Department of Neurology, Maastricht University Medical Center, 6202AZ, Maastricht, The Netherlands.
Department of Pathology, Maastricht University, Maastricht, 6200MD, The Netherlands.
Theranostics. 2020 Jul 25;10(21):9512-9527. doi: 10.7150/thno.44394. eCollection 2020.
Hypertension is a major risk factor for cerebral small vessel disease, the most prevalent cause of vascular cognitive impairment. As we have shown, hypertension induced by a prolonged Angiotensin II infusion is associated with increased permeability of the blood-brain barrier (BBB), chronic activation of microglia and myelin loss. In this study we therefore aim to determine the contribution of microglia to hypertension-induced cognitive impairment in an experimental hypertension model by a pharmacological depletion approach. For this study, adult x reporter mice were infused for 12 weeks with Angiotensin II or saline and subgroups were treated with PLX5622, a highly selective CSF1R tyrosine kinase inhibitor. Systolic blood pressure (SBP) was measured via tail-cuff. Short- and long-term spatial memory was assessed during an Object Location task and a Morris Water Maze task (MWM). Microglia depletion efficacy was assessed by flow cytometry and immunohistochemistry. BBB leakages, microglia phenotype and myelin integrity were assessed by immunohistochemistry. SBP, heart weight and carotid pulsatility were increased by Ang II and were not affected by PLX5622. Short-term memory was significantly impaired in Ang II hypertensive mice, and partly prevented in Ang II mice treated with PLX5622. Histological and flow cytometry analysis revealed almost complete ablation of microglia and a 60% depletion of brain resident perivascular macrophages upon CSF1R inhibition. Number and size of BBB leakages were increased in Ang II hypertensive mice, but not altered by PLX5622 treatment. Microglia acquired a pro-inflammatory phenotype at the site of BBB leakages in both Saline and Ang II mice and were successfully depleted by PLX5622. There was however no significant change in myelin integrity at the site of leakages. Our results show that depletion of microglia and PVMs, by CSF1R inhibition prevents short-term memory impairment in Ang II induced hypertensive mice. We suggest this beneficial effect is mediated by the major decrease of pro-inflammatory microglia within BBB leakages. This novel finding supports the critical role of brain immune cells in the pathogenesis of hypertension-related cognitive impairment. An adequate modulation of microglia /PVM density and phenotype may constitute a relevant approach to prevent and/or limit the progression of vascular cognitive impairment.
高血压是小血管疾病的主要危险因素,也是血管性认知障碍最常见的病因。正如我们所展示的,血管紧张素 II 输注引起的高血压与血脑屏障 (BBB) 的通透性增加、小胶质细胞的慢性激活和髓鞘丢失有关。因此,在这项研究中,我们旨在通过药理学耗竭方法确定小胶质细胞在实验性高血压模型中引起高血压诱导的认知障碍中的作用。为此,研究使用了成年 x 报告小鼠,通过 Angiotensin II 或盐水输注 12 周,并将亚组用 PLX5622 治疗,PLX5622 是一种高度选择性的 CSF1R 酪氨酸激酶抑制剂。通过尾套测量收缩压 (SBP)。通过物体位置任务和 Morris 水迷宫任务 (MWM) 评估短期和长期空间记忆。通过流式细胞术和免疫组织化学评估小胶质细胞耗竭效果。通过免疫组织化学评估 BBB 渗漏、小胶质细胞表型和髓鞘完整性。SBP、心脏重量和颈动脉脉动性在 Ang II 高血压小鼠中升高,而 PLX5622 不影响它们。Ang II 高血压小鼠的短期记忆明显受损,而 Ang II 小鼠用 PLX5622 治疗后部分得到预防。组织学和流式细胞术分析显示,CSF1R 抑制后,小胶质细胞几乎完全消融,脑驻留血管周巨噬细胞减少 60%。在 Ang II 高血压小鼠中,BBB 渗漏的数量和大小增加,但 PLX5622 治疗不改变它们。在 Saline 和 Ang II 小鼠中,BBB 渗漏部位的小胶质细胞获得了促炎表型,并被 PLX5622 成功耗竭。然而,渗漏部位的髓鞘完整性没有明显变化。我们的结果表明,通过 CSF1R 抑制耗尽小胶质细胞和 PVM 可预防 Ang II 诱导的高血压小鼠的短期记忆障碍。我们认为这种有益作用是通过 BBB 渗漏处促炎小胶质细胞的主要减少介导的。这一新发现支持脑免疫细胞在高血压相关认知障碍发病机制中的关键作用。适当调节小胶质细胞/PVM 的密度和表型可能是预防和/或限制血管性认知障碍进展的一种有效方法。
