Oxidative degradation of N-Nitrosopyrrolidine by the ozone/UV process: Kinetics and pathways.

N-Nitrosopyrrolidine (NPYR) is an emerging contaminant in drinking water and wastewater. The degradation kinetics and mechanisms of NPYR degradation by the O3/UV process were investigated and compared with those of UV direct photolysis and ozonation. A synergistic effect of ozone and UV was observed in the degradation of NPYR due to the accelerated production of OH• by ozone photolysis. This effect was more pronounced at higher ozone dosages. The second-order rate constants of NPYR reacting with OH• and ozone was determined to be 1.38 (± 0.05) × 10(9) M(-1) s(-1) and 0.31 (± 0.02) M(-1) s(-1), respectively. The quantum yield by direct UV photolysis was 0.3 (± 0.01). An empirical model using Rct (the ratio of the exposure of OH• to that of ozone) was established for NPYR degradation in treated drinking water and showed that the contributions of direct UV photolysis and OH• oxidation on NPYR degradation were both significant. As the reaction proceeded, the contribution by OH• became less important due to the exhausting of ozone. Nitrate was the major product in the O3/UV process by two possible pathways. One is through the cleavage of nitroso group to form NO• followed by hydrolysis, and the other is the oxidation of the intermediates of amines by ozonation.

Mesoporous carbon nitride for adsorption and fluorescence sensor of N-nitrosopyrrolidine.

A metal-free mesoporous carbon nitride (MCN) was investigated for the first time as an adsorbent for N-nitrosopyrrolidine (NPYR), which is one of the nitrosamine pollutants. Under the same condition, the adsorption capability of the MCN was found to be higher than that of the MCM-41. Since the adsorption isotherm was consistent with Langmuir and Freundlich model equations, it was suggested that the adsorption of NPYR molecules on the MCN occurred in the form of mono-molecular layer on the heterogeneous surface sites. It was proposed that MCN with suitable adsorption sites was beneficial for the adsorption of NPYR. The evidence on the interaction between the NPYR molecules and the MCN was supported by fluorescence spectroscopy. Two excitation wavelengths owing to the terminal N-C and N=C groups were used to monitor the interactions between the emission sites of the MCN and the NPYR molecules. It was confirmed that the intensity of the emission sites was quenched almost linearly with the concentration of NPYR. This result obviously suggested that the MCN would be applicable as a fluorescence sensor for detection of the NPYR molecules. From the Stern-Volmer plot, the quenching rate constant of terminal N-C groups was determined to be ca. two times higher than that of the N=C groups on MCN, suggesting that the terminal N-C groups on MCN would be the favoured sites interacted with the NPYR. Since initial concentration can be easily recovered, the interactions of NPYR on MCN were weak and might only involve electrostatic interactions.

Spanish honeys protect against food mutagen-induced DNA damage.

BACKGROUND: Honey contains a variety of polyphenols and represents a good source of antioxidants, while the human diet often contains compounds that can cause DNA damage. The present study investigated the protective effect of three commercial honey samples of different floral origin (rosemary, heather and heterofloral) from Madrid Autonomic Community (Spain) as well as an artificial honey on DNA damage induced by dietary mutagens, using a human hepatoma cell line (HepG2) as in vitro model system and evaluation by the alkaline single-cell gel electrophoresis or comet assay. RESULTS: Rosemary, heather and heterofloral honeys protected against DNA strand breaks induced by N-nitrosopyrrolidine (NPYR), benzo(a)pyrene (BaP) and 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP), but none of the honey samples tested prevented DNA strand breaks induced by N-nitrosodimethylamine (NDMA). Heterofloral and heather (unifloral) honeys with higher phenolic content were most effective in protecting HepG2 cells against DNA damage induced by food mutagens. Heterofloral honey was more protective against NPYR and BaP, while heather honey was more protective against PhIP. Artificial honey did not show a protective effect against DNA damage induced by any of the food mutagens tested, indicating that the protective effects of honeys could not be due to their sugar components. CONCLUSION: The results suggest that the protective effect of three kinds of Spanish honey of different floral origin could be attributed in part to the phenolics present in the samples. Honeys with higher phenolic content, i.e. heather and heterofloral honeys, were most effective in protecting against food mutagen-induced DNA damage in HepG2 cells. In addition, a possible synergistic effect between other minor honey components could also be involved.

