Carolina Francelin, Alexandre Borin, Jessica Funari, Fernando Pradella, Leonilda M B Santos, Wilson Savino, Alessandro S Farias
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引用次数: 0
Abstract
Introduction: The thymus is the primary lymphoid organ responsible for normal T-cell development. Yet, in abnormal metabolic conditions as well as an acute infection, the organ exhibits morphological and cellular alterations. It is well established that the immune system is in a tidy connection and dependent on the central nervous system (CNS), which regulates thymic function by means of innervation and neurotransmitters. Sympathetic innervation leaves the CNS and spreads through thymic tissue, where nerve endings interact directly or indirectly with thymic cells contributing to their maintenance and development.
Methods: Herein, we hypothesized that brain damage due to an inflammatory process might elicit alterations upon the thymic-CNS neuroimmune axis, altering not just the sympathetic innervation and neurotransmitter release, but also modifying the thymus microenvironment and T-cell development. We used the well-established multiple sclerosis model of experimental autoimmune encephalomyelitis (EAE), to study putative changes in the thymic neural, lymphoid, and microenvironmental compartments.
Results: We showed that along with EAE clinical development, thymus morphology, and cellular compartments are affected, altering the peripheric T-cell population and modifying the retrograde thymic communication toward the CNS.
Conclusion: Altogether, our data suggest that the thymic-CNS neuroimmune bidirectional axis is compromised in EAE. This imbalance may contribute to an increased and uncontrolled auto-immune reaction.
胸腺是负责 T 细胞正常发育的主要淋巴器官。然而,在代谢异常和急性感染的情况下,该器官会出现形态和细胞改变。众所周知,免疫系统与中枢神经系统(CNS)有着紧密的联系和依赖关系,中枢神经系统通过神经支配和神经递质调节胸腺功能。交感神经支配离开中枢神经系统,通过胸腺组织传播,神经末梢直接或间接地与胸腺细胞相互作用,促进胸腺细胞的维持和发育。在此,我们假设炎症过程导致的脑损伤可能会引起胸腺-中枢神经系统神经免疫轴的改变,不仅改变交感神经支配和神经递质的释放,还会改变胸腺微环境和T细胞的发育。我们利用实验性自身免疫性脑脊髓炎(EAE)这一成熟的多发性硬化症模型,研究了胸腺神经、淋巴和微环境的可能变化。我们发现,随着EAE临床发展,胸腺形态和细胞区受到影响,外周T细胞群发生改变,胸腺向中枢神经系统的逆行通讯也发生改变。总之,我们的数据表明,胸腺-中枢神经系统神经免疫双向轴在 EAE 中受到损害。这种失衡可能会导致自身免疫反应的加剧和失控。
期刊介绍:
The rapidly expanding area of research known as neuroimmunomodulation explores the way in which the nervous system interacts with the immune system via neural, hormonal, and paracrine actions. Encompassing both basic and clinical research, ''Neuroimmunomodulation'' reports on all aspects of these interactions. Basic investigations consider all neural and humoral networks from molecular genetics through cell regulation to integrative systems of the body. The journal also aims to clarify the basic mechanisms involved in the pathogenesis of the CNS pathology in AIDS patients and in various neurodegenerative diseases. Although primarily devoted to research articles, timely reviews are published on a regular basis.