Abstract
Alterations in mitochondrial dynamics, including their intracellular trafficking, are common early manifestations of neuronal degeneration. However, current methodologies used to study mitochondrial trafficking events rely on parameters that are primarily altered in later stages of neurodegeneration. Our objective was to establish a reliable applied statistical analysis to detect early alterations in neuronal mitochondrial trafficking. We propose a novel quantitative analysis of mitochondria trajectories based on innovative movement descriptors, including straightness, efficiency, anisotropy, and kurtosis. We evaluated time- and dose-dependent alterations in trajectory descriptors using biological data from differentiated SH-SY5Y cells treated with the mitochondrial toxicants 6-hydroxydopamine and rotenone. MitoTracker Red CMXRos-labelled mitochondria movement was analyzed by total internal reflection fluorescence microscopy followed by computational modelling to describe the process. Based on the aforementioned trajectory descriptors, this innovative analysis of mitochondria trajectories provides insights into mitochondrial movement characteristics and can be a consistent and sensitive method to detect alterations in mitochondrial trafficking occurring in the earliest time points of neurodegeneration.
Highlights
Neurons are polarized post-mitotic cells encompassing three structurally, functionally, and metabolically distinct domains, i.e. the cell body, dendrites with numerous branches, and the axon
Our results present a new quantitative paradigm of mitochondrial dynamics in health and diseased neuronal cells
The improvement of microscopy methods together with the development of automated particle tracking algorithms with certain level of accuracy allowed for the analysis of mitochondrial motility
Summary
Neurons are polarized post-mitotic cells encompassing three structurally, functionally, and metabolically distinct domains, i.e. the cell body, dendrites with numerous branches, and the axon. As individual neuronal domains feature specific needs for the level of Ca2+ as well as metabolites, their homeostasis is maintained by corresponding number of mitochondria [1, 9, 10]. The movement from the cell body to cellular extremities (anterograde transport) is mediated by the kinesin-1 family proteins, while dynein proteins are responsible for the opposite movement (retrograde transport) Both types of transport are dependent on ATP hydrolysis [11, 12]
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