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Literature DB >> 34433638

LAG-3 expression on peripheral blood cells identifies patients with poorer outcomes after immune checkpoint blockade.

Ronglai Shen¹, Michael A Postow^2,3, Matthew Adamow^4,5, Arshi Arora¹, Margaret Hannum¹, Colleen Maher^2,5, Phillip Wong^4,5, Michael A Curran⁶, Travis J Hollmann^5,7, Liwei Jia^7,8, Hikmat Al-Ahmadie⁷, Niamh Keegan², Samuel A Funt^2,3, Gopa Iyer^2,3, Jonathan E Rosenberg^2,3, Dean F Bajorin^2,3, Paul B Chapman^2,3, Alexander N Shoushtari^2,3, Allison S Betof^2,3, Parisa Momtaz^2,3, Taha Merghoub^2,3,5,9,10, Jedd D Wolchok^2,3,5,9,10, Katherine S Panageas¹, Margaret K Callahan^11,3,5.

Abstract

Immune checkpoint blocking antibodies are a cornerstone in cancer treatment; however, they benefit only a subset of patients and biomarkers to guide immune checkpoint blockade (ICB) treatment choices are lacking. We designed this study to identify blood-based correlates of clinical outcome in ICB-treated patients. We performed immune profiling of 188 ICB-treated patients with melanoma using multiparametric flow cytometry to characterize immune cells in pretreatment peripheral blood. A supervised statistical learning approach was applied to a discovery cohort to classify phenotypes and determine their association with survival and treatment response. We identified three distinct immune phenotypes (immunotypes), defined in part by the presence of a LAG-3+CD8+ T cell population. Patients with melanoma with a LAG+ immunotype had poorer outcomes after ICB with a median survival of 22.2 months compared to 75.8 months for those with the LAG- immunotype (P = 0.031). An independent cohort of 94 ICB-treated patients with urothelial carcinoma was used for validation where LAG+ immunotype was significantly associated with response (P = 0.007), survival (P < 0.001), and progression-free survival (P = 0.004). Multivariate Cox regression and stratified analyses further showed that the LAG+ immunotype was an independent marker of outcome when compared to known clinical prognostic markers and previously described markers for the clinical activity of ICB, PD-L1, and tumor mutation burden. The pretreatment peripheral blood LAG+ immunotype detects patients who are less likely to benefit from ICB and suggests a strategy for identifying actionable immune targets for further investigation.

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Year: 2021 PMID： 34433638 PMCID： PMC9254663 DOI： 10.1126/scitranslmed.abf5107

Source DB: PubMed Journal: Sci Transl Med ISSN： 1946-6234 Impact factor: 19.319

36 in total

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Journal: Cancer Immunol Res Date: 2017-12-05 Impact factor: 11.151

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Journal: N Engl J Med Date: 2014-11-19 Impact factor: 91.245

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Journal: Science Date: 2015-03-12 Impact factor: 47.728

5. A phase I pharmacokinetic and biological correlative study of IMP321, a novel MHC class II agonist, in patients with advanced renal cell carcinoma.

Authors: Chrystelle Brignone; Bernard Escudier; Caroline Grygar; Manon Marcu; Frédéric Triebel
Journal: Clin Cancer Res Date: 2009-09-15 Impact factor: 12.531

Review 6. Inhibitory receptors and ligands beyond PD-1, PD-L1 and CTLA-4: breakthroughs or backups.

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Journal: Nat Immunol Date: 2019-10-14 Impact factor: 25.606

7. Absolute lymphocyte count as a prognostic biomarker for overall survival in patients with advanced melanoma treated with ipilimumab.

Authors: Michael A Postow; Scott D Chasalow; Deborah Kuk; Katherine S Panageas; Michael L Cheng; Jianda Yuan; Jedd D Wolchok
Journal: Melanoma Res Date: 2020-02 Impact factor: 3.199

8. Peripheral natural killer cells and myeloid-derived suppressor cells correlate with anti-PD-1 responses in non-small cell lung cancer.

Authors: Je-In Youn; Su-Myeong Park; Seyeon Park; Gamin Kim; Hee-Jae Lee; Jimin Son; Min Hee Hong; Aziz Ghaderpour; Bumseo Baik; Jahirul Islam; Ji-Woong Choi; Eun-Young Lee; Hang-Rae Kim; Sang-Uk Seo; Soonmyung Paik; Hong In Yoon; Inkyung Jung; Chun-Feng Xin; Hyun-Tak Jin; Byoung Chul Cho; Seung-Yong Seong; Sang-Jun Ha; Hye Ryun Kim
Journal: Sci Rep Date: 2020-06-03 Impact factor: 4.379

9. Pan-cancer identification of clinically relevant genomic subtypes using outcome-weighted integrative clustering.

Authors: Arshi Arora; Adam B Olshen; Venkatraman E Seshan; Ronglai Shen
Journal: Genome Med Date: 2020-12-03 Impact factor: 11.117

10. The role of PD-L1 expression as a predictive biomarker: an analysis of all US Food and Drug Administration (FDA) approvals of immune checkpoint inhibitors.

