Novel extracellular vesicle release pathway facilitated by toxic superoxide dismutase 1 oligomers

Amyotrophic lateral sclerosis (ALS) is a devastating neurodegenerative disease resulting in paralysis and death within three to five years. Mutations in over forty different proteins have been linked to ALS, leading to controversy whether ALS is one disease or many diseases with a similar phenotype. Mutations in Cu,Zn superoxide dismutase 1 (SOD1) are only found in 2-3% of ALS cases, yet misfolded SOD1 is found in both sporadic (sALS) and familial (fALS) patients. Yet, mutations in TDP-43 or FUS increase the level of misfolded SOD1 on extracellular vesicles (EVs). Additionally, small EVs isolated from ALS patient samples caused cell death of wild type motor neurons and myotubules. The toxicity and protein alterations of ALS EVs have led to the theory that EVs are responsible for the spread of ALS. We hypothesize that previously-identified toxic trimeric SOD1 is spreading on EVs in ALS and altering the spread of other ALS-related proteins, linking them to a common mechanism. To test our hypothesis, we isolate EVs from motor neuron-like cells expressing trimer stabilizing mutations and perform a sandwich enzyme-linked immunoassay (ELISA) (CD9 capture antibody) to quantify whether misfolded SOD1 and 17 other ALS-related proteins increase or decrease on EVs with trimer stabilization. We identify which EV release pathway is being affected by trimeric SOD1 utilizing endocytosis and exocytosis inhibitors, and determine if any specific EV-related proteins are altered with trimer stabilization. We establish that VAPB, VCP, and Stathmin-2 increase on EVs with trimer stabilization. The common pathway between SOD1 and three other ALS-associated proteins is affected by multiple pathways, including the Caveolae endocytosis pathway, suggesting a novel hybrid pathway of EV release present in ALS.