Literature DB >> 32870971

The critical role of CD4+ T cells in PD-1 blockade against MHC-II-expressing tumors such as classic Hodgkin lymphoma.

Joji Nagasaki1,2,3,4, Yosuke Togashi1,2,3, Takeaki Sugawara5, Makiko Itami6, Nobuhiko Yamauchi1,2,7, Junichiro Yuda1,2,7, Masato Sugano8, Yuuki Ohara1,2,8, Yosuke Minami7, Hirohisa Nakamae4, Masayuki Hino4, Masahiro Takeuchi5, Hiroyoshi Nishikawa1,2,9.   

Abstract

Classic Hodgkin lymphoma (cHL) responds markedly to PD-1 blockade therapy, and the clinical responses are reportedly dependent on expression of major histocompatibility complex class II (MHC-II). This dependence is different from other solid tumors, in which the MHC class I (MHC-I)/CD8+ T-cell axis plays a critical role. In this study, we investigated the role of the MHC-II/CD4+ T-cell axis in the antitumor effect of PD-1 blockade on cHL. In cHL, MHC-I expression was frequently lost, but MHC-II expression was maintained. CD4+ T cells highly infiltrated the tumor microenvironment of MHC-II-expressing cHL, regardless of MHC-I expression status. Consequently, CD4+ T-cell, but not CD8+ T-cell, infiltration was a good prognostic factor in cHL, and PD-1 blockade showed antitumor efficacy against MHC-II-expressing cHL associated with CD4+ T-cell infiltration. Murine lymphoma and solid tumor models revealed the critical role of antitumor effects mediated by CD4+ T cells: an anti-PD-1 monoclonal antibody exerted antitumor effects on MHC-I-MHC-II+ tumors but not on MHC-I-MHC-II- tumors, in a cytotoxic CD4+ T-cell-dependent manner. Furthermore, LAG-3, which reportedly binds to MHC-II, was highly expressed by tumor-infiltrating CD4+ T cells in MHC-II-expressing tumors. Therefore, the combination of LAG-3 blockade with PD-1 blockade showed a far stronger antitumor immunity compared with either treatment alone. We propose that PD-1 blockade therapies have antitumor effects on MHC-II-expressing tumors such as cHL that are mediated by cytotoxic CD4+ T cells and that LAG-3 could be a candidate for combination therapy with PD-1 blockade.
© 2020 by The American Society of Hematology.

Entities:  

Mesh:

Substances:

Year:  2020        PMID: 32870971      PMCID: PMC7479950          DOI: 10.1182/bloodadvances.2020002098

Source DB:  PubMed          Journal:  Blood Adv        ISSN: 2473-9529


  54 in total

1.  Mass cytometry of Hodgkin lymphoma reveals a CD4+ regulatory T-cell-rich and exhausted T-effector microenvironment.

Authors:  Fathima Zumla Cader; Ron C J Schackmann; Xihao Hu; Kirsty Wienand; Robert Redd; Bjoern Chapuy; Jing Ouyang; Nicole Paul; Evisa Gjini; Mikel Lipschitz; Philippe Armand; David Wu; Jonathan R Fromm; Donna Neuberg; X Shirley Liu; Scott J Rodig; Margaret A Shipp
Journal:  Blood       Date:  2018-06-07       Impact factor: 22.113

Review 2.  CD4+ T cell help in cancer immunology and immunotherapy.

Authors:  Jannie Borst; Tomasz Ahrends; Nikolina Bąbała; Cornelis J M Melief; Wolfgang Kastenmüller
Journal:  Nat Rev Immunol       Date:  2018-10       Impact factor: 53.106

3.  Major Histocompatibility Complex Class II and Programmed Death Ligand 1 Expression Predict Outcome After Programmed Death 1 Blockade in Classic Hodgkin Lymphoma.

