Compositions, e.g., therapeutic agents, and methods are provided for modulating gene and protein expression of Forkhead Box protein 1 (Foxp1). The therapeutic agents include short nucleic acid molecules that modulate gene and protein expression of Forkhead Box protein 1 (Foxp1) expression, viral vectors containing such molecules, T cells transduced with these viruses for adoptive therapies, and any small molecules that bind to and inactivate Foxp1. These compounds and methods have applications in cancer therapy either alone or in combination with other therapies that stimulate the endogenous immune system in the environment of the cancer, e.g., tumor.

Provided herein are cell populations transiently expressing a chimeric antigen receptor (CAR) and their use in the chronic treatment of hyperproliferative diseases such as cancer.

Provided are methods, compositions, recombinant DNA molecules, and kits for cloning T cell receptors (TCRs). The methods facilitate construction of TCR expression libraries from biological samples containing antigen-specific T cells, including but not limited to tumor biopsies, including frozen tumor biopsies. Peripheral T cells that were engineered with library-derived TCR genes show potent therapeutic anti-tumor effects. The method can be performed using any sample that contains T cells, and can be performed with oligoclonal populations of T cells, such as T cells that have infiltrated a tumor. Primer combinations for first strand cDNA synthesis, second strand cDNA synthesis, and for cloning a plurality of distinct TCR ? and TCR ? chains into a plurality of vectors are provided. Cells containing the vectors are provided, as are kits for use in rapid cloning of the TCR ? and TCR ? chains.

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.

The invention provides methods of making immune effector cells (e.g., T cells, NK cells) that can be engineered to express a chimeric antigen receptor (CAR), compositions and reaction mixtures comprising the same, and methods of treatment using the same.

The present disclosure provides an automated method of producing genetically modified immune cells, including chimeric antigen receptor T (CAR T) cells, utilizing a fully-enclosed cell engineering system.

The present invention relates to a human macrophage for use in cancer therapy, said human macrophage comprising at least one mutation in both alleles of a chromosomal gene, wherein said macrophage is resistant to tumor-induced reprogramming and/or shows anti-tumor activity. The human macrophage of the invention demonstrates typical markers of an M1 macrophage, such as the presence of MHC class II proteins, even after having been cultured in an environment which promotes M2-polarization, such as in the presence of M-CSF and/or IL4 and/or IL13. The invention also relates to a collection of human macrophages of the invention, to their use in medicine, and in particular to their use in cancer therapy such as the treatment of solid tumors as a preferred example.

Provided herein are, among other things, methods for treating a patient suffering from a HER2+ cancer.

The present invention provides methods for isolating and cryopreserving tumor infiltrating lymphocytes (TILs) and producing therapeutic populations of TILs, including methods via use of a kit and a semi-automatic device for aseptic disaggregation, enrichment, and cryopreservation of a resected tumor prior to expansion of the TIL population. The present invention also provides methods for expansion, and/or stabilization of TILs, for instance UTILs, compositions involving the same and methods of treatment involving the same.

The presently disclosed subject matter provides for chimeric receptors that target MUC16 and cells comprising such chimeric receptors. The presently disclosed subject matter further provides uses of the chimeric receptors for treatment.