Some consequences of SOD1 and G93A mutant expression in neuroblastomas. Implications for amyotrophic lateral sclerosis (ALS).

Some familial ALS (fALS) are caused by mutations in the Cu,Zn-superoxide dismutase enzyme (SOD1). It was thought that the mutated enzymes would have impaired SOD activity, but this has not been corroborated so far. Presently, it is more accepted that the mutated enzymes acquire a new toxic function. What this new toxic function is and how it relates to the degeneration of motor neurons remains debatable. Here, we compared human neuroblastoma cells transfected with fALS mutant G93A (SH-SY5YG93A) or wild-type SOD1 (SH-SY5YWT) with parent cells (SH-SY5Y) in regard to growth, viability, basal oxidant production, SOD and peroxidase activities, and SOD forms. Transfected cells presented increased growth rate and basal oxidant production. SH-SY5YWT and SH-SY5YG93A cells in early culture stage showed SOD expression and activity consistent with the expected two-fold increase; SH-SY5YWT homogenates showed increased peroxidase activity. After four weeks, SH-SY5YG93A maintained SOD1 expression levels but peroxidase and dismutase activities were lower. SOD1 expression increased the levels of altered SOD1 forms such as the reduced enzyme, disulfide multimers and detergent-insoluble forms, particularly in SH-SY5YG93A cells. Among the insoluble forms a covalent SOD dimer was identified. These altered SOD forms are probably responsible for proteasome activation and endoplasmatic reticulum stress response verified in transfected cells. In conclusion, SOD1 over-expression was sufficient to increase intracellular immature and oligomerized SOD1 forms and basal oxidation and the G93A mutation enhanced these processes. (AU)