Champagne Julien, Nielsen Morten M, Feng Xiaodong, Montenegro Navarro Jasmine, Pataskar Abhijeet, Voogd Rhianne, Giebel Lisanne, Nagel Remco, Berenst Nadine, Fumagalli Amos, Kochavi Adva, Lovecchio Domenica, Valcanover Lorenzo, Malka Yuval, Yang Weiwen, Laos Maarja, Li Yingqian, Proost Natalie, van de Ven Marieke, van Tellingen Olaf, Bleijerveld Onno B, Haanen John B A G, Olweus Johanna, Agami Reuven
Division of Oncogenomics, Oncode institute, the Netherlands Cancer Institute, Amsterdam, the Netherlands.
Department of Cancer Immunology, Institute for Cancer Research, Oslo University Hospital Radiumhospitalet, Oslo, Norway; Precision Immunotherapy Alliance, University of Oslo, Oslo, Norway.
Immunity. 2025 Jan 14;58(1):247-262.e9. doi: 10.1016/j.immuni.2024.12.004. Epub 2025 Jan 3.
Prolonged exposure to interferon-gamma (IFNγ) and the associated increased expression of the enzyme indoleamine 2,3-dioxygenase 1 (IDO1) create an intracellular shortage of tryptophan in the cancer cells, which stimulates ribosomal frameshifting and tryptophan to phenylalanine (W>F) codon reassignments during protein synthesis. Here, we investigated whether such neoepitopes can be useful targets of adoptive T cell therapy. Immunopeptidomic analyses uncovered hundreds of W>F neoepitopes mainly presented by the HLA-A24:02 allele. We identified a T cell receptor (TCR) possessing high affinity and specificity toward TMBIM6/HLA-A24:02, the inducible W>F neoepitope with the broadest expression across cancer cell lines. TCR T cells are activated by tryptophan-depleted cancer cells but not by non-cancer cells. Finally, we provide in vivo proof of concept for clinical application, whereby TCR T cells promote cancer cell killing by TCR T cells through the generation of W>F neoepitopes. Thus, neoepitopes arising from W>F substitution present shared and highly expressed immunogenic targets with the potential to overcome current limitations in adoptive T cell therapy.
长期暴露于干扰素-γ(IFNγ)以及随之而来的吲哚胺2,3-双加氧酶1(IDO1)表达增加,会导致癌细胞内色氨酸短缺,这会在蛋白质合成过程中刺激核糖体移码以及色氨酸到苯丙氨酸(W>F)的密码子重新分配。在此,我们研究了此类新表位是否可成为过继性T细胞疗法的有用靶点。免疫肽组学分析发现了数百个主要由HLA-A24:02等位基因呈递的W>F新表位。我们鉴定出一种对TMBIM6/HLA-A24:02具有高亲和力和特异性的T细胞受体(TCR),TMBIM6/HLA-A24:02是在癌细胞系中表达最广泛的可诱导W>F新表位。TCR T细胞被色氨酸耗竭的癌细胞激活,但不被非癌细胞激活。最后,我们提供了临床应用的体内概念验证,即TCR T细胞通过产生W>F新表位促进TCR T细胞杀伤癌细胞。因此,由W>F替换产生的新表位呈现出共享且高表达的免疫原性靶点,有可能克服当前过继性T细胞疗法的局限性。
