TY - JOUR
T1 - Dynamic encoding of perception, memory, and movement in a C. elegans chemotaxis circuit
AU - Luo, Linjiao
AU - Wen, Quan
AU - Ren, Jing
AU - Hendricks, Michael
AU - Gershow, Marc
AU - Qin, Yuqi
AU - Greenwood, Joel
AU - Soucy, Edward R.
AU - Klein, Mason
AU - Smith-Parker, Heidi K.
AU - Calvo, Ana C.
AU - Colón-Ramos, Daniel A.
AU - Samuel, Aravinthan D.T.
AU - Zhang, Yun
N1 - Funding Information:
We thank the Caenorhabditis Genetics Center (funded by National Institute of Health Office of Research Infrastructure Programs P40 OD010440) for strains, Oliver Hobert (Columbia University, New York) for the lsy-6(ot71) mutant and transgenic line expressing otls204 transgene, Junchao Yu for making the linear salt gradient plates, and Yuichi Iino for sharing data prior to publication. D.A.C-.R. is funded by NIH (R01NS076558). A.D.T.S. is supported by the NSF (PHY-0957185) and NIH (8DP1GM105383-05 and 1P01GM103770). Y.Z. is funded by The John Merck Fund and NIH (R01DC009852, P01GM103770). L.L. is funded by NSFC (11304153).
PY - 2014/6/4
Y1 - 2014/6/4
N2 - Brain circuits endow behavioral flexibility. Here, we study circuits encoding flexible chemotaxis in C. elegans,where the animal navigates up or down NaCl gradients (positive or negative chemotaxis) to reach the salt concentration of previous growth (the set point). The ASER sensory neuron mediates positive and negative chemotaxis by regulating the frequency and direction of reorientation movements in response to salt gradients. Both salt gradients and set point memory are encoded in ASER temporal activity patterns. Distinct temporal activity patterns in interneurons immediately downstream of ASER encode chemotactic movement decisions. Different interneuron combinations regulate positive versus negative chemotaxis. We conclude that sensorimotor pathways are segregated immediately after the primary sensory neuron in the chemotaxis circuit, and sensory representation is rapidly transformed to motor representation at the first interneuron layer. Our study reveals compact encoding of perception, memory, and locomotion in an experience-dependent navigational behavior in C. elegans.
AB - Brain circuits endow behavioral flexibility. Here, we study circuits encoding flexible chemotaxis in C. elegans,where the animal navigates up or down NaCl gradients (positive or negative chemotaxis) to reach the salt concentration of previous growth (the set point). The ASER sensory neuron mediates positive and negative chemotaxis by regulating the frequency and direction of reorientation movements in response to salt gradients. Both salt gradients and set point memory are encoded in ASER temporal activity patterns. Distinct temporal activity patterns in interneurons immediately downstream of ASER encode chemotactic movement decisions. Different interneuron combinations regulate positive versus negative chemotaxis. We conclude that sensorimotor pathways are segregated immediately after the primary sensory neuron in the chemotaxis circuit, and sensory representation is rapidly transformed to motor representation at the first interneuron layer. Our study reveals compact encoding of perception, memory, and locomotion in an experience-dependent navigational behavior in C. elegans.
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U2 - 10.1016/j.neuron.2014.05.010
DO - 10.1016/j.neuron.2014.05.010
M3 - Article
C2 - 24908490
AN - SCOPUS:84901787674
SN - 0896-6273
VL - 82
SP - 1115
EP - 1128
JO - Neuron
JF - Neuron
IS - 5
ER -