The disclosure provides synthetic immune receptors (SIRs), nucleic acids encoding the SIRs, methods of making and using the SIRs, in, for example, adoptive cell therapy.

The present disclosure provides ex vivo methods which employ modified cells of leukemic origin to enhance the efficacy of adoptive cell therapy.

Disclosed in the present invention are a TCR nd an application thereof. The TCR comprises a TCR -chain variable region and/or a TCR -chain variable region. The TCR can specifically recognize and bind to HLA-A*02:01/SLLMWITQC, and is characterized in that the affinity K.sub.D1 of the TCR for the HLA-A*02:01/SLLMWITQC is 0.1-10 M. The TCR can also specifically recognize and bind to one or more of HLA-A*02:03/SLLMWITQC, HLA-A*02:09/SLLMWITQC, HLA-A*02:12/SLLMWITQC, and HLA-A*02:16/SLLMWITQC, and the affinity K.sub.D2 is 0.1-85 M. The TCR in the present invention has extremely high affinity, excellent safety, and wider applicability.

The invention involves generating a T cell response to subdominant antigens and using the cells to therapeutically change the cellular homeostasis and nature of the immune response. In a preferred embodiment, the cells are generated outside of the patient avoiding the influence of the patient's immunologic milieu. By stimulating and growing the T cells from a patient in a tissue culture to one or more subdominant antigens and the transplanting them into the patient, if enough cells are expanded and transplanted, the transplanted cells overwhelm the endogenous dominant T cells in the response to either break or induce immune tolerance or otherwise modify the immune response to the cells or organism expressing that antigen. When the memory cells are established they are then reflective of this new immunodominance hierarchy so that the desired therapeutic effect is long lasting. In effect, the transplantation exogenously generated T cells reactive to the subdominant antigens is recapitulating priming and rebalancing the patient's immune response to target previously subdominant antigens in the cells or organism to produce a therapeutic benefit.

The invention involves generating a T cell response to subdominant antigens and using the cells to therapeutically change the cellular homeostasis and nature of the immune response. In a preferred embodiment, the cells are generated outside of the patient avoiding the influence of the patient's immunologic milieu. By stimulating and growing the T cells from a patient in a tissue culture to one or more subdominant antigens and the transplanting them into the patient, if enough cells are expanded and transplanted, the transplanted cells overwhelm the endogenous dominant T cells in the response to either break or induce immune tolerance or otherwise modify the immune response to the cells or organism expressing that antigen. When the memory cells are established they are then reflective of this new immunodominance hierarchy so that the desired therapeutic effect is long lasting. In effect, the transplantation exogenously generated T cells reactive to the subdominant antigens is recapitulating priming and rebalancing the patient's immune response to target previously subdominant antigens in the cells or organism to produce a therapeutic benefit.

The invention involves generating a T cell response to subdominant antigens and using the cells to therapeutically change the cellular homeostasis and nature of the immune response. In a preferred embodiment, the cells are generated outside of the patient avoiding the influence of the patient's immunologic milieu. By stimulating and growing the T cells from a patient in a tissue culture to one or more subdominant antigens and the transplanting them into the patient, if enough cells are expanded and transplanted, the transplanted cells overwhelm the endogenous dominant T cells in the response to either break or induce immune tolerance or otherwise modify the immune response to the cells or organism expressing that antigen. When the memory cells are established they are then reflective of this new immunodominance hierarchy so that the desired therapeutic effect is long lasting. In effect, the transplantation exogenously generated T cells reactive to the subdominant antigens is recapitulating priming and rebalancing the patient's immune response to target previously subdominant antigens in the cells or organism to produce a therapeutic benefit.

The invention involves generating a T cell response to subdominant antigens and using the cells to therapeutically change the cellular homeostasis and nature of the immune response. In a preferred embodiment, the cells are generated outside of the patient avoiding the influence of the patient's immunologic milieu. By stimulating and growing the T cells from a patient in a tissue culture to one or more subdominant antigens and the transplanting them into the patient, if enough cells are expanded and transplanted, the transplanted cells overwhelm the endogenous dominant T cells in the response to either break or induce immune tolerance or otherwise modify the immune response to the cells or organism expressing that antigen. When the memory cells are established they are then reflective of this new immunodominance hierarchy so that the desired therapeutic effect is long lasting. In effect, the transplantation exogenously generated T cells reactive to the subdominant antigens is recapitulating priming and rebalancing the patient's immune response to target previously subdominant antigens in the cells or organism to produce a therapeutic benefit.

Provided are methods, compositions, recombinant DNA molecules, and kits for cloning T cell receptors (TCRs). The methods facilitate construction of TCR expression libraries from biological samples containing antigen-specific T cells, including but not limited to tumor biopsies, including frozen tumor biopsies. Peripheral T cells that were engineered with library-derived TCR genes show potent therapeutic anti-tumor effects. The method can be performed using any sample that contains T cells, and can be performed with oligoclonal populations of T cells, such as T cells that have infiltrated a tumor. Primer combinations for first strand cDNA synthesis, second strand cDNA synthesis, and for cloning a plurality of distinct TCR and TCR chains into a plurality of vectors are provided. Cells containing the vectors are provided, as are kits for use in rapid cloning of the TCR and TCR chains.

Described herein are engineered antigen presenting cells that can be capable of modulating a target T-cell in a T-cell antigen specific manner. In some embodiments, the engineered APCs can include a modified antigen presentation pathway. Also described herein are methods of making and using the engineered antigen presenting cells.

Disclosed are compositions and methods for targeted treatment of cancer. The present disclosure provides chimeric antigen receptors and cells expressing such chimeric antigen receptors. In certain embodiments, engineered cells expressing the chimeric antigen receptors are specific for a low density cancer antigen or peptide in groove antigen.