Causal relationship between immune cell-mediated circulating inflammatory proteins and rheumatoid arthritis

doi:10.12307/2026.267

Abstract

Abstract: BACKGROUND: Studies have shown that circulating inflammatory proteins and immune cells are associated with rheumatoid arthritis, but the causal relationship is unclear.
OBJECTIVE: To explore the causal relationships between circulating inflammatory proteins and rheumatoid arthritis mediated by immune cells.
METHODS: We downloaded data on circulating inflammatory proteins and immune cell phenotypes from the GWAS Catalog database (a publicly accessible database jointly established and maintained by the National Human Genome Research Institute and the European Bioinformatics Institute), and genome-wide association study data for rheumatoid arthritis from the FinnGen database (a genomics project resulting from collaboration between Finnish research institutions, biobanks, and international industry partners, also publicly accessible). A two-step Mendelian randomization analysis was then conducted. In the first step, inverse variance weighted method was used to evaluate the causal effects of 91 circulating inflammatory proteins and 731 immune cells on rheumatoid arthritis risk. MR-Egger, weighted median, weighted mode, simple mode, and sensitivity analyses were performed to ensure robustness and assess pleiotropy. The second step evaluated the mediating effects of identified immune cells on the relationship between circulating inflammatory proteins and rheumatoid arthritis.
RESULTS AND CONCLUSION: (1) Inverse variance weighted analysis showed that four circulating inflammatory proteins were significantly correlated with the risk of rheumatoid arthritis, with one circulating inflammatory protein being a risk factor for rheumatoid arthritis and three circulating inflammatory proteins being protective factors for rheumatoid arthritis. Forty-six kinds of immune cells were significantly associated with rheumatoid arthritis, comprising 20 risk factors and 26 protective factors. Reverse Mendelian randomization analysis found no causal associations between rheumatoid arthritis and four identified circulating inflammatory proteins. Sensitivity analyses revealed no significant heterogeneity or horizontal pleiotropy. Further Mediation analysis showed that CD19 on IgD- CD38br partially mediated the causal effect of interleukin-18 on rheumatoid arthritis (β=0.064, odds ratio=1.066, P=0.044), with a mediation effect of 0.004, accounting for 5.7% of the total effect, and a direct effect of 0.060. (2) The study findings reveal that circulating inflammatory proteins and immune cells have causal associations with rheumatoid arthritis, and demonstrate that CD19 on IgD- CD38br partially mediates the causal effect of interleukin-18 on rheumatoid arthritis. With the rich accumulation of data in international multi-omics research platforms and trans-ethnic cohorts, China can reference their multi-dimensional data integration frameworks to construct a dedicated database integrating epigenomics, proteomics, and metabolomics for the Chinese population, revealing molecular regulatory networks underlying complex diseases and aiding in disease subtyping and early diagnostic biomarker development. Learning from transnational collaborative research mechanisms, establishing multi-ethnic and multi-regional natural population cohorts in China will systematically dissect the impact of gene-environment interactions on health, providing a scientific basis for localized disease prevention strategies.

Key words: circulating inflammatory proteins, immune cells, rheumatoid arthritis, Mendelian randomization, inverse variance weighted, causality, mediation analysis, FinnGen database

CLC Number:

Wang Chun, Gan Lizhen, Ren He, Fang Yi, Gao Zishan, Wu Yunchuan. Causal relationship between immune cell-mediated circulating inflammatory proteins and rheumatoid arthritis[J]. Chinese Journal of Tissue Engineering Research, 2026, 30(25): 6669-6679.

