Cormie Peter, Robinson Kenneth R
Purdue University, Department of Biological Sciences, 915 West State Street, West Lafayette, IN 47907, USA.
Neurosci Lett. 2007 Jan 10;411(2):128-32. doi: 10.1016/j.neulet.2006.10.030. Epub 2006 Nov 7.
Naturally occurring electric fields (EFs) have been implicated in cell guidance during embryonic development and adult wound healing. Embryonic Xenopus laevis neurons sprout preferentially towards the cathode, turn towards the cathode, and migrate faster towards the cathode in the presence of an external EF in vitro. A recent Phase 1 clinical trial has investigated the effects of oscillating EFs on human spinal cord regeneration. The purpose of this study was to investigate whether embryonic zebrafish neurons respond to an applied EF, and thus extend this research into another vertebrate system. Neural tubes of zebrafish embryos (16-17 somites) were dissected and dissociated neuroblasts were plated onto laminin-coated glass. A 100 mV/mm EF was applied to cell cultures for 4 or 20 h and the responses of neurons to the applied EFs were investigated. After 4h in an EF neurites were significantly shorter than control neurites. No other statistically significant effects were observed. After 20 h, control and EF-exposed neurites were no different in length. No length difference was seen between cathodally- and anodally-sprouted neurites. Application of an EF did not affect the average number of neurons in a chamber. Growth cones did not migrate preferentially towards either pole of the EF and no asymmetry was seen in neurite sprout sites. We conclude that zebrafish neurons do not respond to a 100 mV/mm applied EF in vitro. This suggests that neurons of other vertebrate species may not respond to applied EFs in the same ways as Xenopus laevis neurons.
自然产生的电场(EFs)在胚胎发育和成人伤口愈合过程中的细胞引导方面发挥了作用。非洲爪蟾胚胎神经元在体外存在外部电场时,会优先向阴极方向发芽、转向阴极,并向阴极方向更快地迁移。最近的一项1期临床试验研究了振荡电场对人类脊髓再生的影响。本研究的目的是调查斑马鱼胚胎神经元是否对施加的电场作出反应,从而将这项研究扩展到另一个脊椎动物系统。解剖斑马鱼胚胎(16 - 17体节)的神经管,将解离的神经母细胞接种到层粘连蛋白包被的玻璃片上。对细胞培养物施加100 mV/mm的电场4小时或20小时,并研究神经元对施加电场的反应。在电场中处理4小时后,神经突明显短于对照神经突。未观察到其他统计学上的显著影响。20小时后,对照和暴露于电场的神经突长度没有差异。阴极和阳极发芽的神经突长度没有差异。施加电场不影响培养室中神经元的平均数量。生长锥不会优先向电场的任何一极迁移,神经突发芽部位也没有观察到不对称现象。我们得出结论,斑马鱼神经元在体外对100 mV/mm的施加电场没有反应。这表明其他脊椎动物物种的神经元可能不会像非洲爪蟾神经元那样对施加的电场作出相同反应。