Evolution of research on the DNA adduct chemistry of N-nitrosopyrrolidine and related aldehydes.

This perspective reviews our work on the identification of DNA adducts of N-nitrosopyrrolidine and some related aldehydes. The research began as a focused project to investigate mechanisms of cyclic nitrosamine carcinogenesis but expanded into other areas, as aldehyde metabolites of NPYR were shown to have their own diverse DNA adduct chemistry. A total of 69 structurally distinct DNA adducts were identified, and some of these, found in human tissues, have provided intriguing leads for investigating carcinogenesis mechanisms in humans due to exposure to both endogenous and exogenous agents.

Adsorption of nitrosamines by mesoporous zeolite.

On the basis of a study of the adsorption of zeolite and mesoporous silica, we attempted to create a hierarchical structure in the new nitrosamines trapper. Thus, mesoporous HZSM-5 zeolite was fabricated through impregnating a structure-directing agent into the as-synthesized MCM-41 followed by dry-gel conversion to transform amorphous silica to zeolite crystal. The texture of mesoporous ZSM-5 was tailored by adjusting the Si/Al ratio in the MCM-41 source and the thermal treatment time. The resulting samples were characterized by N(2) adsorption to evaluate their textural properties. One volatile nitrosamine, N-nitrosopyrrolidine (NPYR), was used as probe molecule in instantaneous adsorption to survey the function of the resulting composites. Adsorptions of N'-nitrosonornicotine (NNN) in dichloromethane solution and tobacco-specific nitrosamines (TSNA) in tobacco-extract solution were also utilized for the same purpose. As expected, mesoporous zeolite exhibits a good adsorption capacity in laboratory tests, superior to either microporous zeolite or mesoporous silica, providing a valuable candidate for controlling nitrosamines in the environment.

The photodissociation dynamics of N-nitrosopyrrolidine from the first and second excited singlet states studied by velocity map imaging.

The photodissociation reaction of N-nitrosopyrrolidine isolated and cooled in a supersonic jet has been studied following excitation to the S(1) and S(2) electronic states. The nascent NO (X[combining tilde] (2)Pi((1/2),3/2), v, j) radicals were ionized by state-selective (1 + 1)-REMPI via the A(2)Sigma(+) state. The angularly resolved velocity distribution of these ions was measured with the velocity-map imaging (VMI) technique. Photodissociation from S(1) produces NO in the vibrational ground state and the pyrrolidine radical in the electronic ground state 1 (2)B. About 73% of the excess energy is converted into kinetic energy of the fragments. The velocity distribution shows a strong negative anisotropy (beta = -0.9) in accordance with the npi*-character of the S(0)--> S(1) transition. An upper limit for the N-NO dissociation energy of (14 640 +/- 340) cm(-1) is determined. We conclude that photodissociation from S(1) occurs very fast on a completely repulsive potential energy surface. Excitation into the S(2)pipi*-state leads to a bimodal velocity distribution. Two dissociation channels can be distinguished which show both positive anisotropy (beta = 1.3 and 1.6) but differ considerably in the total kinetic energy and the rotational energy of the NO fragment. We assign one channel to the direct dissociation on the S(2) potential energy surface, leading to pyrrolidine radicals in the excited electronic state 1 (2)A. The second channel leads to pyrrolidine in the electronic ground state 1 (2)B, presumably after crossing to the S(1) state via a conical intersection.

Mass spectrometric analysis of a cyclic 7,8-butanoguanine adduct of N-nitrosopyrrolidine: comparison to other N-nitrosopyrrolidine adducts in rat hepatic DNA.

