Disclosed herein are clones of murine F77 monoclonal antibodies, humanized F77 antibodies, single chain variable fragments (scFvs) and single chain antigen binding fragments (scFabs) of the antibodies, and chimeric antigen receptors. The humanized F77 antibodies and their fragments retain the binding specificity of the murine F77 monoclonal antibody to PC-3 cells. The humanized F77 antibodies and their fragments can be used for diagnostic and/or therapeutic tools in diagnosis or treatment of localized (stages I and II), locally advanced (stage III), or advanced (stage IV) prostate cancer.

A monocyte, monocyte derived cell or macrophage infected with an oncolytic herpes simplex virus is disclosed together with uses of such infected cells in the treatment of diseases such as cancer.

The invention relates to therapy and methods of applying the therapy to a patient. The invention includes the introduction of immature dendritic cells into the patient and the introduction of anti-TNF antibody into the patient. The immature dendritic cells are introduced intratumorally and/or through vessel and the anti-TNF antibody is introduced intratumorally and/or through vessel and/or subcutaneously. The immature dendritic cells can be formed by collecting monocyte cells from the patient and culturing the cells in a culture medium. The invention can be effective to regress, reduce or eliminate tumor cells in tumor tissue of the patients, including metastasized tumors. Further, the treatment of the invention is effective in the absence of conventional therapy, such as radiotherapy and chemotherapy.

Compositions and methods are disclosed herein for producing one or more immunoglobulins in an isolated B lymphocyte cell line. An isolated recombinant cell line includes an isolated B lymphocyte cell line capable of expressing at least one endogenous membrane immunoglobulin reactive to a first antigen and at least one exogenously incorporated nucleic acid encoding at least one secreted immunoglobulin reactive to a second antigen.

The invention provides methods of treating inflammation in a specific organ or tissue of an individual. The method involves determining whether the individual has previously been infected with at least one pathogen that is pathogenic in the specific organ or tissue; and administering to the individual an anti-inflammatory composition comprising antigenic determinants, the antigenic determinants selected or formulated so that together they are specific for the at least one pathogen. The pathogen may be an endogenous or exogenous pathogen, and may further be a bacterial pathogen, a viral pathogen, a fungal pathogen, a protozoan pathogen, or a helminth pathogen.

Described herein is a reliable method for preparing a potent vaccine useful for immunotherapy comprising the step of cryopreserving a population of cells undergoing immunogenic cell death, and using such cells to activate dendritic cells for use in immunotherapy. In a specific embodiment, the method comprises cryopreserving cancer cells undergoing cell death, which can be used to prepare a pharmaceutical composition for immunotherapy against cancer.

The invention provides compositions and methods for treating cancer by using immune effector cells (e.g., T cells, NK cells) engineered to conditionally express an agent which enhances the immune effector response of an immune effector cell that expresses a Chimeric Antigen Receptor (CAR). The conditional agents described herein include agents that target a cancer associated antigen, e.g., a CAR, agents that inhibit one or more checkpoint inhibitors of the immune response, and a cytokine.

Disclosed herein are genetically engineered T cell receptors, and methods, vectors, and genetically engineered T cells related to genetically engineered T cell receptors.

The present disclosure provides compositions and methods that rapidly and selectively modify cells of the immune system to achieve therapeutic objectives. The methods can be practiced in vivo and any cell type that expresses a known marker can be targeted for a therapeutic objective.

Provided herein are compositions and methods for treating neuroendocrine cancer and preventing or treating metastasis originating from a neuroendocrine cancer.