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相互抑制性电路通过不同的机制运作,对扰动和调制的稳健性也不同。

Reciprocally inhibitory circuits operating with distinct mechanisms are differently robust to perturbation and modulation.

机构信息

Volen Center and Department of Biology, Brandeis University, Waltham, United States.

Biology Department, University of Oregon, Eugene, United States.

出版信息

Elife. 2022 Feb 1;11:e74363. doi: 10.7554/eLife.74363.

DOI:10.7554/eLife.74363
PMID:35103594
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8884723/
Abstract

Reciprocal inhibition is a building block in many sensory and motor circuits. We studied the features that underly robustness in reciprocally inhibitory two neuron circuits. We used the dynamic clamp to create reciprocally inhibitory circuits from pharmacologically isolated neurons of the crab stomatogastric ganglion by injecting artificial graded synaptic (I) and hyperpolarization-activated inward (I) currents. There is a continuum of mechanisms in circuits that generate antiphase oscillations, with 'release' and 'escape' mechanisms at the extremes, and mixed mode oscillations between these extremes. In release, the active neuron primarily controls the off/on transitions. In escape, the inhibited neuron controls the transitions. We characterized the robustness of escape and release circuits to alterations in circuit parameters, temperature, and neuromodulation. We found that escape circuits rely on tight correlations between synaptic and H conductances to generate bursting but are resilient to temperature increase. Release circuits are robust to variations in synaptic and H conductances but fragile to temperature increase. The modulatory current (I) restores oscillations in release circuits but has little effect in escape circuits. Perturbations can alter the balance of escape and release mechanisms and can create mixed mode oscillations. We conclude that the same perturbation can have dramatically different effects depending on the circuits' mechanism of operation that may not be observable from basal circuit activity.

摘要

相互抑制是许多感觉和运动回路的基础。我们研究了在相互抑制的双神经元回路中产生稳健性的特征。我们使用动态钳位技术,通过注射人工分级突触(I)和超极化激活内向(I)电流,从蟹胃神经节的药理学分离神经元中创建相互抑制的电路。在产生反相振荡的电路中有一个连续体,在极端情况下有“释放”和“逃逸”机制,在这些极端之间有混合模式振荡。在释放中,活性神经元主要控制关/开转换。在逃逸中,抑制神经元控制转换。我们描述了逃逸和释放电路对电路参数、温度和神经调制变化的稳健性。我们发现,逃逸电路依赖于突触和 H 电导之间的紧密相关性来产生爆发,但对温度升高有很强的抵抗力。释放电路对突触和 H 电导的变化具有很强的鲁棒性,但对温度升高很脆弱。调制电流(I)恢复释放电路的振荡,但对逃逸电路几乎没有影响。扰动可以改变逃逸和释放机制之间的平衡,并可以产生混合模式振荡。我们的结论是,相同的扰动可能会根据电路的操作机制产生截然不同的效果,而这些效果可能无法从基本电路活动中观察到。

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