CD4+T细胞介导的免疫耐受对恶性胸腔积液发生发展影响的研究进展

doi:10.13481/j.1671-587X.20250429

Abstract

Abstract:

Malignant pleural effusion （MPE） is a common complication in patients with advanced malignant tumors，which not only significantly reduces their quality of life but also shortens their survival duration. Despite the widespread use of traditional treatment methods such as thoracentesis and pleurodesis，their efficacy is limited accompanied by high recurrence rates. Therefore，exploring novel therapeutic strategies becomes particularly urgent. In recent years， immunotherapy has attracted extensive attention for its potential in cancer treatment. This article systematically reviews the roles of CD4+T cell subsets，including regulatory T cells （Treg）， T helper cell（Th）17， Th9， and Th22 cells， within the immunosuppressive microenvironment of MPE. These cell subsets are involved in the formation of the immunosuppressive state of MPE through various mechanisms and play key roles in the occurrence and development of the disease. In addition，the article discusses in detail the role of immune checkpoint molecules， such as programmed death protein 1 （PD-1）， PD-1 ligand（PD-L1）， and cytotoxic T-lymphocyte-associated protein 4 （CTLA-4）， in the immune evasion of MPE. The abnormal expressions of these molecules provide opportunity for tumor cells to evade immune system surveillance. At the same time， this article also summarizes the application prospects of novel immunotherapy strategies， such as adoptive cell therapy （ACT） and chimeric antigen receptor T cell （CAR-T） therapy，in the treatment of MPE. These innovative therapies offer possibilities for improving the prognosis of MPE patients through activating and enhancing the anti-tumor immune response.

Key words: Malignant pleural effusion, Immune tolerance, Regulatory T cells, T helper 17 cells, T helper 9 cells, T helper 22 cells

CLC Number:

R734.3

Geer A,Qin WANG,Lijing JIAO,Hailun ZHOU,Shanshan GAN,Yang HAN,Ruichao LIU,Yabin GONG. Research progress in effects of CD4+T cell-mediated immune tolerance on occurrence and development of malignant pleural effusion[J].Journal of Jilin University(Medicine Edition), 2025, 51(4): 1121-1128.

