Thomson A M, Deuchars J, West D C
Department of Physiology, Royal Free Hospital School of Medicine, London, U.K.
Neuroscience. 1993 May;54(2):347-60. doi: 10.1016/0306-4522(93)90257-g.
In slices of adult rat somatosensory/motor cortex, paired recordings were made from pyramidal and non-pyramidal neurons. Single axon excitatory postsynaptic potentials evoked in the non-pyramidal neuron by action potentials in the pyramidal neuron were large and fast and demonstrated large fluctuations in amplitude, with coefficients of variation between 0.1 and 1.25. Excitatory postsynaptic potential amplitude distributions included a large number of apparent failures of transmission as well as some extremely large events. This contrasted dramatically with the relatively narrow distribution of amplitudes for pyramid-pyramid connections in neocortex. Excitatory postsynaptic potentials increased in amplitude with postsynaptic membrane hyperpolarization. Very small changes in the coefficient of variation when mean amplitudes increased substantially were consistent with the increase being due to a change in quantal amplitude. These excitatory postsynaptic potentials displayed profound paired pulse facilitation. Moreover, third and fourth spikes in a presynaptic burst also evoked large responses. This facilitation was associated with a decrease in the proportion of apparent failures in transmission and a change in the shape of the excitatory postsynaptic potential amplitude distribution, both indicative of an increase in the probability of transmitter release. However a large change in the mean amplitude was not associated with a similar change in the inverse square of the coefficient of variation. The result of this third test, taken in isolation, might therefore suggest that quantal amplitude had increased with paired-pulse facilitation. However, of the three tests applied, this last is the most heavily model-dependent and produced a result inconsistent with the results of the other two tests. The possibility is therefore discussed that both the shape of the excitatory postsynaptic potential amplitude distribution and the failure of coefficient of variation analysis to detect an apparently presynaptic change might result from the release at these synapses being poorly fit by a simple model. Based on a more complex model of synaptic release proposed by Faber and Korn [Faber and Korn (1991) Biophys. J. 60, 1288-1294] and a hypothesis proposed by Scharfman et al. [Scharfman et al. (1990) Neuroscience 37, 693-707], two hypotheses arising from the present study are discussed: (i) that branch point failure contributes to the pattern of synaptic activation at these connections; and (ii) that both presynaptic pyramidal firing pattern and axonal geometry contribute to the selection of the type of postsynaptic neurone preferentially activated.(ABSTRACT TRUNCATED AT 400 WORDS)
在成年大鼠体感/运动皮层切片中,对锥体神经元和非锥体神经元进行了配对记录。锥体神经元动作电位在非锥体神经元中诱发的单轴突兴奋性突触后电位大且快速,幅度波动很大,变异系数在0.1至1.25之间。兴奋性突触后电位幅度分布包括大量明显的传递失败以及一些极大的事件。这与新皮层中锥体-锥体连接幅度相对狭窄的分布形成了鲜明对比。兴奋性突触后电位幅度随着突触后膜超极化而增加。当平均幅度大幅增加时变异系数变化非常小,这与增加是由于量子幅度变化一致。这些兴奋性突触后电位表现出显著的双脉冲易化。此外,突触前爆发中的第三个和第四个动作电位也诱发了大的反应。这种易化与传递中明显失败比例的降低以及兴奋性突触后电位幅度分布形状的改变有关,两者都表明递质释放概率增加。然而,平均幅度的大幅变化与变异系数倒数平方的类似变化无关。因此,单独来看,这第三个测试的结果可能表明量子幅度随着双脉冲易化而增加。然而,在应用的三个测试中,最后一个测试对模型依赖性最强,并且产生了与其他两个测试结果不一致的结果。因此讨论了一种可能性,即兴奋性突触后电位幅度分布的形状以及变异系数分析未能检测到明显的突触前变化,可能是由于这些突触的释放不太适合简单模型。基于Faber和Korn [Faber和Korn(1991年)《生物物理学杂志》60,1288 - 1294]提出的更复杂的突触释放模型以及Scharfman等人 [Scharfman等人(1990年)《神经科学》37,693 - 707]提出的假设,讨论了本研究产生的两个假设:(i)分支点失败促成了这些连接处的突触激活模式;(ii)突触前锥体放电模式和轴突几何形状都有助于优先激活的突触后神经元类型的选择。(摘要截断于400字)
