Litcius/Paper detail

Context-dependent operation of neural circuits underlies a navigation behavior in <i>Caenorhabditis elegans</i>

Muneki Ikeda, Shunji Nakano, Andrew C. Giles, Linghuan Xu, Wagner Steuer Costa, Alexander Gottschalk, Ikue Mori

2020Proceedings of the National Academy of Sciences54 citationsDOIOpen Access PDF

Abstract

navigates in the thermal environment and migrates toward its cultivation temperature by moving up or down thermal gradients depending not only on absolute temperature but on relative difference between current and previously experienced cultivation temperature. Although previous studies showed that such thermal context-dependent opposing migration is mediated by bias in frequency and direction of reorientation behavior, the complete neural pathways-from sensory to motor neurons-and their circuit logics underlying the opposing behavioral bias remain elusive. By conducting comprehensive cell ablation, high-resolution behavioral analyses, and computational modeling, we identified multiple neural pathways regulating behavioral components important for thermotaxis, and demonstrate that distinct sets of neurons are required for opposing bias of even single behavioral components. Furthermore, our imaging analyses show that the context-dependent operation is evident in sensory neurons, very early in the neural pathway, and manifested by bidirectional responses of a first-layer interneuron AIB under different thermal contexts. Our results suggest that the contextual differences are encoded among sensory neurons and a first-layer interneuron, processed among different downstream neurons, and lead to the flexible execution of context-dependent behavior.

Topics & Concepts

NeuroscienceContext (archaeology)InterneuronCaenorhabditis elegansSensory systemNeuroethologyBiological neural networkBiologySensory cueInhibitory postsynaptic potentialGeneticsPaleontologyGeneGenetics, Aging, and Longevity in Model OrganismsCircadian rhythm and melatoninPhotoreceptor and optogenetics research