The well established rat hepatocarcinogen N-nitrosopyrrolidine (NPYR, 1) requires metabolic activation to DNA adducts to express its carcinogenic activity. Among the NPYR-DNA adducts that have been identified, the cyclic 7,8-butanoguanine adduct 2-amino-6,7,8,9-tetrahydro-9-hydroxypyrido[2,1-f]purine-4(3H)-one (6) has been quantified using moderately sensitive methods, but its levels have never been compared to those of other DNA adducts of NPYR in rat hepatic DNA. Therefore, in this study, we developed a sensitive new LC-ESI-MS/MS-SRM method for the quantitation of adduct 6 and compared its levels to those of several other NPYR-DNA adducts formed by different mechanisms. The new method was shown to be accurate and precise, with good recoveries and low fmol detection limits. Rats were treated with NPYR by gavage at doses of 46, 92, or 184 mg/kg body weight and sacrificed 16 h later. Hepatic DNA was isolated and analyzed for NPYR-DNA adducts. Adduct 6 was by far the most prevalent, with levels ranging from about 900-3000 micromol/mol Gua and responsive to dose. Levels of adducts formed from crotonaldehyde, a metabolite of NPYR, were about 0.2-0.9 micromol/mol dGuo, while those of adducts resulting from reaction with DNA of tetrahydrofuranyl-like intermediates were in the range of 0.01-4 micromol/mol deoxyribonucleoside. The results of this study demonstrate that, among typical NPYR-DNA adducts, adduct 6 is easily the most abundant in hepatic DNA. Since previous studies have shown that it can be detected in the urine of NPYR-treated rats, the results suggest that it is a potential candidate as a biomarker for assessing human exposure to and metabolic activation of NPYR.

A cell-microelectronic sensing technique for profiling cytotoxicity of chemicals.

A cell-microelectronic sensing technique is developed for profiling chemical cytotoxicity and is used to study different cytotoxic effects of the same class chemicals using nitrosamines as examples. This technique uses three human cell lines (T24 bladder, HepG2 liver, and A549 lung carcinoma cells) and Chinese hamster ovary (CHO-K1) cells in parallel as the living components of the sensors of a real-time cell electronic sensing (RT-CES) method for dynamic monitoring of chemical toxicity. The RT-CES technique measures changes in the impedance of individual microelectronic wells that is correlated linearly with changes in cell numbers during t log phase of cell growth, thus allowing determination of cytotoxicity. Four nitrosamines, N-nitrosodimethylamine (NDMA), N-nitrosodiphenylamine (NDPhA), N-nitrosopiperidine (NPip), and N-nitrosopyrrolidine (NPyr), were examined and unique cytotoxicity profiles were detected for each nitrosamine. In vitro cytotoxicity values (IC(50)) for NDPhA (ranging from 0.6 to 1.9 mM) were significantly lower than the IC(50) values for the well-known carcinogen NDMA (15-95 mM) in all four cell lines. T24 cells were the most sensitive to nitrosamine exposure among the four cell lines tested (T24>CHO>A549>HepG2), suggesting that T24 may serve as a new sensitive model for cytotoxicity screening. Cell staining results confirmed that administration of the IC(50) concentration from the RT-CES experiments inhibited cell growth by 50% compared to the controls, indicating that the RT-CES method provides reliable measures of IC(50). Staining and cell-cycle analysis confirmed that NDPhA caused cell-cycle arrest at the G0/G1 phase, whereas NDMA did not disrupt the cell cycle but induced cell death, thus explaining the different cytotoxicity profiles detected by the RT-CES method. The parallel cytotoxicity profiling of nitrosamines on the four cell lines by the RT-CES method led to the discovery of the unique cytotoxicity of NDPhA causing cell-cycle arrest. This study demonstrates a new approach to comprehensive testing of chemical toxicity.

Genotoxicity screening for N-nitroso compounds. Electrochemical and electrochemiluminescent detection of human enzyme-generated DNA damage from N-nitrosopyrrolidine.

We report for the first time voltammetric/electrochemiluminescent sensors applied to predict genotoxicity of N-nitroso compounds bioactivated by human cytochrome P450 enzymes.

Identification of adducts formed in the reaction of alpha-acetoxy-N-nitrosopyrrolidine with deoxyribonucleosides and DNA.

