Mechanisms and Functions of Brain- Body- Environment Interactions in C. elegans

Our research explores how the brain organizes and controls behavior by studying the tiny roundworm C. elegans. Despite its small size, this worm has a complex but small nervous system that allows it to perform sophisticated behaviors. By using advanced imaging technology, we can record the activity of nearly every neuron in its brain while it moves freely. Our main scientific objectives of this project are to decipher the neuronal computations underlying sensory processing, decision making and behavior generation. Our main hypotheses are that these processes are intimately linked and coupled to the ongoing explorative motor behaviors of the animal.

In the preceding funding period, we have developed various microscopy approaches and computational pipelines that enable us to record brain activity of worms freely exploring sensory environments. We performed our first study to establish a baseline mapping between spontaneous behaviors and neuronal network activity in the absence of sensory inputs. One of our key discoveries is that the worm’s brain does not control movement through isolated neurons but instead through a coordinated, large-scale pattern of activity. These activity patterns form what we call a "neural manifold"—a kind of latent structure in brain activity that organizes the worm’s major movements into longer-lasting action sequences. This means that movement is not dictated by single neurons sending commands but emerges from the way many neurons work together.
We also found that this system follows a hierarchy, meaning larger-scale brain states shape more fine-tuned movements. This finding supports a long-standing idea in biology—that behavior is organized in hierarchical manner—but provides direct evidence for how it happens at the level of neuronal circuits.

Our study challenges the idea that high-level decisions, like predicting movement outcomes, are controlled by specific brain cells. Instead, these processes may emerge from the interaction of many neurons working together. Understanding these principles in C. elegans helps us uncover general rules about how brains—including the ones of bigger animals—organize behavior. In the future, this research could help us better understand behavior and decision-making in animals, including humans.