The control structure of the nematode Caenorhabditis elegans: neuro-sensory integration and propioceptive feedback

TL;DR

This paper presents a biophysical model of C. elegans that integrates muscle, neural circuitry, and proprioception to reproduce complex locomotive behaviors like omega turns, offering insights into neural control mechanisms.

Contribution

It introduces the first integrated neuromechanical model demonstrating how connectomic control and proprioceptive feedback generate complex behaviors in C. elegans.

Findings

Model reproduces omega turns and complex waveforms

Weighted proprioceptive suppression is key to behavior

Biologically plausible neuromodulation mechanisms proposed

Abstract

We develop a biophysically realistic model of the nematode C. elegans that includes: (i) its muscle structure and activation, (ii) key connectomic activation circuitry, and (iii) a weighted and time-dynamic proprioception. In combination, we show that these model components can reproduce the complex waveforms exhibited in C. elegans locomotive behaviors, chiefly omega turns. This is achieved via weighted, time-dependent suppression of the proprioceptive signal. Though speculative, such dynamics are biologically plausible due to the presence of neuromodulators which have recently been experimentally implicated in the escape response, which includes an omega turn. This is the first integrated neuromechanical model to reveal a mechanism capable of generating the complex waveforms observed in the behavior of C. elegans, thus contributing to a mathematical framework for understanding how control decisions can be executed at the connectome level in order to produce the full repertoire of observed behaviors.