N-Nitrosopyrrolidine (NPYR) is a well-established hepatocarcinogen in the rat. NPYR requires metabolic activation by cytochrome P450-catalyzed alpha-hydroxylation to express its carcinogenic activity. This produces alpha-hydroxyNPYR (2), which spontaneously ring opens to 4-oxobutanediazohydroxide (4), a highly reactive intermediate, which may itself modify DNA or yield a cascade of electrophiles that react with DNA to produce adducts. Multiple dGuo adducts formed in this reaction have been previously characterized, but there are no examples of adducts formed with other DNA nucleobases. In this study, we used alpha-acetoxyNPYR (3) as a stable precursor to 2 and 4. Compound 3 was allowed to react with DNA. The DNA was enzymatically hydrolyzed to deoxyribonucleosides, and the products were analyzed by LC-ESI-MS and LC-ESI-MS/MS. Reactions of 3 with individual deoxyribonucleosides were also carried out. The products were identified by their MS, UV, and NMR spectra as N6-(tetrahydrofuran-2-yl)dAdo (16) and N4-(tetrahydrofuran-2-yl)dCyd (17) in addition to the previously characterized N2-(tetrahydrofuran-2-yl)dGuo (13). Unstable dThd adducts were also formed. Further characterization of the adducts was achieved by NaBH3CN reduction of the reaction mixtures of 3 with deoxyribonucleosides or DNA. This produced N6-(4-hydroxybut-1-yl)dAdo (21), N4-(4-hydroxybut-1-yl)dCyd (22), O2-(4-hydroxybut-1-yl)dThd (23), O4-(4-hydroxybut-1-yl)dThd (24), and 3-(4-hydroxybut-1-yl)dThd (25). Adducts 21 and 22 were characterized by their spectral properties, while the dThd adducts 23-25 were identified by comparison to synthetic standards. The results of this study demonstrate that 3 forms adducts with dAdo, dCyd, and dThd in DNA, in addition to the previously characterized dGuo adducts. These newly characterized standards can be used to investigate DNA adduct formation in rats treated with NPYR.

Analysis of adducts in hepatic DNA of rats treated with N-nitrosopyrrolidine.

N-Nitrosopyrrolidine (NPYR) is a hepatocarcinogen in rats. It is metabolically activated by cytochrome P450 enzymes in the liver leading to the formation of 4-oxobutanediazohydroxide (4) and related intermediates that react with DNA to form adducts. Because DNA adducts are thought to be critical in carcinogenesis by NPYR, we analyzed hepatic DNA of NPYR-treated rats for several adducts: N2-(tetrahydrofuran-1-yl)dGuo (N2-THF-dGuo, 13), N6-THF-dAdo (14), N4-THF-dCyd (17), and dThd adducts 15 and 16. The rats were treated with NPYR in the drinking water, 600 ppm for 1 week, or 200 ppm for 4 or 13 weeks. Hepatic DNA was isolated, enzymatically hydrolyzed, and analyzed by capillary LC-ESI-MS-SIM, which indicated the presence of adducts 13, 14, and 17. Because these adducts can be unstable at the deoxyribonucleoside level, further analyses were carried out using DNA treated with NaBH3CN, which converts adducts 13-17 to N2-(4-hydroxybut-1-yl)dGuo [N2-(4-HOB)dGuo, 18], N6-(4-HOB)dAdo (19), O2-(4-HOB)dThd (20), O4-(4-HOB)dThd (21), and N4-(4-HOB)dCyd (22). [15N]-Labeled analogues of adducts 18-20 and 22 were synthesized and used in this analysis, which was performed by capillary LC-ESI-MS/MS-SRM. Convincing evidence for the presence of adducts 18-22 was obtained. Levels of 18, 19, 20, and 21 were (mumol/mol dGuo): 3.41-5.39, 0.02-0.04, 2.56-3.87, and 2.28-5.05, respectively. Compound 22 was not quantified due to interfering peaks. These results provide the first evidence for tetrahydrofuranyl-substituted DNA adducts in the livers of rats treated with NPYR. The finding of dAdo and dThd adducts is of particular interest since previous studies have shown that NPYR causes mutations at AT base pairs in DNA of rat liver.

Synthesis and aqueous chemistry of alpha-acetoxy-N-nitrosomorpholine: reactive intermediates and products.

