Cell culture systems and methods provide improved immunotherapeutic product manufacturing with greater scalability, flexibility, and automation. Cell culture systems are configured with interchangeable cartridges, allowing versatility and scalability. Systems are configured to have multiple connected cell culture chambers, which allows parallel processing of different types of cells. Gas-impermeable cell culture chambers and methods for generating cells in closed systems prevent contamination and user error. Methods for recycling cell culture medium provide additional efficiencies.

The invention pertains to a cell population for use in treating cancer in a patient, comprising CD1c (BDCA-1).sup.+/CD19.sup.− dendritic cells, wherein CD1c(BDCA-1).sup.+/CD19.sup.− dendritic cells are depleted for CD1c (BDCA-1).sup.+/CD19.sup.−/CD14.sup.+ cells.

The invention covers the use of certain classes of lipids including cationic lipids in ex-vivo dendritic cell therapies. The cationic lipids enhance antigen uptake, processing and presentation of the processed antigens by dendritic cells to CD8+ and CD4+ T-cells via the MHC classes I and II presentation pathways respectively. Antigen uptake via cationic lipid by dendritic cells result in significant lowering of the population of the immune suppressive regulatory T cells in the tumors and a significant increase of the tumor targeting cytotoxic T-cells. Loss of regulatory T cells and increase of tumor specific cytotoxic cells are conducive to effective elimination of the tumors.

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.

The present invention relates to a monoclonal antibody or antigen-binding fragment thereof that specifically binds to TIM-3 and uses thereof.

The monoclonal antibody, hTIM-3_NCC1, of the present invention specifically recognizes human and mouse cells expressing TIM-3, and it can be useful for various fields such as diagnosis of diseases mediated by TIM-3 expressing cells as well as prevention or treatment thereof.

Peptides have immune system modulation properties. The immunologically active peptides can be derived from the heavy-chain complementarity determining region-3 of a humanized monoclonal antibody to NaPi2B transporter. Such peptides can be used to modulate the immune system of a subject under cancer treatment.

A method for producing a professional antigen-presenting cell, including inducing expression of c-MYC, BMI1, and MDM2 in a myeloid cell (MC) to obtain a proliferative myeloid cell (pMC), and inducing expression of GM-CSF and/or M-CSF in the pMC to obtain a professional antigen-presenting cell (pAPC). The myeloid cell is a myeloid cell differentiated from a pluripotent stem cell.

The present invention provides isolated immune cells, immune cell populations and compositions, as well as markers, marker signatures and molecular targets characterising the immune cells. The cell products, substances, compositions, markers, marker signatures, molecular targets, kits of parts and methods of the present invention provide for new ways to characterise, evaluate and modulate the immune system and immune responses.

The present invention provides CDCA1-derived epitope peptides having the ability to induce cytotoxic T cells. The present invention further provides polynucleotides encoding the peptides, antigen-presenting cells presenting the peptides, and cytotoxic T cells targeting the peptides, as well as methods of inducing the antigen-presenting cells or CTLs. The present invention also provides compositions and pharmaceutical compositions containing them as an active ingredient. Further, the present invention provides methods of treating and/or preventing cancer, and/or preventing postoperative recurrence thereof, using the peptides, polynucleotides, antigen-presenting cells, cytotoxic T cells or pharmaceutical compositions of the present invention. Methods of inducing an immune response against cancer are also provided.

Disclosed are modified DAP12 and methods of their use for enhancing immune responses and for treating cancer.