Aluminum (Al) overload in dialysis patients and experimental animals is associated with the development of anemia. However, the precise mechanisms of erythrocyte Al uptake and toxicity are poorly understood. Al accumulation, hemoglobin (Hb) synthesis and cell growth were evaluated in dimethylsulfoxide (DMSO)-induced Friend erythroleukemia cells (FEC), a model system for erythroid differentiation. FEC were grown in media containing either Al citrate, transferrin-aluminum (Tf-Al), Tf or no additions. Al accumulation occurring only in cells grown in Tf-Al containing media was detected at 24 hours and increased linearly up to 96 hours after induction. By 96 hours, 200 +/- 36 micrograms Al/liter lysed cells were detected in Tf-Al grown cells versus 5 +/- 1 micrograms Al/liter lysed cells in cells grown in Al citrate (P less than 0.001). Tf-Al inhibited Hb synthesis at 72 hours after induction. At 96 hours 50 +/- 15% cells were benzidine positive when grown in Tf-Al compared to 76 +/- 15% in Al citrate (P less than 0.001). FEC grown in increasing concentrations of Tf-Al (100 to 500 micrograms/ml) showed inhibition of Hb synthesis at lower concentrations of Tf-Al at 100 micrograms/ml than for cell growth at 300 micrograms/ml. Higher concentrations of Tf-Al (greater than 300 micrograms/ml) did not further inhibit Hb synthesis or cell growth. Iron (Fe) and Tf uptake were increased in Al loaded FEC compared to control cells. The increased Tf uptake was probably the result of increased Tf receptor expression on FES since Tf cell cycling time was unchanged. These data indicate that Al utilizes the Tf uptake pathway for entry into erythrocyte precursors. Al is toxic at sites distal to Fe uptake, possibly at the heme and/or globin synthetic pathways, resulting in decreased Hb synthesis and cell growth.
Aluminum (AI) and iron (Fe) have been implicated as playing a toxic role in the pathologic lesions of Alzheimer's disease. In the following report we describe the uptake and toxicity of Al, the effect of Al on Fe uptake, and the expression of neurofibrillary tangle (NFT) protein in murine neuroblastoma cells (Neuro 2A). Significant cell Al uptake and inhibition of cell growth were seen in Neuro 2A cells at 24, 48, 72, and 96 h after plating in medium containing Al transferrin (AI-Tf) and Al citrate. Al-loaded Neuro 2A cells showed increased rates of 59Fe and lZ51-Tf uptake and total cellular Fe content at 24, 48, 72, and 96 h after plating compared with control cultures. Significant increases in NFT protein staining were detected in Al-exposed cells at 72 and 96 h in culture compared with controls.
This study examines whether there is a relationship between aluminum overload and the accumulation of lipofuscin products (aging pigments) and lipid peroxides in red blood cells (RBC) of hemodialyzed patients. Lipid peroxides levels were assessed by the thiobarbituric acid reactivity; lipofuscin products were assessed by determining fluorescence in the lipid extracts at excitation 360 nm and emission 440 nm. Aluminum was measured by atomic absorption spectrophotometry. Controls were age-matched normal volunteers. Data show that there was a significant increase in the lipid peroxides and lipofuscin products in hemodialyzed patients compared with controls even after normalization with hemoglobin or phospholipids in RBC. Further, the increase in the lipid peroxides and lipofuscin products significantly correlated with the levels of aluminum accumulation in RBC of hemodialyzed patients. This study suggests that aluminum overload has a role in increased membrane peroxidation, which in turn can cause reduced RBC life span and contribute to anemia in chronic renal failure patients.
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