Predominant mutated non-canonical tumor-specific antigens identified by proteogenomics demonstrate immunogenicity and tumor suppression in CRC.

Tumor-specific antigens (TSAs) are crucial for activating T cells against cancer, but traditional discovery methods focusing on exonic mutations overlook non-canonical TSAs from non-coding regions. We employed an integrative proteogenomic strategy combining whole-genome and RNA sequencing with immunoprecipitation mass spectrometry to comprehensively explore TSA generation in colorectal cancer patients. Analysis of 10 paired tumor samples identified 96 mutated major histocompatibility complex class I-presented neo-epitopes, with 80.21% originating from non-coding regions. In hypermutated tumors with high mutational burden, neo-epitopes predominantly arose from intergenic and intronic areas, while in non-hypermutated tumors with low mutational burden, they mainly stemmed from coding variations and alternative splicing events. Functional validation in mouse models demonstrated that mutated non-canonical neo-epitopes effectively activated CD8(+) T cells and significantly suppressed tumor growth. These findings underscore the importance of considering the entire genomic landscape in TSA discovery, suggesting new avenues for personalized immunotherapy.