Iron-induced lipid peroxidation and inhibition of dopamine synthesis in striatum synaptosomes

Crude striatum synaptosomes (P₂ fraction) from Fisher 344 female rats were incubated in the presence of ADP-chelated Fe³⁺ (0.5–50 M) and ascorbate (250 M). Intrasynaptosomal conversion of tyrosine to dopamine (DA) was measured by¹⁴CO₂ evolution froml-[1-¹⁴C]tyrosine in the absence of added cofactors and DOPA decarboxylase. Malondialdehyde (MDA) was measured as an index of lipid peroxidation. A concentration-dependent inhibition of DA synthesis by ADP-Fe³⁺/ascorbate was found with 50% inhibition occurring at 2.5 M Fe³⁺ concentration. This was accompanied by marked accumulation of MDA. Ascorbate or ADP alone did not affect DA synthesis and ADP-Fe³⁺ in the absence of exogenous ascorbate was effective only above 25 M. Exogenously added MDA did not inhibit DA synthesis. Purified synaptosomes were isolated from peroxidized and control P₂ fractions using sucrose gradients. Membrane microviscosity of the purifled synaptosomes was assessed by nitroxyl spin labels of stearic acid using electron paramagetic resonance techniques. There was a significant increase in membrane microviscosity as a result of ADP-Fe³⁺/ascorbate induced peroxidation. Maleimide nitroxide spin-label binding to protein sulhydryls was significantly modified by peroxidation of striatum synaptosomes. The weakly immobilized component of the sulhydryl spin-label (w) was drastically decreased whereas the strongly immobilized component (s) was modified less, thus leading to a marked reduction of w/s ratio. The exposure of striatum synaptosomes to the peroxidizing system resulted in a significant increase in total iron and in a 25% decrease in protein sulhydryl content. It is concluded that ironinduced damage to the DA synthetic system is mediated by alterations of the structural properties of nerve ending membranes.