Effects of aqueous extracts of Halimeda incrassata (Ellis) Lamouroux and Bryothamnion triquetrum (S.G.Gmelim) Howe on hydrogen peroxide and methyl mercury-induced oxidative stress in GT1-7 mouse hypothalamic immortalized cells.

The current investigation focuses attention on the neuroprotective and antioxidant properties of aqueous extracts from Halimeda incrassata (Hi) and Bryothamniom triquetrum (Bt) in the mouse immortalized hypothalamic GT1-7 cell line. Under basal oxidative conditions, Hi extract reduces intracellular reactive oxygen species production, as assessed by 2',7'-dichlorofluorescein fluorescence, while Bt extract does not contribute to basal ROS generation. Both extracts, at concentrations higher than 0.20 mg/ml, exert protection against hydrogen peroxide-mediated cell death, although only Hi extract can additionally prevent hydrogen peroxide-induced ROS production. The two seaweed aqueous extracts, at concentrations higher than 0.05 mg/ml, also display protection against neuronal death induced by methyl mercury chloride, as well as against methyl mercury chloride-mediated ROS generation. None of the extracts increase GSH intracellular pools, in basal conditions, after depleting its levels with either hydrogen peroxide or methyl mercury chloride. Some comments on the probable targets of the neuroprotection exerted by these two extracts are included in this paper.

Modification of glutamate-induced oxidative stress by lead: the role of extracellular calcium.

The role of extracellular calcium in glutamate-induced oxidative stress, and the role of glutamatergic neuronal stimulation and oxidative stress in lead neurotoxicity were explored in mouse hypothalamic GT1-7 cells. Glutamate increased the production of reactive oxygen species (ROS) whether or not extracellular calcium was present. Glutamate-induced ROS production was amplified by lead acetate (PbAc), but only in the absence of extracellular calcium. However, PbAc on its own did not increase the production of ROS. A PKC inhibitor (Ro 31-8220) and superoxide dismutase (SOD) abolished the amplification of glutamate-induced production of ROS by PbAc, but did not inhibit ROS production induced by glutamate alone. Both glutamate and PbAc decreased the levels of intracellular glutathione (GSH), and amplified each other's effect on GSH depletion. Glutamate did not decrease cell viability, whereas the cytotoxicity of PbAc was amplified by glutamate. Extracellular calcium, a PKC inhibitor, or SOD did not modify the effects of glutamate, PbAc or their combination on the levels of GSH or cell viability. These data indicate that in GT1-7 cells extracellular calcium is not essential for glutamate-induced ROS production, which is amplified by PbAc, but only without extracellular calcium. The joint cytotoxicity of glutamate and PbAc is mainly induced by PbAc, preferentially through mechanisms other than ROS production.

Lead amplifies glutamate-induced oxidative stress.

Lead markedly amplified L-glutamate-induced oxidative stress, that is, increased L-glutamate-induced production of reactive oxygen species, decreased cellular glutathione, and induced cytotoxicity in human neuroblastoma cells. It was notable that oxidative burst induced by L-glutamate alone was observed only when neuronal glutathione was depleted. A role of protein kinase C (PKC) in glutamate-induced production of reactive oxygen species is likely because it was blocked by a PKC inhibitor. We suggest here that the mechanism whereby lead causes its neurotoxicity may be through the amplification of glutamate-induced oxidative stress, possibly through PKC activation.