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Written | My best friend, the old red hat, in the past three decades, a series of tumor antigens that can be recognized by T cells have been discovered [1], and the tumor antigens encoded by tumor-specific somatic mutations and the efficacy of immunotherapy This is closely related, and even more, studies have given evidence of a direct correlation between the efficacy of immunotherapy and somatic mutations in tumor lesions, for example, immunotherapy is more likely to work in cancer patients with abnormal DNA damage repair [ 2,3], while a study on melanoma infiltrating lymphocytes found that T cell-specific antigens encoded by somatic mutations were found in half of the patients [4]
.
Tumor antigens are one of the safest immune targets because they are not expressed in normal tissues.
However, how T cells discover and recognize these tumor antigens is still a big problem
.
The discovery of tumor antigens is usually achieved by algorithms based on major histocompatibility complexes, but this approach does not take into account the question of whether T cells can specifically recognize antigens
.
In fact, a large-scale study in 2019 found that only 1.6% of antigens could be recognized by T cells [5]
.
Therefore, there is an urgent need to establish a method that can rapidly discover antigens that T cells can recognize
.
On April 21, 2022, James C.
Yang's research group from the National Institutes of Health published an article in Cancer Cell entitled A phenotypic signature that identifies neoantigen-reactive T cells in fresh human lung cancers, which defines the identification of tumors Molecular signature of antigenic T cells
.
TCR-CITE sequencing enables rapid analysis and integration of cell surface molecular, cellular transcriptome, and T cell receptor (TCR) information at the single-cell level
.
Therefore, if a cell's TCR sequence is known, its transcriptome and cell surface molecule expression can also be predicted
.
The authors first recruited 4 patients with non-small cell lung cancer, and performed amplification and whole exome sequencing of lymphoid infiltrating cells in their tumor lesions.
Identify tumor-mutated TCRs
.
Among them, 7 groups were derived from CD8+ T cells, and 4 groups were derived from CD4+ T cells
.
Next, the authors compared each patient's tumor-specific CD8+ T cells with other CD8+ T cells at the protein and gene levels, and identified 24 groups of molecules that were significantly altered in several patients, including 22 groups that were up-regulated and 2 groups down
.
Among them, CD39 and CD103 are highly expressed in tumor antigen-specific T cells
.
In addition, up-regulated molecules include CXCL13[6,7], PDCD1, LAYN, CD27, BATF, TIGIT and MIR55HG, and down-regulated molecules include IL7R
.
Among the four patients, three CD8+ T cells expressed CD39 in 23% to 34%, while the fourth patient, the only patient who received anti-PD-1 antibody treatment, expressed only 5.7 % of CD8+ T cells express CD39
.
The proportion of CD8+ T cells expressing CXCL13 fluctuated between 2.5% and 11.1%
.
The content of antigen-specific CD4+ T cells is relatively small.
The authors integrated data from multiple sources and determined that CD4+ T cells that recognize tumor antigens also highly express CD39, TIGIT, and CXCL13
.
Among them, CD39+ T cells basically also highly express TIGIT, and such CD39+ TIGIT+ cells can be divided into two subtypes, one is FoxP3+ Treg, the other is CXCL13+ and contains basically all the tumor antigens that can specifically recognize clone
.
Finally, the authors analyzed 985 CD8+ T cells and 303 CD4+ T cells that could recognize tumor antigens, and found that among these CD8+ T cells, CD39, CD103 and PD-1 were highly expressed, CD4, CD8A, CD45RA, Low expression of CD62L and CD134
.
Transcriptome analysis of CD8+ T cells recognizing tumor antigens identified upregulation of CXCL13, ENTPD1, LAYN, TIGIT, BATF, GZMB, CD27 and PHLDA1, while downregulation of CD127
.
CXCL13, ENTPD1, ADGRG1, NMB, ITM2A, NR3C1 and ETV7 were highly expressed in CD4+ T cells
.
In conclusion, the authors identified a set of CD39 and CXCL13-based molecular signatures of T cells that can rapidly recognize tumor antigens by analyzing the transcriptome and TCR of tumor-infiltrating lymphocytes from four patients with non-small cell lung cancer
.
Of course, the sample size of 4 patients is relatively small, and whether the above results are universal remains to be discussed
.
Original link: https://doi.org/10.1016/j.ccell.2022.03.012
Publisher: Eleven References 1.
Morgan, RA, Dudley, ME, Yu, YYL, Zheng, Z.
, Robbins, PF, Theoret, MR, Wunderlich, JR, Hughes, MS, Restifo, NP, and Rosenberg, SA (2003).
High efficiency TCR gene transfer into primary human lymphocytes af- fords avid recognition of melanoma tumor antigen glycoprotein 100 and does not alter the recognition of autologous melanoma antigens.
J.
Immunol.
171, 3287–3295.2.Le, DT, Uram, JN, Wang, H., Bartlett, BR, Kemberling, H., Eyring, AD, Skora, AD, Luber, BS, Azad , NS, Laheru, D., et al.(2015).
PD-1 blockade in tumors with mismatch-repair deficiency.N.Engl.J.Med.372, 2509–2520.3.
