Postnatal Development Of Dendritic Morphology And Action Potential Shape In Rat Substantia Nigra Dopaminergic Neurons

Estelle M Moubarak, Florian Wernert, Fabien Tell, Jean-Marc Goaillard
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Abstract

Substantia nigra pars compacta (SNc) dopaminergic (DA) neurons are characterized by specific morphological and electrophysiological properties. First, in ~90% of the cases, their axon arises from an axon-bearing dendrite (ABD) at highly variable distances from the soma. Second, they display a highly regular pattern of spontaneous activity (aka pacemaking) and a broad action potential (AP) that faithfully back-propagate through the entire dendritic arbor. In previous studies (Moubarak et al., 2019; Moubarak et al., 2022), we demonstrated that the presence of a high density of sodium current in the ABD and the complexity of this dendrite played a critical role in the robustness of pacemaking and setting the half-width of the AP. In the current study, we investigated the postnatal development of both morphology and AP shape in SNc DA neurons in order to determine when and how the mature electrophysiological phenotype of these neurons was achieved. To do so, we performed electrophysiological recordings of SNc DA neurons at 4 postnatal ages (P3, P7, P14, P21) and fully reconstructed their dendritic and proximal axon morphology. Our results show that several morphological parameters, including the length of the ABD, display abrupt changes between P7 and P14, such that a mature morphology is reached by P14. We then showed that AP shape followed a similar timecourse. Using realistic multicompartment Hodgkin-Huxley modeling, we then demonstrated that the rapid morpho-electrical maturation of SNc DA neurons likely arises from synergistic increases in dendritic length and in somatodendritic sodium channel density.
大鼠黑质下多巴胺能神经元树突形态和动作电位形状的产后发育
黑质下密质(SNc)多巴胺能(DA)神经元具有特殊的形态学和电生理学特性。首先,在约 90% 的病例中,它们的轴突来自轴突树突(ABD),与体节的距离非常不固定。其次,它们显示出高度规则的自发活动模式(又称起搏)和宽泛的动作电位(AP),并忠实地反向传播整个树突轴。在之前的研究中(Moubarak 等人,2019 年;Moubarak 等人,2022 年),我们证明了 ABD 中高密度钠离子电流的存在以及该树突的复杂性对起搏的稳健性和 AP 半宽的设定起着至关重要的作用。在本研究中,我们研究了SNc DA神经元形态学和AP形状的产后发育,以确定这些神经元的成熟电生理表型是何时以及如何实现的。为此,我们对出生后4个年龄段(P3、P7、P14、P21)的SNc DA神经元进行了电生理记录,并完全重建了它们的树突和近端轴突形态。我们的结果表明,包括 ABD 长度在内的几个形态参数在 P7 和 P14 之间发生了突变,因此到 P14 时已达到成熟形态。随后我们还发现,AP 的形状也遵循类似的时间进程。利用逼真的多室霍奇金-赫胥黎模型,我们证明了SNc DA神经元的快速形态电学成熟可能源于树突长度和体支钠通道密度的协同增加。
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