Interaction of [4-14C]estradiol and its metabolites with polynucleotides in the presence of peroxidase

Diaryl dimers of estradiol and of estrone may be formed as major metabolites by mouse mammary glands

The formation of a novel estrogen metabolite by mammary tissues was investigated. Polar and nonpolar metabolites of endogenous estrogens are formed in liver and other tissues. Polar products such as the catechol estrogens are implicated in tumorigenesis in breast tissue, whereas a nonpolar metabolite, 2-methoxyestradiol, may be protective. Diaryl ether dimers, as a novel form, have been reported as nonpolar products from liver microsomes. We have noted major amounts of nonpolar metabolites in other tissues that were neither 2-methoxyestrogens nor estrogen fatty acid esters. The possible formation of such novel metabolites by breast tissues from adult nulliparous mice with [(3)H]-labeled estrogens as substrates was considered. Steroids were recovered from media by solid-phase extraction and profiles were obtained from HPLC (acetonitrile:water). Saponification was done with an internal standard of estradiol stearate. Major amounts of nonpolar metabolites were formed in all instances, with one or two principal peaks. Alkaline hydrolysis had no effect on the nonpolar product(s) but released estradiol from its stearate. Strong acid treatment also had no effect as shown by HPLC. Thus, it is suggested that diaryl dimers of estrogens may be formed as major metabolites by mouse mammary glands.

Ontogeny of peroxidase activity in epithelium and eosinophils of the mouse uterus

Outbred CD-1 mice treated for 1 or 4 days with 1 mg/kg of diethylstilbestrol (DES) at various ages after birth were examined for histochemical localization of peroxidase in the uterine epithelium. Peroxidase activity in uterine extracts was also measured by a radiometric assay and the conversion of [3H]DES to [3H]Z,Z-diensestrol (Z,Z-DIES). While no peroxidase activity was detected by a histochemical method in uterine epithelium from untreated 5-day old mice, the enzyme was apparent in mice treated for 4 days with DES; uterine eosinophils were absent at this age. By day 9, DES-induced staining for peroxidase in uterine epithelial cells and the number of uterine eosinophils had increased significantly. In addition, at this age, the biochemical assays for uterine peroxidase were sensitive enough to show that DES is converted to Z,Z-DIES and that [3H]estradiol gives rise to 3H2O and water-soluble radioactive metabolites. The peroxidase response to DES, determined by both histochemical and biochemical methods, increased with the age of the immature mice. These data indicate that the neonatal uterus, although deficient in eosinophils, demonstrates a peroxidase response to estrogen and that this response is localized primarily in the luminal epithelium. The role of this DES-induced peroxidase activity in converting DES to activated metabolites that may cause cell damage is discussed.

Peroxidase-catalyzed displacement of tritium from regiospecifically labeled estradiol and 2-hydroxyestradiol

Estradiol and 2-hydroxyestradiol with 3H at different positions in rings A, B or D were incubated with lactoperoxidase without added H2O2 and their oxidative transformation was followed by transfer of 3H into 3H2O. With estradiol, 3H loss from different positions in the aromatic ring was almost equal and also occurred to a lesser extent from the alicyclic portion of the molecule. Glutathione had less effect on the formation of 3H2O for the aromatic ring of estradiol than from that of the catechol estrogen where it increased the yield 6-fold. The rate of 3H loss was also very much greater from tritiated 2-hydroxyestradiol than from estradiol and NADPH was inhibitory with both steroids. Conditions for the release of 3H from estradiol and 2-hydroxyestradiol by peroxidase as well as the effect of some biochemical inhibitors were also investigated. The possible contribution of peroxidative formation of 3H2O during the radiometric assay for catechol estrogen biosynthesis by tissue monooxygenases is discussed.

Characterization of free radicals produced during oxidation of etoposide (VP-16) and its catechol and quinone derivatives. An ESR Study

Spectroscopic evidence for the radical-mediated metabolism of VP-16, VP-16 catechol, and VP-16 quinone during enzymatic oxidation and autoxidation has been obtained. Autoxidation of the catechol yields the primary semiquinone together with the primary molecular product VP-16 quinone, which subsequently undergoes hydrolytic oxidation to form secondary quinones and semiquinones. Both primary and secondary phenoxyl radicals were detected during peroxidatic oxidation of VP-16. Neither the primary nor the secondary radicals react with DNA at a detectable rate. Evidence for the production of hydroxyl radical during iron-catalyzed oxidation of VP-16 catechol was obtained. These free radical reactions may have implications for the mechanism of antitumor action of VP-16.

Different metabolism by mammalian and horseradish peroxidases in vitro of steroidal estrogens and their catechol metabolites

Radioactively labeled estradiol-17 beta and 17 alpha-ethynylestradiol and their 2-hydroxy derivatives were incubated with either horseradish peroxidase or mouse uterus peroxidase, and the formation of polar products, which could not be extracted with diethyl ether, and of ether-extractable metabolites was studied. Moreover, the extent of DNA binding was determined. The different peroxidases gave rise to different products, indicating that different pathways in the metabolism of these steroidal estrogens are catalysed by the two peroxidases.