Rizvi, NA, Hellmann, MD, Snyder , A., Kvistborg, P., Makarov, V., Havel, JJ, Lee, W., Yuan, J., Wong, P., Ho, TS, et al.(2015).
Mutational landscape de- termines sensitivity to PD-1 blockade in non-small cell lung cancer.
Science 348, 124–128.4.
Robbins, PF, Lu, Y.-C., El-Gamil, M., Li, YF, Gross , C., Gartner, J., Lin, JC, Teer, JK, Cliften, P., Tycksen, E., et al.(2013).
Mining exomic sequencing data to identify mutated antigens recognized by adoptively transferred tu- mor- reactive T cells.
Nat.Med.19, 747–752.5.
Parkhurst, MR, Robbins, PF, Tran, E., Prickett, TD, Gartner, JJ, Jia, L., Ivey, G., Li, YF, El -Gamil, M., Lalani, A., et al.
(2019).
Unique neoantigens arise from somatic mutations in patients with gastrointestinal cancers.
Cancer Discov.9, 1022–1035.6.
Li, H., van der Leun, AM, Yofe, I., Lubling, Y., Gelbard-Solodkin, D., van Akkooi, ACJ, van den Braber, M., Rozeman, EA, Haanen, JBAG, Blank, CU, et al.
(2018).
Dysfunctional CD8 T cells form a proliferative, dynamically regulated compartment within human melanoma.
Cell 176, 775– 789.e18.7.
Sade-Feldman, M., Yizhak, K., Bjorgaard, SL, Ray, JP, de Boer, CG , Jenkins, RW, Lieb, DJ, Chen, JH, Frederick, DT, Barzily-Rokni, M., et al.
(2018).Defining T cell states associated with response to checkpoint immunotherapy in melanoma.
Cell 175, 998–1013 .e20.
Instructions for reprinting [Original article] BioArt original articles are welcome to forward and share.
Reprinting is prohibited without permission.
The copyright of all works published is owned by BioArtInstructions for reprinting [Original article] BioArt original articles are welcome to forward and share, and reprinting is prohibited without permission.
The copyright of all works published is owned by BioArt
.
BioArt reserves all legal rights and violators will be held accountable
.
Morgan, RA, Dudley, ME, Yu, YYL, Zheng, Z.
, Robbins, PF, Theoret, MR, Wunderlich, JR, Hughes, MS, Restifo, NP, and Rosenberg, SA (2003).
High efficiency TCR gene transfer into primary human lymphocytes af- fords avid recognition of melanoma tumor antigen glycoprotein 100 and does not alter the recognition of autologous melanoma antigens.
J.
Immunol.
171, 3287–3295.2.Le, DT, Uram, JN, Wang, H., Bartlett, BR, Kemberling, H., Eyring, AD, Skora, AD, Luber, BS, Azad , NS, Laheru, D., et al.(2015).
PD-1 blockade in tumors with mismatch-repair deficiency.N.Engl.J.Med.372, 2509–2520.3.
Rizvi, NA, Hellmann, MD, Snyder , A., Kvistborg, P., Makarov, V., Havel, JJ, Lee, W., Yuan, J., Wong, P., Ho, TS, et al.(2015).
Mutational landscape de- termines sensitivity to PD-1 blockade in non-small cell lung cancer.
Science 348, 124–128.4.
Robbins, PF, Lu, Y.-C., El-Gamil, M., Li, YF, Gross , C., Gartner, J., Lin, JC, Teer, JK, Cliften, P., Tycksen, E., et al.(2013).
Mining exomic sequencing data to identify mutated antigens recognized by adoptively transferred tu- mor- reactive T cells.
Nat.Med.19, 747–752.5.
Parkhurst, MR, Robbins, PF, Tran, E., Prickett, TD, Gartner, JJ, Jia, L., Ivey, G., Li, YF, El -Gamil, M., Lalani, A., et al.
(2019).
Unique neoantigens arise from somatic mutations in patients with gastrointestinal cancers.
Cancer Discov.9, 1022–1035.6.
Li, H., van der Leun, AM, Yofe, I., Lubling, Y., Gelbard-Solodkin, D., van Akkooi, ACJ, van den Braber, M., Rozeman, EA, Haanen, JBAG, Blank, CU, et al.
(2018).
Dysfunctional CD8 T cells form a proliferative, dynamically regulated compartment within human melanoma.
Cell 176, 775– 789.e18.7.
Sade-Feldman, M., Yizhak, K., Bjorgaard, SL, Ray, JP, de Boer, CG , Jenkins, RW, Lieb, DJ, Chen, JH, Frederick, DT, Barzily-Rokni, M., et al.
(2018).Defining T cell states associated with response to checkpoint immunotherapy in melanoma.
Cell 175, 998–1013 .e20.
Instructions for reprinting [Original article] BioArt original articles are welcome to forward and share.
Reprinting is prohibited without permission.
The copyright of all works published is owned by BioArtInstructions for reprinting [Original article] BioArt original articles are welcome to forward and share, and reprinting is prohibited without permission.
The copyright of all works published is owned by BioArt
.
BioArt reserves all legal rights and violators will be held accountable
.
