Abstract
Behaviour is a sensitive and integrative readout of nervous system function and therefore an attractive measure for assessing the effects of mutation or drug treatment on animals. Video data provide a rich but high-dimensional representation of behaviour, and so the first step of analysis is often some form of tracking and feature extraction to reduce dimensionality while maintaining relevant information. Modern machine-learning methods are powerful but notoriously difficult to interpret, while handcrafted features are interpretable but do not always perform as well. Here, we report a new set of handcrafted features to compactly quantify Caenorhabditis elegans behaviour. The features are designed to be interpretable but to capture as much of the phenotypic differences between worms as possible. We show that the full feature set is more powerful than a previously defined feature set in classifying mutant strains. We then use a combination of automated and manual feature selection to define a core set of interpretable features that still provides sufficient power to detect behavioural differences between mutant strains and the wild-type. Finally, we apply the new features to detect time-resolved behavioural differences in a series of optogenetic experiments targeting different neural subsets.This article is part of a discussion meeting issue ‘Connectome to behaviour: modelling C. elegans at cellular resolution’.
Highlights
Measuring phenotypes is essential in most areas of biology, but there are no rules that determine which aspects of a phenotype to focus on
We found that two categories of features could be eliminated entirely with little effect on classification accuracy: those derived from the distribution of eigenworm amplitudes and those based on dorsoventral asymmetries
A critical step in any phenotyping project is choosing the right representation for the problem at hand
Summary
Measuring phenotypes is essential in most areas of biology, but there are no rules that determine which aspects of a phenotype to focus on. This has led to calls for more exhaustive characterizations of phenotype under the umbrella term phenomics [1,2]. The success of deep learning approaches demonstrates the usefulness of automatically learned features on image analysis problems [3]. The tasks solved in deep learning have well-defined objectives such as minimizing cross-entropy loss. Our objective is to find a middle ground using a range of interpretable features optimized to quantify Caenorhabditis elegans morphology and behaviour
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