Mechanisms underlying the recruitment of inhibitory interneurons in fictive swimming in developing Xenopus laevis tadpoles
Abstract
Developing spinal circuits generate patterned motor outputs while many neurons with high membrane resistances are still maturing. In the spinal cord of hatchling frog tadpoles of unknown sex, we found that the firing reliability in swimming of inhibitory interneurons with commissural and ipsilateral ascending axons was negatively correlated with their cellular membrane resistance. Further analyses showed that neurons with higher resistances had outward rectifying properties, low firing thresholds and little delay in firing evoked by current injections. Input synaptic currents these neurons received during swimming, either compoundˎ unitary current amplitudes or unitary synaptic current numbers, were scaled with their membrane resistances, but their own synaptic outputs were correlated with membrane resistances of their postsynaptic partners. Analyses of neuronal dendritic and axonal lengths and their activities in swimming and cellular input resistances did not reveal a clear correlation pattern. Incorporating these electrical and synaptic properties in a computer swimming model produced robust swimming rhythms whereas randomising input synaptic strengths led to the breakdown of swimming rhythms, coupled with less synchronised spiking in the inhibitory interneurons. We conclude that the recruitment of these developing interneurons in swimming can be predicted by cellular input resistances, but the order is opposite to the motor-strength based recruitment scheme depicted by Henneman’s size principle. This form of recruitment/integration order in development before the emergence of refined motor control is progressive potentially with neuronal acquisition of mature electrical and synaptic properties, among which the scaling of input synaptic strengths with cellular input resistance plays a critical role.
Citation
Ferrario , A , Saccomanno , V , Zhang , H-Y , Borisyuk , R & Li , W-C 2023 , ' Mechanisms underlying the recruitment of inhibitory interneurons in fictive swimming in developing Xenopus laevis tadpoles ' , The Journal of Neuroscience , vol. 43 , no. 8 , JN-RM-0520-22 , pp. 1387-1404 . https://doi.org/10.1523/JNEUROSCI.0520-22.2022
Publication
The Journal of Neuroscience
Status
Peer reviewed
ISSN
0270-6474Type
Journal article
Description
Funding: Authors thank BBSRC for funding this research (BB/L000814/1 to R.B.; BB/T003146 to W.L.).Collections
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