Figures/Tables 12

苷酸多态性对结果产生显著影响，分析结果具有较好的稳健性。可视化结果显示，散点图中5种分析方法的因果效应方向保持一致，未发现异常值。漏斗图中各单核苷酸多态性的效应值呈对称分布态势，数据点集中分布于基准线两侧，未观察到明显偏离正常分布范围的离群值。循环炎症蛋白与类风湿关节炎正向因果关系的异质性检验和水平多效性检验结果，见表2，3。循环炎症蛋白与类风湿关节炎正向因果关系的留一法敏感性分析结果见图4。循环炎症蛋白与类风湿关节炎正向因果关系的散点图结果，见图5。循环炎症蛋白与类风湿关节炎正向因果关系的漏斗图结果，见图6。 2.2 循环炎症蛋白与类风湿关节炎的反向孟德尔随机化分析结果将类风湿关节炎作为暴露因素，已识别的4种循环炎症蛋白作为结局因素进行反向孟德尔随机化分析。以逆方差加权法作为主要分析方法，结果显示类风湿关节炎与CCL23(β=0.130，OR=1.138，P=0.187)、IL-15RA(β=0.123，OR=1.130，P=0.114)、IL-18(β=0.081，OR=1.084，P=0.676)、TNFB(β=0.091，OR=1.096，P=0.361)的P均＞0.05，见表4，表明类风湿关节炎与4种循环炎症蛋白不存在反向因果关系，未观察到类风湿关节炎影响4种循环炎症蛋白的证据。 2.3 免疫细胞与类风湿关节炎因果关系的孟德尔随机化结果将免疫细胞作为暴露因素，类风湿关节炎作为结局因素，以逆方差加权法为主要分析法，经过一系列筛选后，发现46种免疫细胞与类风湿关节炎存在显著相关性，见图2，图7。敏感性分析结果表明，46种免疫细胞与类风湿关节炎不存在异质性和水平多效性，并且因果效应方向显示一致性。异质性检验和水平多效性检验结果见表5，6。 2.4 中介分析结果在上述研究的基础上，以免疫细胞作为中介，以确定免疫细胞是否充当从循环炎症蛋白到类风湿关节炎的介质，分析过程同上述过程一致，结果表明，炎症蛋白IL-18与免疫细胞CD4 on EM CD4+和CD19 on IgD- CD38br存在显著因果关系，见表7。将CD4 on EM CD4+输入到中介分析中评估IL-18与类风湿关节炎的相关性，结果显示P > 0.05，相关性不具有统计学意义。将CD19 on IgD- CD38br输入到中介分析中评估IL-18与类风湿关节炎的相关性，结果显示P < 0.05，相关性仍然具有统计学意义。具体而言，IL-18对类风湿关节炎的总效应值为0.064，表明IL-18与类风湿关节炎风险的总体效应呈正相关。进一步中介分析结果显示，CD19 on IgD- CD38br对类风湿关节炎的中介效应为0.004，中介占比为5.7%，直接效应为0.060，表明控制CD19 on IgD- CD38br的影响后IL-18与类风湿关节炎风险仍呈正相关关系，见表8，图8。综合以上结果表明，CD19 on IgD- CD38br可能介导循环炎症蛋白IL-18与类风湿关节炎风险的关联。 2.5 功能富集分析和蛋白质-蛋白质相互作用分析结果多种功能富集分析显示，已识别的炎症蛋白IL-18在多个关键的生物学过程中表现出显著的参与性：在基因本体论富集层面，炎症蛋白IL-18显著参与细胞对脂多糖的响应、"

