Literature DB >> 33414997

CD4+ T cell exhaustion leads to adoptive transfer therapy failure which can be prevented by immune checkpoint blockade.

Jinfei Fu1,2, Anze Yu1,3, Xiang Xiao1,4, Juyu Tang2, Xiongbing Zu3, Wenhao Chen1,4, Bin He1,5.   

Abstract

Cytotoxic CD8+ T cell exhaustion is one of the mechanisms underlying the tumor immune escape. The paradigm-shifting immune checkpoint therapy can mitigate CD8+ T lymphocyte exhaustion, reinvigorate the anticancer immunity, and achieve durable tumor regression for some patients. Emerging evidence indicates that CD4+ T lymphocytes also have a critical role in anticancer immunity, either by directly applying cytotoxicity toward cancer cells or as a helper to augment CD8+ T cell cytotoxicity. Whether anticancer CD4+ T lymphocytes undergo exhaustion during immunotherapy of solid tumors remains unknown. Here we report that melanoma antigen TRP-1/gp75-specific CD4+ T lymphocytes exhibit an exhaustion phenotype after being adoptively transferred into mice bearing large subcutaneous melanoma. Exhaustion of these CD4+ T lymphocytes is accompanied with reduced cytokine release and increased expression of inhibitory receptors, resulting in loss of tumor control. Importantly, we demonstrate that PD-L1 immune checkpoint blockade can prevent exhaustion, induce proliferation of the CD4+ T lymphocytes, and consequently prevent tumor recurrence. Therefore, when encountering an excessive amount of tumor antigens, tumor-reactive CD4+ T lymphocytes also enter the exhaustion state, which can be prevented by immune checkpoint blockade. Our results highlight the importance of tumor-specific CD4+ T lymphocytes in antitumor immunity and suggest that the current immune checkpoint blockade therapy may achieve durable anticancer efficacy by rejuvenating both tumor antigen-specific CD8+ T lymphocytes and CD4+ T lymphocytes. AJCR
Copyright © 2020.

Entities:  

Keywords:  CD4+ T cells; adoptive transfer therapy; exhaustion; immune checkpoint blockade

Year:  2020        PMID: 33414997      PMCID: PMC7783768     

Source DB:  PubMed          Journal:  Am J Cancer Res        ISSN: 2156-6976            Impact factor:   6.166


  21 in total

1.  Checkpoint Blockade Immunotherapy Induces Dynamic Changes in PD-1-CD8+ Tumor-Infiltrating T Cells.

Authors:  Sema Kurtulus; Asaf Madi; Giulia Escobar; Max Klapholz; Jackson Nyman; Elena Christian; Mathias Pawlak; Danielle Dionne; Junrong Xia; Orit Rozenblatt-Rosen; Vijay K Kuchroo; Aviv Regev; Ana C Anderson
Journal:  Immunity       Date:  2019-01-08       Impact factor: 31.745

2.  Intratumoral Tcf1+PD-1+CD8+ T Cells with Stem-like Properties Promote Tumor Control in Response to Vaccination and Checkpoint Blockade Immunotherapy.

Authors:  Imran Siddiqui; Karin Schaeuble; Vijaykumar Chennupati; Silvia A Fuertes Marraco; Sandra Calderon-Copete; Daniela Pais Ferreira; Santiago J Carmona; Leonardo Scarpellino; David Gfeller; Sylvain Pradervand; Sanjiv A Luther; Daniel E Speiser; Werner Held
Journal:  Immunity       Date:  2019-01-08       Impact factor: 31.745

3.  Naive tumor-specific CD4(+) T cells differentiated in vivo eradicate established melanoma.

Authors:  Ying Xie; Akgül Akpinarli; Charles Maris; Edward L Hipkiss; Malcolm Lane; Eun-Kyung M Kwon; Pawel Muranski; Nicholas P Restifo; Paul Andrew Antony
Journal:  J Exp Med       Date:  2010-02-15       Impact factor: 14.307

4.  Tumor-specific Th17-polarized cells eradicate large established melanoma.

Authors:  Pawel Muranski; Andrea Boni; Paul A Antony; Lydie Cassard; Kari R Irvine; Andrew Kaiser; Chrystal M Paulos; Douglas C Palmer; Christopher E Touloukian; Krzysztof Ptak; Luca Gattinoni; Claudia Wrzesinski; Christian S Hinrichs; Keith W Kerstann; Lionel Feigenbaum; Chi-Chao Chan; Nicholas P Restifo
Journal:  Blood       Date:  2008-03-19       Impact factor: 22.113

5.  Removal of homeostatic cytokine sinks by lymphodepletion enhances the efficacy of adoptively transferred tumor-specific CD8+ T cells.

