Your search keyword '"Masanori Kawabata"' showing total 4 results

1. Ipsilateral-Dominant Control of Limb Movements in Rodent Posterior Parietal Cortex

Author

Yoshikazu Isomura, Kazuto Kobayashi, Shigeki Kato, Yutaka Sakai, Masanori Kawabata, Junichi Yoshida, Satoshi Nonomura, Alain Ríos, Shogo Soma, Fusao Kato, Yukari Takahashi, and Yae K. Sugimura

Subjects

Male, 0301 basic medicine, Patch-Clamp Techniques, genetic structures, Movement, Channelrhodopsin, Posterior parietal cortex, Biology, Optogenetics, behavioral disciplines and activities, Functional Laterality, Lateralization of brain function, Premotor cortex, 03 medical and health sciences, 0302 clinical medicine, Channelrhodopsins, Parietal Lobe, Forelimb, medicine, Animals, gamma-Aminobutyric Acid, Research Articles, Electromyography, General Neuroscience, Motor Cortex, Rats, body regions, 030104 developmental biology, medicine.anatomical_structure, nervous system, Conditioning, Operant, Rats, Transgenic, Primary motor cortex, Neuroscience, Psychomotor Performance, psychological phenomena and processes, 030217 neurology & neurosurgery, Motor cortex

Abstract

It is well known that the posterior parietal cortex (PPC) and frontal motor cortices in primates preferentially control voluntary movements of contralateral limbs. The PPC of rats has been defined based on patterns of thalamic and cortical connectivity. The anatomical characteristics of this area suggest that it may be homologous to the PPC of primates. However, its functional roles in voluntary forelimb movements have not been well understood, particularly in the lateralization of motor limb representation; that is, the limb-specific activity representations for right and left forelimb movements. We examined functional spike activity of the PPC and two motor cortices, the primary motor cortex (M1) and the secondary motor cortex (M2), when head-fixed male rats performed right or left unilateral movements. Unlike primates, PPC neurons in rodents were found to preferentially represent ipsilateral forelimb movements, in contrast to the contralateral preference of M1 and M2 neurons. Consistent with these observations, optogenetic activation of PPC and motor cortices, respectively, evoked ipsilaterally and contralaterally biased forelimb movements. Finally, we examined the effects of optogenetic manipulation on task performance. PPC or M1 inhibition by optogenetic GABA release shifted the behavioral limb preference contralaterally or ipsilaterally, respectively. In addition, weak optogenetic PPC activation, which was insufficient to evoke motor responses by itself, shifted the preference ipsilaterally; although similar M1 activation showed no effects on task performance. These paradoxical observations suggest that the PPC plays evolutionarily different roles in forelimb control between primates and rodents.SIGNIFICANCE STATEMENTIn rodents, the primary and secondary motor cortices (M1 and M2, respectively) are involved in voluntary movements with contralateral preference. However, it remains unclear whether and how the posterior parietal cortex (PPC) participates in controlling multiple limb movements. We recorded functional activity from these areas using a behavioral task to monitor movements of the right and left forelimbs separately. PPC neurons preferentially represented ipsilateral forelimb movements and optogenetic PPC activation evoked ipsilaterally biased forelimb movements. Optogenetic PPC inhibition via GABA release shifted the behavioral limb preference contralaterally during task performance, whereas weak optogenetic PPC activation, which was insufficient to evoke motor responses by itself, shifted the preference ipsilaterally. Our findings suggest rodent PPC contributes to ipsilaterally biased motor response and/or planning.

Published

2018

2. Area-specific Modulation of Functional Cortical Activity During Block-based and Trial-based Proactive Inhibition

Author

Masanori Kawabata, Minoru Kimura, Yoshikazu Isomura, Ko Yamanaka, Alain Ríos, Shogo Soma, Satoshi Nonomura, Akiko Saiki, Junichi Yoshida, and Yutaka Sakai

Subjects

Cerebral Cortex, Neurons, 0301 basic medicine, Brain Mapping, General Neuroscience, Action Potentials, Context (language use), Motor Activity, Task (project management), 03 medical and health sciences, Proactive Inhibition, 030104 developmental biology, 0302 clinical medicine, Behavioral response, Block (telecommunications), Animals, Premovement neuronal activity, Rats, Long-Evans, Psychology, Microelectrodes, Neuroscience, 030217 neurology & neurosurgery

