Context-dependent ATP7 Interactions with Parkinson's Disease-associated Genes Modulate Copper Homeostasis Phenotypes

Copper is an essential micronutrient required by enzymes that catalyze oxygen-dependent reactions, but toxic in excess. Mutations in the ATP7A and ATP7B copper transporters cause neuropsychiatric symptoms and neurodegeneration by mechanisms that remain to be elucidated. We previously reported that the ATP7A biochemical interactome is enriched in Parkinsons disease (PD) and neurodegeneration associated proteins, yet the functional outcomes of these interactions are unknown. Using Drosophila, we tested genetic interactions between ATP7 mutants that alter copper levels and a subset of these PD and neurodegeneration causative genes and found sex differences with some candidate genes enhancing ATP7 deleterious phenotypes in both sexes, while others were sex specific. Most notably, we found that Lrrk2 (Lrrk), the most commonly mutated gene in familial forms of PD, protects against ATP7 dysfunction in epidermal epithelial cells with a stronger effect in males than females. However, in dopaminergic neurons Lrrk plays a role in intracellular copper induced toxicity in females but not males, supporting context dependent interactions between ATP7A and PD-associated genes to protect against disruptions in copper homeostasis. Summary StatementWe performed a genetic interaction screen to explore the relationship between copper homeostasis and Parkinsons disease and other neurodegeneration associated genes.