Department of Translational Biomedicine and Neuroscience School of Medicine, University of Bari Aldo Moro, Piazza Giulio Cesare, Bari, 70100, Italy.
Department of Bioscience, Biotechnology and Environment, University of Bari Aldo Moro, Bari, Italy.
Acta Neuropathol Commun. 2024 Oct 10;12(1):159. doi: 10.1186/s40478-024-01870-4.
The water channel aquaporin-4 (AQP4) is crucial for water balance in the mammalian brain. AQP4 has two main canonical isoforms, M23, which forms supramolecular structures called Orthogonal Arrays of Particles (OAP) and M1, which does not, along with two extended isoforms (M23ex and M1ex). This study examines these isoforms' roles, particularly AQP4ex, which influences water channel activity and localization at the blood-brain barrier. Using mice lacking both AQP4ex isoforms (AQP4ex-KO) and lacking both AQP4M23 isoforms (OAP-null) mice, we explored brain water dynamics under osmotic stress induced by an acute water intoxication (AWI) model. AQP4ex-KO mice had lower basal brain water content than WT and OAP-null mice. During AWI, brain water content increased rapidly in WT and AQP4ex-KO mice, but was delayed in OAP-null mice. AQP4ex-KO mice had the highest water content increase at 20 min. Immunoblot analysis showed stable total AQP4 in WT mice initially, with increases at 30 min. AQP4ex and its phosphorylated form (p-AQP4ex) levels rose quickly, but the p-AQP4ex/AQP4ex ratio dropped at 20 min. AQP4ex-KO mice showed a compensatory rise in canonical AQP4 at 20 min post-AWI. These findings highlight the important role of AQP4ex in water content dynamics in both normal and pathological states. To evaluate brain waste clearance, amyloid-β (Aβ) removal was assessed using a fluorescent Aβ intra-parenchyma injection model. AQP4ex-KO mice demonstrated markedly impaired Aβ clearance, with extended diffusion distances and reduced fluorescence in cervical lymph nodes, indicating inefficient drainage from the brain parenchyma. Mechanistically, the polarization of AQP4 at astrocytic endfeet is essential for efficient clearance flow, aiding interstitial fluid movement into the CSF and lymphatic system. In AQP4ex-KO mice, disrupted polarization forces reliance on slower, passive diffusion for solute clearance, significantly reducing Aβ removal efficiency and altering extracellular space dynamics. Our results underscore the importance of AQP4ex in both brain water homeostasis and solute clearance, particularly Aβ. These findings highlight AQP4ex as a potential therapeutic target for enhancing waste clearance mechanisms in the brain, which could have significant implications for treating brain edema and neurodegenerative diseases like Alzheimer's.
水通道蛋白 aquaporin-4(AQP4)对于哺乳动物大脑中的水平衡至关重要。AQP4 有两个主要的规范同工型,M23 形成称为正交排列颗粒(OAP)的超分子结构,而 M1 则不形成,以及两个扩展同工型(M23ex 和 M1ex)。本研究检查了这些同工型的作用,特别是 AQP4ex,它影响水通道在血脑屏障的活性和定位。使用缺乏两种 AQP4ex 同工型(AQP4ex-KO)和缺乏两种 AQP4M23 同工型(OAP- 缺失)的小鼠,我们在急性水中毒(AWI)模型诱导的渗透胁迫下探讨了脑水动力学。AQP4ex-KO 小鼠的基础脑含水量低于 WT 和 OAP- 缺失小鼠。在 AWI 期间,WT 和 AQP4ex-KO 小鼠的脑含水量迅速增加,但 OAP- 缺失小鼠的增加延迟。AQP4ex-KO 小鼠在 20 分钟时的含水量增加最高。免疫印迹分析显示 WT 小鼠的总 AQP4 最初稳定,30 分钟时增加。AQP4ex 和其磷酸化形式(p-AQP4ex)水平迅速升高,但 20 分钟时 p-AQP4ex/AQP4ex 比值下降。AWI 后 20 分钟,AQP4ex-KO 小鼠的经典 AQP4 代偿性升高。这些发现强调了 AQP4ex 在正常和病理状态下脑含水量动态中的重要作用。为了评估脑废物清除,使用荧光 Aβ 脑实质内注射模型评估 Aβ 清除。AQP4ex-KO 小鼠表现出明显的 Aβ 清除受损,颈部淋巴结中的扩散距离延长,荧光强度降低,表明脑实质中的引流效率低下。从机制上讲,AQP4 在星形胶质细胞足突的极化对于有效的清除流至关重要,有助于将细胞外间隙中的间质液转移到 CSF 和淋巴系统中。在 AQP4ex-KO 小鼠中,极化力的破坏依赖于较慢的、被动的扩散来清除溶质,显著降低了 Aβ 的清除效率并改变了细胞外空间动力学。我们的结果强调了 AQP4ex 在脑水平衡和溶质清除(特别是 Aβ)中的重要性。这些发现表明 AQP4ex 是增强脑废物清除机制的潜在治疗靶点,这可能对治疗脑水肿和阿尔茨海默病等神经退行性疾病具有重要意义。
