Repopulated microglia after pharmacological depletion decrease dendritic spine density in adult mouse brain

IF 5.4 2区 医学 Q1 NEUROSCIENCES
Glia Pub Date : 2024-05-23 DOI:10.1002/glia.24541
Jonathan Wickel, Ha-Yeun Chung, Mihai Ceanga, Nikolai von Stackelberg, Nina Hahn, Özge Candemir, Carolin Baade-Büttner, Nils Mein, Paula Tomasini, Dan M. Woldeyesus, Nico Andreas, Peter Baumgarten, Philipp Koch, Marco Groth, Zhao-Qi Wang, Christian Geis
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Abstract

Microglia are innate immune cells in the brain and show exceptional heterogeneity. They are key players in brain physiological development regulating synaptic plasticity and shaping neuronal networks. In pathological disease states, microglia-induced synaptic pruning mediates synaptic loss and targeting microglia was proposed as a promising therapeutic strategy. However, the effect of microglia depletion and subsequent repopulation on dendritic spine density and neuronal function in the adult brain is largely unknown. In this study, we investigated whether pharmacological microglia depletion affects dendritic spine density after long-term permanent microglia depletion and after short-term microglia depletion with subsequent repopulation. Long-term microglia depletion using colony-stimulating-factor-1 receptor (CSF1-R) inhibitor PLX5622 resulted in increased overall spine density, especially of mushroom spines, and increased excitatory postsynaptic current amplitudes. Short-term PLX5622 treatment with subsequent repopulation of microglia had an opposite effect resulting in activated microglia with increased synaptic phagocytosis and consequently decreased spine density and reduced excitatory neurotransmission, while Barnes maze and elevated plus maze testing was unaffected. Moreover, RNA sequencing data of isolated repopulated microglia showed an activated and proinflammatory phenotype. Long-term microglia depletion might be a promising therapeutic strategy in neurological diseases with pathological microglial activation, synaptic pruning, and synapse loss. However, repopulation after depletion induces activated microglia and results in a decrease of dendritic spines possibly limiting the therapeutic application of microglia depletion. Instead, persistent modulation of pathological microglia activity might be beneficial in controlling synaptic damage.

Abstract Image

药物消耗后重新增殖的小胶质细胞会降低成年小鼠大脑树突棘的密度。
小胶质细胞是大脑中的先天性免疫细胞,具有特殊的异质性。它们是大脑生理发育的关键角色,调节突触可塑性并塑造神经元网络。在病理疾病状态下,小胶质细胞诱导的突触修剪介导突触丢失,因此靶向小胶质细胞被认为是一种很有前景的治疗策略。然而,小胶质细胞耗竭和随后的重新填充对成人大脑树突棘密度和神经元功能的影响在很大程度上是未知的。在这项研究中,我们研究了药物性小胶质细胞耗竭是否会影响长期永久性小胶质细胞耗竭后的树突棘密度,以及短期小胶质细胞耗竭后的树突棘密度。使用集落刺激因子-1 受体(CSF1-R)抑制剂 PLX5622 进行长期小胶质细胞耗竭会导致整体棘突密度增加,尤其是蘑菇棘突,并增加兴奋性突触后电流幅度。短期的 PLX5622 处理和随后的小胶质细胞再填充则产生了相反的效果,导致小胶质细胞活化,突触吞噬作用增强,从而降低了棘突密度,减少了兴奋性神经传递,而巴恩斯迷宫和高架加迷宫测试则不受影响。此外,分离出的重新填充的小胶质细胞的 RNA 测序数据显示了激活和促炎表型。对于存在病理性小胶质细胞活化、突触修剪和突触丢失的神经系统疾病,长期消耗小胶质细胞可能是一种很有前景的治疗策略。然而,消耗后的重新填充会诱导活化的小胶质细胞,并导致树突棘的减少,这可能会限制小胶质细胞消耗的治疗应用。相反,持续调节病理小胶质细胞的活性可能有利于控制突触损伤。
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来源期刊
Glia
Glia 医学-神经科学
CiteScore
13.10
自引率
4.80%
发文量
162
审稿时长
3-8 weeks
期刊介绍: GLIA is a peer-reviewed journal, which publishes articles dealing with all aspects of glial structure and function. This includes all aspects of glial cell biology in health and disease.
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