A method for suppression of progress of, suppression of recurrence of and/or treatment of cancer, by administering an Allergin-1 antagonist in a therapy of a cancer patient with insufficient therapeutic efficacy by a tumor immunotherapeutic agent, or a cancer therapy in combination with an anti-cancer drug.

The invention relates to a chimeric gallinaceous bird embryo comprising both types of exogenous cells: a. At least one population of cancer cells, and b. At least one population of immune cells, wherein said exogenous cancer cells are present in at least one tissue of said embryo, and said exogenous immune cells are present in at least one tissue of said embryo and/or circulate in the blood vessels of said embryo.

Provided herein, inter alia, are compositions and methods including recombinant oncolytic viruses expressing human IL-15 and human IL-15Rα-sushi domain for the treatment of cancer and immune disorders. The recombinant oncolytic viruses may be used in combination with immune cells expressing chimeric antigen receptors (CAR) targeting EGFR and EGFR mutants.

Provided are CAR-T compositions that are directed to GPC3, including chimeric receptors, and engineered immune cells to GPC3. The disclosure also provides vectors, compositions, and methods of treatment using GPC3 antigen binding molecules and engineered immune cells. GPC3 CAR compositions provided herein can be used for the treatment of certain cancers.

An antigen-loaded nanogel is formed by loading or encapsulating one or more long peptide antigens or one or more protein antigens in a hydrophobized polysaccharide. The long peptide antigen(s) or protein antigen(s) contains (or each contain) one or more CD8+ cytotoxic T cell recognition epitopes and/or one or more CD4+ helper T cell recognition epitopes, which is/are derived from the antigen. The antigen-loaded nanogel is administered at least one day prior to administration of antigen-specific T cells to improve the efficacy of a T cell infusion therapy against an immune checkpoint inhibitor-resistant tumor. The hydrophobized polysaccharide may be pullulan having cholesteryl groups bound thereto. An immune-enhancing agent also may be administered in or with the antigen-loaded nanogel.

The present invention relates to a pharmaceutical composition comprising a compound of formula (I) ##STR00001##
and methods of treating or preventing cell proliferation disorders comprising administering to a subject a therapeutically active amount or a preventive amount of such a compound.

The invention provides in vivo methods for identifying cancer-associated immunotherapy targets.

Disclosed herein are antigenic peptide-MHC complexes, termed comPACT polypeptides and comPACT polynucleotides, and methods of producing such complexes. Also discloses herein are methods of producing libraries of comPACT polynucleotides and polypeptides, and their exemplary use in capturing cancer neoepitope-reactive T cells with high accuracy. Dual particle detection approaches for detection of neoantigen specific T cells with improved sensitivity and specificity are provided. Signal to noise ratio analysis of isolated T cells for detection of neoantigen-specific T cells with improved T cells is also provided.

Among the various aspects of the present disclosure is the provision of engineered cells, animal models, and uses thereof for modeling low grade glioma (LGG). An aspect of the present disclosure provides for a population of cells engineered to silence, downregulate, knock out, or reduce or knock down Cxcl10 expression. Another aspect of the present disclosure provides for an animal engineered to be deficient in Cxcl10, downregulate or reduce expression of Cxcl10, knock out Cxcl10, or knock down Cxcl10 (e.g., Cxcl10.sup.−/− mice). Yet another aspect of the present disclosure provides for a method of growing tumor cell lines or patient-derived xenografts for LGG tumors in an animal (e.g., mouse, rat) including providing a mouse or rat harboring somatic homozygous deletion in the Rag1 or Cxcl10 gene, and implanting an amount of the cells in mice sufficient to grow a tumor.

The invention relates to the field of virology and tumor therapy. In particular, the present invention provides a recombinant herpes simplex virus (HSV) capable of specifically replicating at a high level in a tumor cell and effectively killing the tumor cell, but replicating at low levels in normal cells, thereby the recombinant herpes simplex virus of the present invention not only has high lethality against tumor cells, but also has significantly decreased side effects (especially neurotoxicity). Further, the present invention relates to a viral vector constructed based on the recombinant herpes simplex virus, a pharmaceutical composition comprising the recombinant herpes simplex virus or the viral vector, and the use of the recombinant herpes simplex virus or the viral vector. The recombinant herpes simplex virus of the present invention can be used to infect and kill tumor cells, and can be used for gene drug delivery into tumor cells for gene therapy.