Earlier investigations from our laboratory demonstrated that human term placental peroxidase (HTPP) is capable of metabolism of xenobiotics and endogenous compounds. In this study, purified HTPP was found to bioactivate 2-aminofluorene (2-AF) in the presence of H2O2. 2-AF oxidation was studied spectrophotometrically while radiometry was employed to assess the bioactivation. The rate of oxidation and covalent binding to protein and DNA was dependent upon the pH of the reaction medium and the concentration of 2-AF, the enzyme, and H2O2. To observe maximal enzyme velocity of oxidation, the presence of 16.5 microM H2O2, 100 microM 2-AF, 37 micrograms of the enzyme protein/ml, and pH 7.2 was required. Under optimal assay conditions, the range of specific activity between 130 and 165 nmol of 2-AF oxidized/min/mg HTPP was observed. Using similar assay conditions, the magnitude of covalent binding of [3H]-2-AF to protein (BSA) and calf thymus DNA was found to be about 508 pmol bound/min/mg HTPP/mg BSA and 84 pmol bound/min/mg HTPP/mg DNA, respectively. Potassium cyanide and sodium azide, the known inhibitors of different peroxidases, significantly blocked both the oxidation and covalent binding of 2-AF in a dose dependent manner. These results strongly suggest that peroxidase may be one of the important pathways responsible for the bioactivation of arylamines in human term placenta.
Arylamines such as 2-aminofluorene (2-AF) are known teratogens and transplacental carcinogens in laboratory animal species. Although exposure of women to arylamines is likely to occur during pregnancy, how these chemicals are metabolized by the enzymes from the human conceptual tissues is currently unknown. Highly purified preparations of peroxidase isolated from human intrauterine conceptual tissues at 8 weeks of gestation were used to study in vitro metabolism of 2-AF. The oxidation of 2-AF was examined spectrophotometrically whereas the bioactivation was assessed from the covalent binding to protein and DNA using [3H] 2-AF. Using guaiacol as a model substrate, the purified preparations of peroxidase used exhibited a specific activity of 15-20 micromol/min/mg protein. 2-AF oxidation was found to be enzymatic in nature. Kinetic data obtained under optimal assay conditions yielded a Km = 41 microM for 2-AF, 8.33 microM for H2O2, and a Vmax=1.2 micromol 2-AF oxidized/min/mg protein. Under optimal assay conditions, the covalent binding of reactive intermediates to protein and DNA (nmol equivalent/min/mg enzyme/mg bovine serum albumin or calf thymus DNA) was observed at the rate of about 3.75 +/- 0.39 and 1.90 +/- 0.11 respectively. A significant decline in the rate of both oxidation and bioactivation of 2-AF was observed in the presence of classical peroxidase inhibitors, KCN and NaN3.
We have investigated the genotoxicity of two 3'-derivatives of cytidine, 2,3'-O-cyclocytidine (3'-cycloC) and beta-xylocytidine (xyloC), in human leukemia and solid tumor cell lines. Both derivatives were found to be cytotoxic at micromolar concentrations. For example, in the alveolar tumor cell line A549 which was included in all experiments as a reference, drug concentrations required to induce 50% inhibition of cell growth (D50 values) equalled 55 microM for 3'-cycloC and 80 microM for xyloC. Compared with the response of this reference cell line, none of the solid tumor cell lines tested--representing five different malignancies--displayed significant hypersensitivity to these drugs, while the acute lymphoblastic leukemia cell lines proved to be hypersensitive (range of D50 values, 5-13 microM). To gain insight into the modes of cytotoxic action of xyloC and 3'-cycloC, we compared the effect on DNA metabolism of these compounds with that of 1-beta-D-arabinofuranosylcytosine (araC), a potent inhibitor of semi-conservative DNA replication and long-patch excision repair. As seen with araC, the xylo compound strongly inhibited both DNA replicative synthesis and the repair of DNA damage induced by UV light and 60Co gamma-radiation. In gamma-irradiated A549 cells, the extent of repair inhibition by 1 mM xyloC was approximately 40% of that inhibited by araC, and concomitant exposure of the irradiated cultures to xyloC plus araC gave rise to a synergistic response. Since araC was employed at a concentration (0.1 mM) which produced a maximal effect on DNA repair when applied alone, the observed synergistic response implies that the mode of action of xyloC on DNA repair is different from that of araC. In contrast to that observed with xyloC, 3'-cycloC proved to be a very weak inhibitor of DNA replication and repair, strongly suggesting that the genotoxic action of the latter analog may be through a mechanism other than inhibition of DNA synthesis.
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