Section of Cardiovascular Medicine, Dept of Internal Medicine, Yale University School of Medicine, New Haven, CT, United States.
Department of Obstetrics and Gynecology, Shengjing Hospital of China Medical University, Shenyang, China.
Front Immunol. 2022 Sep 23;13:1020889. doi: 10.3389/fimmu.2022.1020889. eCollection 2022.
Endothelial cells (ECs) form a critical immune interface regulating both the activation and trafficking of alloreactive T cells. In the setting of solid organ transplantation, donor-derived ECs represent sites where alloreactive T cells encounter major and minor tissue-derived alloantigens. During this initial encounter, ECs may formatively modulate effector responses of these T cells through expression of inflammatory mediators. Direct allorecognition is a process whereby recipient T cells recognize alloantigen in the context of donor EC-derived HLA molecules. Direct alloresponses are strongly modulated by human ECs and are galvanized by EC-derived inflammatory mediators. Complement are immune proteins that mark damaged or foreign surfaces for immune cell activation. Following labeling by natural IgM during ischemia reperfusion injury (IRI) or IgG during antibody-mediated rejection (ABMR), the complement cascade is terminally activated in the vicinity of donor-derived ECs to locally generate the solid-phase inflammatory mediator, the membrane attack complex (MAC). Via upregulation of leukocyte adhesion molecules, costimulatory molecules, and cytokine trans-presentation, MAC strengthen EC:T cell direct alloresponses and qualitatively shape the alloimmune T cell response. These processes together promote T cell-mediated inflammation during solid organ transplant rejection. In this review we describe molecular pathways downstream of IgM- and IgG-mediated MAC assembly on ECs in the setting of IRI and ABMR of tissue allografts, respectively. We describe work demonstrating that MAC deposition on ECs generates 'signaling endosomes' that sequester and post-translationally enhance the stability of inflammatory signaling molecules to promote EC activation, a process potentiating EC-mediated direct allorecognition. Additionally, with consideration to first-in-human xenotransplantation procedures, we describe clinical therapeutics based on inhibition of the complement pathway. The complement cascade critically mediates EC activation and improved understanding of relevant effector pathways will uncover druggable targets to obviate dysregulated alloimmune T cell infiltration into tissue allografts.
内皮细胞 (ECs) 形成了一个关键的免疫界面,调节同种反应性 T 细胞的激活和迁移。在实体器官移植中,供体来源的 ECs 代表了同种反应性 T 细胞遇到主要和次要组织来源同种抗原的部位。在这个初始接触过程中,ECs 可能通过表达炎症介质来调节这些 T 细胞的效应反应。直接同种识别是一种受体 T 细胞在供体 EC 衍生的 HLA 分子背景下识别同种抗原的过程。直接同种反应受到强烈的人类 ECs 调节,并被 EC 衍生的炎症介质激发。补体是标记受损或外来表面以激活免疫细胞的免疫蛋白。在缺血再灌注损伤 (IRI) 期间天然 IgM 或抗体介导排斥反应 (ABMR) 期间 IgG 标记后,补体级联在供体来源的 EC 附近终末激活,以局部产生固相炎症介质膜攻击复合物 (MAC)。通过上调白细胞黏附分子、共刺激分子和细胞因子的转位呈现,MAC 增强 EC:T 细胞的直接同种反应,并从质上塑造同种免疫 T 细胞反应。这些过程共同促进实体器官移植排斥反应期间 T 细胞介导的炎症。在这篇综述中,我们描述了分别在 IRI 和组织同种异体移植物的 ABMR 中,IgM 和 IgG 介导的 MAC 在 EC 上组装的下游分子途径。我们描述了证明 MAC 在 EC 上沉积会产生“信号内体”的工作,这些内体可以隔离和翻译后增强炎症信号分子的稳定性,以促进 EC 激活,这是促进 EC 介导的直接同种识别的过程。此外,考虑到首例人类异种移植程序,我们描述了基于抑制补体途径的临床治疗方法。补体级联在 EC 激活中起着关键作用,对相关效应途径的更好理解将揭示可用于避免失调的同种免疫 T 细胞浸润到组织同种异体移植物的药物靶点。
