Provided is a membrane surface protein containing a GPI anchor region. Specifically, provided are a fusion protein comprising a functional domain and a GPI anchor region, and the use thereof. The fusion protein can effectively activate and proliferate immune cells, and improve the effector function of immune cells.

This invention provides methods to prepare and use immunostimulatory cells for enhancing an immune response. The invention provides a method for preparing mature dendritic cells (DCs), comprising the sequential steps of: (a) signaling isolated immature dendritic cells (iDCs) with a first signal comprising an interferon gamma receptor (IFN-R) agonist and/or a tumor necrosis factor alpha receptor (TNF-R) agonist to produce signaled dendritic cells; and (b) signaling said signaled dendritic cells with a second transient signal comprising an effective amount of a CD40 agonist to produce CCR7.sup.+ mature dendritic cells. Also provided by this invention are enriched populations of dendritic cells prepared by the methods of the invention. Such dendritic cells have enhanced immunostimulatory properties and increased IL-12 secretion and/or decreased IL-10 secretion. CD40 signaling can be initiated by one or more of polypeptide translated from an exogenous polynucleotide encoding CD40L (e.g., mRNA or DNA), an agonistic antibody to CD40 receptor or by CD40 ligand polypeptide. The enriched populations can be further modified by the administration of an immunogen to the DC. The DC will take up and process the immunogen on its cell surface.

The present disclosure provides compositions and methods for engineering T cells (e.g., v1 T cells and v2 T cells) with an IL-15 receptor subunit (IL-15R), e.g., by transduction with a viral vector, to restore IL-15 responsiveness. Further provided are populations of engineered T cells and methods of using the same.

Several embodiments of the methods and compositions disclosed herein relate to immune cells that are engineered to express cytotoxic chimeric receptors and various dosing regimens for administering such cells. In several embodiments, the immune cells express a chimeric receptor that targets ligands of NKG2D on tumor cells. In several embodiments, the cancer is a blood cancer, for example, acute myeloid leukemia (e.g., relapsed/refractory acute myeloid leukemia) or myelodysplastic syndrome. In several embodiments, the tumor is a solid tumor, for example, intrahepatic cholangiocarcinoma or other liver tumor, for example, secondary metastases from colorectal cancer.

The present invention relates to the use of interleukin-15 (IL-15) as selectable marker for gene transfer, preferably of at least one gene of therapeutic interest, into a mammalian cell or cell line, in particular a human cell or cell line. The present invention furthermore relates to transgenic mammalian cells or cell lines expressing IL-15 as selectable marker and co-expressing at least one protein of interest encoded by at least one gene of interest, which is preferably a protein of therapeutic interest. The present invention is in particular suitable for chimeric antigen receptors (CARs) as the gene or protein of interest and their expression in lymphocytes. The transgenic mammalian cells and cell lines are furthermore suitable for use as a medicament, in particular in the treatment of cancer and in immunotherapy, such as adoptive, target-cell specific immunotherapy.

This invention provides methods to prepare and use immunostimulatory cells for enhancing an immune response. The invention provides a method for preparing mature dendritic cells (DCs), comprising the sequential steps of: (a) signaling isolated immature dendritic cells (iDCs) with a first signal comprising an interferon gamma receptor (IFN-R) agonist and/or a tumor necrosis factor alpha receptor (TNF-R) agonist to produce signaled dendritic cells; and (b) signaling said signaled dendritic cells with a second transient signal comprising an effective amount of a CD40 agonist to produce CCR7.sup.+ mature dendritic cells. Also provided by this invention are enriched populations of dendritic cells prepared by the methods of the invention. Such dendritic cells have enhanced immunostimulatory properties and increased IL-12 secretion and/or decreased IL-10 secretion. CD40 signaling can be initiated by one or more of polypeptide translated from an exogenous polynucleotide encoding CD40L (e.g., mRNA or DNA), an agonistic antibody to CD40 receptor or by CD40 ligand polypeptide. The enriched populations can be further modified by the administration of an immunogen to the DC. The DC will take up and process the immunogen on its cell surface.

In various aspects, the present disclosure provides polynucleotides encoding a fusion protein, as well as vectors, cells, and compositions comprising the same. In embodiments, the fusion protein includes an insulin signal peptide and an MDA-7/IL-24 protein. Methods of using the polynucleotides, vectors, cells, and compositions, such as in the treatment or prevention of cancer, are also provided.

A cancer vaccine technology is provided which knocks out expression of cell surface immune checkpoint proteins, to facilitate their processing by immune cells, and optionally by knocking-in the expression of cytokines to boost immune response. Non-replicating tumor cells lacking cell surface CD47 are highly effective immunizing agents against subcutaneous mouse melanoma. Whole-cell vaccines inhibited tumor growth, and immunophenotyping showed a dramatic increase in activated effector cell subsets and M1-type macrophages aided by a significant reduction in the tumor-associated macrophage and myeloid derived suppressor cell compartments. A remarkable downregulation of cell surface CD47 was observed in the tumors that did escape after vaccination with genetically modified cells, suggesting the intricate involvement of CD47 in a prophylactic situation. An effective vaccination strategy to increase tumor-specific immune response in solid tumors is provided to improve the outcome of cancer immunotherapy.

A cancer vaccine technology is provided which knocks out expression of cell surface immune checkpoint proteins, to facilitate their processing by immune cells, and optionally by knocking-in the expression of cytokines to boost immune response. Non-replicating tumor cells lacking cell surface CD47 are highly effective immunizing agents against subcutaneous mouse melanoma. Whole-cell vaccines inhibited tumor growth, and immunophenotyping showed a dramatic increase in activated effector cell subsets and M1-type macrophages aided by a significant reduction in the tumor-associated macrophage and myeloid derived suppressor cell compartments. A remarkable downregulation of cell surface CD47 was observed in the tumors that did escape after vaccination with genetically modified cells, suggesting the intricate involvement of CD47 in a prophylactic situation. An effective vaccination strategy to increase tumor-specific immune response in solid tumors is provided to improve the outcome of cancer immunotherapy.

The present invention belongs to the technical fields of immunology and oncologic therapies. Provided are a tumor microenvironment-regulated CAR-monocyte/macrophage, and a preparation method therefor and the use thereof. When the CAR-monocyte/macrophage forms a chimeric antigen receptor composite structure, GM-CSF can be expressed intracellularly and autocrine to extracellular to promote the differentiation of the CAR-monocyte/macrophage to form an M1 type macrophage, so that the tumor microenvironment can be further regulated while the property of resisting M2 type macrophage reversal in the tumor microenvironment is maintained, thereby sensitizing the anti-tumor effect of the CAR-monocyte/macrophage. On the basis of GM-CSF, a tumor microenvironment-regulated CAR macrophage technology platform is constructed, which can maintain the M1-type characteristics of CAR-M and can also produce a TME reversal effect, thereby achieving the efficient anti-tumor effect of a CAR-monocyte/macrophage.