- Oxidative transformation of 2-hydroxyestrone. Stability and reactivity of 2,3-estrone quinone and its relationship to estrogen carcinogenicity
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The carcinogenicity of estrogens in rodents and man has been attributed to either alkylation of cellular macromolecules and/or redox-cycling, generation of active radicals, and DNA damage. Metabolic activation of estradiol leading to the formation of catechol estrogens is believed to be a prerequisite for its genotoxic effects. 4-Hydroxyestradiol, although not 2- hydroxyestradiol, is a potent inducer of tumors in hamsters. Previous studies have shown that 3,4-estrone quinone can redox-cycle and is capable of inducing exclusively single strand DNA breaks in MCF-7 breast cancer cells, as well as react with various nucleophiles (thiol, imidazole, amino, phenolate, and acetoxy) to give Michael addition products. These results support the possible involvement of 3,4-catechol/quinone estrogens in estrogen's carcinogenicity. To explain the decreased carcinogenicity of 2- hydroxyestrogens, the reactions of 2,3-estrone quinone (2,3-EQ) with nucleophiles were investigated. Reactions of 4-methylimidazole with 2,3-EQ gave a complex mixture of products leading to the formation of the catechol, C-O dimerization product, and a 1,6-Michael addition product identified as the 1-(4-methylimidazolo)-2-hydroxyestrone. Reactions of 2,3-EQ under mildly basic conditions with either ethyl phenolate or acetate gave several products which were characterized as the C-O and C-C dimers, catechol, and 3,5- dihydroxy-1(10),3-estradiene-2,17-dione. No Michael addition products were detected under these experimental conditions. The same products were also observed during the synthesis of 2,3-EQ, which led us to postulate that the lack of carcinogenicity of 2-hydroxyestrogens may be related to the increased reactivity and decreased stability of the quinone under physiological conditions. These results are contrasted with those obtained with 3,4-EQ which is much more stable and therefore could diffuse from the site of formation to the target tissue. These results along with rapid methylation and clearance may be very likely explanations for the decreased carcinogenicity of 2-hydroxyestrogens.
- Tabakovic,Gleason,Ojala,Abul-Hajj
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- Bioactivation of estrone and its catechol metabolites to quinoid-glutathione conjugates in rat liver microsomes
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Although the carcinogenic effects of estrogens have been mainly attributed to hormonal properties, there is interest in estrogens acting as chemical carcinogens by binding to cellular macromolecules. In the present study, we explored factors which influence the rate of P450-catalyzed formation of the o-quinones (3,5-cyclohexadiene-1,2-diones) from 2-hydroxyestrone (2-OHE) and 4-hydroxyestrone (4-OHE) as well as from estrone in rat liver microsomes. The initially formed o-quinones were trapped as their GSH conjugates which were separated and characterized by HPLC with electrospray-MS detection. Two mono-GSH conjugates were observed from the 2-OHE-o-qutnone as well as a conjugate where GSH had added twice to the molecule producing a di-GSH conjugate. 4-OHE-o-quinone gave only one mono-GSH adduct as well as a di-GSH adduct. Both 2-OHE and 4-OHE were excellent substrates for P450, generating o-quinone GSH adducts at 94 and 40 times, respectively, the rate of estrone. 2-OHE but not 4-OHE saturated P450 at unusually low concentrations (0.2 nmol of P450/mL) perhaps due to differences in the stability of the o-quinones formed in the active site of the enzyme. Preliminary data suggest that the o-quinones of both 2-OHE and 4-OHE could isomerize to quinone methides (4-alkyl-2,5-cyclohexadien-1-ones, QMs). The o-quinones of the catechol estrogens were incubated at 37°C (pH 7.4) in the absence of GSH. Aliquots were removed at various times and combined with GSH. From the pseudo-first-order rate of disappearance of the o-quinone GSH adducts, the half-lives of the o-quinones were determined. The o-quinone from 2-OHE has a half-life of 42 ± 3 s at 37°C (pH 7.4), and the o-quinone from 4-OHE has a half-life of 12.2 ± 0.4 min under identical conditions. The o-quinones of the AB ring analogs of the catechol estrogens (3,4-dihydroxy-5,6,7,8-tetrahydronaphthalene and 1,2-dihydroxy-5,6,7,8-tetrahydronaphthalene) isomerize to QMs, suggesting that a similar reaction pathway could occur with the o-quinones from catechol estrogens. In support of this, oxidation of 4-OHE and quenching with GSH after 70 min produced 9-dehydro-4-hydroxyestrone (3-hydroxy-1,3,5-(10),9(11)-estratetraen-17-one), a product which could result from either the QM hydrolysis product or the QM-glutathione conjugate, both of which could eliminate to give the conjugated alkene of 4-OHE. The implications of the o-quinone/QM pathway to the in vivo effects of catechol estrogens are not known; however, given the direct link between excessive exposure to endogenous estrogens and the enhanced risk of breast cancer, the potential for formation of additional reactive intermediates needs to be explored.
