Cortico-thalamic communication for action coordination in a skilled motor sequence.

Yi Li, Xu An, Patrick J Mulcahey, Yongjun Qian, X Hermione Xu, Shengli Zhao, Hemanth Mohan, Shreyas M Suryanarayana, Ludovica Bachschmid-Romano, Nicolas Brunel, Ian Q Whishaw, Z Josh Huang
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Abstract

The coordination of forelimb and orofacial movements to compose an ethological reach-to-consume behavior likely involves neural communication across brain regions. Leveraging wide-field imaging and photo-inhibition to survey across the cortex, we identified a cortical network and a high-order motor area (MOs-c), which coordinate action progression in a mouse reach-and-withdraw-to-drink (RWD) behavior. Electrophysiology and photo-inhibition across multiple projection neuron types within the MOs-c revealed differential contributions of pyramidal tract and corticothalamic (CTMOs) output channels to action progression and hand-mouth coordination. Notably, CTMOs display sustained firing throughout RWD sequence and selectively enhance RWD-relevant activity in postsynaptic thalamus neurons, which also contribute to action coordination. CTMOs receive converging monosynaptic inputs from forelimb and orofacial sensorimotor areas and are reciprocally connected to thalamic neurons, which project back to the cortical network. Therefore, motor cortex corticothalamic channel may selectively amplify the thalamic integration of cortical and subcortical sensorimotor streams to coordinate a skilled motor sequence.

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在熟练的运动行为中表达序列顺序的皮层网络和投射神经元类型。
熟练的运动行为需要有秩序的协调多个组成运动与感官线索,以实现目标,但潜在的脑回路机制尚不清楚。在这里,我们展示了目标引导的小鼠伸手抓水(RGD)涉及一组前肢和口腔动作的排序和协调。多种谷氨酸能投射神经元(PN)类型的全皮质活动成像揭示了一个网络,涉及次级运动皮层(MOs),前肢初级运动皮层和躯体感觉皮层,跟踪RGD运动。光抑制突出了MOs在协调RGD运动中的作用。在MOs中,群体神经轨迹跟踪RGD进展和跨组成运动的单个神经元活动。值得注意的是,脑外肌、锥体束和皮质丘脑PN活动与动作协调相关,表现出不同的神经动力学轨迹,并对运动协调有不同的贡献。我们的研究结果描绘了一个皮层网络和关键区域,PN类型和其中的神经动力学,阐明了熟练行为的序列顺序和协调。
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