Abstract
Selective degeneration of substantia nigra dopaminergic (DA) neurons is a hallmark pathology of familial Parkinson’s disease (PD). While the mechanism of degeneration is elusive, abnormalities in mitochondrial function and turnover are strongly implicated. An Autosomal Recessive-Juvenile Parkinsonism (AR-JP) Drosophila melanogaster model exhibits DA neurodegeneration as well as aberrant mitochondrial dynamics and function. Disruptions in mitophagy have been observed in parkin loss-of-function models, and changes in mitochondrial respiration have been reported in patient fibroblasts. Whether loss of parkin causes selective DA neurodegeneration in vivo as a result of lost or decreased mitophagy is unknown. This study employs the use of fluorescent constructs expressed in Drosophila DA neurons that are functionally homologous to those of the mammalian substantia nigra. We provide evidence that degenerating DA neurons in parkin loss-of-function mutant flies have advanced mitochondrial aging, and that mitochondrial networks are fragmented and contain swollen organelles. We also found that mitophagy initiation is decreased in park (Drosophila parkin/PARK2 ortholog) homozygous mutants, but autophagosome formation is unaffected, and mitochondrial network volumes are decreased. As the fly ages, autophagosome recruitment becomes similar to control, while mitochondria continue to show signs of damage, and climbing deficits persist. Interestingly, aberrant mitochondrial morphology, aging and mitophagy initiation were not observed in DA neurons that do not degenerate. Our results suggest that parkin is important for mitochondrial homeostasis in vulnerable Drosophila DA neurons, and that loss of parkin-mediated mitophagy may play a role in degeneration of relevant DA neurons or motor deficits in this model.
Highlights
A growing body of evidence suggests that parkin, an E3 ubiquitin ligase, plays an important role in mitochondrial integrity
Since mitochondrial network fragmentation and swelling can be a sign of damage, we measured the size and sphericity of protocerebral posterior lateral region 1 (PPL1) and PPM3 DA neuron mitochondria in control flies, park heterozygotes and park homozygotes that express mitoGFP and tyrosine hydroxylase (TH)-GAL4
These apparently swollen mitochondria were few in number relative to fragmented mitochondria; the average mitochondrial volume per PPL1 region was smaller in the park−/− condition on days 10 and 20 (Figures 1A–C)
Summary
A growing body of evidence suggests that parkin, an E3 ubiquitin ligase, plays an important role in mitochondrial integrity. Park homozygous mutants that lack the glutathione S-transferase S1 (GstS1) gene (encoding antioxidant glutathione s-transferase) have more pronounced phenotypes, and GstS1 overexpression prevents DA neuron degeneration (Greene et al, 2005; Whitworth et al, 2005). This suggests that increased reactive oxygen species (ROS) load is a major factor in neurodegeneration caused by the absence of parkin. How the absence of parkin yields increased oxidative stress is unclear, but decreased mitophagy and/or proteasomemediated turnover of mitochondrial proteins may be implicated (Vincow et al, 2013)
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