Fully automated leg tracking of Drosophila neurodegeneration models reveals distinct conserved movement signatures.

Lakshmi Narasimhan Govindarajan,Li Cheng,Camilo Libedinsky,Daiqin Li,Lin Gu,Graham K Taylor,Sherry Shiying Aw,James Charles Stewart,Joses Wei Hao Ho,Boon Hui Wong,Eng-King Tan,Malvika Katarya,Shuang Wu,Kah Junn Tan,Adam Claridge-Chang

doi:10.1371/journal.pbio.3000346

Abstract

Some neurodegenerative diseases, like Parkinsons Disease (PD) and Spinocerebellar ataxia 3 (SCA3), are associated with distinct, altered gait and tremor movements that are reflective of the underlying disease etiology. Drosophila melanogaster models of neurodegeneration have illuminated our understanding of the molecular mechanisms of disease. However, it is unknown whether specific gait and tremor dysfunctions also occur in fly disease mutants. To answer this question, we developed a machine-learning image-analysis program, Feature Learning-based LImb segmentation and Tracking (FLLIT), that automatically tracks leg claw positions of freely moving flies recorded on high-speed video, producing a series of gait measurements. Notably, unlike other machine-learning methods, FLLIT generates its own training sets and does not require user-annotated images for learning. Using FLLIT, we carried out high-throughput and high-resolution analysis of gait and tremor features in Drosophila neurodegeneration mutants for the first time. We found that fly models of PD and SCA3 exhibited markedly different walking gait and tremor signatures, which recapitulated characteristics of the respective human diseases. Selective expression of mutant SCA3 in dopaminergic neurons led to a gait signature that more closely resembled those of PD flies. This suggests that the behavioral phenotype depends on the neurons affected rather than the specific nature of the mutation. Different mutations produced tremors in distinct leg pairs, indicating that different motor circuits were affected. Using this approach, fly models can be used to dissect the neurogenetic mechanisms that underlie movement disorders.

Highlights

Walking requires coordination of the central and peripheral nervous systems and the musculoskeletal system
Feature Learning-based LImb segmentation and Tracking (FLLIT) automatically performs a series of image processing steps (Fig 1Bi) on a subset of the images from the video of interest: background subtraction [27], medial axis skeletonization, and edge extraction, to identify only high-confidence positive and negative pixel examples for learning. (The grey regions, while part of the region of interest obtained after background subtraction, are not of high enough confidence to be determined as being either leg or non-leg and are not used for learning)
Our study describes the development of FLLIT, a fully automated machine-learning method for tracking leg claw positions of freely moving flies and its use to study gait and tremors in fly models of Parkinsons disease (PD) and Spinocerebellar ataxia Type 3 (SCA3)

Summary

Introduction

Walking requires coordination of the central and peripheral nervous systems and the musculoskeletal system. Our understanding of movement disorders can benefit greatly from study in a genetic animal model with a relatively small and manipulatable nervous system. An automated background subtraction step was built into FLLIT. This automated background subtraction algorithm requires the subject animal to move at least a distance of 1.5 body lengths; videos were made with this criteria in mind. All data shown were generated using the FLLIT-derived automated background subtraction. In most cases, this procedure performed well; in some cases, or if the subject animal does not traverse at least 1.5 body lengths, loading of a background can substantially improve segmentation and tracking (S2D Fig). A manual background can be made either by taking a separate image of the background alone or by constructing one via image processing

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Results

Conclusion