Tombor Lukas S, Lautenschläger Till, Glaser Simone F, Fischer Ariane, Merten Maximilian, Hille Susanne S, Müller Oliver J, Kupatt Christian, Bozoglu Tarik, Kugler Christoph, Sami Haider, Ogris Manfred, Stilz Kathrin A, Panthel Josefine, Muhly-Reinholz Marion, Kettenhausen Lisa-Maria, Zanders Lukas, Stein Leonie, Kiessling Paul, Sicklinger Florian, Leuschner Florian, Schuhmacher Bianca, Siragusa Mauro, Rodriguez Morales David, John David, Kujundzic Haris, Katschke Minh-Thuy, Solomonidis Emmanouil G, Luxán Guillermo, Hehlgans Stephanie, Rödel Franz, Kuppe Christoph, Abplanalp Wesley T, Cremer Sebastian, Dimmeler Stefanie
Institute of Cardiovascular Regeneration (L.S.T., T.L., S.F.G., A.F., M.M., K.A.S., J.P., M.M.-R., L.-M.K., L.Z., L.S., B.S., D.R.M., D.J., H.K., M.-T.K., E.G.S., G.L., W.T.A., S.C., S.D.), Goethe University, Frankfurt, Germany.
German Centre for Cardiovascular Research (DZHK), Frankfurt (L.S.T., T.L., S.F.G., K.A.S., L.Z., L.S., M.S., D.R.M., D.J., E.G.S., G.L., W.T.A., S.C., S.D.).
Circ Res. 2025 Aug 29;137(6):866-879. doi: 10.1161/CIRCRESAHA.125.326145. Epub 2025 Jul 30.
Endothelial cells (ECs) play pivotal roles in maintaining cardiac blood supply and regulating inflammation by acting as gatekeepers for immune cell activity. This study unveils a novel immunomodulatory function of cardiac ECs following myocardial infarction.
We used single-cell RNA sequencing and spatial transcriptomics to identify EC states after acute myocardial infarction in mice. Subsequently, we mimicked the cytokine environment that was predicted to induce EC activation in cell culture studies and confirmed the results in an endothelial-specific deletion mouse model.
Single-cell RNA sequencing analysis identified a transient myeloid immunomodulatory EC phenotype (IMEC) emerging between days 1 and 3 after myocardial infarction. IMECs derived from tissue resident cells as shown by bone marrow transplantation and lineage tracing experiment. Ligand-receptor interaction predictions indicated a cytokine-mediated activation of IMECs, which we validated through in vitro experiments in cultured ECs. Notably, while cytokine treatment with IL-1β and TGF-β (transforming growth factor β) induced mesenchymal gene expression, the addition of IFN-γ (interferon γ) facilitated the transition into the immunomodulatory phenotype. IMECs exhibited an upregulation of MHC-II (major histocompatibility complex class II) genes, along with the expression of (runt-related transcription factor-1) and proinflammatory cytokines, such as IL-6 and IL-12. IMECs induced T-cell activation through paracrine signaling and were colocalized with T cells in vivo. Inhibition of endothelial-specific IFN-γ-signaling in mice by IFN-γ receptor 1 deletion improved the recovery after myocardial infarction.
These findings provide insight into the role of ECs regulating adaptive immune responses following myocardial infarction, offering potential insights into therapeutic interventions for postinfarction immunomodulation.
内皮细胞(ECs)在维持心脏血液供应以及通过作为免疫细胞活动的守门人来调节炎症方面发挥着关键作用。本研究揭示了心肌梗死后心脏内皮细胞的一种新的免疫调节功能。
我们使用单细胞RNA测序和空间转录组学来鉴定小鼠急性心肌梗死后的内皮细胞状态。随后,我们在细胞培养研究中模拟了预计会诱导内皮细胞激活的细胞因子环境,并在内皮细胞特异性缺失小鼠模型中证实了结果。
单细胞RNA测序分析确定了心肌梗死后第1天到第3天出现的一种短暂的髓样免疫调节内皮细胞表型(IMEC)。骨髓移植和谱系追踪实验表明,IMECs来源于组织驻留细胞。配体-受体相互作用预测表明细胞因子介导的IMECs激活,我们通过培养的内皮细胞的体外实验验证了这一点。值得注意的是,虽然用IL-1β和TGF-β(转化生长因子β)进行细胞因子处理会诱导间充质基因表达,但添加IFN-γ(干扰素γ)则促进了向免疫调节表型的转变。IMECs表现出MHC-II(主要组织相容性复合体II类)基因上调,以及RUNX( runt相关转录因子-1)和促炎细胞因子如IL-6和IL-12的表达。IMECs通过旁分泌信号诱导T细胞激活,并在体内与T细胞共定位。通过缺失IFN-γ受体1抑制小鼠内皮细胞特异性IFN-γ信号通路可改善心肌梗死后的恢复情况。
这些发现为内皮细胞在心肌梗死后调节适应性免疫反应中的作用提供了见解,为梗死后免疫调节的治疗干预提供了潜在的见解。
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