References

[1] CUSH JJ. Rheumatoid Arthritis: Early Diagnosis and Treatment. Med Clin North Am. 2021;105(2): 355-365.
[2] ALMUTAIRI K, NOSSENT J, PREEN D, et al. The global prevalence of rheumatoid arthritis: a meta-analysis based on a systematic review. Rheumatol Int. 2021;41(5):863-877.
[3] MA Y, CHEN H, LV W, et al. Global, regional and national burden of rheumatoid arthritis from 1990 to 2021, with projections of incidence to 2050: a systematic and comprehensive analysis of the Global Burden of Disease study 2021. Biomark Res. 2025;13(1):47.
[4] LIN YJ, ANZAGHE M, SCHÜLKE S. Update on the Pathomechanism, Diagnosis, and Treatment Options for Rheumatoid Arthritis. Cells. 2020; 9(4):880.
[5] BOUZIT L, MALSPEIS S, SPARKS JA, et al. Assessing improved risk prediction of rheumatoid arthritis by environmental, genetic, and metabolomic factors. Semin Arthritis Rheum. 2021;51(5):1016-1022.
[6] KERSCHBAUMER A, SEPRIANO A, BERGSTRA SA, et al. Efficacy of synthetic and biological DMARDs: a systematic literature review informing the 2022 update of the EULAR recommendations for the management of rheumatoid arthritis. Ann Rheum Dis. 2023;82(1):95-106.
[7] GAUTAM S, WHITTAKER JE, VEKARIYA R, et al. The distinct transcriptomic signature of the resolution phase fibroblast-like synoviocytes supports endothelial cell dysfunction. Commun Biol. 2025;8(1):837.
[8] GAUTAM S, KUMAR R, KUMAR U, et al. Yoga maintains Th17/Treg cell homeostasis and reduces the rate of T cell aging in rheumatoid arthritis: a randomized controlled trial. Sci Rep. 2023;13(1):14924.
[9] ZHENG Y, LIU Q, GORONZY JJ, et al. Immune aging - A mechanism in autoimmune disease. Semin Immunol. 2023;69:101814.
[10] JANG S, KWON EJ, LEE JJ. Rheumatoid Arthritis: Pathogenic Roles of Diverse Immune Cells. Int J Mol Sci. 2022;23(2):905.
[11] KOMATSU N, TAKAYANAGI H. Mechanisms of joint destruction in rheumatoid arthritis - immune cell-fibroblast-bone interactions. Nat Rev Rheumatol. 2022;18(7):415-429.
[12] SKRIVANKOVA VW, RICHMOND RC, WOOLF BAR,
et al. Strengthening the Reporting of Observational Studies in Epidemiology Using Mendelian Randomization: The STROBE-MR Statement. JAMA. 2021;326(16):1614-1621.
[13] RICHMOND RC, DAVEY SMITH G. Mendelian Randomization: Concepts and Scope. Cold Spring Harb Perspect Med. 2022;12(1):a040501.
[14] ZHAO JH, STACEY D, ERIKSSON N, et al. Genetics of circulating inflammatory proteins identifies drivers of immune-mediated disease risk and therapeutic targets. Nat Immunol. 2023;24(9):1540-1551.
[15] ORRÙ V, STERI M, SIDORE C, et al. Complex genetic signatures in immune cells underlie autoimmunity and inform therapy. Nat Genet. 2020;52(10):1036-1045.
[16] KURKI MI, KARJALAINEN J, PALTA P, et al. FinnGen provides genetic insights from a well-phenotyped isolated population. Nature. 2023; 613(7944):508-518.
[17] LIU QP, DU HC, XIE PJ, et al. Effect of the immune cells and plasma metabolites on rheumatoid arthritis: a mediated mendelian randomization study. Front Endocrinol (Lausanne). 2024;15:1438097.
[18] XU J, SI S, HAN Y, et al. Genetic insight into dissecting the immunophenotypes and inflammatory profiles in the pathogenesis of Sjogren syndrome. J Transl Med. 2025;23(1): 56.
[19] LI DH, WU Q, LAN JS, et al. Plasma metabolites and risk of myocardial infarction: a bidirectional Mendelian randomization study. J Geriatr Cardiol. 2024;21(2):219-231.
[20] 容向宾,郑海波,莫学燊,等.血浆代谢物、免疫细胞与髋骨关节炎的因果推断：GWAS数据欧洲群体资料分析[J].中国组织工程研究, 2026,30(4):1028-1035.
[21] JIN C, LU Z, CHEN Y, et al. Identification of biomarkers for chronic lymphocytic leukemia risk: a proteome-wide Mendelian randomization study. Discov Oncol. 2025;16(1):2.
[22] MA H, CHEN Y. Examining the causal relationship between sex hormone-binding globulin (SHBG) and infertility: A Mendelian randomization study. PLoS One. 2024;19(6):e0304216.
