HIV-1 Tat 诱导的小胶质细胞 EVs 导致神经元突触树突状损伤:NeuroHIV 中的小胶质细胞-神经元交叉对话。

Muthukumar Kannan, Seema Singh, Divya T Chemparathy, Abiola A Oladapo, Dinesh Y Gawande, Shashank M Dravid, Shilpa Buch, Susmita Sil
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引用次数: 0

摘要

目的:小胶质细胞 NLRP3 炎性体的激活是导致艾滋病毒相关神经系统疾病(HAND)的神经炎症的重要因素。在病理条件下,小胶质细胞衍生的EVs(MDEVs)可通过向受体细胞传递神经毒性介质来影响神经元功能。然而,迄今为止,小胶质细胞 NLRP3 在介导神经元突触树突损伤中的作用仍未得到研究。在本研究中,我们试图评估 HIV-1 Tat 诱导的小胶质细胞 NLRP3 在神经元突触树突损伤中的调控作用。我们假设,HIV-1 Tat 介导的携带大量 NLRP3 的小胶质细胞 EVs 会导致突触树突损伤,从而影响神经元的成熟:为了了解小胶质细胞与神经元之间的交叉对话,我们使用 siNLRP3 RNA 从 BV2 和人类原代小胶质细胞(HPM)中分离出了 NLRP3 缺失或未缺失的 EVs。我们采用差速离心法分离了EVs,并通过ZetaView纳米颗粒追踪分析、电子显微镜和Western印迹分析对外泌体标记物进行了表征。纯化的EV暴露于从E18大鼠分离的原代大鼠神经元。在转染绿色荧光蛋白(GFP)质粒的同时,还进行了免疫细胞化学分析,以观察神经元突触树突损伤。用 Western 印迹法测量 siRNA 的转染效率和神经元突触变性的程度。共聚焦显微镜捕获图像,然后使用神经元重建软件 Neurolucida 360 进行 Sholl 分析,以分析树突棘。对海马神经元进行了电生理学功能评估:结果:我们的研究结果表明,HIV-1 Tat 可诱导小胶质细胞 NLRP3 和 IL1β 的表达,而且这些物质被包装在小胶质细胞外泌体(MDEV)中,并被神经元吸收。将大鼠原发性神经元暴露于小胶质细胞 Tat-MDEVs 会导致突触蛋白 PSD95、突触素、兴奋性 vGLUT1 的下调,以及抑制蛋白 Gephyrin、GAD65 的上调,从而暗示神经元的传递性受损。我们的研究结果还表明,Tat-MDEVs 不仅会导致树突棘的缺失,还会影响树突棘亚型--蘑菇棘和矮棘--的数量。突触树突损伤进一步影响了功能损伤,这体现在微型兴奋性突触后电流(mEPSCs)的减少上。为了评估 NLRP3 在这一过程中的调节作用,神经元还暴露于来自 NLRP3 沉默的小胶质细胞的 Tat-MDEVs 中。来自 NLRP3 沉默的小胶质细胞的 Tat-MDEV 对神经元突触蛋白、脊柱密度以及 mEPSCs 起到了保护作用:总之,我们的研究强调了小胶质细胞 NLRP3 在 Tat-MDEV 介导的突触树突损伤中的重要作用。虽然 NLRP3 在炎症中的作用已被充分描述,但它在 EV 介导的神经元损伤中的作用却是一个有趣的发现,这意味着它是手足口病治疗的一个靶点。
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HIV-1 Tat induced microglial EVs leads to neuronal synaptodendritic injury: microglia-neuron cross-talk in NeuroHIV.

Aim: Activation of microglial NLRP3 inflammasome is an essential contributor to neuroinflammation underlying HIV-associated neurological disorders (HAND). Under pathological conditions, microglia-derived-EVs (MDEVs) can affect neuronal functions by delivering neurotoxic mediators to recipient cells. However, the role of microglial NLRP3 in mediating neuronal synaptodendritic injury has remained unexplored to date. In the present study, we sought to assess the regulatory role of HIV-1 Tat induced microglial NLRP3 in neuronal synaptodendritic injury. We hypothesized that HIV-1 Tat mediated microglia EVs carrying significant levels of NLRP3 contribute to the synaptodendritic injury, thereby affecting the maturation of neurons.

Methods: To understand the cross-talk between microglia and neuron, we isolated EVs from BV2 and human primary microglia (HPM) cells with or without NLRP3 depletion using siNLRP3 RNA. EVs were isolated by differential centrifugation, characterized by ZetaView nanoparticle tracking analysis, electron microscopy, and western blot analysis for exosome markers. Purified EVs were exposed to primary rat neurons isolated from E18 rats. Along with green fluorescent protein (GFP) plasmid transfection, immunocytochemistry was performed to visualize neuronal synaptodendritic injury. Western blotting was employed to measure siRNA transfection efficiency and the extent of neuronal synaptodegeneration. Images were captured in confocal microscopy, and subsequently, Sholl analysis was performed for analyzing dendritic spines using neuronal reconstruction software Neurolucida 360. Electrophysiology was performed on hippocampal neurons for functional assessment.

Results: Our findings demonstrated that HIV-1 Tat induced expression of microglial NLRP3 and IL1β, and further that these were packaged in microglial exosomes (MDEV) and were also taken up by the neurons. Exposure of rat primary neurons to microglial Tat-MDEVs resulted in downregulation of synaptic proteins- PSD95, synaptophysin, excitatory vGLUT1, as well as upregulation of inhibitory proteins- Gephyrin, GAD65, thereby implicating impaired neuronal transmissibility. Our findings also showed that Tat-MDEVs not only caused loss of dendritic spines but also affected numbers of spine sub-types- mushroom and stubby. Synaptodendritic injury further affected functional impairment as evidenced by the decrease in miniature excitatory postsynaptic currents (mEPSCs). To assess the regulatory role of NLRP3 in this process, neurons were also exposed to Tat-MDEVs from NLRP3 silenced microglia. Tat-MDEVs from NLRP3 silenced microglia exerted a protective role on neuronal synaptic proteins, spine density as well as mEPSCs.

Conclusion: In summary, our study underscores the role of microglial NLRP3 as an important contributor to Tat-MDEV mediated synaptodendritic injury. While the role of NLRP3 in inflammation is well-described, its role in EV-mediated neuronal damage is an interesting finding, implicating it as a target for therapeutics in HAND.

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