells used in producing the polypeptide of the invention are also disclosed. Compositions comprising the bispecific polypeptides and methods of treating cancer and stimulating activation and expansion of immune cells in vivo and in vitro are also disclosed.

The present application is directed to bispecific polypeptides comprising a first domain binding an antigen on an antigen presenting cell (ARC) and a second domain binding an antigen on an immune cell expressing a chimeric antigen receptor (CAR). Nucleic acids, vectors and host cells used in producing the polypeptide of the invention are also disclosed. Compositions comprising the bispecific polypeptides and methods of treating cancer and stimulating activation and expansion of immune cells in vivo and in vitro are also disclosed.

Provided herein are chimeric antigen receptors (CARs) for cancer therapy, and more particularly, CARs containing a scFv from an anti-MUC16 monoclonal antibody. Provided are immune effector cells containing such CARs, and methods of treating proliferative disorders.

Provided herein are modified T lymphocytes comprising chimeric receptors and methods thereof.

The instant disclosure provides chimeric polypeptides which modulate various cellular processes following a cleavage event induced upon binding of a specific binding member of the polypeptide with its binding partner. Methods of using chimeric polypeptides to modulate cellular functions, including e.g., induction of gene expression, are also provided. Nucleic acids encoding the subject chimeric polypeptides and associated expression cassettes and vectors as well as cells that contain such nucleic acids and/or expression cassettes and vectors are provided. Also provided, are methods of treating a subject using the described components and methods as well as kits for practicing the subject methods.

The present invention relates to T cell compositions and methods of using the same in the context of therapy and treatment. In particular, the invention provides T cells that are modified (e.g., genetically and/or functionally) to maintain functionality under conditions in which unmodified T cells display exhaustion. Compositions and methods disclosed herein find use in preventing exhaustion of engineered (e.g., chimeric antigen receptor (CAR) T cells) as well as non-engineered T cells thereby enhancing T cell function (e.g., activity against cancer or infectious disease).

The present invention relates to a new device for a scalable, biomanufacturing platform for the production of CAR-modified T-cells while eliminating on-target/off-tumor toxicity and decreasing the current production cost by 500 times (per treatment). The invention relates to a device to produce modified T-cells comprising a first chamber for proliferating a population of T-cells and a second chamber for modifying the T-cells to express a desired T-cell receptor antigen.

Compositions disclosed herein, and methods of use thereof included those for inhibiting or reducing the incidence of cytokine release syndrome or cytokine storm in a subject undergoing CAR T-cell therapy, wherein the subjects are administered compositions comprising apoptotic cells or apoptotic cell supernatants. In certain instances compositions and methods of use thereof disclosed herein do not reduce the efficacy of the CAR T-cell cancer therapy. Disclosed herein are also compositions and methods of use thereof for decreasing or inhibiting cytokine production in a subject experiencing cytokine release syndrome or cytokine storm comprising administration of a composition comprising apoptotic cells or an apoptotic cell supernatant.