Marcella Nazzaro-Porro

Antimitochondrial effect of saturated medium chain length (C8-C13) dicarboxylic acids

In isolated rat liver mitochondria, respiration was competitively inhibited by medium chain length (C8 to C13) dicarboxylic acids to different extents: the higher the number of carbon atoms up to C12, the greater the inhibition. In particular, experiments on submitochondrial particles showed that the competitive inhibition concerned the following enzymes: NADH dehydrogenase, succinic dehydrogenase and reduced ubiquinone: cytochrome c oxido-reductase. These results tend to confirm the suggestion that the melanocytotoxic effect of dicarboxylic acids, which are also competitive inhibitors of tyrosinase, may be primarily due to an antimitochondrial effect rather than being tyrosinase-dependent.

Role of skin surface lipids in UV-induced epidermal cell changes.

SummaryUltraviolet irradiation is capable of affecting skin surface lipids, especially squalene and cholesterol, both in vitro and in vivo, with generation of active lipoperoxides. The photodecomposition of the skin lipid component was carefully evaluated by capillary gas-chromatography. The effects of UV-induced lipoperoxides on human keratinocytes in culture and on guinea pig ear slices were compared with those of synthetic lipoperoxides, i.e. cumene hydroperoxide and 13-hydroperoxylinoleate. A time- and dose-dependent effect on protein synthesis and mitotic activity was observed. In cell culture low concentrations (0.05–5 Μg/ml) of peroxidated squalene and synthetic lipoperoxides stimulated the incorporation of radiolabelled thymidine and phenylalanine, while higher concentrations (>10 Μg/ml), or longer periods of treatment, induced cellular damage. In guinea pig ear slices, the lipoperoxides (5–50 Μg/ml) increased aminoacid incorporation and the number of epidermal pigment cells; higher concentrations (>100 Μg/ml) caused a derangement of epidermal structure. The results suggest that UV irradiation of skin generates lipoperoxides from the surface lipids which, in vitro, are capable of producing a number of changes in epidermal cells.

Mechanism of antitumoral activity of catechols in culture

Cell lines Raji and K 562, lacking tyrosinase, and two melanotic human melanoma cell lines (IRE 1 and IRE 2), were exposed to concentrations from 5 X 10(-3) M to 10(-5) M of different phenols which are substrates of tyrosinase, i.e. l-dopa, dopamine, hydroquinone, terbutylcatechol, and of phenols which are not substrates of the tyrosinase, i.e. resorcinol, butylated hydroxyanisole and hydroquinone dimethyl ether. Cultures were carried out in the presence or in the absence of oxygen radical scavenger enzymes superoxide dismutase, catalase and peroxidase. The stability of each substance in culture medium was assayed by high performance liquid chromatography (HPLC). Results showed that: catechols which are substrates of tyrosinase decompose fully after 24 hr in medium; they are equally toxic for melanoma and non-melanoma cell lines; their toxicity increases when they are preincubated in medium for 24 hr and 48 hr before addition of cells; their toxicity is significantly reduced by addition of scavenger enzymes; on the contrary, phenols not substrates of tyrosinase are stable in medium and their toxicity is not reduced by scavenger enzymes. It is concluded that tyrosinase does not play a major role in catechol toxicity in vitro, which is probably due to some products of catechol decomposition, especially oxygen radicals, acting outside the cells.

Saturated dicarboxylic acids as products of unsaturated fatty acid oxidation.

Upon chemical, radiation-induced or enzymatic oxidation, cis-polyunsaturated fatty acids, i.e., C18:2(n-6), C18:3(n-3), C20:2(n-6), C20:3(n-6), C20:3(n-3), C20:4(n-6), C20:5(n-3), C22:2(n-3), C22:4(n-6), C22:6(n-3), were found to generate saturated short and medium-chain length dicarboxylic acids, which can be regarded as a distinctive feature of the particular double bonds positions in the polyunsaturated fatty acid molecule. Two different dicarboxylic acids, which were unambiguously quantified by GC-MS, were produced from a single fatty acid: one deriving from the oxidative splitting at the level of the first double bond in the molecule, the other being two-carbon-atoms lower homologous. Formation of dicarboxylic acids occurred also from triacylglycerols and phospholipids containing cis-polyunsaturated fatty acids. In this case, following oxidation, the diacids remained covalently bound to the starting molecule and transesterification was necessary for identification. Being extremely stable and easily detectable compounds, dicarboxylic acids may be considered potential markers of oxidative attack to both free and esterified unsaturated fatty acids.

Scavenging Activity of Azelaic Acid on Hydroxyl Radicals in Vitro

Azelaic acid is an aliphatic dicarboxylic acid (HOOC-(CH2)7-COOH) which has recently been shown to have some practical therapeutic applications in skin diseases of different etiologies. It possesses diverse biological activities and its mechanisms of action are still under investigation. Azelaic acid, as disodium salt (C(9)2Na), at concentrations from 0.05 mM to 1.0 mM is capable of inhibiting significantly the hydroxylation of 1-tyrosine to 1-DOPA due to hydroxylradicals (HO.) produced by Fenton reaction. Similarly C(9)2Na significantly inhibits the heterogeneous photocatalytic oxidation of toluene to cresols, and the peroxidation of arachidonic acid (C20:4,n6), due to HO. formed by dissolved oxygen in the presence of UV-irradiated semiconductor TiO2 (photo-Fenton type reaction). C(9)2Na decomposition and its by-products formation are quantifiable only at high HO. concentrations. On the contrary, C(9)2Na is not a scavenger of O2-. generated by xanthine-xanthine oxidase system. Under the same experimental conditions, mannitol behaves like C(9)2Na. These data indicate that HO. scavenging capacity of C(9)2Na in vitro, and represent a useful tool for further investigations on the mechanisms of action of azelaic acid in biological systems.