Tracey J. Parker scite author profile

Loss-of-function mutations of the parkin gene, which encodes a ubiquitin-protein ligase, are a common cause of autosomal recessive juvenile parkinsonism (ARJP). Previous work has led to the identification of a number of Parkin substrates that implicate specific pathways in ARJP pathogenesis, including endoplasmic reticulum (ER) stress and cell cycle activation. To test the involvement of previously implicated pathways, as well as to identify novel pathways in ARJP pathogenesis, we are using genetic and genomic approaches to study Parkin function in the fruit fly Drosophila melanogaster. In previous work, we demonstrated that Drosophila parkin null mutants exhibit mitochondrial pathology and flight muscle degeneration. To further explore the mechanisms responsible for pathology in parkin mutants, we analyzed the transcriptional alterations that occur during muscle degeneration and performed a genetic screen for parkin modifiers. Results of these studies indicate that oxidative stress response components are induced in parkin mutants and that loss-of-function mutations in oxidative stress components enhance the parkin mutant phenotypes. Genes involved in the innate immune response are also induced in parkin mutants. In contrast, our studies did not reveal evidence for cell cycle or ER stress pathway induction in parkin mutants. These results suggest that oxidative stress and/or inflammation may play a fundamental role in the etiology of ARJP.

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Mutations of a Drosophila NPC1 Gene Confer Sterol and Ecdysone Metabolic Defects

Fluegel

Parker

Pallanck

2006

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The molecular mechanisms by which dietary cholesterol is trafficked within cells are poorly understood. Previous work indicates that the NPC1 family of proteins plays an important role in this process, although the precise functions performed by this protein family remain elusive. We have taken a genetic approach to further explore the NPC1 family in the fruit fly Drosophila melanogaster. The Drosophila genome encodes two NPC1 homologs, designated NPC1a and NPC1b, that exhibit 42% and 35% identity to the human NPC1 protein, respectively. Here we describe the results of mutational analysis of the NPC1a gene. The NPC1a gene is ubiquitously expressed, and a null allele of NPC1a confers early larval lethality. The recessive lethal phenotype of NPC1a mutants can be partially rescued on a diet of high cholesterol or one that includes the insect steroid hormone 20-hydroxyecdysone. We also find that expression of NPC1a in the ring gland is sufficient to rescue the lethality associated with the loss of NPC1a and that cholesterol levels in NPC1a mutant larvae are unchanged relative to controls. Our results suggest that NPC1a promotes efficient intracellular trafficking of sterols in many Drosophila tissues including the ring gland where sterols must be delivered to sites of ecdysone synthesis. S TEROLS are critical in eukaryotic biology as structural components of all membranes and as precursors for the synthesis of the large eukaryotic family of steroid hormones (Mouritsen and Zuckermann 2004;Payne and Hales 2004;Becher and McIlhinney 2005). While sterols are essential due to the important biological functions they serve, an overabundance of the primary mammalian sterol, cholesterol, is toxic and contributes to a variety of prevalent diseases including heart disease and stroke (Choy et al. 2004;Saini et al. 2004). Accumulating evidence also suggests that alterations in cholesterol homeostasis may contribute to neurodegenerative disorders such as Alzheimer's disease, although the mechanisms by which alterations in cholesterol metabolism affect neuronal integrity remain unclear (Burns and Duff 2002;Reiss et al. 2004;Wellington 2004).The importance of sterols in eukaryotic biology and disease pathogenesis has stimulated intensive investigation of cholesterol homeostasis in vertebrates. This body of work has clarified many features of cholesterol metabolism, including its de novo synthesis from acetate in the endoplasmic reticulum (ER) (Bloch 1965;Lynen 1966), its packaging into and transport within lipoprotein particles (Oncley 1954;Fredrickson 1957), and the receptor-mediated uptake of these particles by cells (Brown and Goldstein 1986). While these advances have fostered the development of treatment strategies that affect the etiology of hypercholesterolemia, this disorder remains a major source of morbidity, and our knowledge of cholesterol metabolism and the health consequences associated with altered cholesterol homeostasis is far from complete. In particular, the molecular mechanisms by which cholesterol is ab...

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Tracey J. Parker

Genetic and genomic studies of Drosophila parkin mutants implicate oxidative stress and innate immune responses in pathogenesis

Mutations of a Drosophila NPC1 Gene Confer Sterol and Ecdysone Metabolic Defects

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