Abstract

Animals can suppress their behavioral response in advance according to changes in environmental context (proactive inhibition: delaying the start of response), a process in which several cortical areas may participate. However, it remains unclear how this process is adaptively regulated according to contextual changes on different timescales. To address the issue, we used an improved stop-signal task paradigm to behaviorally and electrophysiologically characterize the temporal aspect of proactive inhibition in head-fixed rats. In the task, they must respond to a go cue as quickly as possible (go trial), but did not have to respond if a stop cue followed the go cue (stop trial). The task alternated between a block of only go trials (G-block) and a block of go-and-stop trials (GS-block). We observed block-based and trial-based proactive inhibition (emerging in GS-block and after stop trial, respectively) by behaviorally evaluating the delay in reaction time in correct go trials depending on contextual changes on different timescales. We electrophysiologically analyzed task-related neuronal activity in the primary and secondary motor, posterior parietal, and orbitofrontal cortices (M1, M2, PPC, and OFC, respectively). Under block-based proactive inhibition, spike activity of cue-preferring OFC neurons was attenuated continuously, while M1 and M2 activity was enhanced during motor preparation. Subsequently, M1 activity was attenuated during motor decision/execution. Under trial-based proactive inhibition, the OFC activity was continuously enhanced, and PPC and M1 activity was also enhanced shortly during motor decision/execution. These results suggest that different cortical mechanisms underlie the two types of proactive inhibition in rodents.

Published

2018

3. Inhibitory neurons exhibit high controlling ability in the cortical microconnectome

Author

Masanori Shimono, Felix Goetze, Tatsuya Akutsu, Ritsuki Nomura, Motoki Kajiwara, Masanori Kawabata, and Yoshikazu Isomura

Subjects

0301 basic medicine, Electrical recording, Physiology, Entropy, Information Theory, Action Potentials, Diagnostic Radiology, Mice, 0302 clinical medicine, Animal Cells, Medicine and Health Sciences, Centrality, Biology (General), Cerebral Cortex, Neurons, Motor Neurons, Ecology, Physics, Radiology and Imaging, Magnetic Resonance Imaging, Electrophysiology, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, Excitatory postsynaptic potential, Connectome, Thermodynamics, Female, Selection method, Cellular Types, Information Entropy, Network Analysis, Research Article, Computer and Information Sciences, Neural Networks, Imaging Techniques, QH301-705.5, Neurophysiology, Biology, Research and Analysis Methods, Inhibitory postsynaptic potential, Membrane Potential, 03 medical and health sciences, Cellular and Molecular Neuroscience, Diagnostic Medicine, Genetics, Animals, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Biology and Life Sciences, Cell Biology, Cortex (botany), Mice, Inbred C57BL, 030104 developmental biology, Inhibitory Postsynaptic Potentials, nervous system, Cellular Neuroscience, Neuroscience, 030217 neurology & neurosurgery, Immunostaining

Abstract

The brain is a network system in which excitatory and inhibitory neurons keep activity balanced in the highly non-random connectivity pattern of the microconnectome. It is well known that the relative percentage of inhibitory neurons is much smaller than excitatory neurons in the cortex. So, in general, how inhibitory neurons can keep the balance with the surrounding excitatory neurons is an important question. There is much accumulated knowledge about this fundamental question. This study quantitatively evaluated the relatively higher functional contribution of inhibitory neurons in terms of not only properties of individual neurons, such as firing rate, but also in terms of topological mechanisms and controlling ability on other excitatory neurons. We combined simultaneous electrical recording (~2.5 hours) of ~1000 neurons in vitro, and quantitative evaluation of neuronal interactions including excitatory-inhibitory categorization. This study accurately defined recording brain anatomical targets, such as brain regions and cortical layers, by inter-referring MRI and immunostaining recordings. The interaction networks enabled us to quantify topological influence of individual neurons, in terms of controlling ability to other neurons. Especially, the result indicated that highly influential inhibitory neurons show higher controlling ability of other neurons than excitatory neurons, and are relatively often distributed in deeper layers of the cortex. Furthermore, the neurons having high controlling ability are more effectively limited in number than central nodes of k-cores, and these neurons also participate in more clustered motifs. In summary, this study suggested that the high controlling ability of inhibitory neurons is a key mechanism to keep balance with a large number of other excitatory neurons beyond simple higher firing rate. Application of the selection method of limited important neurons would be also applicable for the ability to effectively and selectively stimulate E/I imbalanced disease states., 脳が安定して活動を続けられるメカニズムの一端を解明 --新皮質で、抑制性細胞は他細胞を制御しやすいトポロジカルな位置取りをする--. 京都大学プレスリリース. 2021-04-09.

Published

2021

4. In Vivo Spiking Dynamics of Intra- and Extratelencephalic Projection Neurons in Rat Motor Cortex

Author

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