Different modulation of common motor information in rat primary and secondary motor cortices.

Akiko Saiki,Yoko Fujiwara-Tsukamoto,Yoshikazu Isomura,Yutaka Sakai,Toshikazu Samura,Rie Kimura,Kelvin E. Jones

doi:10.1371/journal.pone.0098662

Akiko Saiki, Yoko Fujiwara-Tsukamoto + Show 5 more

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https://doi.org/10.1371/journal.pone.0098662

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Abstract

Rodents have primary and secondary motor cortices that are involved in the execution of voluntary movements via their direct and parallel projections to the spinal cord. However, it is unclear whether the rodent secondary motor cortex has any motor function distinct from the primary motor cortex to properly control voluntary movements. In the present study, we quantitatively examined neuronal activity in the caudal forelimb area (CFA) of the primary motor cortex and rostral forelimb area (RFA) of the secondary motor cortex in head-fixed rats performing forelimb movements (pushing, holding, and pulling a lever). We found virtually no major differences between CFA and RFA neurons, regardless of neuron subtypes, not only in their basal spiking properties but also in the time-course, amplitude, and direction preference of their functional activation for simple forelimb movements. However, the RFA neurons, as compared with the CFA neurons, showed obviously a greater susceptibility of their functional activation to an alteration in a behavioral situation, a 'rewarding' response that leads to reward or a 'consummatory' response that follows reward water, which might be accompanied by some internal adaptations without affecting the motor outputs. Our results suggest that, although the CFA and RFA neurons commonly process fundamental motor information to properly control forelimb movements, the RFA neurons may be functionally differentiated to integrate motor information with internal state information for an adaptation to goal-directed behaviors.

Highlights

Voluntary movements are controlled by the frontal part of the cerebral cortex in mammals
The ongoing spike rates of caudal forelimb area (CFA)-RS neurons were only slightly but significantly higher than those of rostral forelimb area (RFA)-RS neurons (Fig. 2A; CFA-RS 2.163.5 Hz, n = 1,214; RFA-RS 1.762.6 Hz, n = 861; t-test p, 0.001, which may be an effect of a large sample size), and there was no difference between CFA-FS and RFA-FS neurons (CFAFS 8.3612.0 Hz, n = 136; RFA-FS 7.069.9 Hz, n = 58; t-test p. 0.4)
The coefficient of variation (CV) of inter-spike interval (ISI) was slightly smaller in CFA-RS than in RFA-RS neurons (Fig. 2B,C; KS test p,0.001), and there was no difference between CFA-FS and RFA-FS neurons (p.0.9)

Summary

Introduction

Voluntary movements are controlled by the frontal part of the cerebral cortex in mammals. Researchers have identified two distinct motor cortices in rodents, the primary and secondary motor cortices (M1 and M2, according to a standard brain atlas [13]). These motor cortices, mapped somatotopically by microstimulation [14,15,16,17,18,19,20,21,22,23,24], have reciprocal connections [25,26,27] as well as direct and parallel projections to the spinal cord [25,28]. The motor cortices are activated during skilled voluntary movements with forelimbs [23,29,30], but it is not clear whether the rodent secondary motor cortex has differentiated motor function as seen in the primate

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