A method for engineering less alloreactive immune cells, including T-cells that express chimeric antigen receptors (CARs), using a nucleotide sequence in form of an RNA encoding a anti-TCR CAR to achieve the transient expression of anti-TCR CAR at the cell surface. The transient expression of the anti-TCR CAR recognized by the alpha beta TCR on the cell surface unexpectedly enabled the a purification of the TCR-negative CAR expressing cells. The TCR-negative CAR expressing immune cells can be used in adoptive therapy to treat diseases associated with cell surface antigens, such as cancer with less side effects, in particular less GVHD.

The present invention provides anti-Siglec-15 antibodies and antigen-binding fragments thereof as well as isolated nucleic acids, vectors, engineered cells, formulations thereof, and methods of use thereof for treating diseases including cancer and bone disease in a human subject. The invention is further directed to bispecific and multispecific antibodies, antibody-drug conjugates and chimeric antigen receptors derived from the anti-Siglec-15 antibodies and fragments thereof.

A cell which co-expresses a first chimeric antigen receptor (CAR) and second CAR at the cell surface, each CAR comprising an antigen-binding domain, wherein the antigen-binding domain of the first CAR binds to CD19 and the antigen-binding domain of the second CAR binds to CD22.

Provided herein are de novo binding domain containing polypeptides (DBDpp) that specifically bind a target of interest. Nucleic acids encoding the DBDpp, and vectors and host cells containing the nucleic acids are also provided. Libraries of DBDpp, methods of producing and screening such libraries and the DBDpp identified from such libraries and screens are also encompassed. Methods of making and using the DBDpp are additionally provided. Such uses include, without limitation, affinity purification, and diagnostic and therapeutic applications.

Among other things, the present disclosure provides technologies comprising immune cells and antibody-recruiting molecules. In some embodiments, immune cells are memory-like natural killer cells. In some embodiments, provided technologies are particularly useful for treating a condition, disorder or disease like cancer. In some embodiments, provided technologies provide high efficacy. In some embodiments, provided technologies provide less or less severe side effects associated with natural killer cell therapy.

The present invention includes dead-guide RNA (dgRNA) libraries and methods of use in immunology and immunotherapy thereof. Also provided are engineered primary or chimeric antigen receptor (CAR) T cells that overexpress Prodh2, Ccnblip1, Sreklip1, or Wdr37 or a fragment thereof, and methods of use in immunology and immunotherapy thereof.

The present invention provides therapeutics for the treatment of CD22-positive cancers such as B-cell acute lymphoblastic leukemia (B-ALL). In particular, the present invention provides an anti-CD22 monoclonal antibody whose scFv as a part of chimeric antigen receptors (CAR) T-cells can target the fcst Ig extracellular domain of the CD22 antigen, the farthest domain from the membrane, for use in the treatment of CD22-positive cancers.

Provided herein are de novo binding domain containing polypeptides (DBDpp) that specifically bind a target of interest. Nucleic acids encoding the DBDpp, and vectors and host cells containing the nucleic acids are also provided. Libraries of DBDpp, methods of producing and screening such libraries and the DBDpp identified from such libraries and screens are also encompassed. Methods of making and using the DBDpp are additionally provided. Such uses include, without limitation, affinity purification, and diagnostic and therapeutic applications.

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).

Provided herein are immuno-responsive cells expressing a B cell targeting pCAR comprising a 2nd generation chimeric antigen receptor (CAR) and a chimeric co-stimulatory receptor (CCR). Also provided herein are methods of preparing the immuno-responsive cells and methods of directing T cell mediated immune response using the immuno-responsive cells.