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 present invention relates to tolerogenic mammalian dendritic cells (iDCs) and methods for the production of tolerogenic DCs. In addition, the present invention provides methods for administration of tolerogenic dendritic cells as well as particles containing oligonucleotides to mammalian subjects. Enhanced tolerogenicity in a host can be useful for treating inflammatory and autoimmune related diseases, such as type 1 diabetes.

Embodiments of the disclosure concern methods and compositions for immunotherapy for human papillomavirus infection and diseases associated therewith. In specific embodiments, methods concern production of immune cells that target one or more antigens of HPV16 and/or HPV18, including methods with stimulation steps that employ IL-7 and IL-15, but not IL-6 and/or IL-12. Other specific embodiments utilize stimulations in the presence of certain cells, such as costimulatory cells and certain antigen presenting cells.

The present invention relates to the use of a vehicle for specific molecular targeting of Langerin+ cells, wherein the vehicle is capable of specifically binding to a Langerin+ cell, said vehicle comprising (a) at least one carrier and (b) at least one saccharide moiety-based conjugate for a targeted cargo delivery into a Langerin+ cell, as well as pharmaceutical compositions and uses comprising the inventive vehicle.

Provided herein are methods for the efficient in vitro differentiation of somatic cell-derived pluripotent stem cells to hematopoietic precursor cells, and the further differentiation of the hematopoietic precursor cells into immune cells of various myeloid or lymphoid lineages, particularly T cells, NK cells, and dendritic cells. The pluripotent cells may be maintained and differentiated under defined conditions; thus, the use of mouse feeder cells or serum is not required in certain embodiments for the differentiation of the hematopoietic precursor cells.

Disclosed are methods of obtaining a cell population enriched for T cells having antigenic specificity for a cancer-specific mutation using in vitro stimulation of memory T cells. Also disclosed are related methods of isolating a T cell receptor (TCR), populations of cells, TCRs or antigen-binding portions thereof, pharmaceutical compositions, and methods of treating or preventing cancer.

Described herein are compositions and methods for treating cancer through the combination of tumor antigen-pulsed dendritic cells and Dengue Virus. The combination of the two forms of therapeutic intervention provides enhanced tumor cell reduction compared to either alone. The cancer targeted by compositions and methods described herein may be a solid cancer or blood cancer.

This invention relates to peptide-exchange proteins comprising the luminal domain of TAP-binding protein-related (TAPBPR), which functions as a MHC class I peptide-exchange catalyst when presented to mammalian cells either as a soluble extracellular protein or as a membrane bound cell surface protein. This may be useful in modulating immune responses, including for example loading immunogenic peptide onto tumours or other disease cells to induce their recognition by T cells. Peptide-exchange proteins and methods for their use are provided.

A method for increasing dendritic cell migration ability, and a use thereof are disclosed. A method according to one aspect can increase the migration ability of mature dendritic cells and increase the induction, by dendritic cells, of inflammatory cytokine production, T lymphocyte proliferation and T lymphocyte polarization, and thus can be used for the prevention or treatment of immune-related diseases.

A method of producing an immunotherapy vaccine is provided. The method includes performing a heat treatment to exosomes separated from cancer cells or body fluids including blood of a cancer patient to promote inactivation of proteolytic enzymes in the exosomes, and introducing or co-culturing the exosomes in dendritic cells derived from blood of the cancer patient or a healthy person to make antigen-presenting cells.