Department of Physiology and Medical Physics, Centre for the Study of Neurological Disorders, Royal College of Surgeons in Ireland, 123 St. Stephen's Green, Dublin 2, Ireland.
Tissue Biology Laboratory, Department of Medical Biochemistry and Biophysics, Karolinska Institute, Scheeles v. 2, 17177, Stockholm, Sweden.
Neuropharmacology. 2018 May 1;133:503-511. doi: 10.1016/j.neuropharm.2018.02.022. Epub 2018 Feb 25.
Loss-of-function mutations in the angiogenin (ANG) gene have been identified in familial and sporadic ALS patients. Previous work from our group identified human ANG (huANG) to protect motoneurons in vitro, and provided proof-of-concept that daily intraperitoneal (i.p.) huANG injections post-symptom onset increased lifespan and delayed disease progression in SOD1 mice. huANG's mechanism of action remains less well understood. Here, we implemented a preclinical in vivo design to validate our previous results, provide pharmacokinetic and protein distribution data after systemic administration, and explore potential pleiotropic activities of huANG in vivo. SOD1 mice (n = 45) and non-transgenic controls (n = 31) were sex- age- and litter-matched according to the 2010 European ALS/MND group guidelines, and treated with huANG (1 μg, i.p., 3 times/week) or vehicle from 90 days on. huANG treatment increased survival and delayed motor dysfunction as assessed by rotarod in SOD1 mice. Increased huANG serum levels were detectable 2 and 24 h after i.p. injection equally in transgenic and non-transgenic mice. Exogenous huANG localized to spinal cord astrocytes, supporting a glia-mediated, paracrine mechanism of action; uptake into endothelial cells was also observed. 1 μg huANG or vehicle were administered from 90 to 115 days of age for histological analysis. Vehicle-treated SOD1 mice showed decreased motoneuron numbers and vascular length per ventral horn area, while huANG treatment resulted in improved vascular network maintenance and motoneuron survival. Our data suggest huANG represents a new class of pleiotropic ALS therapeutic that acts on the spinal cord vasculature and glia to delay motoneuron degeneration and disease progression.
血管生成素(ANG)基因的失功能突变已在家族性和散发性 ALS 患者中被发现。我们小组的先前工作鉴定了人 ANG(huANG)可在体外保护运动神经元,并提供了概念验证,即在症状出现后每天腹腔内(i.p.)注射 huANG 可延长 SOD1 小鼠的寿命并延缓疾病进展。huANG 的作用机制仍不太清楚。在这里,我们实施了一项临床前体内设计,以验证我们之前的结果,提供系统给药后的药代动力学和蛋白质分布数据,并探索 huANG 在体内的潜在多效性活性。根据 2010 年欧洲 ALS/MND 小组指南,SOD1 小鼠(n=45)和非转基因对照(n=31)按性别、年龄和窝匹配,并从 90 天开始用 huANG(1μg,i.p.,每周 3 次)或载体处理。huANG 治疗可增加 SOD1 小鼠的存活率并延迟旋转棒评估的运动功能障碍。在转基因和非转基因小鼠中,腹腔注射后 2 和 24 小时均可检测到 huANG 血清水平升高。外源性 huANG 定位于脊髓星形胶质细胞,支持胶质介导的旁分泌作用机制;还观察到内皮细胞摄取。在 90 至 115 天龄时给予 1μg huANG 或载体进行组织学分析。用载体处理的 SOD1 小鼠显示运动神经元数量减少和腹角区每单位面积血管长度减少,而 huANG 治疗可改善血管网络维持和运动神经元存活。我们的数据表明,huANG 代表了一类新的多效性 ALS 治疗药物,可作用于脊髓血管和胶质细胞,以延迟运动神经元变性和疾病进展。
