Abstract: A method for identifying T-cell epitopes which can be used to elicit T cells targeting cells capable of regenerating cancers is disclosed. The method identifies T-cell epitopes with a high curative potential, high potency and high probability of T cell recognition (HP). The method includes: (i) identifying high curative potential tumor protein target i.e., identifying HP-TP; (ii) identifying peptide sequences within the protein sequence of an HP-TP that have a high probability of eliciting T cell killing; and (iii) qualifying the sequence specificity based on the fold difference between the specific target and non-targets. The identified T-cell epitopes include a core sequence of 9 amino acids homologous to a sequence expressed within a qualified HP-TP. The T-cell epitopes can be used in a method for reprograming T cells to selectively attack tumor cells capable of perpetuating a tumor and treating patients, for example, cancer patients.

Abstract: A method for identifying T-cell epitopes which can be used to elicit T cells targeting cells capable of regenerating cancers is disclosed. The method identifies T-cell epitopes with a high curative potential, high potency and high probability of T cell recognition (HP). The method includes: (i) identifying high curative potential tumor protein target i.e., identifying HP-TP; (ii) identifying peptide sequences within the protein sequence of an HP-TP that have a high probability of eliciting T cell killing; and (iii) qualifying the sequence specificity based on the fold difference between the specific target and non-targets. The identified T-cell epitopes include a core sequence of 9 amino acids homologous to a sequence expressed within a qualified HP-TP. The T-cell epitopes can be used in a method for reprogramming T cells to selectively attack tumor cells capable of perpetuating a tumor and treating patients, for example, cancer patients.

Abstract: Finding biologically relevant cancer markers is key to developing an effective treatment. Once specific antigens have been identified that are present on the cell population responsible for propagating tumors, T cells can be genetically altered to target these antigens and then used for personalized T cell therapy. A method to identify and select peptide antigens that effectively associate with and are presented by host HLA surface molecules originating from tumor cells responsible for the persistence and propagation of a cancer has been developed. The system of using these data to produce T cells engineered to express T cell receptors recognizing the peptide antigens is used in the production of a personalized adoptive T cell therapy for cancer that eliminates the cells capable of tumor propagation and cancer progression. The system is especially useful in the production of cancer treatments to achieve complete durable remission of cancers of epithelial origin.

Abstract: Finding biologically relevant cancer markers is key to developing an effective treatment. Once specific antigens have been identified that are present on the cell population responsible for propagating tumors, T cells can be genetically altered to target these antigens and then used for personalized T cell therapy. A method to identify and select peptide antigens that effectively associate with and are presented by host HLA surface molecules originating from tumor cells responsible for the persistence and propagation of a cancer has been developed. The system of using these data to produce T cells engineered to express T cell receptors recognizing the peptide antigens is used in the production of a personalized adoptive T cell therapy for cancer that eliminates the cells capable of tumor propagation and cancer progression. The system is especially useful in the production of cancer treatments to achieve complete durable remission of cancers of epithelial origin.