Jacobs G A, Miller J P, Murphey R K
J Neurosci. 1986 Aug;6(8):2298-311. doi: 10.1523/JNEUROSCI.06-08-02298.1986.
Several identified interneurons in the cricket cercal afferent system display directional sensitivity to wind stimuli: the spike frequency of these cells depends on the wind direction with respect to the animal's body. Factors determining the directional sensitivity of one of these identified interneurons (interneuron 10-3) were studied in detail. This cell has 3 dendritic branches that arborize in 3 distinct regions of the terminal abdominal ganglion. Using 2 independent methods, it was demonstrated that the dendrites have different receptive fields to wind stimuli. First, small patches of filiform hairs, whose afferents projected to individual dendrites, were isolated and selectively stimulated. In each case the response of the cell matched the receptive field of the afferents in the patch. Second, a laser beam directed through the stereo dissecting microscope was used to photoinactivate small portions of the cell in situ during intracellular recording. By isolating or ablating individual dendrites, the contributions of each of the 3 dendrites to the overall receptive field were assessed. Although the receptive field of the whole cell could be predicted by a summation of the receptive fields of all 3 dendrites, the precise directional sensitivity of the cell could not be predicted by a simple linear summation of the receptive fields of each dendrite. Two factors were found to account for this nonlinearity of summation. The first factor was polysynaptic inhibition from other interneurons within the terminal abdominal ganglion. Wind directions that activate inhibition in interneuron 10-3 were identified, and the specific classes of filiform afferents that activate the inhibitory pathway were determined. The net effect of the inhibition was to "sharpen" the directional sensitivity of 10-3 by selectively decreasing the cell's response to specific excitatory inputs. The second factor that contributed to directional sensitivity was the complex electroanatomy of the interneuron. The probable location of the spike-initiating zone (SIZ) was determined by using the laser photoinactivation technique. The relative efficacies of synaptic inputs onto the 3 different branches were then interpreted with respect to their different electrotonic distances from the SIZ. On the basis of the data obtained in this report, we present a qualitative model for the basis of directional sensitivity in this cell.
在蟋蟀尾须传入系统中,已鉴定出的几种中间神经元对风刺激表现出方向敏感性:这些细胞的放电频率取决于风向与动物身体的相对方向。我们详细研究了其中一种已鉴定出的中间神经元(中间神经元10 - 3)方向敏感性的决定因素。该细胞有3个树突分支,在腹部末端神经节的3个不同区域形成分支。使用两种独立的方法,证明了树突对风刺激具有不同的感受野。首先,分离出丝状毛的小斑块,其传入纤维投射到单个树突上,并进行选择性刺激。在每种情况下,细胞的反应都与斑块中传入纤维的感受野相匹配。其次,在细胞内记录过程中,使用通过立体解剖显微镜引导的激光束对细胞的小部分进行原位光灭活。通过分离或切除单个树突,评估了3个树突中每个树突对整体感受野的贡献。尽管整个细胞的感受野可以通过所有3个树突的感受野总和来预测,但细胞精确的方向敏感性不能通过每个树突感受野的简单线性总和来预测。发现有两个因素导致了这种总和的非线性。第一个因素是来自腹部末端神经节内其他中间神经元的多突触抑制。确定了激活中间神经元10 - 3抑制作用的风向,并确定了激活抑制途径的丝状传入纤维的特定类别。抑制的净效应是通过选择性降低细胞对特定兴奋性输入的反应来“锐化”10 - 3的方向敏感性。导致方向敏感性的第二个因素是中间神经元复杂的电解剖结构。通过使用激光光灭活技术确定了动作电位起始区(SIZ)的可能位置。然后根据突触输入到3个不同分支上的相对效能,相对于它们与SIZ的不同电紧张距离进行了解释。根据本报告中获得的数据,我们提出了该细胞方向敏感性基础的定性模型。