Authors:  Margaretha G M Roemer; Robert A Redd; Fathima Zumla Cader; Christine J Pak; Sara Abdelrahman; Jing Ouyang; Stephanie Sasse; Anas Younes; Michelle Fanale; Armando Santoro; Pier Luigi Zinzani; John Timmerman; Graham P Collins; Radhakrishnan Ramchandren; Jonathon B Cohen; Jan Paul De Boer; John Kuruvilla; Kerry J Savage; Marek Trneny; Stephen Ansell; Kazunobu Kato; Benedetto Farsaci; Anne Sumbul; Philippe Armand; Donna S Neuberg; Geraldine S Pinkus; Azra H Ligon; Scott J Rodig; Margaret A Shipp
Journal:  J Clin Oncol       Date:  2018-02-02       Impact factor: 44.544

4.  Tumor rejection by gene transfer of the MHC class II transactivator in murine mammary adenocarcinoma cells.

Authors:  Raffaella Meazza; Alberto Comes; Anna M Orengo; Silvano Ferrini; Roberto S Accolla
Journal:  Eur J Immunol       Date:  2003-05       Impact factor: 5.532

5.  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

6.  The expression of MHC class II molecules on murine breast tumors delays T-cell exhaustion, expands the T-cell repertoire, and slows tumor growth.

Authors:  Tyler R McCaw; Mei Li; Dmytro Starenki; Sara J Cooper; Mingyong Liu; Selene Meza-Perez; Rebecca C Arend; Donald J Buchsbaum; Andres Forero; Troy D Randall
Journal:  Cancer Immunol Immunother       Date:  2018-10-17       Impact factor: 6.968

Review 7.  Cancer immunoediting: integrating immunity's roles in cancer suppression and promotion.

Authors:  Robert D Schreiber; Lloyd J Old; Mark J Smyth
Journal:  Science       Date:  2011-03-25       Impact factor: 47.728

8.  Targeting VEGFR2 with Ramucirumab strongly impacts effector/ activated regulatory T cells and CD8+ T cells in the tumor microenvironment.

Authors:  Yasuko Tada; Yosuke Togashi; Daisuke Kotani; Takeshi Kuwata; Eichi Sato; Akihito Kawazoe; Toshihiko Doi; Hisashi Wada; Hiroyoshi Nishikawa; Kohei Shitara
Journal:  J Immunother Cancer       Date:  2018-10-11       Impact factor: 13.751

9.  Melanoma-specific MHC-II expression represents a tumour-autonomous phenotype and predicts response to anti-PD-1/PD-L1 therapy.

Authors:  Douglas B Johnson; Monica V Estrada; Roberto Salgado; Violeta Sanchez; Deon B Doxie; Susan R Opalenik; Anna E Vilgelm; Emily Feld; Adam S Johnson; Allison R Greenplate; Melinda E Sanders; Christine M Lovly; Dennie T Frederick; Mark C Kelley; Ann Richmond; Jonathan M Irish; Yu Shyr; Ryan J Sullivan; Igor Puzanov; Jeffrey A Sosman; Justin M Balko
Journal:  Nat Commun       Date:  2016-01-29       Impact factor: 14.919

10.  Adaptive resistance to therapeutic PD-1 blockade is associated with upregulation of alternative immune checkpoints.

Authors:  Shohei Koyama; Esra A Akbay; Yvonne Y Li; Grit S Herter-Sprie; Kevin A Buczkowski; William G Richards; Leena Gandhi; Amanda J Redig; Scott J Rodig; Hajime Asahina; Robert E Jones; Meghana M Kulkarni; Mari Kuraguchi; Sangeetha Palakurthi; Peter E Fecci; Bruce E Johnson; Pasi A Janne; Jeffrey A Engelman; Sidharta P Gangadharan; Daniel B Costa; Gordon J Freeman; Raphael Bueno; F Stephen Hodi; Glenn Dranoff; Kwok-Kin Wong; Peter S Hammerman
Journal:  Nat Commun       Date:  2016-02-17       Impact factor: 14.919
View more
  28 in total

Review 1.  Infiltrating T lymphocytes in the tumor microenvironment of small cell lung cancer: a state of knowledge review.