- Iverson, Suzanne L.,Shen, Li,Anlar, Nilgun,Bolton, Judy L.
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- Assay of labile estrogen o-quinones, potent carcinogenic molecular species, by high performance liquid chromatography-electrospray ionization tandem mass spectrometry with phenazine derivatization
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A sensitive and selective assay method for labile estrogen o-quinones, estrone (E1)-2,3-quinone (Q), E1-3,4-Q, estradiol (E2)-2,3-Q and E2-3,4-Q, based on the use of phenazine (Phz) derivatization with o-phenylenediamine and high performance liquid chromatography-electrospray ionization tandem mass spectrometry (HPLC-ESI-MS/MS) was described. The Phz derivatives of four estrogen o-quinones were purified by solid phase extraction and analyzed by HPLC-ESI-MS/MS. The protonated molecule was observed as a base peak for all Phz derivatives in their ESI-mass spectra (positive mode). In multiple reaction monitoring, the transition from [M+H]+ to m/z 231 was chosen for quantification. Calibration curves for the o-quinones were obtained using standard catechol estrogens after sodium metaperiodate treatment and Phz derivatization. Using this method, these four estrogen o-quinones were analyzed with the limit of quantification of 5ng/ml in acetonitrile (MeCN)-blank matrix (1:4, v/v), respectively, on a basis of the weight of catechol estrogens. Assay accuracy and precision for four estrogen o-quinones were 89.6-113.0% and 3.1-12.6% (5, 125 and 2000ng/ml in MeCN-blank matrix). Applications of this method enabled to determine the catalytic activities on hydroxylation and subsequent oxidation of E1 and E2 of Mushroom tyrosinase and rat liver microsomal fraction. It was confirmed by this method that tyrosinase exhibited 2- and 4-hydroxylation and further oxidation activities for catechols in the ring-A of estrogens. Whereas rat liver microsomal fraction possessed only 2- and 4-hydroxylation activities, and further oxidation activity for catechol estrogens was low.
- Yamashita, Kouwa,Masuda, Akina,Hoshino, Yuka,Komatsu, Sachiko,Numazawa, Mitsuteru
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experimental part
p. 141 - 148
(2011/02/22)
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- Balance of beneficial and deleterious health effects of quinones: A casestudy of the chemical properties of genistein and estrone quinones
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Substances containing a phenolic moiety are often metabolized to quinones whose high reactivity makes them difficult to study. Some of these precursors have clear health benefits, and some quinones themselves are used in cancer therapy, whereas others are
- Zhang, Qiang,Tu, Tingting,D'Avignon, D. Andrea,Gross, Michael L.
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experimental part
p. 1067 - 1076
(2009/06/28)
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- Adduction of catechol estrogens to nucleosides.
