Bidirectional thermotaxis in Caenorhabditis elegans is mediated by distinct sensorimotor strategies driven by the AFD thermosensory neurons

Luo, Linjiao; Cook, Nathan; Venkatachalam, Vivek; Martinez-Velazquez, Luis; Zhang, Xiaodong; Calvo, Ana; Hawk, Josh; MacInnis, Bronwyn; Frank, Michelle; Ng, Jia Hong Ray; Klein, Mason; Gershow, Marc; Hammarlund, Marc; Goodman, Miriam; Colon-Ramos, Daniel; Zhang, Yun; Samuel, Aravinthan D T

Bidirectional thermotaxis in Caenorhabditis elegans is mediated by distinct sensorimotor strategies driven by the AFD thermosensory neurons

Linjiao Luo, Nathan Cook, Vivek Venkatachalam, Luis Martinez-Velazquez, Xiaodong Zhang, Ana Calvo, Josh Hawk, Bronwyn MacInnis, Michelle Frank, Jia Hong Ray Ng, Mason Klein, Marc Gershow, Marc Hammarlund, Miriam Goodman, Daniel Colon-Ramos, Yun Zhang and Aravinthan D T Samuel

Working Paper from Harvard University OpenScholar

Abstract: The nematode Caenorhabditis elegans navigates toward a pre- ferred temperature setpoint (Ts) determined by long-term temper- ature exposure. During thermotaxis, the worm migrates down temperature gradients at temperatures above Ts (negative ther- motaxis) and performs isothermal tracking near Ts. Under some conditions, the worm migrates up temperature gradients below Ts (positive thermotaxis). Here, we analyze positive and negative thermotaxis toward Ts to study the role of specific neurons that have been proposed to be involved in thermotaxis using genetic ablation, behavioral tracking, and calcium imaging. We find differ- ences in the strategies for positive and negative thermotaxis. Neg- ative thermotaxis is achieved through biasing the frequency of reorientation maneuvers (turns and reversal turns) and biasing the direction of reorientation maneuvers toward colder temper- atures. Positive thermotaxis, in contrast, biases only the direction of reorientation maneuvers toward warmer temperatures. We find that the AFD thermosensory neuron drives both positive and negative thermotaxis. The AIY interneuron, which is postsyn- aptic to AFD, may mediate the switch from negative to positive thermotaxis below Ts. We propose that multiple thermotactic behaviors, each defined by a distinct set of sensorimotor trans- formations, emanate from the AFD thermosensory neurons. AFD learns and stores the memory of preferred temperatures, detects temperature gradients, and drives the appropriate thermotactic behavior in each temperature regime by the flexible use of downstream circuits.

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