Several embodiments disclosed herein relate to methods and compositions for enhanced expansion of NK cells in culture. In several embodiments, the methods utilize one or more soluble interleukins as culture media supplements at one or more time points during expansion of the NK cell, or other immune cell, the expansion employing a feeder cell population.

The present invention is directed to a mammalian-avian chimeric model system comprising a fertilized avian egg comprising a chorioallantoic membrane (CAM); and multiple types of mammalian cells dispersed in a hydrogel. Further provided is a method for preparing the system and a method of using the same.

Provided herein are methods and compositions for dynamically controlling and targeting multiple immunosuppressive mechanisms in cancer. Some aspects provide cells engineered to produce multiple effector molecules, each of which modulates a different immunosuppressive mechanisms of a tumor, as well as methods of using the cells to treat cancer, such as ovarian, breast, or colon cancer.

Embodiments of the disclosure provide methods and compositions that facilitate cancer treatment including at least because they concern therapies that circumvent the tumor microenvironment. In specific embodiments, compositions are utilized for therapy that utilize NK cells that are protected from the direct inhibition of their activity (using TGF-beta inhibitors) and/or that are indirectly protected from TGF-beta (using integrin inhibitors). In specific embodiments, the NK cells have deficient expression and/or activity for TGF-beta Receptor 2 and/or glucocorticoid receptor.

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 including 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 including administration of a composition including apoptotic cells or an apoptotic cell supernatant.

The disclosure provides immune cells comprising a first activator receptor specific to mesothelin and a second inhibitory receptor specific to a ligand that has been lost in a mesothelin-positive cancer cell, and methods of making and using same for the treatment of cancer.

The present specification provides methods for augmenting the antigenic content, especially of tumor-associated antigens (TAA), and immunogenicity of cancer cells; methods for enhancing cross-presentation in dendritic cells, compositions comprising such manipulated cells derived from single cancer patients; and methods of using those compositions as a personal immunotherapeutic product to treat the donor patient's cancer.

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.

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.

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 including 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 including administration of a composition including apoptotic cells or an apoptotic cell supernatant.