The present invention relates to a method for memory B cell-specific differentiation induction and to uses thereof and, more specifically, to an anti-CD3 antibody or ligand in a biological sample obtained from and individual, a method for memory B cell-specific differentiation induction comprising a step of treating an anti-CD28 antibody or ligand, and a method for detection a memory B cell which is specific to a specific antigen by using same.

Provided herein are methods for ex vivo expansion of a T cells, including tumor-reactive T cells, and compositions containing such T cells. Also provided are methods for treating diseases and conditions such as cancer using compositions of the present disclosure.

The disclosure provides methods and compositions for affecting the development of antigen presenting cell (APC, e.g., a macrophage or dendritic cell). The methods include maturing an APC, promoting anti-inflammatory phenotype, promoting development of a T regulatory cell (Treg) from a naive T cell. The methods generally include exposing an APC to a tryptophan derived microbiota metabolite (TDMM), such as an anti-inflammatory or pro-mucosal TDMM, and permitting the APC to mature. In some embodiments, the conditioned APC is exposed to a naive T cell to further promote development of a T regulatory cell (Treg). In some embodiments, the TDMM is selected from the group consisting of indole, indole-3-acetate, 5-hydroxyindole, and indole-3-pyruvate.

Provided herein are methods and customized media compositions for culturing CIK NKT cells.

Methods of expanding tumor infiltrating lymphocytes (TILs), including peripheral blood lymphocytes and marrow infiltrating lymphocytes, from blood and/or bone marrow of patients with hematological malignancies, such as liquid tumors, including lymphomas and leukemias, and uses of such expanded TILs in the treatment of diseases such as cancers and hematological malignancies are disclosed herein.

Provided herein are methods for transduction of T cells. In some embodiments, the provided methods include transduction of T cells by incubation with a retroviral vector particle, e.g., lentiviral vector, in which the cells have been selected for CCR7+ expression. The provided methods improve the process for genetically engineering T cells by increasing transduction frequency and/or by reducing the variability in transduction frequency among biological samples. Also provided are resulting cells transduced with a recombinant or heterologous gene, and compositions thereof. In some embodiments, the provided cells and compositions can be used in methods of adoptive immunotherapy

A method for producing an engineered T cell population includes obtaining a cell population containing a monocyte and a T cell, resting the obtained cell population on a surface, adhering the monocyte to the surface, retaining a non-adherent cell population, activating the non-adherent cell population, introducing a nucleic acid into the activated non-adherent cell population to obtain a transformed T cell, and expanding the transformed T cell to obtain the engineered T cell population.

The present disclosure provides a CAR comprising a tumor antigen binding domain, a transmembrane domain, and an intracellular domain comprising an intracellular signaling domain of an interleukin-9 receptor alpha (IL9Ra), and modified cell(s), i.e., immune cell(s) or precursor cell(s) thereof, engineered to express the CAR. Also provided are methods and uses of the modified cells, e.g., for treating at least one sign and/or symptom of cancer. Related nucleic acids, vectors, and pharmaceutical compositions are also provided.

The invention provides improved T cell compositions and methods for manufacturing T cells. More particularly, the invention provides methods of T cell manufacturing that result in adoptive T cell immunotherapies with improved survival, expansion, and persistence in vivo.

Methods for developing engineered T-cells for immunotherapy that are both non-alloreactive and resistant to immunosuppressive drugs. The present invention relates to methods for modifying T-cells by inactivating both genes encoding target for an immunosuppressive agent and T-cell receptor, in particular genes encoding CD52 and TCR. This method involves the use of specific rare cutting endonucleases, in particular TALE-nucleases (TAL effector endonuclease) and polynucleotides encoding such polypeptides, to precisely target a selection of key genes in T-cells, which are available from donors or from culture of primary cells. The invention opens the way to standard and affordable adoptive immunotherapy strategies for treating cancer and viral infections.