Nature of the macromolecular binding of diethylstilbestrol to DNA and protein following oxidation by peroxidase/hydrogen peroxide

Incubation of [14C]diethylstilbestrol ([14C]DES) with horseradish peroxidase(HRP)/hydrogen peroxide in the presence of various polynucleotides and proteins led to macromolecular binding of radioactivity. Binding to DNA proved stable against ethanol precipitation, but was completely removed when the DNA was subjected to gel electrophoresis, caesium chloride density centrifugation, and mild hydrolysis. In contrast, binding to protein was stable in gel electrophoresis. The extent of binding did not differ significantly between proteins with and without thiol groups. These results imply that the products of peroxidase-mediated oxidation of DES bind to DNA in a strong but non-covalent manner, whereas binding to protein appears to be covalent and does not depend on the presence of thiol groups. The possible nature of the binding species is discussed.

Phenol oxidation product(s), formed by a peroxidase reaction, that bind to DNA

Phenol oxidation by horseradish peroxidase/H2O2 initially results in p,p'-biphenol and o.o'-biphenol formation and subsequently results in polymer formation. o,o'-Biphenol is the major product formed, but it is rapidly oxidized to the polymer, particularly in the presence of phenol. p,p'-Biphenol is very rapidly oxidized to p,p'-biphenoquinone which can also be involved in polymer formation. Extensive binding of 14C-phenol oxidation products to DNA occurs if the DNA is present in the reaction mixture. However, enzymic hydrolysis of DNA releases the bound polymers. p,p'-Biphenol, however, did not bind to DNA following peroxidase-catalysed oxidation, but o,o'-biphenol readily binds to DNA following peroxidase-catalysed oxidation. Enzymic hydrolysis of the oxidized o,o'-biphenol-bound DNA also resulted in the release of the polymers.

Peroxidase-catalysed binding of [U-14C]phenol to DNA

14C-Phenol binds irreversibly to calf-thymus DNA in the presence of horseradish peroxidase and hydrogen peroxide, approximately 65% of the added phenol was bound to DNA. Binding was maximal at an equimolar concentration of hydrogen peroxide. Binding also occurred to homopolyribonucleotides polyadenylic acid, polyguanylic acid, polycytidylic acid and polyuridylic acid, and suggests that binding is relatively non-specific with respect to the nucleotide bases. p,p'-Biphenol, p,p'-biphenoquinone, o,o'-biphenol and two unidentified products were formed by the oxidation of phenol, in the presence and in absence of DNA. DNA accelerated phenol oxidation four fold and prevented the polymerization of oxidized phenol products, but was found to have no effect on the range of ethyl acetate-extractable products. Phenol accelerated the metabolism of o,o'-biphenol but had no effect on p,p'-biphenol metabolism. The mechanism of phenol activation is not clear, but p,p'-biphenoquinone binds to protein and not to DNA. DNA binding was prevented by glutathione, N-acetyl-cysteine and ascorbate, and the mechanism was shown to involve reduction of the activated phenol intermediates and the formation of conjugates with glutathione and N-acetyl-cysteine. DNA binding was not inhibited by lysine and proline.

DNA clastogenic activity of diethylstilbestrol

Incubation of human leukocytes with the synthetic estrogen and known human carcinogen, diethylstilbestrol (DES), for 40 min caused extensive DNA strand breakage (clastogenesis), as measured by a fluorometric assay. The level of DNA clastogenesis was dose dependent above an apparent threshold of 10 microM. Clastogenesis was increased by addition of cysteamine, a reducing agent and hydroxyl radical scavenger, and was blocked by low concentrations of plasma. DES epoxide, a weakly estrogenic derivative, was about one-tenth as potent as a DNA clastogen. Unexpected and paradoxical findings were observed when cells were treated with DES in the presence of a hydrogen peroxide-generating system plus a peroxidase. At the subthreshold concentration of 10 microM DES, the oxidizing system increased DNA clastogenicity, yet at 30 microM DES the oxidizing system decreased clastogenicity. The addition of superoxide dismutase to the oxidizing system increased clastogenicity at both concentrations of DES. DNA damage was largely blocked by arsenite, N-ethylmaleimide, iodoacetamide and bromophenacyl bromide. These experiments provide further indication of the complex nature of reactions involving DES which can lead to DNA damage and which may be relevant to DES-induced carcinogenesis.

