The present disclosure provides methods and compositions for enhancing the immune response toward cancers and pathogens. The presently disclosed subject matter provides methods and compositions for enhancing the immune response toward cancers and pathogens. It relates to cells comprising a c-Kit mutant, e.g., a c-Kit mutant comprising an activating mutation. The cells can further comprise an antigen-recognizing receptor (e.g., a chimeric antigen receptors (CAR) or a T cell receptors (TCR)). The presently disclosed subject matter relates to the use of cells for treatment, e.g., treating cancers.

This document provides methods and materials for assessing a mammal having or suspected of having cancer and/or for treating a mammal having cancer. For example, molecules including one or more antigen-binding domains (e.g., a single-chain variable fragment (scFv)) that can bind to a modified peptide (e.g., a tumor antigen), as well as method for using such molecules, are provided.

The present disclosure provides methods of promoting a persistent effector function of immune cells, comprising modifying the cells to overexpress c-Jun and reduced levels of a NR4A gene and/or protein. Also provided are modified cells, e.g., immune cell, which have been modified to overexpress c-Jun and express reduced levels of NR4A gene and/or protein. Overexpressing c-Jun and simultaneously reducing expression levels of a NR4A gene and/or protein leads to exhaustion/dysfunction resistant cells, which are apoptosis resistant and also immune checkpoint resistant, and also to the maintenance of anti-tumor function in tumor microenvironments.

A splice variant of bcr-abl mRNA that produces BCR-ABL protein with a truncated C-terminus and its role in resistance to treatment with kinase inhibitors is disclosed. Vectors for expressing the truncated gene product are provided as well as recombinant cells that express the truncated gene product from a cDNA construct. Also provided are methods compositions and kits for detecting the BCR-ABL splice variant. Additionally, methods for screening BCR-ABL kinase domain inhibitors which rely on the recombinant cells and methods of predicting likelihood for resistance of a CML patient with a BCR/ABL translocation respond to treatment with one or more BCR-ABL kinase inhibitors are also disclosed.

A splice variant of bcr-abl mRNA that produces BCR-ABL protein with a truncated C-terminus and its role in resistance to treatment with kinase inhibitors is disclosed. Vectors for expressing the truncated gene product are provided as well as recombinant cells that express the truncated gene product from a cDNA construct. Also provided are methods compositions and kits for detecting the BCR-ABL splice variant. Additionally, methods for screening BCR-ABL kinase domain inhibitors which rely on the recombinant cells and methods of predicting likelihood for resistance of a CML patient with a BCR/ABL translocation respond to treatment with one or more BCR-ABL kinase inhibitors are also disclosed.

A cell of the present invention contains a nucleic acid construct encoding a WT1 gene product or a fragment of the WT1 gene product. The nucleic acid construct contains (i) a region encoding a desired fragment of the WT1 gene product and (ii) only AUG as a functional start codon. The present invention can provide a cell into which the nucleic acid construct is introduced so that an expression level of a WT1 gene product or a fragment of the WT1 gene product is remarkably enhanced.

A cell of the present invention contains a nucleic acid construct encoding a WT1 gene product or a fragment of the WT1 gene product. The nucleic acid construct contains (i) a region encoding a desired fragment of the WT1 gene product and (ii) only AUG as a functional start codon. The present invention can provide a cell into which the nucleic acid construct is introduced so that an expression level of a WT1 gene product or a fragment of the WT1 gene product is remarkably enhanced.

Methods and compositions for treating a urothelial and/or a micropapillary carcinoma, such as a micropapillary urothelial carcinoma are disclosed.

Methods and compositions for treating a urothelial and/or a micropapillary carcinoma, such as a micropapillary urothelial carcinoma are disclosed.

[Object] To provide a novel examination method for a cancer treatment effect, screening method for a peptide for a cancer vaccine, and peptide and composition for inducing an immune response against cancer. [Solving Means] Provided are an examination method for a cancer treatment effect and a screening method for a peptide for a cancer vaccine each including detecting an antibody against a cancer/testis antigen or an anti-p53 antibody in a sample. It is suitable that an anti-XAGE1 antibody (IgG and/or IgA) be detected, or an anti-NY-ESO-1 antibody (IgG) be detected. Also provided are a novel peptide and novel composition for inducing immune responses against cancer.