[reaction: see text] Alpha-acetoxy-N-nitrosomorpholine (7) has been synthesized starting by the anodic oxidation of N-acetylmorpholine in methanol. The 55% yield of N-nitrosomorpholinic acid, after cyanide-for-methoxy group exchange and hydrolysis, is an improvement of approximately 10-fold over our original 10-step method, and this is readily converted to 7. A study of the kinetics of decomposition of 7 in aqueous media at 25 degrees C and 1 M ionic strength was conducted over the pH range from 1 to 12. The reaction exhibited good first-order kinetics at all values of pH, and a plot of the log of k0, the buffer-independent rate constant for decomposition, against pH indicated that a pH-independent reaction dominates in the neutral pH region whereas acid- and base-catalyzed reactions dominate in the low and high pH regions, respectively. Reaction at neutral pH in the presence of increasing concentrations of acetate ion results in a decrease in the value of k(obsd), to an apparent limiting value consistent with a common-ion inhibition by the capture, and competing base-catalyzed hydration of, an N-nitrosiminium ion intermediate. The 100-fold smaller reactivity of 7 at neutral pH compared with its carbon analogue, alpha-acetoxy-N-nitrosopiperidine, is also consistent with the electronic effects expected for such a reaction. The dinitrophenylhydrazones derived from pH-independent and acid-catalyzed reactions are identical in kind and quantity, within experimental error, to those observed in the decay of alpha-hydroxy-N-nitrosomorpholine. Decay of 7 in the presence of benzimidazole buffer results in the formation of 2-(2-(1H-benzo[d]imidazol-1-yl)ethoxy)acetaldehyde (12) and 2-(1H-benzo[d]imidazol-1-yl)ethanol (13). Independent synthesis and study of 12 indicates that it is stable at 80 degrees C in 0.1 M DCl, but it slowly decomposes to 13 in neutral and basic media in a reaction that is stimulated by primary and secondary amines, but not by tertiary amines and carbonate buffer. The benzimidazole trapping studies and those of the stability of 12 indicate the possibility that metabolic activation of N-nitrosomorpholine by hydroxylation alpha to the nitroso nitrogen can result in the deposition of a metastable ethoxyacetaldehyde adduct on the heteroatoms of DNA.

Cytochrome P450 2A-catalyzed metabolic activation of structurally similar carcinogenic nitrosamines: N'-nitrosonornicotine enantiomers, N-nitrosopiperidine, and N-nitrosopyrrolidine.

N'-Nitrosonornicotine (NNN) and N-nitrosopiperidine (NPIP) are potent esophageal and nasal cavity carcinogens in rats and pulmonary carcinogens in mice. N-Nitrosopyrrolidine (NPYR) induces mainly liver tumors in rats and is a weak pulmonary carcinogen in mice. These nitrosamines may be causative agents in human cancer. alpha-Hydroxylation is believed to be the key activation pathway in their carcinogenesis. P450 2As are important enzymes of nitrosamine alpha-hydroxylation. Therefore, a structure-activity relationship study of rat P450 2A3, mouse P450 2A4 and 2A5, and human P450 2A6 and 2A13 was undertaken to compare the catalytic activities of these enzymes for alpha-hydroxylation of (R)-NNN, (S)-NNN, NPIP, and NPYR. Kinetic parameters differed significantly among the P450 2As although their amino acid sequence identities were 83% or greater. For NNN, alpha-hydroxylation can occur at the 2'- or 5'-carbon. P450 2As catalyzed 5'-hydroxylation of (R)- or (S)-NNN with Km values of 0.74-69 microM. All of the P450 2As except P450 2A6 catalyzed (R)-NNN 2'-hydroxylation with Km values of 0.73-66 microM. (S)-NNN 2'-hydroxylation was not observed. Although P450 2A4 and 2A5 differ by only 11 amino acids, they were the least and most efficient catalysts of NNN 5'-hydroxylation, respectively. The catalytic efficiencies (kcat/Km) for (R)-NNN differed by 170-fold whereas there was a 46-fold difference for (S)-NNN. In general, P450 2As catalyzed (R)- and (S)-NNN 5'-hydroxylation with significantly lower Km and higher kcat/Km values than NPIP or NPYR alpha-hydroxylation (p <0.05). Furthermore, P450 2As were better catalysts of NPIP alpha-hydroxylation than NPYR. P450 2A4, 2A5, 2A6, and 2A13 exhibited significantly lower Km and higher kcat/Km values for NPIP than NPYR alpha-hydroxylation (p <0.05), similar to previous reports with P450 2A3. Taken together, these data indicate that critical P450 2A residues determine the catalytic activities of NNN, NPIP, and NPYR alpha-hydroxylation.

