Myers P Z, Bastiani M J
Department of Biology, University of Utah, Salt Lake City 84112.
J Neurosci. 1993 Jan;13(1):127-43. doi: 10.1523/JNEUROSCI.13-01-00127.1993.
We have used time-lapse video microscopy to study the behavior of a neuron, Q1, that pioneers the posterior commissure of the embryonic grasshopper. Our goal is to use time-lapse video as a tool to acquire a precise picture of normal development over time, and thereby identify stereotypic activities that might indicate important interactions necessary for proper formation of the commissure. We have identified specific and reproducible behaviors that suggest the presence of underlying cellular interactions that may play a role in pathfinding. In particular, the Q1 growth cone undergoes several morphological changes as it contacts the midline. As a commissural neuron, the midline may be a target in its outgrowth; Q1's typical response upon contacting the midline with its filopodia, however, is a rapid retraction. This inhibitory reaction can be overridden by contact with filopodia of its contralateral homolog. Q1's growth cone can translocate across the midline at an accelerated rate by a process resembling "filopodial dilation" (O'Connor et al., 1990) once the two Q1 growth cones meet. Ablation of the contralateral Q1 blocks Q1's advance across the midline. We have also analyzed in detail the behavior of individual filopodia to identify behavioral differences that could indicate differences in substrate adhesivity. Except for instances of filopodial dilation seen only at the midline, we found no significant asymmetries in rates of filopodial extension and retraction, or in the survival times of individual filopodia. We suggest that either the adhesive signal used by Q1 is relatively weak, requiring the integration of many adhesive interactions by many filopodia to be resolved, or the guidance cues may not be adhesive in nature.
我们利用延时视频显微镜研究了神经元Q1的行为,该神经元是胚胎期蚱蜢后连合的先驱。我们的目标是将延时视频作为一种工具,获取随时间推移正常发育的精确图像,从而识别可能表明连合正确形成所需重要相互作用的刻板活动。我们已经确定了特定且可重复的行为,这表明可能存在潜在的细胞相互作用,这些相互作用可能在路径寻找中发挥作用。特别是,Q1生长锥在接触中线时会经历几种形态变化。作为连合神经元,中线可能是其生长的目标;然而,Q1的丝状伪足接触中线时的典型反应是迅速回缩。这种抑制反应可以被与其对侧同源物的丝状伪足接触所克服。一旦两个Q1生长锥相遇,Q1的生长锥可以通过类似于“丝状伪足扩张”(奥康纳等人,1990年)的过程以加速速率穿过中线。对侧Q1的消融会阻止Q1穿过中线。我们还详细分析了单个丝状伪足的行为,以识别可能表明底物粘附性差异的行为差异。除了仅在中线观察到的丝状伪足扩张情况外,我们发现丝状伪足伸展和回缩的速率或单个丝状伪足的存活时间没有显著的不对称性。我们认为,要么Q1使用的粘附信号相对较弱,需要许多丝状伪足整合许多粘附相互作用才能解决,要么引导线索本质上可能不是粘附性的。