N3Ade Adducts Research Articles

Mechanism of DNA depurination by carcinogens in relation to cancer initiation

Depurinating DNA adducts formed by aromatic hydrocarbons and catechol estrogen quinones play a major role in cancer initiation. Most of these adducts depurinate instantaneously, but some guanine adducts depurinate from DNA with half-lives of hours. We report here, that after 10 h at 37 °C, reaction of estradiol-3,4-quinone (E(2)-3,4-Q) with ds-DNA to yield N7Gua and N3Ade adducts was complete and more efficient than with ss-DNA. When E(2)-3,4-Q reacted with t-RNA, no adducts were detected after 10 h, and the level of N3Ade and N7Gua adducts after 10 days was less than half that with ss-DNA after 10 h. Reaction of E(2)-3,4-Q and dG yielded 4-OHE(2)-1-N7dG, which spontaneously depurinated to yield 4-OHE(2)-1-N7Gua. To investigate the mechanism of depurination, E(2)-3,4-Q was reacted with carbocyclicdeoxyguanosine, in which the ring oxygen of the deoxyribose moiety is substituted with CH(2) , and depurination was observed. The results from this experiment demonstrate that the oxocarbenium ion mechanism plays the major role in depurination and provides the first experimental evidence for this mechanism. A newly discovered β-elimination mechanism also plays a minor role in depurination. Understanding why the depurinating estrogen-DNA adducts come from DNA, and not from RNA, underscores the critical role that these adducts play in initiating cancer.

Benzene and dopamine catechol quinones could initiate cancer or neurogenic disease

Catechol quinones of estrogens react with DNA by 1,4-Michael addition to form depurinating N3Ade and N7Gua adducts. Loss of these adducts from DNA creates apurinic sites that can generate mutations leading to cancer initiation. We compared the reactions of the catechol quinones of the leukemogenic benzene (CAT-Q) and N-acetyldopamine (NADA-Q) with 2′-deoxyguanosine (dG) or DNA. NADA was used to prevent intramolecular cyclization of dopamine quinone. Reaction of CAT-Q or NADA-Q with dG at pH 4 afforded CAT-4-N7dG or NADA-6-N7dG, which lost deoxyribose with a half-life of 3 h to form CAT-4-N7Gua or 4 h to form NADA-6-N7Gua. When CAT-Q or NADA-Q was reacted with DNA, N3Ade adducts were formed and lost from DNA instantaneously, whereas N7Gua adducts were lost over several hours. The maximum yield of adducts in the reaction of CAT-Q or NADA-Q with DNA at pH 4 to 7 was at pH 4. When tyrosinase-activated CAT or NADA was reacted with DNA at pH 5 to 8, adduct levels were much higher (10- to 15-fold), and the highest yield was at pH 5. Reaction of catechol quinones of natural and synthetic estrogens, benzene, naphthalene, and dopamine with DNA to form depurinating adducts is a common feature that may lead to initiation of cancer or neurodegenerative disease.

Potential biomarker for early risk assessment of prostate cancer

Catechol estrogen quinones (CEQ) derived from 4-hydroxyestrone (4-OHE1) and 4-hydroxyestradiol (4-OHE2) react with DNA to form depurinating--N7Gua and--N3Ade adducts. This damage leads to mutations that can initiate breast and prostate cancer. To determine whether this damage occurs in humans, urine samples from men with prostate cancer and benign urological conditions, and healthy controls were analyzed. The objective was determining whether any of the cancer patients had formed the depurinating 4-OHE1(E2)-1-N3Ade adducts. The adducts were extracted from samples by using affinity columns equipped with a monoclonal antibody developed for detecting 4-OHE1(E2)-1-N3Ade adducts. Eluted extracts were separated by capillary electrophoresis with field-amplified sample stacking and/or ultraperformance liquid chromatography. Absorption/luminescence spectroscopies and mass spectrometry were used to identify the adducts. 4-OHE1-1-N3Ade was detected at higher levels in samples from subjects with prostate cancer (n = 7) and benign urological conditions (n = 4) compared to healthy males (n = 5). This is the first demonstration that CEQ-derived DNA adducts are present in urine samples from subjects with prostate cancer.

The Greater Reactivity of Estradiol-3,4-quinone vs Estradiol-2,3-quinone with DNA in the Formation of Depurinating Adducts: Implications for Tumor-Initiating Activity

