Valeria Rizzoli

AN IN VITRO STUDY ON THE TOXIC EFFECTS OF NONYLPHENOLS (NP) IN MITOCHONDRIA

This paper is focused on alkylphenols, compounds which are formed by the biodegradation of polyethoxilatedalkylphenols detergents. Our experiments show that alkylphenols act not only as detergents, but also as uncouplers of the oxidative phosphorylation. This effect, can be observed at very low doses, thus suggesting that the preferential target of nonylphenols in living organisms are mitochondria.

Horseradish peroxidase-catalyzed sulfoxidation of promethazine and properties of promethazine sulfoxide

Promethazine sulfoxide was obtained with a quantitative yield in a horse radish peroxidase-catalyzed reaction of promethazine and hydrogen peroxide and was also prepared by direct chemical synthesis. The enzymatic sulfoxidation of promethazine was studied in vitro as a function of pH, promethazine, and hydrogen peroxide concentration. Promethazine sulfoxide inhibits with an apparent K(i) of 59.7 microM at pH 5.5 the enzymatic reaction, followed spectrophotometrically, polarographically, potentiometrically, and luminometrically. The reaction was also inhibited by ascorbic acid (K(i) 26.8 microM) and glutathione (K(i) 41.8 microM). The spectrophotometric techniques employed, together with ESR spectrometry, allowed the identification of at least three radical species formed in the course of the reaction. Promethazine sulfoxide is devoid of the antioxidant effect exhibited by promethazine on rat brain synaptosomes. The sulfoxide also lacks photosensitizing action, while retaining the neuroleptic effect of the parent compound.

Interactions of trialkyllead compounds with rat liver mitochondria

The interactions of two trialkyllead (TAL) compounds, (trimethyl)Pb-Cl and (tributyl)Pb-Cl, with mitochodria from rat liver have been studied. A stimulation of the respiratory rate induced by the trialkyllead compounds added at low doses was observed which was not dependent on the presence of chloride in the medium. In contrast with the major current view, we propose that trialkyllead compounds behave as uncouplers of the oxidative phosphorylation and not (or not only) as Cl-/OH- exchangers. In fact the present results suggest that the TAL compounds enter the mitochondria as (alkyl)3Pb+ cations and are extruded as electroneutral (alkyl)3 Pb-OH compounds, the overall result being the transport of a proton through the membrane as in the case of classical uncouplers. The uncoupling effect could explain the toxicity of the compounds as a result of the decrease in the energy level of the cell. Furthermore, such a mechanism, in which the uptake of TAL compounds is supposed to be driven by a negative potential, could explain their preferential toxicity for neuronal cells, which maintain a higher negative-inside potential than most other cell types.

Protective action of a new benzofuran derivative on lipid peroxidation and sulphydryl groups oxidation.

The antioxidant properties of a novel water-soluble antioxidant of the benzofuran family (5-hydroxy-4,6,7-trimethyl-2,3-dihydrobenzofuran-2-acetic acid, BFA) were studied. In rat liver mitochondria BFA increases the lag-time and decreases the extent of lipid peroxidation induced by ascorbate/Fe2+; an IC50 value of about 12 microM was observed. In rat liver microsomes it inhibits the lipid peroxidation induced both by NADPH/Fe2+/ADP (iron-dependent) and by cumene hydroperoxide (iron-independent), showing IC50 values of 25 and 30 microM respectively. The antioxidant efficiency of BFA is slightly higher than that of the congener compound Trolox C. BFA is also able to inhibit the oxidation of protein sulphydryl groups consequent to microsomal lipid peroxidation induced by NADPH/Fe2+/ADP. The antioxidant properties of BFA are discussed considering its hydrophilic character and pharmacological features.

Interactions of melatonin with mammalian mitochondria. Reducer of energy capacity and amplifier of permeability transition

Melatonin, a metabolic product of the amino acid tryptophan, induces a dose-dependent energy drop correlated with a decrease in the oxidative phosphorylation process in isolated rat liver mitochondria. This effect involves a gradual decrease in the respiratory control index and significant alterations in the state 4/state 3 transition of membrane potential (ΔΨ). Melatonin, alone, does not affect the insulating properties of the inner membrane but, in the presence of supraphysiological Ca2+, induces a ΔΨ drop and colloid-osmotic mitochondrial swelling. These events are sensitive to cyclosporin A and the inhibitors of Ca2+ transport, indicative of the induction or amplification of the mitochondrial permeability transition. This phenomenon is triggered by oxidative stress induced by melatonin and Ca2+, with the generation of hydrogen peroxide and the consequent oxidation of sulfydryl groups, glutathione and pyridine nucleotides. In addition, melatonin, again in the presence of Ca2+, can also induce substantial release of cytochrome C and AIF (apoptosis-inducing factor), thus revealing its potential as a pro-apoptotic agent.

Fructose-1,6-diphosphate counteracts ethanol-stimulated calcium uptake in isolated BHK cells.

Ethanol increases the uptake of 45Ca by isolated baby hamster kidney (BHK) cells in vitro. The effect is dependent on ethanol and 45Ca++ concentration and on the incubation time. Fructose-1,6-diphosphate (FDP) added at different concentration during the pre-incubation exerts a protective effect through a membrane-stabilizing action which is consistent with its in vivo anti-alcohol activity documented in previous studies.

S-Acetyl- and S-Phenylacetyl-Glutathione as Glutathione Precursors in Rat Plasma and Tissue Preparations

S-acetyl- and S-phenylacetyl-glutathione derivatives were synthesized by using a new procedure. The derivatives were incubated with rat plasma and red blood cells, and also with cytosol from rat liver, kidney and heart, or tissue slices from rat heart, kidney and liver. A limited hydrolysis of the compounds occurs in plasma, whereas hydrolysis occurs to a larger extent in tissue cytosols. Both purified and crude gamma-glutamyl-transpeptidase from different sources recognized the S-acetyl- and S-phenylacetyl derivatives as substrates. Intracellular glutathione increases after incubating the derivatives with red blood cells. A potential role of S-acetyl- and S-phenylacetyl-glutathione in replenishing cells with exogenous glutathione is envisaged.