Preferential metabolic activation of N-nitrosopiperidine as compared to its structural homologue N-nitrosopyrrolidine by rat nasal mucosal microsomes.

N-Nitrosopiperidine (NPIP) is a potent rat nasal carcinogen whereas N-nitrosopyrrolidine (NPYR), a hepatic carcinogen, is weakly carcinogenic in the nose. NPIP and NPYR may be causative agents in human cancer. P450-catalyzed alpha-hydroxylation is the key activation pathway by which these nitrosamines elicit their carcinogenic effects. We hypothesize that the differences in NPIP and NPYR metabolic activation in the nasal cavity contribute to their differing carcinogenic activities. In this study, the kinetics of tritium-labeled NPIP or NPYR alpha-hydroxylation mediated by Sprague-Dawley rat nasal olfactory or respiratory microsomes were investigated. To compare alpha-hydroxylation rates of the two nitrosamines, tritiated 2-hydroxytetrahydro-2H-pyran and 2-hydroxy-5-methyltetrahydrofuran, the major NPIP alpha-hydroxylation products, and tritiated 2-hydroxytetrahydrofuran, the major NPYR alpha-hydroxylation product, were quantitated by HPLC with UV absorbance and radioflow detection. These microsomes catalyzed the alpha-hydroxylation of NPIP more efficiently than that of NPYR. K(M) values for NPIP were lower as compared to those for NPYR (13.9-34.7 vs 484-7660 muM). Furthermore, catalytic efficiencies (V(max)/K(M)) of NPIP were 20-37-fold higher than those of NPYR. Previous studies showed that P450 2A3, present in the rat nose, also exhibited this difference in catalytic efficiency. For both types of nasal microsomes, coumarin (100 muM), a P450 2A inhibitor, inhibited NPIP and NPYR alpha-hydroxylation from 63.8 to 98.5%. Furthermore, antibodies toward P450 2A6 inhibited nitrosamine alpha-hydroxylation in these microsomes from 68.8 to 78.4% whereas antibodies toward P450 2E1 did not inhibit these reactions. Further immunoinhibition studies suggest some role for P450 2G1 in NPIP metabolism by olfactory microsomes. In conclusion, olfactory and respiratory microsomes from rat nasal mucosa preferentially activate NPIP over NPYR with P450 2A3 likely playing a key role. These results are consistent with local metabolic activation of nitrosamines as a contributing factor in their tissue-specific carcinogenicity.

Reactions of alpha-acetoxy-N-nitrosopyrrolidine with deoxyguanosine and DNA.

We investigated the reactions of alpha-acetoxy-N-nitrosopyrrolidine (alpha-acetoxyNPYR) with dGuo and DNA. Alpha-acetoxyNPYR is a stable precursor to the major proximate carcinogen of NPYR, alpha-hydroxyNPYR (3). Our goal was to develop appropriate conditions for the analysis of DNA adducts of NPYR formed in vivo. Products of the alpha-acetoxyNPYR-dGuo reactions were analyzed directly by HPLC or after treatment of the reaction mixtures with NaBH3CN. Products of the alpha-acetoxyNPYR-DNA reactions were released by enzymatic or neutral thermal hydrolysis of the DNA, then analyzed by HPLC. Alternatively, the DNA was treated with NaBH3CN prior to hydrolysis and HPLC analysis. The reactions of alpha-acetoxyNPYR with dGuo and DNA were complex. We have identified 13 products of the dGuo reaction-6 of these were characterized in this reaction for the first time. They were four diastereomers of N2-(3-hydroxybutylidene)dGuo (20, 21), 7-(N-nitrosopyrrolidin-2-yl)Gua (2), and 2-(2-hydroxypyrrolidin-1-yl)deoxyinosine (12). Adducts 20 and 21 were identified by comparison to standards produced in the reaction of 3-hydroxybutanal with dGuo. Adduct 2 was identified by its spectral properties while adduct 12 was characterized by comparison to an independently synthesized standard. With the exception of adduct 2, all products of the dGuo reactions were also observed in the DNA reactions. The major product in both the dGuo and DNA reactions was N2-(tetrahydrofuran-2-yl)dGuo (10), consistent with previous studies. Several other previously identified adducts were also observed in this study. HPLC analysis of reaction mixtures treated with NaBH3CN provided improved conditions for adduct identification, which should be useful for in vivo studies of DNA adduct formation by NPYR.

