| Literature DB >> 30392795 |
Alexandra Oranth1, Christian Schultheis2, Oleg Tolstenkov1, Karen Erbguth1, Jatin Nagpal3, David Hain1, Martin Brauner1, Sebastian Wabnig1, Wagner Steuer Costa1, Rebecca D McWhirter4, Sven Zels5, Sierra Palumbos4, David M Miller Iii4, Isabel Beets5, Alexander Gottschalk6.
Abstract
Finding food and remaining at a food source are crucial survival strategies. We show how neural circuits and signaling molecules regulate these food-related behaviors in Caenorhabditis elegans. In the absence of food, AVK interneurons release FLP-1 neuropeptides that inhibit motorneurons to regulate body posture and velocity, thereby promoting dispersal. Conversely, AVK photoinhibition promoted dwelling behavior. We identified FLP-1 receptors required for these effects in distinct motoneurons. The DVA interneuron antagonizes signaling from AVK by releasing cholecystokinin-like neuropeptides that potentiate cholinergic neurons, in response to dopaminergic neurons that sense food. Dopamine also acts directly on AVK via an inhibitory dopamine receptor. Both AVK and DVA couple to head motoneurons by electrical and chemical synapses to orchestrate either dispersal or dwelling behavior, thus integrating environmental and proprioceptive signals. Dopaminergic regulation of food-related behavior, via similar neuropeptides, may be conserved in mammals.Entities:
Keywords: Ca2+ imaging; FMRFamide neuropeptides; behavioral quantification; behavioral switching; channelrhodopsin-2; halorhodopsin; optogenetics; premotor navigational regulation; sensory integration; video tracking
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Year: 2018 PMID: 30392795 DOI: 10.1016/j.neuron.2018.10.024
Source DB: PubMed Journal: Neuron ISSN: 0896-6273 Impact factor: 17.173