In one aspect, a method of treating cancer in a mammal is provided. The method comprises administering to the mammal an oncolytic vector that expresses a tumour antigen to which the mammal has a pre-existing immunity. In another aspect, a method of boosting immune response in a mammal having a pre-existing immunity to an antigen is provided comprising intravenous administration to the mammal of a B-cell infecting vector that expresses the antigen.

Therapeutic modalities are provided for targeting adoptive cellular therapies to specific sites of disease, involving the use of specific repertoirs of PRR ligands. In effect, innate immune system signaling is provoked so as to facilitate the homing of adoptive immune cells to sites of disease, for example to the site of a solid tumor.

Therapeutic modalities are provided for targeting adoptive cellular therapies to specific sites of disease, involving the use of specific repertoirs of PRR ligands. In effect, innate immune system signaling is provoked so as to facilitate the homing of adoptive immune cells to sites of disease, for example to the site of a solid tumor.

A novel vaccine that can induce sufficiently high cell-mediated immunity is disclosed. The vaccine of the present invention contains, as an effective component, a polypeptide comprising a tandem repeat structure in which an MHC class I epitope region derived from an antigen protein and a spacer sequence are linked to each other alternately and repeatedly at least three times, or a recombinant vector which comprises a polynucleotide encoding said polypeptide and is capable of expressing said polypeptide in vivo. The spacer sequence is, for example, a sequence generated as an amino acid sequence inevitably encoded by a single base sequence which is designed such that the MHC class I epitope region derived from the antigen protein, an MHC class II epitope region derived from the antigen protein, and at least one higher-order-structure-stabilizing region are encoded by different reading frames in said single base sequence.

The present invention includes compositions and methods for modifying a T cell with a nucleic acid encoding a switch molecule comprising an extracellular domain comprising a membrane receptor or fragment thereof and an intracellular domain comprising a signaling receptor or fragment thereof. In one aspect, a method comprises introducing a nucleic acid encoding a switch molecule and a nucleic acid encoding a soluble fusion protein and/or a nucleic acid encoding a bispecific antibody into a population of cells comprising T cells, wherein the T cells transiently expresses the switch molecule and soluble fusion protein or bispecific antibody. In other aspect, compositions of T cells and methods of treating a disease or condition, such as cancer or an autoimmune disease, are also included.

In various embodiments methods of producing a cell population enriched for CLEC9A+ dendritic cells are provided where the methods involve culturing stem cells and/or progenitor cells in a cell culture comprising culture medium, a notch ligand, stem cell factor (SCF), FLT3 ligand (FLT3L); thrombopoietin (TPO); and IL-3 and/or GMCSF.

Disclosed are immunotherapeutic compositions and the concurrent use of combinations of such compositions for the improved induction of therapeutic immune responses and/or for the prevention, amelioration and/or treatment of disease, including, but not limited to, cancer and infectious disease.

Materials and methods for identifying and using MEW molecule variants for activating self-reactive T cells in a peptide-specific manner, and their use to focus autoimmune cellular responses against diseases such as cancers and persisting viral infections, are described.

The present disclosure provides compositions and methods comprising spherical nucleic acid (SNA) components for use as immunotherapeutic agents. The disclosure provides a method comprising: treating a population of antigen presenting cells with a SNA comprising a nanoparticle, an antigen, and an adjuvant; and determining a time at which the population of antigen presenting cells presents a maximal signal that is indicative of antigen presentation by the antigen presenting cells and a time at which the population of antigen presenting cells presents a maximal co-stimulatory signal due to the adjuvant. The disclosure includes compositions that comprise a pharmaceutically acceptable carrier and a SNA of the disclosure, wherein the SNA comprises a nanoparticle, an oligonucleotide on the surface of the nanoparticle, and an antigen that is associated with the surface of the SNA via a linker. The disclosure additionally includes articles of manufacture and kits.

The present invention includes compositions and methods for modifying a T cell with a nucleic acid encoding a switch molecule comprising an extracellular domain comprising a membrane receptor or fragment thereof and an intracellular domain comprising a signaling receptor or fragment thereof. In one aspect, a method comprises introducing a nucleic acid encoding a switch molecule and a nucleic acid encoding a soluble fusion protein and/or a nucleic acid encoding a bispecific antibody into a population of cells comprising T cells, wherein the T cells transiently expresses the switch molecule and soluble fusion protein or bispecific antibody. In other aspect, compositions of T cells and methods of treating a disease or condition, such as cancer or an autoimmune disease, are also included.