驱动蛋白重链在果蝇神经胶质细胞中的功能控制神经元活性。
Kinesin heavy chain function in Drosophila glial cells controls neuronal activity.
机构信息
Institut für Neurobiologie, Universität Münster, D-48149 Münster, Germany.
出版信息
J Neurosci. 2012 May 30;32(22):7466-76. doi: 10.1523/JNEUROSCI.0349-12.2012.
Abstract
Kinesin heavy chain (Khc) is crucially required for axonal transport and khc mutants show axonal swellings and paralysis. Here, we demonstrate that in Drosophila khc is equally important in glial cells. Glial-specific downregulation of khc by RNA interference suppresses neuronal excitability and results in spastic flies. The specificity of the phenotype was verified by interspecies rescue experiments and further mutant analyses. Khc is mostly required in the subperineurial glia forming the blood-brain barrier. Following glial-specific knockdown, peripheral nerves are swollen with maldistributed mitochondria. To better understand khc function, we determined Khc-dependent Rab proteins in glia and present evidence that Neurexin IV, a well known blood-brain barrier constituent, is one of the relevant cargo proteins. Our work shows that the role of Khc for neuronal excitability must be considered in the light of its necessity for directed transport in glia.
摘要
驱动蛋白重链 (Khc) 对于轴突运输至关重要,Khc 突变体表现出轴突肿胀和瘫痪。在这里,我们证明了在果蝇中,Khc 在神经胶质细胞中同样重要。通过 RNA 干扰特异性下调 Khc 可抑制神经元兴奋性,并导致痉挛性果蝇。表型的特异性通过种间拯救实验和进一步的突变分析得到验证。Khc 主要在形成血脑屏障的亚神经胶质细胞中发挥作用。在神经胶质特异性敲低后,外围神经肿胀,线粒体分布不均。为了更好地理解 Khc 的功能,我们确定了神经胶质细胞中依赖 Khc 的 Rab 蛋白,并提供了证据表明神经连接蛋白 IV 是血脑屏障的组成部分之一,是相关的货物蛋白之一。我们的工作表明,在考虑 Khc 对神经元兴奋性的作用时,必须考虑其在神经胶质细胞中定向运输的必要性。
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