1. In Vivo Spiking Dynamics of Intra- and Extratelencephalic Projection Neurons in Rat Motor Cortex
- Author
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Junichi Yoshida, Yoshikazu Isomura, Minoru Kimura, Yutaka Sakai, Kazuto Kobayashi, Shogo Soma, Masanori Kawabata, Hiromu Yawo, Ryoji Fukabori, and Akiko Saiki
- Subjects
Male ,Telencephalon ,0301 basic medicine ,Cognitive Neuroscience ,Thalamus ,Action Potentials ,Striatum ,Biology ,Optogenetics ,Statistics, Nonparametric ,03 medical and health sciences ,Cellular and Molecular Neuroscience ,0302 clinical medicine ,Channelrhodopsins ,In vivo ,Neural Pathways ,medicine ,Animals ,Neurons ,Membrane potential ,Motor Cortex ,Motor control ,Rats ,Luminescent Proteins ,030104 developmental biology ,medicine.anatomical_structure ,Nonlinear Dynamics ,nervous system ,Cerebral cortex ,Rats, Transgenic ,Neuroscience ,030217 neurology & neurosurgery ,Motor cortex - Abstract
In motor cortex, 2 types of deep layer pyramidal cells send their axons to other areas: intratelencephalic (IT)-type neurons specifically project bilaterally to the cerebral cortex and striatum, whereas neurons of the extratelencephalic (ET)-type, termed conventionally pyramidal tract-type, project ipsilaterally to the thalamus and other areas. Although they have totally different synaptic and membrane potential properties in vitro, little is known about the differences between them in ongoing spiking dynamics in vivo. We identified IT-type and ET-type neurons, as well as fast-spiking-type interneurons, using novel multineuronal analysis based on optogenetically evoked spike collision along their axons in behaving/resting rats expressing channelrhodopsin-2 (Multi-Linc method). We found "postspike suppression" (~100 ms) as a characteristic of ET-type neurons in spike auto-correlograms, and it remained constant independent of behavioral conditions in functionally different ET-type neurons. Postspike suppression followed even solitary spikes, and spike bursts significantly extended its duration. We also observed relatively strong spike synchrony in pairs containing IT-type neurons. Thus, spiking dynamics in IT-type and ET-type neurons may be optimized differently for precise and coordinated motor control.
- Published
- 2017
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