Authors: Andrew A Davis; Vaibhav G Patel
Journal: J Immunother Cancer Date: 2019-10-26 Impact factor: 13.751

15 in total

Review 1. Research Progress of Biomarkers for Immune Checkpoint Inhibitors on Digestive System Cancers.

Authors: Jingting Wang; Xiao Ma; Zhongjun Ma; Yan Ma; Jing Wang; Bangwei Cao
Journal: Front Immunol Date: 2022-04-13 Impact factor: 8.786

Review 2. A decade of checkpoint blockade immunotherapy in melanoma: understanding the molecular basis for immune sensitivity and resistance.

Authors: Alexander C Huang; Roberta Zappasodi
Journal: Nat Immunol Date: 2022-03-03 Impact factor: 31.250

3. LAG-3xPD-L1 bispecific antibody potentiates antitumor responses of T cells through dendritic cell activation.

Authors: Eunsil Sung; Minkyung Ko; Ju-Young Won; Yunju Jo; Eunyoung Park; Hyunjoo Kim; Eunji Choi; Ui-Jung Jung; Jaehyoung Jeon; Youngkwang Kim; Hyejin Ahn; Da-Som Choi; Seunghyun Choi; Youngeun Hong; Hyeyoung Park; Hanbyul Lee; Yong-Gyu Son; Kyeongsu Park; Jonghwa Won; Soo Jin Oh; Seonmin Lee; Kyu-Pyo Kim; Changhoon Yoo; Hyun Kyu Song; Hyung-Seung Jin; Jaeho Jung; Yoon Park
Journal: Mol Ther Date: 2022-05-06 Impact factor: 12.910

Review 4. Challenges and the Evolving Landscape of Assessing Blood-Based PD-L1 Expression as a Biomarker for Anti-PD-(L)1 Immunotherapy.

Authors: Tao Wang; Desirée Denman; Silvia M Bacot; Gerald M Feldman
Journal: Biomedicines Date: 2022-05-20

Review 5. Novel Immune Checkpoints in Esophageal Cancer: From Biomarkers to Therapeutic Targets.

Authors: Xueyin Zhou; Ting Ren; Hongyuan Zan; Chunyan Hua; Xufeng Guo
Journal: Front Immunol Date: 2022-05-20 Impact factor: 8.786

6. Clinical and molecular characteristics associated with response to therapeutic PD-1/PD-L1 inhibition in advanced Merkel cell carcinoma.

Authors: Ivelina Spassova; Selma Ugurel; Linda Kubat; Lisa Zimmer; Patrick Terheyden; Annalena Mohr; Hannah Björn Andtback; Lisa Villabona; Ulrike Leiter; Thomas Eigentler; Carmen Loquai; Jessica C Hassel; Thilo Gambichler; Sebastian Haferkamp; Peter Mohr; Claudia Pfoehler; Lucie Heinzerling; Ralf Gutzmer; Jochen S Utikal; Kai Horny; Hans-Ulrich Schildhaus; Daniel Habermann; Daniel Hoffmann; Dirk Schadendorf; Jürgen Christian Becker
Journal: J Immunother Cancer Date: 2022-01 Impact factor: 13.751

7. Case Report: Sarcoid-Like Reactions and Tertiary Lymphoid Structures Following Dual Checkpoint Inhibition in a Patient with Early-Stage Lung Adenocarcinoma.

Authors: Xiaoliang Zhao; Dongsheng Yue; Juanjuan Qian; Lei Zhang; Jin Song; Bin Zhang; Chunmei Zhang; Leina Sun; Yuchen Ma; Henghui Zhang; Changli Wang
Journal: Front Immunol Date: 2022-01-31 Impact factor: 7.561

Review 8. Seven mysteries of LAG-3: a multi-faceted immune receptor of increasing complexity.

Authors: Stephanie E A Burnell; Lorenzo Capitani; Bruce J MacLachlan; Georgina H Mason; Awen M Gallimore; Andrew Godkin
Journal: Immunother Adv Date: 2021-12-20

Review 9. Comparison of Laboratory Methods for the Clinical Follow Up of Checkpoint Blockade Therapies in Leukemia: Current Status and Challenges Ahead.

Authors: Basak Aru; Mojdeh Soltani; Cemil Pehlivanoglu; Ege Gürlü; Mazdak Ganjalikhani-Hakemi; Gülderen Yanikkaya Demirel
Journal: Front Oncol Date: 2022-01-27 Impact factor: 6.244

10. Combined angiogenesis and PD-1 inhibition for immunomodulatory TNBC: concept exploration and biomarker analysis in the FUTURE-C-Plus trial.

Authors: Song-Yang Wu; Ying Xu; Li Chen; Lei Fan; Xiao-Yan Ma; Shen Zhao; Xiao-Qing Song; Xin Hu; Wen-Tao Yang; Wen-Jun Chai; Xiao-Mao Guo; Xi-Zi Chen; Yan-Hui Xu; Xiao-Yu Zhu; Jian-Jun Zou; Zhong-Hua Wang; Yi-Zhou Jiang; Zhi-Ming Shao
Journal: Mol Cancer Date: 2022-03-25 Impact factor: 27.401