Methyl Mercury Stimulates Protein32P Phospholabeling in Cerebellar Granule Cell Culture

Abstract

Cultures of cerebellar granule neurons have been utilized to examine morphological and biochemical consequences of methyl mercury (MeHg). Exposure to MeHg for 24 h was found to exert toxic effects at concentrations below 1 μM characterized by neuron degeneration and neuritic varicosities. Dose-response and time course profiles for cell death were established using the ^5lCr release assay, which revealed that 1 μM MeHg produced 15% cell death at 24 h, progressing to 50% at 48 h. Labeling of cultures with [³²P]orthophosphate following 24-h exposure to 1 μM MeHg disclosed abnormalities in both protein and lipid phosphorylation. After 24-h exposure to 5 μM MeHg, phospholabeling of protein and lipid increased 174 and 128%, respectively, compared with controls. This stimulation of phosphorylation appeared to be neuron specific since cultures enriched in cerebellar glial cells and devoid of granule neurons displayed dose-dependent inhibition of total phosphorylation. Measurement of ³²P labeling of ATP using a cyclic AMP-dependent protein kinase assay in conjunction with the firefly luciferase assay for ATP indicated no significant change in either total ATP levels or [³²P]ATP specific activity at 1 or 4 h as a function of [MeHg]. Studies measuring ³²P-phosphoprotein turnover indicated that MeHg had no effect on intracellular protein phosphatase activity. We conclude that one of the manifestations associated with in vitro cerebellar granule cell neurotoxicity is an abnormality in protein phosphorylation that is independent of [³²P]ATP specific activity and protein phosphatase activity.