Halloran M C, Kalil K
Neuroscience Training Program, University of Wisconsin-Madison 53706.
J Neurosci. 1994 Apr;14(4):2161-77. doi: 10.1523/JNEUROSCI.14-04-02161.1994.
During development, axons of the mammalian corpus callosum must navigate across the midline to establish connections with corresponding targets in the contralateral cerebral cortex. To gain insight into how growth cones of callosal axons respond to putative guidance cues along this CNS pathway, we have used time-lapse video microscopy to observe dynamic behaviors of individual callosal growth cones extending in living brain slices from neonatal hamster sensorimotor cortex. Crystals of the lipophilic dye 1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate (Dil) were inserted into the cortex in vivo to label small populations of callosal axons and their growth cones. Subsequently, 400 microns brain slices that included the injection site, the corpus callosum, and the target cortex were placed in culture and viewed under low-light-level conditions with a silicon-intensified target (SIT) camera. Time-lapse video observations revealed striking differences in growth cone behaviors in different regions of the callosal pathway. In the tract, which is defined as the region of the callosal pathway from the injection site to the corresponding target cortex, growth cones advanced rapidly, displaying continual lamellipodial shape changes and filopodial exploration. Forward advance was sometimes interrupted by brief pauses or retraction. Growth cones in the target cortex had almost uniform compact shapes that were consistently smaller than those in the tract. In cortex, axons adhered to straight radial trajectories and their growth cones extended at only half the speed of those in the tract. Growth cones in subtarget regions of the callosum beneath cortical targets displayed complex behaviors characterized by long pauses, extension of transitory branches, and repeated cycles of collapse, withdrawal, and resurgence. Video observations suggested that extension of axons into cortical targets could occur by interstitial branching from callosal axons rather than by turning behaviors of the primary growth cones. These results suggest the existence of guidance cues distinct for each of these callosal regions that elicit characteristic growth cone behaviors.
在发育过程中,哺乳动物胼胝体的轴突必须穿过中线,与对侧大脑皮质中的相应靶点建立连接。为了深入了解胼胝体轴突的生长锥如何沿着这条中枢神经系统通路对假定的导向线索做出反应,我们使用延时视频显微镜观察了从新生仓鼠感觉运动皮质的活体脑片中伸出的单个胼胝体生长锥的动态行为。将亲脂性染料1,1'-二辛基-3,3,3',3'-四甲基吲哚羰花青高氯酸盐(Dil)的晶体在体内插入皮质,以标记少量的胼胝体轴突及其生长锥。随后,将包含注射部位、胼胝体和目标皮质的400微米脑片置于培养中,并在低光照条件下用硅增强靶(SIT)相机观察。延时视频观察揭示了胼胝体通路不同区域生长锥行为的显著差异。在束中,即从注射部位到相应目标皮质的胼胝体通路区域,生长锥快速前进,表现出持续的片状伪足形状变化和丝状伪足探索。向前推进有时会被短暂的停顿或回缩打断。目标皮质中的生长锥几乎具有均匀的紧凑形状,始终比束中的生长锥小。在皮质中,轴突附着于笔直的放射状轨迹,其生长锥的延伸速度仅为束中生长锥的一半。皮质靶点下方胼胝体亚靶点区域的生长锥表现出复杂的行为,其特征为长时间停顿、短暂分支的延伸以及反复的塌陷、回缩和复苏循环。视频观察表明,轴突向皮质靶点的延伸可能是通过胼胝体轴突的间质分支而非初级生长锥的转向行为实现的。这些结果表明,这些胼胝体区域各自存在独特的导向线索,可引发特征性的生长锥行为。