Strong evidence supports the idea that specific metabolites of estrogens, mainly catechol estrogen-3,4-quinones, can react with DNA to become endogenous initiators of breast, prostate, and other human cancers. Oxidation of the catechol estrogen metabolites 4-hydroxyestradiol (4-OHE2) and 2-OHE2 leads to the quinones, estradiol-3,4-quinone (E2-3,4-Q) and estradiol-2,3-quinone (E2-2,3-Q), respectively. The reaction of E2-3,4-Q with DNA affords predominantly the depurinating adducts 4-OHE2-1-N3Ade and 4-OHE2-1-N7Gua, whereas the reaction of E2-2,3-Q with DNA yields the newly synthesized depurinating adduct 2-OHE2-6-N3Ade. The N3Ade adducts are lost from DNA by rapid depurination, while the N7Gua adduct is lost from DNA with a half-life of approximately 3 h at 37 degrees C. To compare the relative reactivity of E2-3,4-Q and E2-2,3-Q, the compounds were reacted individually with DNA for 0.5-20 h at 37 degrees C, as well as in mixtures (3:1, 1:1, 1:3, and 5:95) for 10 h at 37 degrees C. Depurinating and stable adducts were analyzed. In similar experiments, the relative reactivity of 4-OHE2 and 2-OHE2 with DNA was determined after activation by lactoperoxidase, tyrosinase, prostaglandin H synthase (PHS), or 3-methylcholanthrene-induced rat liver microsomes. Starting with the quinones, the levels of depurinating adducts formed from E2-3,4-Q were much higher than that of the depurinating adduct from E2-2,3-Q. Similar results were obtained with lactoperoxidase or tyrosinase-catalyzed oxidation of 4-OHE2 and 2-OHE2, whereas with activation by PHS or microsomes, a relatively higher amount of the depurinating adduct from E2-2,3-Q was detected. These results demonstrate that the E2-3,4-Q is much more reactive with DNA than E2-2,3-Q. The relative reactivities of E2-3,4-Q and E2-2,3-Q to form depurinating adducts correlate with the carcinogenicity, mutagenicity, and cell-transforming activity of their precursors, the catechol estrogens 4-OHE2 and 2-OHE2. This is essential information for understanding the cancer risk posed by oxidation of the two catechol estrogens.

Formation of the depurinating N3adenine and N7guanine adducts by reaction of DNA with hexestrol-3′,4′-quinone or enzyme-activated 3′-hydroxyhexestrol: Implications for a unifying mechanism of tumor initiation by natural and synthetic estrogens

The nonsteroidal synthetic estrogen hexestrol (HES), which is diethylstilbestrol hydrogenated at the C-3–C-4 double bond, is carcinogenic. Its major metabolite is the catechol, 3′-OH-HES, which can be metabolically converted to the catechol quinone, HES-3′,4′-Q. Study of HES was undertaken with the scope to substantiate evidence that natural catechol estrogen-3,4-quinones are endogenous carcinogenic metabolites. HES-3′,4′-Q was previously shown to react with deoxyguanosine to form the depurinating adduct 3′-OH-HES-6′-N7Gua by 1,4-Michael addition [Jan S-T, Devanesan PD, Stack DE, Ramanathan R, Byun J, Gross ML, et al. Metabolic activation and formation of DNAadducts of hexestrol,a synthetic nonsteroidal carcinogenic estrogen. Chem Res Toxicol 1998;11:412–9.]. We report here formation of the depurinating adduct 3′-OH-HES-6′-N3Ade by reaction of HES-3′,4′-Q with Ade by 1,4-Michael addition. The structure of the N3Ade adduct was established by NMR and MS. We also report here formation of the depurinating 3′-OH-HES-6′-N7Gua and 3′-OH-HES-6′-N3Ade adducts by reaction of HES-3′,4′-Q with DNA or by activation of 3′-OH-HES by tyrosinase, lactoperoxidase, prostaglandin H synthase or 3-methylcholanthrene-induced rat liver microsomes in the presence of DNA. The N3Ade adduct was released instantaneously from DNA, whereas the N7Gua adduct was released with a half-life of approximately 3 h. Much lower (<1%) levels of unidentified stable adducts were detected in the DNA from these reactions. These results are similar to those obtained by reaction of endogenous catechol estrogen-3,4-quinones with DNA. The similarities extend to the instantaneously-depurinating N3Ade adducts and relatively slowly-depurinating N7Gua adducts. The endogenous estrogens, estrone and estradiol, their 4-catechol estrogens and HES are carcinogenic in the kidney of Syrian golden hamsters. These results suggest that estrone (estradiol)-3,4-quinones and HES-3′,4′-Q are the ultimate carcinogenic metabolites of the natural and synthetic estrogens, respectively. Reaction of the electrophilic quinones by 1,4-Michael addition with DNA at the nucleophilic N-3 of Ade and N-7 of Gua is suggested to be the major critical step in tumor initiation by these compounds.

Slow loss of deoxyribose from the N7deoxyguanosine adducts of estradiol-3,4-quinone and hexestrol-3′,4′-quinone.: Implications for mutagenic activity