Authors:  Luca Gattinoni; Steven E Finkelstein; Christopher A Klebanoff; Paul A Antony; Douglas C Palmer; Paul J Spiess; Leroy N Hwang; Zhiya Yu; Claudia Wrzesinski; David M Heimann; Charles D Surh; Steven A Rosenberg; Nicholas P Restifo
Journal:  J Exp Med       Date:  2005-10-03       Impact factor: 14.307

6.  Clonal replacement of tumor-specific T cells following PD-1 blockade.

Authors:  Kathryn E Yost; Ansuman T Satpathy; Daniel K Wells; Yanyan Qi; Chunlin Wang; Robin Kageyama; Katherine L McNamara; Jeffrey M Granja; Kavita Y Sarin; Ryanne A Brown; Rohit K Gupta; Christina Curtis; Samantha L Bucktrout; Mark M Davis; Anne Lynn S Chang; Howard Y Chang
Journal:  Nat Med       Date:  2019-07-29       Impact factor: 53.440

7.  MHC-II neoantigens shape tumour immunity and response to immunotherapy.

Authors:  Elise Alspach; Danielle M Lussier; Alexander P Miceli; Ilya Kizhvatov; Michel DuPage; Adrienne M Luoma; Wei Meng; Cheryl F Lichti; Ekaterina Esaulova; Anthony N Vomund; Daniele Runci; Jeffrey P Ward; Matthew M Gubin; Ruan F V Medrano; Cora D Arthur; J Michael White; Kathleen C F Sheehan; Alex Chen; Kai W Wucherpfennig; Tyler Jacks; Emil R Unanue; Maxim N Artyomov; Robert D Schreiber
Journal:  Nature       Date:  2019-10-23       Impact factor: 49.962

8.  SLAMF6​ deficiency augments tumor killing and skews toward an effector phenotype revealing it as a novel T cell checkpoint.

Authors:  Emma Hajaj; Galit Eisenberg; Shiri Klein; Shoshana Frankenburg; Sharon Merims; Inna Ben David; Thomas Eisenhaure; Sarah E Henrickson; Alexandra Chloé Villani; Nir Hacohen; Nathalie Abudi; Rinat Abramovich; Jonathan E Cohen; Tamar Peretz; Andre Veillette; Michal Lotem
Journal:  Elife       Date:  2020-03-03       Impact factor: 8.140

9.  Chromatin states define tumour-specific T cell dysfunction and reprogramming.

Authors:  Mary Philip; Lauren Fairchild; Liping Sun; Ellen L Horste; Steven Camara; Mojdeh Shakiba; Andrew C Scott; Agnes Viale; Peter Lauer; Taha Merghoub; Matthew D Hellmann; Jedd D Wolchok; Christina S Leslie; Andrea Schietinger
Journal:  Nature       Date:  2017-05-17       Impact factor: 49.962

10.  cDC1 prime and are licensed by CD4+ T cells to induce anti-tumour immunity.

Authors:  Stephen T Ferris; Vivek Durai; Renee Wu; Derek J Theisen; Jeffrey P Ward; Michael D Bern; Jesse T Davidson; Prachi Bagadia; Tiantian Liu; Carlos G Briseño; Lijin Li; William E Gillanders; Gregory F Wu; Wayne M Yokoyama; Theresa L Murphy; Robert D Schreiber; Kenneth M Murphy
Journal:  Nature       Date:  2020-08-12       Impact factor: 49.962
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  2 in total

Review 1.  Clinical implications of T cell exhaustion for cancer immunotherapy.

Authors:  Andrew Chow; Karlo Perica; Christopher A Klebanoff; Jedd D Wolchok
Journal:  Nat Rev Clin Oncol       Date:  2022-10-10       Impact factor: 65.011

Review 2.  CD4 T-Cell Exhaustion: Does It Exist and What Are Its Roles in Cancer?

Authors:  Alexandra M Miggelbrink; Joshua D Jackson; Selena J Lorrey; Ethan S Srinivasan; Jessica Waibl-Polania; Daniel S Wilkinson; Peter E Fecci
Journal:  Clin Cancer Res       Date:  2021-06-14       Impact factor: 12.531
  2 in total

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