References 48

[1]	GAYEN S. Malignant pleural effusion： presentation， diagnosis， and management［J］. Am J Med， 2022， 135（10）： 1188-1192.
[2]	WAHLA A S， UZBECK M， SAMEED Y A E L， et al. Managing malignant pleural effusion［J］. Cleve Clin J Med， 2019， 86（2）： 95-99.
[3]	WALKER S， MERCER R， MASKELL N， et al. Malignant pleural effusion management： keeping the flood gates shut［J］. Lancet Respir Med， 2020， 8（6）： 609-618.
[4]	LIU Y， WANG L L， SONG Q Q， et al. Intrapleural nano-immunotherapy promotes innate and adaptive immune responses to enhance anti-PD-L1 therapy for malignant pleural effusion［J］. Nat Nanotechnol， 2022， 17（2）： 206-216.
[5]	QURESHI M， THAPA B， MURUGANANDAN S. A narrative review-management of malignant pleural effusion related to malignant pleural mesothelioma［J］. Heart Lung Circ， 2023， 32（5）： 587-595.
[6]	ROOFCHAYEE N D， ADCOCK I M， MARJANI M， et al. T helper cell subsets in the pleural fluid of tuberculous patients differentiate patients with non-tuberculous pleural effusions［J］. Front Immunol， 2021， 12： 780453.
[7]	SONG Z H， LUO W Z， ZHENG H C， et al. Translational nanotherapeutics reprograms immune microenvironment in malignant pleural effusion of lung adenocarcinoma［J］. Adv Healthc Mater， 2021， 10（12）： e2100149.
[8]	WU X Z， ZHAI K， YI F S， et al. IL-10 promotes malignant pleural effusion in mice by regulating TH 1-and TH 17-cell differentiation and migration［J］. Eur J Immunol， 2019， 49（4）： 653-665.
[9]	ZHAI K， SHI X Y， YI F S， et al. IL-10 promotes malignant pleural effusion by regulating TH 1 response via an miR-7116-5p/GPR55/ERK pathway in mice［J］. Eur J Immunol， 2020， 50（11）： 1798-1809.
[10]	SHANG Q H， YU X Y， SUN Q， et al. Polysaccharides regulate Th1/Th2 balance： a new strategy for tumor immunotherapy［J］. Biomedecine Pharmacother， 2024， 170： 115976.
[11]	WU X Z， ZHOU Q， LIN H， et al. Immune regulation of toll-like receptor 2 engagement on CD4+T cells in murine models of malignant pleural effusion［J］. Am J Respir Cell Mol Biol， 2017， 56（3）： 342-352.
[12]	CHEN W L， QIN Y Y， LIU S L. CCL20 signaling in the tumor microenvironment［J］. Adv Exp Med Biol， 2020， 1231： 53-65.
[13]	FJAELLEGAARD K， KOEFOD PETERSEN J， REUTER S， et al. Positron emission tomography-computed tomography （PET-CT） in suspected malignant pleural effusion. An updated systematic review and meta-analysis［J］. Lung Cancer， 2021， 162： 106-118.
[14]	ZHANG S J， CHEN L C， ZONG Y， et al. Research progress of tumor-derived extracellular vesicles in the treatment of malignant pleural effusion［J］. Cancer Med， 2023， 12（2）： 983-994.
[15]	MEITEI H T， JADHAV N， LAL G. CCR6-CCL20 axis as a therapeutic target for autoimmune diseases［J］. Autoimmun Rev， 2021， 20（7）： 102846.
[16]	ADDALA D N， RAHMAN N M， MALDONADO F. Personalized prognostication in malignant pleural effusion： the next step？［J］. Chest， 2021， 160（3）： 805-806.
[17]	GEORGIEV P， CHARBONNIER L M， CHATILA T A. Regulatory T cells： the many faces of Foxp3［J］. J Clin Immunol， 2019， 39（7）： 623-640.
[18]	IVANOV I I， MCKENZIE B S， ZHOU L， et al. The orphan nuclear receptor RORgammat directs the differentiation program of proinflammatory IL-17+T helper cells［J］. Cell， 2006， 126（6）： 1121-1133.
[19]	NIU Y R， ZHOU Q. Th17 cells and their related cytokines： vital players in progression of malignant pleural effusion［J］. Cell Mol Life Sci， 2022， 79（4）： 194.
[20]	NGUYEN Q P， DENG T Z， WITHERDEN D A， et al. Origins of CD4+ circulating and tissue-resident memory T-cells［J］. Immunology， 2019， 157（1）： 3-12.
[21]	PAIRMAN L， BECKERT L E L， DAGGER M， et al. Evaluation of pleural fluid cytology for the diagnosis of malignant pleural effusion： a retrospective cohort study［J］. Intern Med J， 2022， 52（7）： 1154-1159.
[22]	HONG H S， MBAH N E， SHAN M R， et al. OXPHOS promotes apoptotic resistance and cellular persistence in TH17 cells in the periphery and tumor microenvironment［J］. Sci Immunol， 2022， 7（77）： eabm8182.
[23]	CHANGCHIEN C Y， CHEN Y， CHANG H H， et al. Effect of malignant-associated pleural effusion on endothelial viability， motility and angiogenesis in lung cancer［J］. Cancer Sci， 2020， 111（10）： 3747-3758.
[24]	LEE A Y S， KÖRNER H. The CCR6-CCL20 axis in humoral immunity and T-B cell immunobiology［J］. Immunobiology， 2019， 224（3）： 449-454.
[25]	KADOMOTO S， IZUMI K， MIZOKAMI A. The CCL20-CCR6 axis in cancer progression［J］. Int J Mol Sci， 2020， 21（15）： 5186.
[26]	ZHANG H， LI C H， HU F， et al. Auxiliary diagnostic value of tumor biomarkers in pleural fluid for lung cancer-associated malignant pleural effusion［J］. Respir Res， 2020， 21（1）： 284.