Authors:  Yamei Chen; Ying Jin; Xiao Hu; Ming Chen
Journal:  J Cancer Res Clin Oncol       Date:  2022-01-08       Impact factor: 4.553

2.  Immune phenotypes and checkpoint molecule expression of clonally expanded lymph node-infiltrating T cells in classical Hodgkin lymphoma.

Authors:  Alexej Ballhausen; Amin Ben Hamza; Carlotta Welters; Kerstin Dietze; Lars Bullinger; Hans-Peter Rahn; Sylvia Hartmann; Martin-Leo Hansmann; Leo Hansmann
Journal:  Cancer Immunol Immunother       Date:  2022-08-10       Impact factor: 6.630

Review 3.  Systemic CD4 Immunity as a Key Contributor to PD-L1/PD-1 Blockade Immunotherapy Efficacy.

Authors:  Miren Zuazo; Hugo Arasanz; Ana Bocanegra; Gonzalo Fernandez; Luisa Chocarro; Ruth Vera; Grazyna Kochan; David Escors
Journal:  Front Immunol       Date:  2020-11-30       Impact factor: 7.561

4.  Ex vivo modelling of PD-1/PD-L1 immune checkpoint blockade under acute, chronic, and exhaustion-like conditions of T-cell stimulation.

Authors:  Alexander Roberts; Lindsay Bentley; Tina Tang; Fay Stewart; Chiara Pallini; Joel Juvvanapudi; Graham R Wallace; Alison J Cooper; Aaron Scott; David Thickett; Sebastian T Lugg; Hollie Bancroft; Bridget Hemming; Charlotte Ferris; Gerald Langman; Andrew Robinson; Joanne Chapman; Babu Naidu; Thomas Pinkney; Graham S Taylor; Kristian Brock; Zania Stamataki; Catherine A Brady; S John Curnow; John Gordon; Omar Qureshi; Nicholas M Barnes
Journal:  Sci Rep       Date:  2021-02-17       Impact factor: 4.379

Review 5.  Non-canonical PD-1 signaling in cancer and its potential implications in clinic.

Authors:  Haoran Zha; Ying Jiang; Xi Wang; Jin Shang; Ning Wang; Lei Yu; Wei Zhao; Zhihua Li; Juan An; Xiaochun Zhang; Huoming Chen; Bo Zhu; Zhaoxia Li
Journal:  J Immunother Cancer       Date:  2021-02       Impact factor: 13.751

Review 6.  Molecular biology of Hodgkin lymphoma.

Authors:  Marc A Weniger; Ralf Küppers
Journal:  Leukemia       Date:  2021-03-08       Impact factor: 11.528

7.  ERK Inhibition Improves Anti-PD-L1 Immune Checkpoint Blockade in Preclinical Pancreatic Ductal Adenocarcinoma.

Authors:  Kelly E Henry; Kyeara N Mack; Veronica L Nagle; Mike Cornejo; Adam O Michel; Ian L Fox; Maria Davydova; Thomas R Dilling; Nagavarakishore Pillarsetty; Jason S Lewis
Journal:  Mol Cancer Ther       Date:  2021-08-04       Impact factor: 6.261

Review 8.  PD-1 and LAG-3 Checkpoint Blockade: Potential Avenues for Therapy in B-Cell Lymphoma.

Authors:  Joshua W D Tobin; Karolina Bednarska; Ashlea Campbell; Colm Keane
Journal:  Cells       Date:  2021-05-10       Impact factor: 6.600

Review 9.  Impact of Immunotherapy on CD4 T Cell Phenotypes and Function in Cancer.

Authors:  Margaux Saillard; Mara Cenerenti; Pedro Romero; Camilla Jandus
Journal:  Vaccines (Basel)       Date:  2021-05-04

Review 10.  Neoantigen: A New Breakthrough in Tumor Immunotherapy.

Authors:  Zheying Zhang; Manman Lu; Yu Qin; Wuji Gao; Li Tao; Wei Su; Jiateng Zhong
Journal:  Front Immunol       Date:  2021-04-16       Impact factor: 7.561
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.