Brain endothelial specific gene therapy improves experimental Sandhoff disease

Journal of Cerebral Blood Flow & Metabolism Pub Date : 2020-06-01 DOI:10.1177/0271678X19865917

Godwin K. Dogbevia, H. Grasshoff, A. Othman, Anke Penno, M. Schwaninger

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引用次数: 14

Abstract

In Tay-Sachs and Sandhoff disease, a deficiency of the lysosomal enzyme β-hexosaminidase causes GM2 and other gangliosides to accumulate in neurons and triggers neurodegeneration. Although the pathology centers on neurons, β-hexosaminidase is mainly expressed outside of neurons, suggesting that gene therapy of these diseases should target non-neuronal cells to reconstitute physiological conditions. Here, we tested in Hexb−/− mice, a model of Sandhoff disease, to determine whether endothelial expression of the genes for human β-hexosaminidase subunit A and B (HEXA, HEXB) is able to reduce disease symptoms and prolong survival of the affected mice. The brain endothelial selective vectors AAV-BR1-CAG-HEXA and AAV-BR1-CAG-HEXB transduced brain endothelial cells, which subsequently released β-hexosaminidase enzyme. In vivo intravenous administration of the gene vectors to adult and neonatal mice prolonged survival. They improved neurological function and reduced accumulation of the ganglioside GM2 and the glycolipid GA2 as well as astrocytic activation. Overall, the data demonstrate that endothelial cells are a suitable target for intravenous gene therapy of GM2 gangliosidoses and possibly other lysosomal storage disorders.

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脑内皮特异性基因治疗改善实验性山德霍夫病

在Tay-Sachs病和Sandhoff病中，溶酶体酶β-己糖氨酸酶缺乏导致GM2和其他神经节苷类物质在神经元中积聚并引发神经变性。虽然病理以神经元为中心，但β-己糖氨酸酶主要在神经元外表达，提示这些疾病的基因治疗应针对非神经元细胞来重建生理状况。在这里，我们在Sandhoff病模型Hexb - / -小鼠中进行了测试，以确定内皮表达人β-己糖氨酸酶亚基a和B (HEXA, Hexb)基因是否能够减轻疾病症状并延长受影响小鼠的生存期。脑内皮选择载体AAV-BR1-CAG-HEXA和AAV-BR1-CAG-HEXB转导脑内皮细胞，随后释放β-己糖氨酸酶。成年和新生小鼠体内静脉注射基因载体延长了存活时间。它们改善了神经功能，减少了神经节苷脂GM2和糖脂GA2的积累以及星形胶质细胞的激活。总的来说，这些数据表明内皮细胞是静脉注射GM2神经节脂质剂量和其他溶酶体储存疾病基因治疗的合适靶点。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Cerebral Blood Flow & Metabolism

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