Elucidation of a Glial Copper Homeostasis Pathway Regulated by the Caenorhabditis elegans Gene swip-10 with Implications for Systemic Metabolism and Neurodegenerative Disease

Using the Caenorhabditis elegans as a model we have employed forward genetic screens to uncover several novel genetic contributors to dopamine (DA) signaling(1). Follow-up characterization of some of these novel contributors have been detailed in published work from our lab(2), while follow-up studies on other pathways are still underway. Moreover, using the powerful Million Mutation Project library, we have uncovered an important link between primary cilium formation and the regulation of the DA transporter dat-1(3). The focus of the body of work detailed in this manuscript is on a glial expressed gene, swip-10, uncovered from our original genetic screen(1, 4, 5). Unlike the other pathways uncovered from our genetic screening, swip-10 does not affect DA signaling via DAT-1 regulation, instead, loss of swip-10 produces excess DA signaling in a glutamate-signaling-dependent manner to cause swimming-induced paralysis (Swip)(4) as well as premature DA neuron degeneration(5). Specifically, the primary aim here was to uncover the molecular pathway by which swip-10 supports these phenotypes.