Division of System Neurophysiology, National Institute for Physiological Sciences, Okazaki 444-8585, Japan.
Department of Physiological Sciences, SOKENDAI (The Graduate University for Advanced Studies), Okazaki 444-8585, Japan.
J Neurosci. 2021 Jun 23;41(25):5502-5510. doi: 10.1523/JNEUROSCI.1330-20.2021. Epub 2021 May 17.
The substantia nigra pars reticulata (SNr) is the output station of the basal ganglia and receives cortical inputs by way of the following three basal ganglia pathways: the cortico-subthalamo (STN)-SNr hyperdirect, the cortico-striato-SNr direct, and the cortico-striato-external pallido-STN-SNr indirect pathways. Compared with the classical direct and indirect pathways via the striatum, the functions of the hyperdirect pathway remain to be fully elucidated. Here we used a photodynamic technique to selectively eliminate the cortico-STN projection in male mice and observed neuronal activity and motor behaviors in awake conditions. After cortico-STN elimination, cortically evoked early excitation in the SNr was diminished, while the cortically evoked inhibition and late excitation, which are delivered through the direct and indirect pathways, respectively, were unchanged. In addition, locomotor activity was significantly increased after bilateral cortico-STN elimination, and apomorphine-induced ipsilateral rotations were observed after unilateral cortico-STN elimination, suggesting that cortical activity was increased. These results are compatible with the notion that the cortico-STN-SNr hyperdirect pathway quickly conveys cortical excitation to the output station of the basal ganglia, resets or suppresses the cortical activity related to ongoing movements, and prepares for the forthcoming movement. The basal ganglia play a pivotal role in the control of voluntary movements, and their malfunctions lead to movement disorders, such as Parkinson's disease and dystonia. Understanding their functions is important to find better treatments for such diseases. Here we used a photodynamic technique to selectively eliminate the projection from the motor cortex to the subthalamic nucleus, the input station of the basal ganglia, and found greatly reduced early excitatory signals from the cortex to the output station of the basal ganglia and motor hyperactivity. These results suggest that the neuronal signals through the cortico-subthalamic hyperdirect pathway reset or suppress ongoing movements and that blockade of this pathway may be beneficial for Parkinson's disease, which is characterized by oversuppression of movements.
黑质网状部(SNr)是基底神经节的输出站,通过以下三种基底神经节通路接收皮质输入:皮质-丘脑底核(STN)-SNr 超直接通路、皮质-纹状体-SNr 直接通路和皮质-纹状体-苍白球外侧部-STN-SNr 间接通路。与经典的通过纹状体的直接和间接通路相比,超直接通路的功能仍有待充分阐明。在这里,我们使用光动力技术选择性地消除雄性小鼠的皮质-STN 投射,并在清醒状态下观察神经元活动和运动行为。皮质-STN 消除后,SNr 中的皮质诱发早期兴奋减弱,而通过直接和间接通路传递的皮质诱发抑制和晚期兴奋则保持不变。此外,双侧皮质-STN 消除后运动活性显著增加,单侧皮质-STN 消除后观察到阿朴吗啡诱导的同侧旋转,表明皮质活动增加。这些结果与皮质-STN-SNr 超直接通路快速将皮质兴奋传递到基底神经节的输出站、重置或抑制与进行中的运动相关的皮质活动并为即将到来的运动做好准备的观点一致。基底神经节在控制自主运动中起着关键作用,它们的功能障碍导致运动障碍,如帕金森病和肌张力障碍。了解它们的功能对于找到治疗这些疾病的更好方法很重要。在这里,我们使用光动力技术选择性地消除来自运动皮层到基底神经节输入站的丘脑底核的投射,发现来自皮层到基底神经节输出站的早期兴奋信号大大减少,并且运动过度活跃。这些结果表明,通过皮质-丘脑底核超直接通路的神经元信号重置或抑制进行中的运动,阻断该通路可能对以运动过度抑制为特征的帕金森病有益。