The present disclosure provides methods of treating a tumor (e.g., renal cell cancer) by administering an immunotherapy comprising dendritic cells loaded with RNA encoding a tumor antigen and a pharmaceutical which can decrease circulating IgG levels, block IgG-mediated activation of CD16.sup.+ T cells, decrease the concentration and/or function of B cells, reduce the frequency of CD38.sup.+ TGF-β.sup.+ B cells, decrease B cell secretion of TGF-β, and/or sustain the frequency of CD25.sup.+CD28.sup.+ CD4 and/or CD8 T cells.

Provided herein are chimeric receptors comprising amyloid binding regions, as well as cells comprising the chimeric receptors. Also provided herein are methods of treating amyloid-based diseases by administering a cell comprising a chimeric receptor.

Disclosed are compositions and methods comprising the administration of pulsed dendritic cells and an immunoregulator molecule inhibitor for the treatment of cancer.

Acute lymphoblastic leukemia (ALL) has not benefited from innovative immunotherapies, mainly because of the lack of actionable immune targets. Novel tumor-specific antigens (TSAs) specifically expressed by ALL cells are described herein. Most of the TSAs described herein derives from aberrantly expressed unmutated genomic sequences, such as intronic and intergenic sequences, which are not expressed in normal tissues. Nucleic acids, compositions, cells, antibodies and vaccines derived from these TSAs are described. The use of the TSAs, nucleic acids, compositions, antibodies, cells and vaccines for the treatment of leukemia such as ALL is also described.

The present disclosure pertains to the technical field of immunotherapy or disease prevention and treatment with vaccines, in particular to a heterocyclic compound containing two or more sulfur atoms and an application thereof in preparing a nano-vaccine. Provided is the application of the heterocyclic compound containing at least two sulfur atoms and capable of being covalently or non-covalently linked to a polypeptide in preparing the nano-vaccine. A nanoparticle prepared by self-assembly of the compound and an antigen can enter the dendritic cytoplasm in nonendocytic pathway, thereby improving the uptake efficiency of the antigen and an immune adjuvant. In the process of entering a cell, the nano-vaccine can effectively avoid or reduce biodegradation of the antigen or nucleic acid adjuvant caused by enzymes in lysosomes, and therefore the nano-vaccine can efficiently activate the dendritic cells and improve the cross-presentation of the antigen, thereby effectively activating CD8+ T cells and promoting T cell proliferation. Therefore, the nano-vaccine can prevent tumor cell proliferation and virus infection by efficient immune activation and immune regulation.

The present invention relates to adenoviral vectors, wherein the viral capsid has been coated with polypeptides, which are capable of stimulating a peptide-specific immune response in a subject and uses thereof (e.g. infectious disease). Furthermore, the present invention relates to methods of treating diseases, e.g., cancer or an infectious disease, by adenoviral vectors which have been coated by polypeptides causing peptide-specific immune response. Also the present invention relates to a method of coating adenoviral vectors by specific peptides as well as to a method of identifying those peptides suitable for coating the capsid of an adenoviral vector.

The invention relates to dendritic cells, the NFκB signaling pathway of which has been manipulated by RNA transfection, to the manufacture thereof and to use thereof.

Provided are a polypeptide and nucleic acid for encoding the polypeptide, a nucleic-acid construct, an expression vector, and a host cell containing the nucleic acid, an antigen-presenting cell presenting the polypeptide on the surface of the cell, and immune effector cell thereof, a pharmaceutical composition containing the polypeptide, a vaccine containing the nucleic acid, the nucleic acid construct, the expression vector, the host cell, the antigen-presenting cell, and the immune effector cell, and an antibody recognizing the polypeptide. Also provided is a therapeutic method using the polypeptide, the nucleic acid, the pharmaceutical composition, the vaccine, and the antibody. Also provided are a diagnosis method and diagnosis apparatus for detecting the described polypeptide. Also provided is an application of the polypeptide in preparing a vaccine, a tumor diagnosis kit, or a pharmaceutical composition, and an application of the polypeptide or the nucleic acid as a test target in tumor diagnosis.

The embodiment of the invention is to enable universal non-classical MHC I peptide vaccines restricted to HLA-E, HLA-F and HLA-G. An algorithm was develop to predict HLA-E binding immunogenic or suppressorgenic peptides of the autologous origins, e.g., autoantigens, inflammatory antigens, IgE and cancer antigens, and of the microbial origins. Thus, the embodiment of the invention is to load the antigenic peptides of medical and therapeutic importance onto the non-polymorphic HLA-E, HLA-F, and HLA-G culminating in universal vaccines, bypassing highly polymorphic classical MHC I, e.g., HLA-A, HLA-B and HLA-C pathways, in order to treat autoimmune diseases, allergy, inflammatory diseases, cancers, and infectious diseases for all human population. Derlin-1 and UL40 pathways are utilized to enable antigen presentation and vaccine efficacies in the non-classical MHC I pathways.

The present disclosure is broadly concerned with the field of cancer immunotherapy. For example, the present invention generally relates to an immune cell comprising a genetically engineered antigen receptor that specifically binds to a target antigen and a genetic disruption agent that reduces or is capable of reducing the expression in the immune cell of a gene that weakens the function of the immune cell.