Discovering sparse control strategies in C. elegans

TL;DR

This paper introduces a systematic perturbation protocol to identify sparse control mechanisms in C. elegans neural circuits, revealing that a few key neurons dominate collective neural behavior and control.

Contribution

The study develops a novel perturbation-based approach to characterize neural-behavioral mappings, highlighting sparse control strategies in C. elegans neural networks.

Findings

Collective neural statistics are most sensitive to a few principal modes.

Eigenvalues decay as a power law, indicating hierarchical structure.

Control is dominated by a few pivotal neurons.

Abstract

Biological circuits such as neural or gene regulation networks use internal states to map sensory input to an adaptive repertoire of behavior. Characterizing this mapping is a major challenge for systems biology, and though experiments that probe internal states are developing rapidly, organismal complexity presents a fundamental obstacle given the many possible ways internal states could map to behavior. Using C. elegans as an example, we propose a protocol for systematic perturbation of neural states that limits experimental complexity but still characterizes collective aspects of the neural-behavioral map. We consider experimentally motivated small perturbations -- ones that are most likely to preserve natural dynamics and are closer to internal control mechanisms -- to neural states and their impact on collective neural behavior. Then, we connect such perturbations to the local information geometry of collective statistics, which can be fully characterized using pairwise perturbations. Applying the protocol to a minimal model of C. elegans neural activity, we find that collective neural statistics are most sensitive to a few principal perturbative modes. Dominant eigenvalues decay initially as a power law, unveiling a hierarchy that arises from variation in individual neural activity and pairwise interactions. Highest-ranking modes tend to be dominated by a few, "pivotal" neurons that account for most of the system's sensitivity, suggesting a sparse mechanism for control of collective behavior.