The present disclosure provides adoptive T cell therapies that have improved architectures for targeting antigens and recruiting multimeric immune signaling complexes for treating, preventing, or ameliorating at least one symptom of a cancer, infectious disease, autoimmune disease, inflammatory disease, and immunodeficiency, or condition associated therewith.

The presently disclosed subject matter provides for chimeric receptors that target ADGRE2 and chimeric receptors that target CLEC12A. The presently disclosed subject matter also provides for cells comprising the ADGRE2-targeted chimeric receptors, cells comprising the CLEC12A-targeted chimeric receptors, and cells comprising the ADGRE2-targeted chimeric receptors and the CLEC12A-targeted chimeric receptors. The presently disclosed subject matter further provides uses of such cells for treating tumors, e.g., AML.

Novel therapeutic immunotherapy compositions comprising at least two vectors, each vector encoding a functional CAR, whereby the combination of vectors results in the expression of two or more non-identical binding domains, wherein each vector encoded binding domain(s) are covalently linked to a transmembrane domain and one or more non-identical intracellular signaling motifs are provided herein as well as are methods of use of same in a patient-specific immunotherapy that can be used to treat cancers and other diseases and conditions.

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 cells expressing a first and a second chimeric protein in the cell membrane. Such cells can solve expression problems of CAR constructs caused by these CAR construct's ability to recognize unwanted internal epitopes or exhibiting unwanted signalling due to misfolding/scFv aggregation. The first chimeric protein comprises an extracellular antigen binding unit and an intracellular dimerization domain. The second chimeric protein comprises a lipid anchoring domain, an intracellular dimerization domain and a signaling domain. Accordingly, the expression of the two proteins allows them to translocate to the cell membrane without much interference and subsequently gain signaling capacity when colocalized at the cell membrane.

This invention is directed to genetically engineered B cells, wherein the B cell expresses and bears on its surface a chimeric B cell receptor, and wherein the genetically engineered B cell further expresses and secretes an antibody or cytokine.

The present invention provides compositions and methods for inducing a CAR mediated trans-signal in a T cell. The trans-signaling CAR T cells comprise a first CAR having a first signaling module and a second CAR having a distinct second signaling module. The present invention also provides cells comprising a plurality of types of CARs, wherein the plurality of types of CARs participate in trans-signaling to induce T cell activation.

The invention provides immune effector cells (for example, T cells, NK cells) that express a chimeric antigen receptor (CAR), and compositions and methods thereof.

The present invention includes compositions and methods for treating AML utilizing bispecific CARs. In certain aspects, the invention includes a bispecific split CAR which binds CD13 and TIM-3 on AML cells.

Compositions and methods for efficient cellular genomic engineering that transduce diverse cell types with minimal toxicity, leading to efficient and stable genomic modifications are described. The compositions and methods are applicable to development of chimeric antigen receptor engineered T cell therapy (CAR-T). An exemplary method introduces a gene of interest into cells by introducing to the cell a viral vector including a transposon encoding the gene of interest and mRNA including a sequence that encodes transposase enzymes configured to mediate targeted integration of the transposon into the cellular genome, whereby the mRNA is introduced to the cell via electroporation. Also disclosed are genetically modified cells and pharmaceutical compositions and methods of use thereof for treating subjects having diseases or disorders.