Provided are chimeric receptors for engineering cells for adoptive therapy, including T cells, and the genetically engineered cells. In some embodiments, the chimeric receptors, such as chimeric antigen receptors (CARs) are modified in a junction region by one or more amino acid modifications such that peptide fragments of such region exhibit a lower binding affinity for a human leukocyte antigen (HLA) and/or the region exhibits reduced immunogenicity, including following administration to a subject. In some aspects, also provided are methods and compositions for engineering and producing cells expressing such chimeric receptors, compositions containing the cells, and method for their administration to subjects. In some embodiments, features of the chimeric receptors and engineered cells containing the chimeric receptors result in methods that provide for increased or improved activity, efficacy and/or persistence.

Immunomodulating polynucleotides are disclosed. The immunomodulating polynucleotides may contain 5-modified uridine, 5-modified cytidine, a total of from 6 to 16 nucleotides, and/or one or more abasic spacers and/or internucleoside phosphotriesters. Also disclosed are conjugates containing a targeting moiety and one or more immunomodulating polynucleotides. The immunomodulating polynucleotides and conjugates may further contain one or more auxiliary moieties. Also disclosed are compositions containing the immunomodulating polynucleotides or the conjugates containing one or more stereochemically enriched internucleoside phosphorothioates. Further disclosed are pharmaceutical compositions containing the immunomodulating polynucleotides or the conjugates and methods of their use.

The present invention relates to a cell which co-expresses a first chimeric antigen receptor (CAR) and second CAR at the cell surface, each CAR comprising: (i) an antigen-binding domain; (ii) a spacer (iii) a trans-membrane domain; and (iv) an endodomain wherein the first CAR is an activating CAR comprising an activating endodomain and the second CAR is an inhibitory CAR comprising a ligation-off inhibitory endodomain; wherein the first CAR binds to a first antigen and the second CAR binds to a second antigen, wherein both the first and second antigens are expressed on the surface of a target cell; wherein the first CAR binds to an epitope on the first antigen which is relatively proximal to the membrane of the target cell, the second CAR binds to an epitope on the second antigen which is relatively distal to the membrane of the target cell, in comparison with the epitope of the first antigen; and wherein the spacer of the first CAR is an equivalent size to the spacer of the second CAR.

The present invention provides 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.

CAR T cells for treating CD19+, CD20+ OR CD22+ tumors, including leukemia and lymphoid malignances, provide increased safety in the therapy of the tumors and prevent epitope masking in CAR+ B-cell leukemia blasts. The CAR T cells decrease the potential risk of CD19?/CAR+, CD20?/CAR+ or CD22?/CAR+ leukemic relapse. In addition, the CAR T cells provide increased safety in the treatment of autoimmune diseases caused by B cells producing auto-antibodies.

The present invention provides compositions comprising anti-CEACAM1 antibodies, compositions comprising antibodies capable of inhibiting or blocking the interaction between PD-1 and its ligands, and methods for their combined use in treating cancer.

The invention provides a chimeric antigen receptor (CAR) comprising an antigen binding domain comprising SEQ ID NOs: 1-6, a transmembrane domain, and an intracellular T cell signaling domain. Nucleic acids, recombinant expression vectors, host cells, populations of cells, antibodies, or antigen binding portions thereof, and pharmaceutical compositions relating to the CARs are disclosed. Methods of detecting the presence of cancer in a mammal and methods of treating or preventing cancer in a mammal are also disclosed.

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.

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.

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.