[Cell-specific deletion of glucosylceramide synthase in brain leads to severe neural defects after birth].

Verhandlungen der Deutschen Gesellschaft fur Pathologie Pub Date : 2006-01-01

R Jennemann, R Sandhoff, H Wiegandt, H-J Gröne

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Abstract

Aims: Gangliosides, i. e. sialic acid containing glycosphingolipids, constitute a major component of neuronal cells and are thought to be essential for brain function. UDP-glucose: ceramide glucosyl-transferase (Ugcg) catalyzes the initial step of glycosphingolipid (GSL) biosynthesis. A total deletion of the Ugcg-gene in mice led to embryonic lethality. In order to gain insight into the role of gangliosides in brain development and function, a cell specific disruption of Ugcg was performed.

Methods: A cell specific disruption of Ugcg in mice was performed using the Cre/loxP-system. LoxP-flanked Ugcg-mice were generated and crossed with nestin-cre mice.

Results: The nestin-promoted gene deletion in neuronal cells was indicated by the absence of virtually all gangliosides already at stage E15.5. Shortly after birth mice showed dysfunction of cerebellum and peripheral nerves, associated with structural defects. Axon-branching of Purkinje cells was significantly reduced. In primary cultures of neurons dendritic complexity was clearly diminished, while pruning occurred. Myelin sheaths of peripheral nerves were broadened and focally severely disorganized. GSL deficiency also led to a downregulation of gene expression sets involved in brain development and homeostasis. Mice died approximately 3 weeks after birth.

Conclusions: The pronounced neurologic symptoms in postnatal mice with neuronal specific deficiency of glucosylceramide synthesis demonstrate that GlcCer-derived GSL may not serve functions essential for early brain development. They are, however, required for neuron differentiation and brain maturation.

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[大脑中葡萄糖神经酰胺合成酶的细胞特异性缺失导致出生后严重的神经缺陷]。

目的:神经节苷类，即含有鞘糖脂的唾液酸，是神经元细胞的主要成分，被认为对脑功能至关重要。udp -葡萄糖:神经酰胺葡萄糖基转移酶(Ugcg)催化鞘糖脂(GSL)生物合成的第一步。uggg基因在小鼠中的完全缺失导致胚胎死亡。为了深入了解神经节苷在大脑发育和功能中的作用，研究人员对Ugcg进行了细胞特异性破坏。方法:采用Cre/ loxp系统对小鼠Ugcg进行细胞特异性破坏。制备了loxp侧翼的ugcg小鼠，并与巢鼠杂交。结果:在E15.5期，几乎所有神经节苷脂都缺失，这表明巢蛋白促进了神经元细胞的基因缺失。出生后不久，小鼠表现出小脑和周围神经功能障碍，并伴有结构缺陷。浦肯野细胞轴突分支明显减少。在原代培养的神经元树突复杂性明显减少，而修剪发生。周围神经髓鞘变宽，局部严重紊乱。GSL缺乏还导致与大脑发育和体内平衡有关的基因表达组下调。小鼠在出生后约3周死亡。结论:糖基神经酰胺合成神经元特异性缺陷的产后小鼠明显的神经系统症状表明，糖基神经酰胺衍生的GSL可能不具有早期大脑发育所必需的功能。然而，它们是神经元分化和大脑成熟所必需的。

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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Verhandlungen der Deutschen Gesellschaft fur Pathologie

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