Mature megakaryocytes acquire immune characteristics in a mouse model of aplastic anemia.

IF 7.4 1区医学 Q1 HEMATOLOGY

Blood advances Pub Date : 2025-07-08 DOI:10.1182/bloodadvances.2024015621

Ashvind Prabahran, Liangliang Wu, Ash Lee Manley, Zhijie Wu, Shouguo Gao, Hiroki Mizumaki, Valentina Baena, Zulfeqhar Syed, Christian A Combs, Jichun Chen, Xingmin Feng, Neal S Young

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引用次数: 0

Abstract

Abstract: Megakaryocytes (MKs) serve diverse roles beyond platelet production, including hematopoietic stem cell maintenance and immune response modulation. In our mouse model of immune bone marrow failure (BMF), we observed the unexpected persistence of MKs despite thrombocytopenia. These MKs exhibited heightened expression of immune activation markers, such as IA-IE and CD53, compared with MKs from healthy controls. Single-cell RNA sequencing analysis (scRNA-seq) revealed upregulation of immune response pathways and downregulation of pathways related to platelet function and homeostasis in MKs from animals with marrow failure (BMF). Electron microscopy demonstrated that these MKs had fewer cytoplasmic extensions, reduced α-granules, and a less developed demarcation membrane system. MKs from BMF animals had reduced ability to produce platelets compared with normal control MKs. Interestingly, when cocultured with BMF-derived T cells, MKs from healthy mice acquired immune characteristics. Functionally, MKs from BMF mice suppressed hematopoietic stem cell colony formation in coculture experiments. Mechanistically, these MKs appeared to act as antigen-presenting cells, capable of T-cell activation. Notably, similar immune activation of MKs was observed in patients with aplastic anemia through scRNA-seq. These findings highlight the immune functions of mature MKs in an alloimmune model of BMF, with potential implications for human aplastic anemia and related hematologic disorders.

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成熟巨核细胞在再生障碍性贫血小鼠模型中获得免疫特征

巨核细胞（MKs）的作用多种多样，不仅能生成血小板，还能维持造血干细胞和调节免疫反应。在免疫性骨髓衰竭（BMF）小鼠模型中，我们观察到尽管血小板减少，但巨核细胞仍意外地持续存在。与健康对照组的骨髓干细胞相比，这些骨髓干细胞表现出更高的免疫激活标志物表达，如IA-IE和CD53。单细胞RNA测序分析（scRNA-seq）显示，在骨髓衰竭动物的MKs中，免疫反应通路上调，而与血小板功能和稳态有关的通路下调。电子显微镜显示，这些骨髓造血干细胞的细胞质延伸较少，a-颗粒减少，分界膜系统不发达。与正常对照的骨髓造血干细胞相比，骨髓衰竭动物的骨髓造血干细胞生成血小板的能力下降。有趣的是，当与 BMF 衍生的 T 细胞共培养时，健康小鼠的 MKs 获得了免疫特征。在功能上，BMF 小鼠的 MKs 在共培养实验中抑制了造血干细胞集落的形成。从机理上讲，这些 MKs 似乎是抗原递呈细胞，能够激活 T 细胞。值得注意的是，通过scRNA-seq在再生障碍性贫血患者中也观察到了类似的MKs免疫激活。这些发现突显了成熟 MKs 在 BMF 同种免疫模型中的免疫功能，对人类再生障碍性贫血和相关血液疾病具有潜在意义。

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

Blood advances Medicine-Hematology

CiteScore

12.70

自引率

2.70%

发文量

840

期刊介绍： Blood Advances, a semimonthly medical journal published by the American Society of Hematology, marks the first addition to the Blood family in 70 years. This peer-reviewed, online-only, open-access journal was launched under the leadership of founding editor-in-chief Robert Negrin, MD, from Stanford University Medical Center in Stanford, CA, with its inaugural issue released on November 29, 2016. Blood Advances serves as an international platform for original articles detailing basic laboratory, translational, and clinical investigations in hematology. The journal comprehensively covers all aspects of hematology, including disorders of leukocytes (both benign and malignant), erythrocytes, platelets, hemostatic mechanisms, vascular biology, immunology, and hematologic oncology. Each article undergoes a rigorous peer-review process, with selection based on the originality of the findings, the high quality of the work presented, and the clarity of the presentation.