Abstract
To fully understand the mechanisms giving rise to behavior, we need to be able to precisely measure it. When coupled with large behavioral data sets, unsupervised clustering methods offer the potential of unbiased mapping of behavioral spaces. However, unsupervised techniques to map behavioral spaces are in their infancy, and there have been few systematic considerations of all the methodological options. We compared the performance of seven distinct mapping methods in clustering a wavelet-transformed data set consisting of the x- and y-positions of the six legs of individual flies. Legs were automatically tracked by small pieces of fluorescent dye, while the fly was tethered and walking on an air-suspended ball. We find that there is considerable variation in the performance of these mapping methods, and that better performance is attained when clustering is done in higher dimensional spaces (which are otherwise less preferable because they are hard to visualize). High dimensionality means that some algorithms, including the non-parametric watershed cluster assignment algorithm, cannot be used. We developed an alternative watershed algorithm which can be used in high-dimensional spaces when a probability density estimate can be computed directly. With these tools in hand, we examined the behavioral space of fly leg postural dynamics and locomotion. We find a striking division of behavior into modes involving the fore legs and modes involving the hind legs, with few direct transitions between them. By computing behavioral clusters using the data from all flies simultaneously, we show that this division appears to be common to all flies. We also identify individual-to-individual differences in behavior and behavioral transitions. Lastly, we suggest a computational pipeline that can achieve satisfactory levels of performance without the taxing computational demands of a systematic combinatorial approach.
Highlights
Understanding how nervous systems integrate information from the environment, past experience and internal states to produce useful behaviors is a key goal of behavioral neuroscience
We refer to our unsupervised clustering methods collectively as mapping methods, and they all share a common structure
For example the method in Berman et al (2014) is tSNE2-watershed mapping as it uses t-distributed stochastic neighbor embedding (tSNE) to reduce the data to two dimensions and a watershed transform for clustering
Summary
Understanding how nervous systems integrate information from the environment, past experience and internal states to produce useful behaviors is a key goal of behavioral neuroscience. Large quantities of neural activity data have been acquired simultaneously with behavioral data in larval zebrafish Danio rerio (Dunn et al 2016), the nematode Caenorhabditis elegans (Nguyen et al 2016, Venkatachalam et al 2016), and the fruit fly Drosophila melanogaster The copyright holder for this preprint It is made available under. These organisms are the focus of past (White et al 1986) or ongoing (Takemura et al 2013) connectomic efforts to map the synapse-level connectivity between all neurons in the brain. While analyses of neural activity and connectivity have been quantitative and richly multidimensional since their inception, the quantification of behavior is comparatively depauperate. For a full accounting of the neural basis of behavior, rich, detailed and unbiased descriptions are needed
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