Asymmetric and transient properties of reciprocal activity of antagonists during the paw-shake response in the cat

Asymmetric and transient properties of reciprocal activity of antagonists during the paw-shake response in the cat

Mutually inhibitory populations of neurons, half-center oscillators (HCOs), are commonly involved in the dynamics of the central pattern generators (CPGs) driving various rhythmic movements. Previously, we developed a multifunctional, multistable symmetric HCO model which produced slow locomotor-lik...

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Bibliographic Details
Main Authors: Cymbalyuk, G.S (Author), Klishko, A.N (Author), Parker, J.R (Author), Prilutsky, B.I (Author)
Format: Article
Language:English
Published: Public Library of Science 2021
Subjects:
action potential
Action Potentials
adult
animal
animal cell
animal experiment
Animals
Article
biological model
biology
cat
Cats
central pattern generator
Central Pattern Generators
Computational Biology
controlled study
electromyography
Electromyography
extensor muscle
female
Female
flexor muscle
hindlimb
Hindlimb
hindlimb muscle
in vivo study
innervation
linear regression analysis
locomotion
Locomotion
Models, Neurological
motor evoked potential
nonhuman
paw
paw shake response
physiology
prediction
simulation
Wilcoxon signed ranks test
Online Access:View Fulltext in Publisher
Description
Summary:Mutually inhibitory populations of neurons, half-center oscillators (HCOs), are commonly involved in the dynamics of the central pattern generators (CPGs) driving various rhythmic movements. Previously, we developed a multifunctional, multistable symmetric HCO model which produced slow locomotor-like and fast paw-shake-like activity patterns. Here, we describe asymmetric features of paw-shake responses in a symmetric HCO model and test these predictions experimentally. We considered bursting properties of the two model half-centers during transient paw-shake-like responses to short perturbations during locomotor-like activity. We found that when a current pulse was applied during the spiking phase of one half-center, let’s call it #1, the consecutive burst durations (BDs) of that half-center increased throughout the paw-shake response, while BDs of the other half-center, let’s call it #2, only changed slightly. In contrast, the consecutive interburst intervals (IBIs) of half-center #1 changed little, while IBIs of half-center #2 increased. We demonstrated that this asymmetry between the half-centers depends on the phase of the locomotor-like rhythm at which the perturbation was applied. We suggest that the fast transient response reflects functional asymmetries of slow processes that underly the locomotor-like pattern; e.g., asymmetric levels of inactivation across the two half-centers for a slowly inactivating inward current. We compared model results with those of in-vivo paw-shake responses evoked in locomoting cats and found similar asymmetries. Electromyographic (EMG) BDs of anterior hindlimb muscles with flexor-related activity increased in consecutive paw-shake cycles, while BD of posterior muscles with extensor-related activity did not change, and vice versa for IBIs of anterior flexors and posterior extensors. We conclude that EMG activity patterns during paw-shaking are consistent with the proposed mechanism producing transient paw-shake-like bursting patterns found in our multistable HCO model. We suggest that the described asymmetry of paw-shaking responses could implicate a multifunctional CPG controlling both locomotion and paw-shaking. © 2021 Parker et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
ISBN:1553734X (ISSN)
DOI:10.1371/journal.pcbi.1009677

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