TCL1A in naïve B cells as a therapeutic target for type 1 diabetes.

IF 9.7 1区医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL EBioMedicine Pub Date : 2025-02-12 DOI:10.1016/j.ebiom.2025.105593

Siweier Luo, Lina Zhang, Chunfang Wei, Chipeng Guo, Zhe Meng, Honghui Zeng, Lele Hou, Le Wang, Zulin Liu, Yufei Du, Shiyu Tan, Yating Zhang, Xiaoding Xu, Liyang Liang, Yiming Zhou

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引用次数: 0

Abstract

Background: Type 1 diabetes (T1D) is an autoimmune disease characterised by the attack of pancreatic β cells by "self" immune cells. Although previous studies demonstrated that B cells contribute to T1D through antigen presentation and autoantibody production, the involvement of different populations of B cells, particularly in the early stages of T1D, has not been fully elucidated.

Methods: In this study, we employed single-cell RNA sequencing (scRNA-seq) and flow cytometry to investigate immune cell populations in patients with newly diagnosed T1D, their relative controls and age-matched healthy controls. Phosphoprotein microarray analysis was employed to investigate changes in protein phosphorylation in B cells. Furthermore, we developed a siRNA-based nanomedicine and evaluated its therapeutic potential in the NOD mouse. The integration of scRNA-seq, flow cytometry, phosphoprotein microarrays, and functional assays established a robust framework for understanding and targeting B cell-mediated autoimmunity in T1D.

Findings: Using single-cell RNA sequencing, we discovered that patients with T1D exhibited increased humoural immunity in the early stage of T1D. Specifically, the population of naïve B cells increased in patients with newly diagnosed T1D who expressed elevated levels of the AKT kinase coactivator TCL1A. Using a protein phosphorylation microarray, we confirmed that TCL1A knockdown specifically impaired AKT2 phosphorylation and affected B cell survival and proliferation. Notably, we discovered that the naïve B cell population increased and TCL1A expression was upregulated in NOD mice that developed T1D. Both the levels of naïve B cells and TCL1A were strongly associated with glucose intolerance in T1D mice. Importantly, treatment with a siRNA-based nanomedicine targeting Tcl1a mRNA effectively reduced the number of naïve B cells, prevented the loss of pancreatic β cells, and improved glucose intolerance in T1D mice.

Interpretation: Using single-cell RNA-seq, we have not only uncovered a naïve B cell specific gene that may contribute to the pathogenesis of T1D but also highlighted the potential of siRNA-based nanomedicine for treating T1D. The clinical translation of these findings offers a new approach for the treatment of T1D.

Funding: See Acknowledgements.

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背景：1 型糖尿病（T1D）是一种自身免疫性疾病，其特征是胰腺 β 细胞受到 "自身 "免疫细胞的攻击。尽管之前的研究表明 B 细胞通过抗原递呈和自身抗体的产生对 T1D 起作用，但不同 B 细胞群的参与，尤其是在 T1D 的早期阶段，尚未完全阐明：在这项研究中，我们采用单细胞 RNA 测序（scRNA-seq）和流式细胞术研究了新诊断 T1D 患者、其相对对照组和年龄匹配的健康对照组的免疫细胞群。磷蛋白芯片分析用于研究 B 细胞中蛋白质磷酸化的变化。此外，我们还开发了一种基于 siRNA 的纳米药物，并在 NOD 小鼠中评估了其治疗潜力。scRNA-seq、流式细胞术、磷蛋白芯片和功能测定的整合建立了一个强大的框架，用于理解和靶向T1D中B细胞介导的自身免疫：通过单细胞RNA测序，我们发现T1D患者在T1D早期表现出更强的体液免疫。具体来说，新确诊的T1D患者体内的幼稚B细胞数量增加，这些患者体内的AKT激酶辅助激活剂TCL1A水平升高。我们利用蛋白质磷酸化芯片证实，TCL1A 的敲除特异性地损害了 AKT2 磷酸化，影响了 B 细胞的存活和增殖。值得注意的是，我们发现在发生 T1D 的 NOD 小鼠中，幼稚 B 细胞数量增加，TCL1A 表达上调。幼稚 B 细胞和 TCL1A 的水平都与 T1D 小鼠的葡萄糖不耐受密切相关。重要的是，用靶向 Tcl1a mRNA 的 siRNA 纳米药物治疗可有效减少幼稚 B 细胞的数量，防止胰腺 β 细胞的丢失，并改善 T1D 小鼠的糖耐量减低：利用单细胞 RNA 截获技术，我们不仅发现了可能导致 T1D 发病机制的天真 B 细胞特异性基因，而且凸显了基于 siRNA 的纳米药物治疗 T1D 的潜力。这些发现的临床转化为治疗T1D提供了一种新方法：参见致谢。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

EBioMedicine Biochemistry, Genetics and Molecular Biology-General Biochemistry,Genetics and Molecular Biology

CiteScore

17.70

自引率

0.90%

发文量

579

审稿时长

5 weeks

期刊介绍： eBioMedicine is a comprehensive biomedical research journal that covers a wide range of studies that are relevant to human health. Our focus is on original research that explores the fundamental factors influencing human health and disease, including the discovery of new therapeutic targets and treatments, the identification of biomarkers and diagnostic tools, and the investigation and modification of disease pathways and mechanisms. We welcome studies from any biomedical discipline that contribute to our understanding of disease and aim to improve human health.