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巨噬细胞有助于维持外周神经损伤后稳定的再生神经突。

Macrophages contribute to the maintenance of stable regenerating neurites following peripheral nerve injury.

作者信息

Luk Hoenie W, Noble Linda J, Werb Zena

机构信息

Department of Anatomy, University of California, San Francisco, California 94143-0452, USA.

出版信息

J Neurosci Res. 2003 Sep 1;73(5):644-58. doi: 10.1002/jnr.10701.

Abstract

Normal adult uninjured nerve is unable to support axonal regeneration. We have studied the mechanisms underlying the regeneration of peripheral nerve by culturing adult mouse dorsal root ganglia (DRG) explants on unfixed, longitudinal cryosections of either the uninjured sciatic nerve or the distal segment of the transected sciatic nerve. We found that, initially, DRG grew vigorously on cryosections of both uninjured and postinjury sciatic nerves. However, the neurites began to degenerate shortly after contact with the uninjured nerve, whereas those growing on postinjury nerve substrate remained healthy for up to 9 days in culture. This ability to support stable outgrowth peaked at 8 days, gradually decreased by 10 days, and disappeared by 20 days after injury. Macrophages appeared in the distal segment by 4 days postinjury and had infiltrated its entire length by 8 days. Uninjured nerve cryosections could be rendered supportive of stable outgrowth by preincubation with macrophage-conditioned medium or by brief trypsinization. The activity of the macrophage-conditioned medium was augmented upon activation of macrophages. Together these findings suggest that the environment of the sciatic nerve undergoes a transformation during Wallerian degeneration such that it becomes transiently supportive of the stable outgrowth of neurites. This transformation may be mediated by a proteolytic activity, generated by activated macrophages, that removes a putative "degeneration signal" protein normally present in the adult nerve and thus contributes to the maintenance of stable regenerating neurites.

摘要

正常成年未受损神经无法支持轴突再生。我们通过将成年小鼠背根神经节(DRG)外植体培养在未受损坐骨神经或横断坐骨神经远端段的未固定纵向冰冻切片上来研究周围神经再生的潜在机制。我们发现,最初,DRG在未受损和损伤后坐骨神经的冰冻切片上均生长旺盛。然而,神经突在与未受损神经接触后不久就开始退化,而在损伤后神经基质上生长的神经突在培养中长达9天仍保持健康。这种支持稳定生长的能力在损伤后8天达到峰值,到10天时逐渐下降,到20天时消失。巨噬细胞在损伤后4天出现在远端段,并在8天时浸润其全长。未受损神经冰冻切片通过用巨噬细胞条件培养基预孵育或短暂胰蛋白酶处理可变得支持稳定生长。巨噬细胞条件培养基的活性在巨噬细胞激活后增强。这些发现共同表明,坐骨神经的环境在沃勒变性过程中发生了转变,使其暂时支持神经突的稳定生长。这种转变可能由活化巨噬细胞产生的蛋白水解活性介导,该活性去除了成年神经中通常存在的一种假定的“退化信号”蛋白,从而有助于维持稳定的再生神经突。

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