Photosensitized irreversible binding of estrone to protein via a hydroperoxide intermediate: an explanation of (photo-) allergic side-effects of estrogens

After irradiation (lambda greater than 425 nm) for 15 min of a solution of [4-14C]-estrone, albumin and the photosensitizer hematoporphyrin in phosphate buffer, more than 30% of the radioactivity could not be extracted. When the protein was added after irradiation, irreversible binding also occurred. Sephadex gel filtration showed that the radiolabel was bound to albumin as well as to the photosensitizer. A 10 beta-hydroperoxide is the reactive intermediate in this binding. Inasmuch as phenolic steroids coupled to proteins have been used for the induction of estrogenic-specific antibodies, the irreversible binding observed between estrone and albumin by photosensitization might be an explanation for (photo)allergic disorders associated with estrogens.

Interaction of the photosensitization products of oestrone with DNA: comparison with the horseradish peroxidase catalyzed reaction

The interaction with DNA of [4-14C]oestrone upon photosensitization with hematoporphyrin (HP) as a photosensitizer has been investigated. By means of Sephadex LH-20 gel filtration and extraction with dichloromethane it was found that, after irradiation (lambda greater than 425 nm) of a solution of HP, DNA and [4-14C]oestrone 21% of the radiolabel was associated with DNA. If DNA was added after irradiation 23% was bound to DNA, whereas 25% of the oestrone remained after photoreaction under the conditions applied. The binding occurs via the reactive 10 beta-hydroperoxy-1,4-estradien-3,17-dione, which is the only product after photosensitization of oestrone. The hydroperoxide has a strong interaction with DNA compared with that of other steroids. By repeated precipitation with 5 M NaCl and ethanol the association can be broken. It is reported, that binding of oestrone to protein induced by both photosensitization and horseradish peroxidase (HRPO)/H2O2 is irreversible, but that the amount of binding to DNA is dependent on the method of determination. However, neither the hydroperoxide nor its reduced product, a p-quinol, is intermediate or product in the HRPO catalyzed reaction of oestrogens. The tight association of the hydroperoxide product of oestrone with DNA, which may proceed via hydrogen bonding between the -OOH group and oxygen atoms of the backbone phosphate groups or of the furanose ring, might be a cause of chemical modification of DNA and of mutagenic effects.

Metabolism of estradiol by uterine peroxidase: nature of the water-soluble products

The nature of the water-soluble products formed by incubating labelled estradiol with uterine peroxidase in the presence of H2O2 and tyrosine was examined by two-dimensional thin-layer chromatography and high voltage electrophoresis. It was shown that the steroid and amino acid were associated in a 1:2 or 1:3 ratio and evidence was provided by 3H-exchange for the interaction of tyrosine with ring A of estradiol at C-2 and C-4. The possible role of estrogen-induced peroxidase in the uterus in vivo is discussed.

Estrogen binding by leukocytes during phagocytosis,

Estradiol binds covalently to normal leukocytes during phagocytosis. The binding involves three cell types, neutrophils, eosinophils, and monocytes and at least two reaction mechanisms, one involving the peroxidase of neutrophils and monocytes (myeloperoxidase [MPO]) and possibly the eosinophil peroxidase, and the second involving catalase. Binding is markedly reduced when leukocytes from patients with chronic granulomatous disease (CGD), severe leukocytic glucose 6-phosphate dehydrogenase deficiency, and familial lipochrome histiocytosis are employed and two populations of neutrophils, one which binds estradiol and one which does not, can be demonstrated in the blood of a CGD carrier. Leukocytes from patients with hereditary MPO deficiency also bind estradiol poorly although the defect is not as severe as in CGD. These findings are discussed in relation to the inactivation of estrogens during infection and the possible role of estrogens in neutrophil function.

Metabolism of (4-14C)estradiol by 7,12-dimethylbenz(a) anthracene-induced mammary tumor peroxidase

The peroxidase and estradiol-metabolizing activities of mammary tumors induced by 7,12-dimethylbenz(a)anthracene were determined in fresh and stored tissue. In both cases, a wide variation in peroxidase activity was observed in 47 different tumors tested. The properties of the enzyme found in the tumors were similar to those of lactoperoxidase. It is suggested that the amount of peroxidase present might reflect the ability of tumor cells to differentiate in response to hormonal stimulation and be indicative of the degree of tumor progression.

Metabolism of (4- 14 C)oestradiol by oestrogen-induced uterine peroxidase

1. An enzyme that catalyses the metabolism and binding of [4-(14)C]oestradiol to protein and to other high-molecular-weight substances in the presence of H(2)O(2) was shown to be absent from the uteri of immature rats and to be induced by physiological doses of oestrogen or pregnant-mare-serum gonadotrophin. 2. The pH optimum, stability to heat and other characteristics of the uterine enzyme system as well as its subcellular distribution were determined. 3. The increase in the ability of uterine preparations to convert [4-(14)C]oestradiol into water-soluble products as a result of oestrogen treatment was accompanied by an increase in peroxidase and NADH oxidase activities and was inhibited by actinomycin D and cycloheximide. 4. The results support the proposal that the increase in peroxidase activity after oestrogen treatment might be part of an adaptive response of the uterus permitting it to bind and inactivate oestrogens and thus limit the duration of their effect upon this target tissue.