树突具有快速的损伤诱导退化程序,其分子特征与发育性修剪不同。
Dendrites have a rapid program of injury-induced degeneration that is molecularly distinct from developmental pruning.
机构信息
Biochemistry and Molecular Biology, The Pennsylvania State University, University Park, Pennsylvania 16802, USA.
出版信息
J Neurosci. 2011 Apr 6;31(14):5398-405. doi: 10.1523/JNEUROSCI.3826-10.2011.
Abstract
Neurons have two types of processes: axons and dendrites. Axons have an active disassembly program activated by severing. It has not been tested whether dendrites have an analogous program. We sever Drosophila dendrites in vivo and find that they are cleared within 24 h. Morphologically, this clearance resembles developmental dendrite pruning and, to some extent, axon degeneration. Like axon degeneration, both injury-induced dendrite degeneration and pruning can be delayed by expression of Wld(s) or UBP2. We therefore hypothesized that they use common machinery. Surprisingly, comparison of dendrite pruning and degeneration in the same cell demonstrated that none of the specific machinery used to prune dendrites is required for injury-induced dendrite degeneration. In addition, we show that the rapid program of dendrite degeneration does not require mitochondria. Thus, dendrites do have a rapid program of degeneration, as do axons, but this program does not require the machinery used during developmental pruning.
摘要
神经元有两种突起
轴突和树突。轴突有一种由切断激活的主动解体程序。尚未测试树突是否具有类似的程序。我们在体内切断果蝇树突,发现它们在 24 小时内被清除。从形态上看,这种清除类似于发育中的树突修剪,在某种程度上也类似于轴突退化。与轴突退化一样,损伤诱导的树突退化和修剪都可以通过 Wld(s)或 UBP2 的表达来延迟。因此,我们假设它们使用共同的机制。令人惊讶的是,对同一细胞中树突修剪和退化的比较表明,用于修剪树突的特定机制都不是损伤诱导的树突退化所必需的。此外,我们还表明,树突快速退化程序不需要线粒体。因此,树突和轴突一样,确实有一个快速的退化程序,但这个程序不需要在发育修剪过程中使用的机制。
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