Research Achievements

March 22, 2016  PRESS RELEASE

From Feeling to Reacting: A Two-way Street between Temperature Sensing, Brain Activity

Nagoya University researchers reveal how perceived external information is converted into a succession of neural activities that are crucial for appropriate navigation in an environment.

press released on Mar.22, 2016


Caption: A tracking microscope was used to study both the movement and AFD neuron response of C. elegans to thermal stimuli.


Nagoya, Japan - When the surrounding environment makes us uncomfortable, we are inclined to move to a more agreeable one.


Studies have shown that animals do the same. They organize sequences of movements to migrate to preferred environments. Understanding how environmental information is converted to sensory information in the brain is vital for a deeper understanding of animal behavior and human perception. However, not much is known about this process.


The movement of Caenorhabditis elegans--or roundworm--in response to temperature changes has been extensively studied. Deletion of a pair of sensory neurons, known as AFD, severely hindered the worms' ability to react to an increase or decrease in temperature, indicating that AFD plays a crucial role in such responses.


Based on this knowledge, researchers from Nagoya University set out to investigate exactly how AFD converts the sequences of sensory inputs that are triggered by changing temperatures into neural activity.


"We used simultaneous calcium imaging and a tracking microscope for freely moving animals to characterize thermal response in C. elegans," first author of the study, Yuki Tsukada, explains. "The worms were raised in different temperatures, but were all subjected to the same temperature range of between 17°C and 23°C during the test."


The researchers found that the responses in the worms were similar regardless of the conditions they were raised in. Interestingly, the adaptation and detection of an input signal was around 20 seconds, a timescale comparable to that of behavioral movements, such as turning. Using a mathematical model, the researchers were able to reconstruct the AFD activity from the observed temperature input and, conversely, the thermal environment from the observed AFD activity and the migration pattern of the worms. This verifies that the thermotaxis of C. elegans is an appropriate model for exploring the relationship between the environment and the response of the organism.


"This modeling approach with the simple nervous system of C. elegans may allow us to conduct behavioral studies at different scales, from single cell organisms like bacteria to mammals," senior author of the study, Ikue Mori, says. "Such studies are extremely valuable in helping to understand the basis for animal behavior, including that of humans, in an ever-changing environment."




The paper "Reconstruction of Spatial Thermal Gradient Encoded in Thermosensory Neuron AFD in Caenorhabditis elegans" appeared 2 March 2016 in The Journal of Neuroscience, with doi: 10.1523/JNEUROSCI.2837-15.2016.




Authors: Assistant Prof. Yuki Tsukada, Mr. Tomoyasu Shimowada(a graduate), Dr. Ohnishi Noriyuki, and Prof. Ikue Mori, Graduate School of Science, Nagoya University, with their research groups at Kyoto Univesity, and Konan University



Related Links:

Ikue Mori's Lab., Group of Molecular Neurobiology, Department of Molecular Neurobiology, Graduate School of Science, Nagoya University


Nagoya Research Center for Brain & Neural Circuit


Media Coverage:




Science Daily

The Medical News

Science Newsline, Biology



Funding: This work was supported by Japan Society for the Promotion of Science Research Funds Grants 24700302 and 23115507, Core Research for Evolutional Science and Technology/Japan Science and Technology Agency, Strategic Research Program for Brain Sciences by Ministry of Education, Culture, Sports, Science, and Technology (MEXT) and Japan Agency for Medical Research and Development (AMED), and the Platform Project for Supporting in Drug Discovery and Life Science Research by MEXT and AMED. 



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