调制输入的联合 LTP 和 LTD 控制初级感觉输入的神经元处理。
Combined LTP and LTD of modulatory inputs controls neuronal processing of primary sensory inputs.
机构信息
Department of Mathematics, University of Pittsburgh, Pittsburgh, Pennsylvania 15260, USA.
出版信息
J Neurosci. 2011 Jul 20;31(29):10579-92. doi: 10.1523/JNEUROSCI.1592-11.2011.
Abstract
A hallmark of brain organization is the integration of primary and modulatory pathways by principal neurons. However, the pathway interactions that shape primary input processing remain unknown. We investigated this problem in mouse dorsal cochlear nucleus (DCN) where principal cells integrate primary, auditory nerve input with modulatory, parallel fiber input. Using a combined experimental and computational approach, we show that combined LTP and LTD of parallel fiber inputs to DCN principal cells and interneurons, respectively, broaden the time window within which synaptic inputs summate. Enhanced summation depolarizes the resting membrane potential and thus lowers the response threshold to auditory nerve inputs. Combined LTP and LTD, by preserving the variance of membrane potential fluctuations and the membrane time constant, fixes response gain and spike latency as threshold is lowered. Our data reveal a novel mechanism mediating adaptive and concomitant homeostatic regulation of distinct features of neuronal processing of sensory inputs.
摘要
大脑组织的一个标志是主要神经元整合初级和调节途径。然而,塑造初级输入处理的途径相互作用仍然未知。我们在小鼠耳蜗背核 (DCN) 中研究了这个问题,其中主要细胞将初级、听神经输入与调节、平行纤维输入整合在一起。使用组合的实验和计算方法,我们表明,DCN 主要细胞和中间神经元的平行纤维输入的联合 LTP 和 LTD 分别拓宽了突触输入总和的时间窗口。增强的总和使静息膜电位去极化,从而降低了对听神经输入的反应阈值。通过保持膜电位波动的方差和膜时间常数,联合 LTP 和 LTD 将反应增益和尖峰潜伏期固定在阈值降低时。我们的数据揭示了一种新的机制,介导了对感觉输入的神经元处理的不同特征的适应性和伴随的同型调节。
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