Aluminium increases xanthine oxidase activity and disturbs antioxidant status in the rat.

The mechanisms responsible for the neurotoxic effects of Al remain poorly understood. In order to determine whether Al promotes oxidative stress in vivo, we measured the enzymatic activity of xanthine oxidase (XO), superoxide dismutase (SOD), glutathione peroxidase (GPX), glutathione-S-transferase (GST) and glutathione reductase (GR) in four groups of rats after eight days of intraperitoneal administration of variable concentrations of Al (0, 5, 10, and 15 mg/kg body weight, respectively). XO activity was measured in both plasma and liver samples, and the activities of the remaining enzymes were further determined in the brain and red blood cells (RBC). The most significant changes were observed in XO and GPX activities, that were enhanced and depressed, respectively. In both instances, the enzyme activities were correlated with Al concentrations, either positively (XO) or negatively (GPX). Enhancement of XO and inhibition of GPX activity may lead to the accumulation of intermediate toxic compounds such as hydrogen peroxide and hydroxyl radicals, since SOD activity is increased as well. The latter finding must be taken with some caution because previous studies have shown contradictory results in this field. Our data suggest that Al toxicity could be mediated by its action on both pro- and anti-oxidant enzymes. The biological significance of these findings remains to be established.

Iron tissue storage and hemoglobin levels of deficient rats repleted with iron bound to the caseinophosphopeptide 1-25 of beta-casein.

Caseinophosphopeptides (CPP) issued from enzyme digestion of caseins bind cations and keep them soluble in the digestive tract. They could be used as ligands to improve iron (Fe) bioavailability. Fe-deficient young rats were repleted with Fe (40 or 200 mg/kg of diet) bound either to the beta-CN (1-25) of beta-casein or to whole beta-casein or as FeSO(4). A control pair-fed group was given 200 mg of Fe (FeSO(4))/kg of diet for 6 weeks. After repletion, hemoglobin concentration of the control group was reached only by the ) animals fed 200 mg of Fe/kg; beta-CN (1-25) bound Fe (40 and 200 mg) produced higher Fe liver and spleen stores than FeSO(4). Binding Fe to the whole, nonhydrolyzed beta-casein gave results intermediate between the other experimental groups. Binding Fe to phosphoserine residues of low molecular weight CPP improved its ability to cure anemia and to restore iron tissue stores, as compared to Fe bound to the whole casein and to inorganic salts.

Determination of metallothioneins by HPLC: application to zinc metabolism.

Metallothioneins (MT) are well known Zn and Cu tissue proteins. Their level is mainly regulated by Zn. Therefore, they have been suggested as an index of Zn status. The determination of MT has been performed by HPLC (fitted with UV-detector) following a preparation phase (heating, ultracentrifugation and filtration). This method allows direct quantification of MT in tissues and shows a good correlation between MT concentrations and peak heights (r2 = 0.995; a = 774.73; b = -148.38) from 0 to 10 micrograms/100 microL. MT determination by RP-HPLC method allows to assess the tissue zinc status as displayed by the correlation between hepatic zinc and metallothionein concentrations (r2 = 0.82; p < 0.001). Variations of MT in response to Zn intakes are observed within 24 hours and for a physiological range of dietary Zn intakes.