[23] GAO B, WANG Z, WANG K, et al. Relationships among gut microbiota, plasma metabolites, and juvenile idiopathic arthritis: a mediation Mendelian randomization study. Front Microbiol. 2024;15:1363776.
[24] HUANG M, XING F, HU Y, et al. Causal inference study of plasma proteins and blood metabolites mediating the effect of obesity-related indicators on osteoporosis. Front Endocrinol (Lausanne). 2025;16:1435295.
[25] YE CJ, LIU D, CHEN ML, et al. Mendelian randomization evidence for the causal effect of mental well-being on healthy aging. Nat Hum Behav. 2024;8(9):1798-1809.
[26] CHEN JY, WANG JF, HU Y, et al. Evaluating the advancements in protein language models for encoding strategies in protein function prediction: a comprehensive review. Front Bioeng Biotechnol. 2025;13:1506508.
[27] DONCHEVA NT, MORRIS JH, HOLZE H, et al. Cytoscape stringApp 2.0: Analysis and Visualization of Heterogeneous Biological Networks. J Proteome Res. 2023;22(2):637-646.
[28] SZKLARCZYK D, GABLE AL, LYON D, et al. STRING v11: protein-protein association networks with increased coverage, supporting functional discovery in genome-wide experimental datasets. Nucleic Acids Res. 2019;47(D1):D607-D613.
[29] IHIM SA, ABUBAKAR SD, ZIAN Z, et al. Interleukin-18 cytokine in immunity, inflammation, and autoimmunity: Biological role in induction, regulation, and treatment. Front Immunol. 2022; 13:919973.
[30] WANG Y, XU D, LONG L, et al. Correlation between plasma, synovial fluid and articular cartilage Interleukin-18 with radiographic severity in 33 patients with osteoarthritis of the knee. Clin Exp Med. 2014;14(3):297-304.
[31] 郑宝林,李婷,刘奔流,等.通痹1号方对实验性类风湿关节炎大鼠血清IL-18与VEGF水平的影响[J].海南医学,2018,29(3):297-299.
[32] AMIN MA, RABQUER BJ, MANSFIELD PJ, et al. Interleukin 18 induces angiogenesis in vitro and in vivo via Src and Jnk kinases. Ann Rheum Dis. 2010;69(12):2204-2212.
[33] SHEN J, ZHANG Y, TANG W, et al. Short IL-18 generated by caspase-3 cleavage mobilizes NK cells to suppress tumor growth. Nat Immunol. 2025;26(3):416-428.
[34] MA H, HU T, TAO W, et al. A lncRNA from an inflammatory bowel disease risk locus maintains intestinal host-commensal homeostasis. Cell Res. 2023;33(5):372-388.
[35] JIANG Q, WANG X, XU X, et al. Inflammasomes in rheumatoid arthritis: a pilot study. BMC Rheumatol. 2023;7(1):39.
[36] 陈泽豪,王景,高翔宇,等.外周血单个核细胞AIM2炎症小体激活释放白细胞介素-18介导带状疱疹的临床研究[J].中国疼痛医学杂志, 2024,30(5):348-355.
[37] HONG J, LUO F, DU X, et al. The immune cells in modulating osteoclast formation and bone metabolism. Int Immunopharmacol. 2024;133: 112151.
[38] LI T, JIANG G, HU X, et al. Punicalin Attenuates Breast Cancer-Associated Osteolysis by Inhibiting the NF-κB Signaling Pathway of Osteoclasts. Front Pharmacol. 2021;12:789552.
[39] WEI L, CHEN W, HUANG L, et al. Alpinetin ameliorates bone loss in LPS-induced inflammation osteolysis via ROS mediated P38/PI3K signaling pathway. Pharmacol Res. 2022;184:106400.
[40] LIU C, ZUO M, ZHAO J, et al. DPHB inhibits osteoclastogenesis by suppressing NF-κB and MAPK signaling and alleviates inflammatory bone destruction. Int Immunopharmacol. 2025; 152: 114377.
[41] XU S, WANG Y, LU J, et al. Osteoprotegerin and RANKL in the pathogenesis of rheumatoid arthritis-induced osteoporosis. Rheumatol Int. 2012;32(11):3397-3403.
[42] QUARESMA TO, DE ALMEIDA SCL, DA SILVA TA, et al. Comparative study of the synovial levels of RANKL and OPG in rheumatoid arthritis, spondyloarthritis and osteoarthritis. Adv Rheumatol. 2023;63(1):13.
[43] MCGRATH S, GRIMSTAD K, THORARINSDOTTIR K, et al. Correlation of Professional Antigen-Presenting Tbet(+)CD11c(+) B Cells With Bone Destruction in Untreated Rheumatoid Arthritis. Arthritis Rheumatol. 2024;76(8):1263-1277.
[44] WANG X, GAO H, ZENG Y, et al. A Mendelian analysis of the relationships between immune cells and breast cancer. Front Oncol. 2024;14:1341292.