Sensory experience controls dendritic structure and behavior by distinct pathways involving degenerins

Sensory experience controls dendritic structure and behavior by distinct pathways involving degenerins

Dendrites are crucial for receiving information into neurons. Sensory experience affects the structure of these tree-like neurites, which, it is assumed, modifies neuronal function, yet the evidence is scarce, and the mechanisms are unknown. To study whether sensory experience affects dendritic morp...

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Bibliographic Details
Main Authors: Sharon Inberg, Yael Iosilevskii, Alba Calatayud-Sanchez, Hagar Setty, Meital Oren-Suissa, Michael Krieg, Benjamin Podbilewicz
Format: Article
Language:English
Published: eLife Sciences Publications Ltd 2025-01-01
Series:eLife
Subjects:
dendritic plasticity
Caenorhabditis elegans
epithelial sodium channels degenerins
PVD neuron
dendritic arborization
sensory experience
Online Access:https://elifesciences.org/articles/83973
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Summary:Dendrites are crucial for receiving information into neurons. Sensory experience affects the structure of these tree-like neurites, which, it is assumed, modifies neuronal function, yet the evidence is scarce, and the mechanisms are unknown. To study whether sensory experience affects dendritic morphology, we use the Caenorhabditis elegans’ arborized nociceptor PVD neurons, under natural mechanical stimulation induced by physical contacts between individuals. We found that mechanosensory signals induced by conspecifics and by glass beads affect the dendritic structure of the PVD. Moreover, developmentally isolated animals show a decrease in their ability to respond to harsh touch. The structural and behavioral plasticity following sensory deprivation are functionally independent of each other and are mediated by an array of evolutionarily conserved mechanosensory amiloride-sensitive epithelial sodium channels (degenerins). Calcium imaging of the PVD neurons in a micromechanical device revealed that controlled mechanical stimulation of the body wall produces similar calcium dynamics in both isolated and crowded animals. Our genetic results, supported by optogenetic, behavioral, and pharmacological evidence, suggest an activity-dependent homeostatic mechanism for dendritic structural plasticity, that in parallel controls escape response to noxious mechanosensory stimuli.
ISSN:2050-084X

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