A variety of evidence has been obtained that estrogens are weak tumor initiators. A major step in the multi-stage process leading to tumor initiation involves metabolic formation of 4-catechol estrogens from estradiol (E 2) and/or estrone and further oxidation of the catechol estrogens to the corresponding catechol estrogen quinones. The electrophilic catechol quinones react with DNA mostly at the N-3 of adenine (Ade) and N-7 of guanine (Gua) by 1,4-Michael addition to form depurinating adducts. The N3Ade adducts depurinate instantaneously, whereas the N7Gua adducts depurinate with a half-life of several hours. Only the apurinic sites generated in the DNA by the rapidly depurinating N3Ade adducts appear to produce mutations by error-prone repair. Analogously to the catechol estrogen-3,4-quinones, the synthetic nonsteroidal estrogen hexestrol-3′,4′-quinone (HES-3′,4′-Q) reacts with DNA at the N-3 of Ade and N-7 of Gua to form depurinating adducts. We report here an additional similarity between the natural estrogen E 2 and the synthetic estrogen HES, namely, the slow loss of deoxyribose from the N7deoxyguanosine (N7dG) adducts formed by reaction of E 2-3,4-Q or HES-3′,4′-Q with dG. The half-life of the loss of deoxyribose from the N7dG adducts to form the corresponding 4-OHE 2-1-N7Gua and 3′-OH-HES-6′-N7Gua is 6 or 8 h, respectively. The slow cleavage of this glycosyl bond in DNA seems to limit the ability of these adducts to induce mutations.

The Role of Endogenous Catechol Quinones in the Initiation of Cancer and Neurodegenerative Diseases

Publisher Summary This chapter explores the role of endogenous catechol quinones in the initiation of cancer and neurodegenerative diseases. Several lines of evidence point to the major role of endogenous catechol quinones in the etiology of cancer and neurodegenerative diseases. The role of catechol estrogen-3,4-quinones in the initiation of breast cancer is very clear. The rapidly-depurinating N3Ade adducts result in a burst of apurinic sites that overwhelm the repair machinery of the cell and generate tumorigenic mutations by error-prone repair. In contrast, repair of the apurinic sites that are formed by the slow depurination of N7Gua adducts can proceed correctly and leads to very few mutations. Mutations at Ade bases accumulate in breast cancer cells, presumably through this mechanism. This pathway of activation for endogenous estrogens is mirrored by the activation of the synthetic estrogens hexestrol and DES. Evolution of fundamental concepts and principles of chemical carcinogenesis are elaborated in this chapter. The chapter explains the mechanism of tumor initiation by PAHs. Formation of estrogen metabolites, conjugates and DNA adducts is described in the chapter. Imbalance in estrogen homeostasis and unifying mechanism of initiation of cancer by endogenous and synthetic estrogens are elaborated as well.

Spectral characterization of catechol estrogen quinone (CEQ)-derived DNA adducts and their identification in human breast tissue extract.

Estrogens, including the natural hormones estrone (E(1)) and estradiol (E(2)), are thought to be involved in tumor induction. Catechol estrogen quinones (CEQ) derived from 4-hydroxyestrone (4-OHE(1)) and 4-hydroxyestradiol (4-OHE(2)) react with DNA and form depurinating N7Gua and N3Ade adducts that might be responsible for tumor initiation (Cavalieri, E. L., et al. (2000) J. Natl. Cancer Inst. Monogr. 27, 75). Current detection limits for the CEQ-derived DNA adducts by high-performance liquid chromatography with multichannel electrochemical detection are in the picomole range. To improve the limit of detection (LOD) for CEQ-derived DNA adducts, spectrophotometric monitoring was investigated. Spectroscopic studies of 4-OHE(1)-1-N3Ade, 4-OHE(1)-1-N7Gua, 4-OHE(2)-1-N3Ade, and 4-OHE(2)-1-N7Gua adduct standards were performed at 77 and 300 K. Upon laser excitation at 257 nm, the 4-OHE(1)- and 4-OHE(2)-derived N7Gua and N3Ade adducts are strongly phosphorescent at T = 77 K. No phosphorescence was observed at 300 K. Both N3Ade and N7Gua adduct types have weak phosphorescence origin bands near 383 and 385 nm, respectively. The corresponding phosphorescence lifetimes are 1.11 +/- 0.05 and 0.37 +/- 0.05 s. The LOD, based on phosphorescence measurements, is in the low femtomole range. The concentration LOD is approximately 10(-9) M, i.e., similar to that recently obtained for CEQ-derived N-acetylcysteine conjugates (Jankowiak, R., et al. (2003) Chem. Res. Toxicol. 16, 304). The LOD in capillary electrophoresis (CE) with field-amplified sample stacking and absorbance detection is about 3 x 10(-8) M. To verify whether CEQ-derived DNA adducts are formed in humans or not, tissue extracts from two breast cancer patients were analyzed by CE interfaced with room temperature absorption and low temperature (laser-excited) phosphorescence spectroscopies. For the first time, formation of CEQ-derived DNA adducts is shown in humans. For example, the level of 4-OHE(1)-1-N3Ade in the breast tissue extract from a patient with breast carcinoma (8.40 +/- 0.05 pmol/g of tissue) is larger by a factor of about 30 than that in the breast tissue sample from a woman without breast cancer (0.25 +/- 0.05 pmol/g of tissue). In contrast, similar amounts of 4-OHE(2)-1-N3Ade were observed in both types of tissue. Although more breast tissue samples from women with and without breast cancer need to be studied, these results suggest that the N3Ade adducts could serve as biomarkers to predict the risk of breast cancer.