Abstract
Animals are able to reach a desired state in an environment by controlling various behavioral patterns. Identification of the behavioral strategy used for this control is important for understanding animals’ decision-making and is fundamental to dissect information processing done by the nervous system. However, methods for quantifying such behavioral strategies have not been fully established. In this study, we developed an inverse reinforcement-learning (IRL) framework to identify an animal’s behavioral strategy from behavioral time-series data. We applied this framework to C. elegans thermotactic behavior; after cultivation at a constant temperature with or without food, fed worms prefer, while starved worms avoid the cultivation temperature on a thermal gradient. Our IRL approach revealed that the fed worms used both the absolute temperature and its temporal derivative and that their behavior involved two strategies: directed migration (DM) and isothermal migration (IM). With DM, worms efficiently reached specific temperatures, which explains their thermotactic behavior when fed. With IM, worms moved along a constant temperature, which reflects isothermal tracking, well-observed in previous studies. In contrast to fed animals, starved worms escaped the cultivation temperature using only the absolute, but not the temporal derivative of temperature. We also investigated the neural basis underlying these strategies, by applying our method to thermosensory neuron-deficient worms. Thus, our IRL-based approach is useful in identifying animal strategies from behavioral time-series data and could be applied to a wide range of behavioral studies, including decision-making, in other organisms.
Highlights
IntroductionA set of sequential decisions necessary for organizing appropriate actions in response to environmental stimuli, to ensure their survival and reproduction
Animals develop behavioral strategies, a set of sequential decisions necessary for organizing appropriate actions in response to environmental stimuli, to ensure their survival and reproduction
By further applying the inverse reinforcement-learning (IRL) to thermosensory neuron-impaired worms, we found that the so-called “AFD” neurons are fundamental for the directed migration (DM) exhibited by the fed worms
Summary
A set of sequential decisions necessary for organizing appropriate actions in response to environmental stimuli, to ensure their survival and reproduction. Such strategies lead animals to their preferred states and provide them with effective solutions to overcome difficulties in a given environment. Understanding behavioral strategies of biological organisms is important from biological, ethological, and engineering point of views. A number of studies have recorded the behavioral sequences reflecting the overall animal strategies. Mechanistic descriptions are different from phenomenological descriptions of recorded behaviors [2], and there is no well-established method that can objectively identify behavioral strategies, a mechanistic component of behavior. To derive behavioral strategies from quantitative time-series behavioral data, we propose a new computational framework based on the concept of reinforcement learning (RL)
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