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We report the formation, detection, quantitation and structural characterization of products resulting from the adduction of deoxynucleosides (deoxyadenosine, deoxyguanosine, deoxycytidine and 5-methyldeoxycytidine) to the catechol estrogens (CE) of estrone, estradiol-17beta and estradiol-17 alpha. The crude products are obtained in a one-pot synthesis through oxidation of catechols to quinones and subsequent Michael-type reaction with the deoxynucleosides in acidic medium.In all experiments, adducts are detected by electrospray ionization mass spectrometry analysis after HPLC separation (LC/ESI/MS(n)). The two pyrimidines deoxycytidine and 5-methyldeoxycytidine yield only CE adducts to deoxynucleosides, which correspond to stable adducts on DNA. For purines, the results depend on the CE (2,3- or 3,4-catechols) used, the function and configuration on carbon 17 (ketone for estrone, alcohol for alpha and beta isomers of estradiol), and on the purine itself (deoxyadenosine or deoxyguanosine). Both stable adducts and deglycosylated adducts are formed, and therefore formation of stable adducts on DNA as well as the loss of purines from the DNA strands could be possible. MS(2) and MS(3) experiments prove to be relevant for further structural determinations, enabling in some cases the elucidation of the regiochemistry of adduction on the A and B rings of the steroid moiety.
- Jouanin, Isabelle,Debrauwer, Laurent,Fauglas, Gwenola,Paris, Alain,Rathahao, Estelle
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p. 1091 - 1099
(2007/10/03)
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- Molecular characteristics of catechol estrogen quinones in reactions with deoxyribonucleosides
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Estrogens can have two roles in the induction of cancer: stimulating proliferation of cells by receptor-mediated processes, and generating electrophilic species that can covalently bind to DNA. The latter role is thought to proceed through catechol estrogen metabolites, which can be oxidized to o-quinones that bind to DNA. Four estrogen-deoxyribonucleoside adducts were synthesized by reaction of estrone 3,4-quinone (E1-3,4-Q), 17β-estradiol 3,4-quinone (E23,4-Q), or estrone 2,3-quinone (E1-2,3-Q) with deoxyguanosine (dG) or deoxyadenosine (dA) in CH3CO2H/H2O (1:1). Reaction of E1-3,4-Q or E2-3,4-Q with dG produced specifically 7-[4- hydroxyestron-1(α,β)-yl]guanine (4-OHE1-1(α,β)-N7Gua) or 7-[4- hydroxyestradiol-1(α,β)-yl]-guanine (4-OHE2-1(α,β)-N7Gua), respectively, in 40% yield, with loss of deoxyribose. These two quinones did not react with dA, deoxycytidine, or thymidine. When E1-2,3-Q was reacted with dG or dA, N2-(2-hydroxyestron-6-yl)deoxyguanosine (2-OHE1-6-N2dG, 10% yield) and N6(2-hydroxyestron-6-yl)deoxyadenosine (2-OHE1-6-N6dA, 80% yield), respectively, were formed. These adducts provide insight into the type of DNA damage that can be caused by o-quinones of the catechol estrogens. The estrogen 3,4-quinones are expected to produce depurinating guanine adducts that are lost from DNA, generating apurinic sites, whereas the 2,3-quinones would form stable adducts that remain in DNA, unless repaired. The adducts reported here will be used as references in studies to elucidate the structure of estrogen adducts in biological systems.
- Stack,Byun,Gross,Rogan,Cavalieri
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p. 851 - 859
(2007/10/03)
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- Synthesis of W-acetylcysteine conjugates of catechol estrogens
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The synthesis of N-acetylcysteine conjugates of 2-hydroxyestrone (2-OHE1) and 4-hydroxyestrone (4-OHE1) is described. The reaction of estrone 2,3-quinone with N-acetylcysteine provided 2-OHE1 and its C-4 and C-1 thioether conjugates in a ratio of 1:1, while estrone 3,4-quinone with N-acetylcysteine gave 4-OHE, and its C-2 thioether conjugate as a sole product. Their structures were characterized by inspection of NMR spectra, chemical derivatization (methylation and acetylation), and comparison with the reactivity of 4-bromoestrone 2,3-quinone or 2-bromoestrone 3,4-quinone toward N-acetylcysteine.
- Suzuki, Emako,Iwasaki, Ryo,Goto, Junichi,Matsuki, Yasuhiko,Nambara, Toshio
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p. 296 - 301
(2007/10/03)
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