In one aspect, the present invention provides a method for treating cancer comprising tumor cell vaccination in combination with hematopoietic and immune cell transplantation. In some embodiments, the method involves autologous tumor cell vaccination prior to autologous hematopoietic and immune cell transplantation. In another aspect, the present invention provides a method of purifying tumor cells from a subject in preparation for vaccination.

This invention provides compositions and methods for cryoprotection of recombinant live cancer cells. Specifically, an improved cryoprotective medium is provided which includes a hydroxyethyl starch and/or derivative thereof alone or in combination with either DMSO or glycerol.

The present disclosure provides an allogeneic whole cell cancer vaccine platform that includes compositions and methods for treating and preventing cancer. Provided herein are compositions containing a therapeutically effective amount of cells from one or more cancer cell lines, some or all of which are modified to (i) inhibit or reduce expression of one or more immunosuppressive factors by the cells, and/or (ii) express or increase expression of one or more immunostimulatory factors by the cells, and/or (iii) express or increase expression of one or more tumor-associated antigens (TAAs), including TAAs that have been mutated, and which comprise cancer cell lines that natively express a heterogeneity of tumor associated antigens and/or neoantigens. Also provided herein are methods of making the vaccine compositions, methods of preparing, and methods of use thereof.

The invention provides a tumor vaccine and method for producing the same. The tumor vaccine comprises cell vesicles derived from apoptotic tumor cells and an adjuvant. The invention further provides a preparation method of the tumor vaccine, comprising the steps of using the UV to irradiate the tumor cells to induce apoptosis, and collecting the cell vesicles released from the apoptotic tumor cells and then mixing the cell vesicles with the adjuvant to form the tumor vaccine. The tumor vaccine provided by the invention contains a broad and comprehensive tumor antigen spectrum, the defect that the existing tumor vaccine cannot have the killing capacity against the broad tumor cells can be overcome, and at the same time the tumor vaccine has good use safety and immune targeting property.

Compounds, compositions, and methods for use in inhibiting the E3 enzyme Cbl-b in the ubiquitin proteasome pathway are disclosed. The compounds, compositions, and methods can be used to modulate the immune system, to treat diseases amenable to immune system modulation, and for treatment of cells in vivo, in vitro, or ex vivo. Also disclosed are pharmaceutical compositions comprising a Cbl-b inhibitor and a cancer vaccine, as well as methods for treating cancer using a Cbl-b inhibitor and a cancer vaccine; and pharmaceutical compositions comprising a Cbl-b inhibitor and an oncolytic virus, as well as methods for treating cancer using a Cbl-b inhibitor and an oncolytic virus.

This document provides novel compositions and methods utilizing immunomodulating agents that can stimulate or indirectly augment the immune system, or can have an immunosuppressive effect. TNFR25 agonists disclosed herein have an anti-inflammatory and healing effect. They can be used, e.g., to treat disease caused by asthma and chronic inflammation, such as inflammatory bowel diseases including ulcerative colitis and Crohn's Disease. TNFR25 antagonists disclosed herein can inhibit CD8 T cell-mediated cellular immune responses and can, for example, mitigate organ or tissue rejection following a tissue transplantation. TNFR25 agonists disclosed herein represent biological response modifiers that alter the interaction between the body's cellular immune defenses and cancer cells to boost, direct, or restore the body's ability to fight the cancer when given with tumor vaccines. TNFR25 specific immunotoxins disclosed herein are also capable of increasing the effectiveness of a chemotherapeutic regimen by depleting a cancer patient of naturally occurring immunosuppressive cells.

The inventors provide a new therapeutic strategy to treat cancers expressing embryonic antigens. Accordingly, the present invention relates to a method of treating a subject suffering from a cancer comprising a step of administration simultaneously, separately or sequentially to said subject a therapeutically amount of i) a population of derived engineered fetal stem cells carrying cancer associated fetal neo-antigen and ii) a compound selected from a group which activates immune response, as a combined preparation.

The present invention relates to a transduced cancer cell line stably expressing a leukemia tumor antigen, wherein the cancer cell line is cervical cancer cells, breast cancer cells, ovarian cancer cells, pancreatic cancer cells, lung cancer cells, or glioblastoma cells. The transduced adherent cell line of the present invention is useful for many pre-clinical applications such as real time cytotoxicity assay or to test the effects of CAR-T cells that target the tumor antigen. The present invention is exemplified by Hela cell line stably expressing CD19.

Adjuvants acting at the level of antigen presentation useful for stimulation of specific immunity against tumor endothelial cells. In one embodiment the invention teaches the use of activation of specific antigen presenting cell programs to selectively induce cytotoxic T cells and antibodies with complement activating ability while not evoking antigenic responses that potentially stimulate angiogenesis or growth of tumor endothelial cells. Specifically, the invention teaches selection and use of adjuvants that inhibit suppressive dendritic cell produced factors, surface bound and soluble, while stimulating activatory cytokines. Adjuvant means include innate activatory molecules, gene silencing means, alarmins, and other stimulatory means resembling “danger” signals.

The present disclosure relates to modified extracellular vesicles, e.g., exosomes, comprising a targeting moiety, wherein the targeting moiety can specifically bind to markers expressed on distinct immune cells (e.g., dendritic cells). Also provided herein are methods for using the exosomes to treat and/or prevent a range of medical disorders.