[27]	ZHANG S， ZHANG Y， FENG W， et al. Prediction modeling using routine clinical parameters to stratify survival in malignant pleural mesothelioma patients complicated with malignant pleural effusion［J］. Thorac Cancer， 2021， 12（24）： 3304-3309.
[28]	XUE G， ZHENG N B， FANG J， et al. Adoptive cell therapy with tumor-specific Th9 cells induces viral mimicry to eliminate antigen-loss-variant tumor cells［J］. Cancer Cell， 2021， 39（12）： 1610-1622.e9.
[29]	PORCEL J M. Diagnosis and characterization of malignant effusions through pleural fluid cytological examination［J］. Curr Opin Pulm Med， 2019， 25（4）： 362-368.
[30]	YU Y F， QIAN J， SHEN L， et al. Distinct profile of cell-free DNA in malignant pleural effusion of non-small cell lung cancer and its impact on clinical genetic testing［J］. Int J Med Sci， 2021， 18（6）： 1510-1518.
[31]	BASHOUR S I， MANKIDY B J， LAZARUS D R. Update on the diagnosis and management of malignant pleural effusions［J］. Respir Med， 2022， 196： 106802.
[32]	LUO L S， DENG S， TANG W， et al. Monocytes subtypes from pleural effusion reveal biomarker candidates for the diagnosis of tuberculosis and malignancy［J］. J Clin Lab Anal， 2022， 36（8）： e24579.
[33]	FAN X， LIU Y Q， LIANG Z G， et al. Diagnostic value of six tumor markers for malignant pleural effusion in 1，230 patients： a single-center retrospective study［J］. Pathol Oncol Res， 2022， 28： 1610280.
[34]	ZHANG Y X， LI W H， ZHAI J W， et al. Phenotypic and functional characterizations of CD8+T cell populations in malignant pleural effusion［J］. Exp Cell Res， 2022， 417（1）： 113212.
[35]	WANG S Y， AN J， HU X R， et al. Single-cell RNA sequencing reveals immune microenvironment of small cell lung cancer-associated malignant pleural effusion［J］. Thorac Cancer， 2024， 15（1）： 98-103.
[36]	LI X X， BECHARA R， ZHAO J J， et al. IL-17 receptor-based signaling and implications for disease［J］. Nat Immunol， 2019， 20（12）： 1594-1602.
[37]	GORCZYNSKI R M. IL-17 signaling in the tumor microenvironment［J］. Adv Exp Med Biol， 2020， 1240： 47-58.
[38]	BRIUKHOVETSKA D， SUAREZ-GOSALVEZ J， VOIGT C， et al. T cell-derived interleukin-22 drives the expression of CD155 by cancer cells to suppress NK cell function and promote metastasis［J］. Immunity， 2023， 56（1）： 143-161.e11.
[39]	NI H H， ZHANG H L， LI L， et al. T cell-intrinsic STING signaling promotes regulatory T cell induction and immunosuppression by upregulating FOXP3 transcription in cervical cancer［J］. J Immunother Cancer， 2022， 10（9）： e005151.
[40]	OIDA T， XU L L， WEINER H L， et al. TGF-beta-mediated suppression by CD4+CD25+T cells is facilitated by CTLA-4 signaling［J］. J Immunol， 2006， 177（4）： 2331-2339.
[41]	YE Z J， ZHOU Q， GU Y Y， et al. Generation and differentiation of IL-17-producing CD4+T cells in malignant pleural effusion［J］. J Immunol， 2010， 185（10）： 6348-6354.
[42]	HUYEN PTHI， LI M Y， LI L， et al. Exploring the value of pleural fluid biomarkers for complementary pleural effusion disease examination［J］. Comput Biol Chem， 2021， 94： 107559.
[43]	ZHANG S W， GANG X K， YANG S， et al. The alterations in and the role of the Th17/treg balance in metabolic diseases［J］. Front Immunol， 2021， 12： 678355.
[44]	LIN H， TONG Z H， XU Q Q， et al. Interplay of Th1 and Th17 cells in murine models of malignant pleural effusion［J］. Am J Respir Crit Care Med， 2014， 189（6）： 697-706.
[45]	KOYI H， WILANDER E. Refined diagnosis of pleural effusions by immunocytochemistry of cell blocks［J］. Anticancer Res， 2023， 43（2）： 669-673.
[46]	LEE P H， YANG T Y， CHEN K C， et al. Higher CD4/CD8 ratio of pleural effusion predicts better survival for lung cancer patients receiving immune checkpoint inhibitors［J］. Sci Rep， 2021， 11（1）： 9381.
[47]	TANO Z E， KIESGEN S， CHINTALA N K， et al. Ex vivo pleural effusion cultures to study chimeric antigen receptor T cell cytotoxicity in an immunocompetent environment［J］. Cell Rep Methods， 2023， 3（11）： 100622.
[48]	GHANIM B， ROSENMAYR A， STOCKHAMMER P， et al. Tumour cell PD-L1 expression is prognostic in patients with malignant pleural effusion： the impact of C-reactive protein and immune-checkpoint inhibition［J］. Sci Rep， 2020， 10（1）： 5784.

Research progress in effects of CD4+T cell-mediated immune tolerance on occurrence and development of malignant pleural effusion

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[15]	YANG Wei, ZHU Wu-Fei, HE Zhi-Fei, WEI Xiao-Xi, SU Jing-Bo, LI Yi. Effects of autoimmune regulator on CD4+CD25+Treg cells [J]. J4, 2010, 36(5): 866-870.