Dutzmann Jochen, Daniel Jan-Marcus, Korte Laura, Kloss Frederik J, Knöpp Kai, Kalies Katrin, Croce Kevin J, Herbst Thomas J, Huibregtse Barbara, Vogt Felix J, Offermanns Stefan, Bauersachs Johann, Sedding Daniel G
Mid-German Heart Center, Division of Cardiology, Vascular Medicine, and Intensive Medical Care University Hospital Halle, Martin-Luther-University Halle-Wittenberg Halle Germany.
Department of Cardiology and Angiology Hannover Medical School Hannover Germany.
J Am Heart Assoc. 2025 Jul 15;14(14):e040143. doi: 10.1161/JAHA.124.040143. Epub 2025 Jul 3.
Vascular restenosis resulting from neointima formation significantly limits the efficacy of percutaneous interventional therapies compared with bypass surgery. The adventitial layer is involved in neointima formation, but the detailed pathophysiological interplay of the different cell types in this process is still unclear.
We analyzed the correlation between adventitial and neointimal tissue size in human postmortem restenotic lesions after angioplasty. In porcine and mouse models of vascular injury, we examined early proliferation of fibroblasts and adventitial expansion. Using anti-CD45 antibodies, we identified recruited leukocytes as the source of fibroblast activation following vascular injury in mice. A time-course experiment on neointima formation demonstrated that adventitial activation precedes the proliferation of medial and neointimal smooth muscle cells (SMCs). To further investigate this process, we developed a mouse model enabling the surgical removal and transplantation of adventitial tissue.
We observed that activated adventitial fibroblasts release interleukin 6 and other cytokines, which strongly induce SMC proliferation and migration in vitro. In interleukin 6 knockout mice, supernatants from activated adventitia grafts failed to stimulate SMC proliferation and migration. Furthermore, transplantation of adventitial grafts from interleukin 6 knockout mice did not induce neointima formation. Cell fate tracking experiments using double transgenic reporter mice demonstrated that resident adventitial cells do not directly contribute to the neointimal cellular mass. Instead, medial SMCs were identified as the primary source of neointimal cells.
We show that the release of interleukin 6 by adventitial fibroblasts induces the subsequent proliferation and migration of medial SMC in the process of neointima formation. Thus, we propose a new paradigm for adventitial fibroblasts in this process as a paracrine inflammatory engine. Anti-inflammatory targeting of the vascular adventitia might thus be promising to limit neointima formation.
与搭桥手术相比,新生内膜形成导致的血管再狭窄显著限制了经皮介入治疗的疗效。外膜层参与新生内膜形成,但在此过程中不同细胞类型之间详细的病理生理相互作用仍不清楚。
我们分析了血管成形术后人体尸检再狭窄病变中外膜和新生内膜组织大小之间的相关性。在猪和小鼠血管损伤模型中,我们检测了成纤维细胞的早期增殖和外膜扩张情况。利用抗CD45抗体,我们确定募集的白细胞是小鼠血管损伤后成纤维细胞激活的来源。一项关于新生内膜形成的时间进程实验表明,外膜激活先于中膜和新生内膜平滑肌细胞(SMC)的增殖。为了进一步研究这一过程,我们建立了一个能够手术切除和移植外膜组织的小鼠模型。
我们观察到激活的外膜成纤维细胞释放白细胞介素6和其他细胞因子,这些因子在体外强烈诱导SMC增殖和迁移。在白细胞介素6基因敲除小鼠中,激活的外膜移植物的上清液未能刺激SMC增殖和迁移。此外,移植来自白细胞介素6基因敲除小鼠的外膜移植物不会诱导新生内膜形成。使用双转基因报告小鼠进行的细胞命运追踪实验表明,常驻外膜细胞不会直接促成新生内膜细胞团。相反,中膜SMC被确定为新生内膜细胞的主要来源。
我们表明,外膜成纤维细胞释放白细胞介素6在新生内膜形成过程中诱导中膜SMC随后的增殖和迁移。因此,我们提出在此过程中外膜成纤维细胞作为旁分泌炎症引擎的新范式。因此,对外膜进行抗炎靶向治疗可能有望限制新生内膜形成。
