Faculty of Life Sciences, University of Manchester, Manchester M13 9PT, United Kingdom.
J Neurosci. 2013 Jun 5;33(23):9644-54. doi: 10.1523/JNEUROSCI.0921-13.2013.
The ability to regulate intrinsic membrane excitability, to maintain consistency of action potential firing, is critical for stable neural circuit activity. Without such mechanisms, Hebbian-based synaptic plasticity could push circuits toward activity saturation or, alternatively, quiescence. Although now well documented, the underlying molecular components of these homeostatic mechanisms remain poorly understood. Recent work in the fruit fly, Drosophila melanogaster, has identified Pumilio (Pum), a translational repressor, as an essential component of one such mechanism. In response to changing synaptic excitation, Pum regulates the translation of the voltage-gated sodium conductance, leading to a concomitant adjustment in action potential firing. Although similar homeostatic mechanisms are operational in mammalian neurons, it is unknown whether Pum is similarly involved. In this study, we report that Pum2 is indeed central to the homeostatic mechanism regulating membrane excitability in rat visual cortical pyramidal neurons. Using RNA interference, we observed that loss of Pum2 leads to increased sodium current (I(Na)) and action potential firing, mimicking the response by these neurons to being deprived of synaptic depolarization. In contrast, increased synaptic depolarization results in increased Pum2 expression and subsequent reduction in INa and membrane excitability. We further show that Pum2 is able to directly bind the predominant voltage-gated sodium channel transcript (NaV1.6) expressed in these neurons and, through doing so, regulates translation of this key determinant of membrane excitability. Together, our results show that Pum2 forms part of a homeostatic mechanism that matches membrane excitability to synaptic depolarization in mammalian neurons.
调节内在膜兴奋性、维持动作电位发放一致性的能力对于稳定的神经回路活动至关重要。如果没有这些机制,基于赫布的突触可塑性可能会使电路趋于饱和或静止。尽管这些内稳态机制的潜在分子成分现在已经得到很好的证明,但仍知之甚少。果蝇,Drosophila melanogaster 的最新研究已经确定了 Pumilio(Pum),一种翻译抑制剂,作为其中一种机制的必需组成部分。响应不断变化的突触兴奋,Pum 调节电压门控钠电流,从而相应地调整动作电位发放。尽管在哺乳动物神经元中存在类似的内稳态机制,但尚不清楚 Pum 是否同样参与其中。在这项研究中,我们报告说 Pum2 确实是调节大鼠视觉皮层锥体神经元膜兴奋性的内稳态机制的核心。通过 RNA 干扰,我们观察到 Pum2 的缺失会导致钠电流(I(Na))和动作电位发放增加,模拟这些神经元对失去突触去极化的反应。相比之下,增加突触去极化会导致 Pum2 表达增加,进而导致 INa 和膜兴奋性降低。我们进一步表明,Pum2 能够直接结合这些神经元中表达的主要电压门控钠通道转录本(NaV1.6),并通过这种方式调节该关键决定膜兴奋性的翻译。总之,我们的结果表明 Pum2 是一种内稳态机制的一部分,该机制使哺乳动物神经元的膜兴奋性与突触去极化相匹配。