Intravitreal delivery of NMO-IgG causes primary retinal damage in the absence of optic nerve injury.

IF 10.1 1区医学 Q1 IMMUNOLOGY

Journal of Neuroinflammation Pub Date : 2025-03-07 DOI:10.1186/s12974-025-03380-z

Biyue Chen, Huanfen Zhou, Mingming Sun, Wanqun Yang, Qianqian Li, Kaishu Yang, Honglu Song, Quangang Xu, Xintong Xu, Yuyu Li, Yanyan Yu, Shihui Wei, Tingjun Chen

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引用次数: 0

Abstract

Background: Neuromyelitis Optica (NMO) is a neuroimmune disorder primarily driven by autoantibodies against aquaporin 4 (AQP4), known as NMO-IgG. Although the mechanisms underlying NMO-IgG-induced retinopathy are not fully understood, the high expression of AQP4 in retinal Müller cells suggests a direct interaction that may trigger inflammatory processes in the retina. Previous studies indicate that microglia play a critical role in mediating immune responses, leading to neuronal dysfunction.

Methods: NMO-IgG obtained from clinical patients was administered via intravitreal injection to female C57BL/6 mice. Techniques such as optical coherence tomography (OCT), Flash Visual Evoked Potential (f-VEP), electroretinography (ERG), real-time fluorescence quantitative PCR (RT-qPCR), and immunofluorescence analyses were used to assess retinal changes. The potential for reversing retinopathy was explored by depleting microglial cells using the CSF1 receptor inhibitor PLX3397. Additionally, a Transwell co-culture system of MIO-M1 (Müller cells) and BV2 (microglia) cells was established to study their interactions.

Results: Intravitreal injection of purified NMO-IgG in mouse models led to its deposition in the retina and downregulation of AQP4 in provided. Vascular leakage was observed, alongside retinal dysfunction characterized by thinning of the retinal nerve fiber layer (RNFL) and loss of retinal ganglion cells (RGCs). On day 7, C3 expression was upregulated in Müller cells, followed by microglial activation. Significant morphological changes in microglia were noted, with increased expression of iNOS and C1q, indicating substantial activation. Ablating microglia significantly mitigated NMO-IgG-induced injury to RGCs. In vitro, NMO-IgG-treated MIO-M1 cells secreted higher levels of C3, enhancing the activation and migration of BV2 cells compared to controls.

Conclusions: The retinal dysfunction observed in NMO may primarily be linked to the activation of Müller cells by NMO-IgG, leading to increased C3 secretion, which in turn activates microglia. Therapeutic strategies targeting Müller cell-microglia interactions in NMO-IgG-induced retinopathy could be promising in addressing the underlying retinal pathology in this condition.

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在没有视神经损伤的情况下，玻璃体内注入NMO-IgG可引起原发性视网膜损伤。

背景：视神经脊髓炎（NMO）是一种主要由抗水通道蛋白4 （AQP4）的自身抗体（即NMO- igg）驱动的神经免疫疾病。尽管nmo - igg诱导视网膜病变的机制尚不完全清楚，但AQP4在视网膜小细胞中的高表达表明，AQP4可能与视网膜炎症过程有直接的相互作用。先前的研究表明，小胶质细胞在介导免疫反应中起关键作用，导致神经元功能障碍。方法：从临床患者处获得NMO-IgG，经玻璃体内注射给雌性C57BL/6小鼠。使用光学相干断层扫描（OCT）、闪烁视觉诱发电位（f-VEP）、视网膜电图（ERG）、实时荧光定量PCR （RT-qPCR）和免疫荧光分析等技术评估视网膜变化。通过使用CSF1受体抑制剂PLX3397消耗小胶质细胞来探索逆转视网膜病变的潜力。此外，建立了MIO-M1 （m ller细胞）和BV2（小胶质细胞）的Transwell共培养系统，研究它们的相互作用。结果：小鼠模型玻璃体内注射纯化的NMO-IgG可导致其在视网膜内沉积，AQP4下调。观察到血管渗漏，并伴有视网膜功能障碍，其特征是视网膜神经纤维层（RNFL）变薄和视网膜神经节细胞（RGCs）丢失。在第7天，C3表达上调，然后是小胶质细胞激活。小胶质细胞形态学发生显著变化，iNOS和C1q的表达增加，表明细胞被激活。消融小胶质细胞可显著减轻nmo - igg诱导的RGCs损伤。在体外，与对照组相比，nmo - igg处理的io - m1细胞分泌更高水平的C3，增强了BV2细胞的激活和迁移。结论：NMO视网膜功能障碍可能主要与NMO- igg激活 ller细胞，导致C3分泌增加，进而激活小胶质细胞有关。在nmo - igg诱导的视网膜病变中，靶向 ller细胞-小胶质细胞相互作用的治疗策略有望解决这种情况下潜在的视网膜病理。

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来源期刊

Journal of Neuroinflammation 医学-神经科学

CiteScore

15.90

自引率

3.20%

发文量

276

审稿时长

1 months

期刊介绍： The Journal of Neuroinflammation is a peer-reviewed, open access publication that emphasizes the interaction between the immune system, particularly the innate immune system, and the nervous system. It covers various aspects, including the involvement of CNS immune mediators like microglia and astrocytes, the cytokines and chemokines they produce, and the influence of peripheral neuro-immune interactions, T cells, monocytes, complement proteins, acute phase proteins, oxidative injury, and related molecular processes. Neuroinflammation is a rapidly expanding field that has significantly enhanced our knowledge of chronic neurological diseases. It attracts researchers from diverse disciplines such as pathology, biochemistry, molecular biology, genetics, clinical medicine, and epidemiology. Substantial contributions to this field have been made through studies involving populations, patients, postmortem tissues, animal models, and in vitro systems. The Journal of Neuroinflammation consolidates research that centers around common pathogenic processes. It serves as a platform for integrative reviews and commentaries in this field.