Reactions of alpha-acetoxy-N-nitrosopyrrolidine and crotonaldehyde with DNA.

alpha-Acetoxy-N-nitrosopyrrolidine (alpha-acetoxyNPYR) is a stable precursor to alpha-hydroxyNPYR, the initial product of metabolism and proposed proximate carcinogen of NPYR. Crotonaldehyde (2-butenal) is a metabolite of NPYR and also a mutagen and carcinogen. Both alpha-acetoxyNPYR and crotonaldehyde are known to form DNA adducts, but these reactions have not been completely characterized. In previous studies, we detected substantial amounts of unidentified radioactivity in hydrolysates of DNA that had been reacted with radiolabelled alpha-acetoxyNPYR. We have now characterized these products as 2-hydroxytetrahydrofuran, the cyclic form of 4-hydroxybutanal, and paraldol, the dimer of 3-hydroxybutanal. They were characterized by comparison with standards and by comparison of their derived 2,4-dinitrophenylhydrazones with standards. [3H]H2O was also identified. 2-Hydroxytetrahydrofuran is the major product in neutral thermal hydrolysates of alpha-acetoxyNPYR-treated DNA and is derived predominantly from N2-(tetrahydrofuran-2-yl)deoxyguanosine 8. Paraldol is present to a lesser extent than 2-hydroxytetrahydrofuran in these reactions and is formed from paraldol-releasing adducts, which in turn are produced by the reaction of crotonaldehyde or paraldol, solvolysis products of alpha-acetoxyNPYR, with DNA. Paraldol is a major product in hydrolysates of crotonaldehyde-treated DNA, being present in amounts 100 times greater than those of previously identified adducts. These results provide a more complete picture of the reactions of alpha-acetoxyNPYR with DNA and yield some new insights on possible endogenous DNA adducts formed from crotonaldehyde.

Lactols in hydrolysates of DNA treated with alpha-acetoxy-N-nitrosopyrrolidine or crotonaldehyde.

alpha-Acetoxy-N-nitrosopyrrolidine (alpha-acetoxyNPYR) is a stable precursor to alpha-hydroxyNPYR, the initial product of metabolism and proposed proximate carcinogen of N-nitrosopyrrolidine (NPYR). Crotonaldehyde (2-butenal) is a metabolite of NPYR and also a mutagen and carcinogen. Both alpha-acetoxyNPYR and crotonaldehyde form DNA adducts, but these reactions have not been completely characterized. In previous studies, we detected substantial amounts of unidentified radioactivity in hydrolysates of DNA that had been treated with radiolabeled alpha-acetoxyNPYR. In this study, we have characterized these products as 2-hydroxytetrahydrofuran, the cyclic form of 4-hydroxybutanal, and paraldol, the dimer of 3-hydroxybutanal. These products were identified by comparison to standards and by conversion to 2,4-dinitrophenylhydrazones. 2-Hydroxytetrahydrofuran is the major product in neutral thermal hydrolysates of alpha-acetoxyNPYR-treated DNA and is derived predominantly from N2-(tetrahydrofuran-2-yl)deoxyguanosine 8. Paraldol is present to a lesser extent than 2-hydroxytetrahydrofuran in these reactions and is formed from paraldol-releasing adducts, which in turn are produced in the reaction of crotonaldehyde, a solvolysis product of alpha-acetoxyNPYR, with DNA. Other products in hydrolysates of alpha-acetoxyNPYR-treated DNA are N7-substituted guanines 5 and 6, cyclic N7-C8 guanines 4, 11, and 12, and 1, N2-propanodeoxyguanosines 9 and 10. Paraldol is a major product in hydrolysates of crotonaldehyde-treated DNA, being present in amounts 100 times greater than those of previously identified adducts 9 and 10. The results of this study provide a more complete picture of the reactions of alpha-acetoxyNPYR with DNA and yield some new insights about possible endogenous DNA adducts formed from crotonaldehyde.

Reactions of alpha-acetoxy-N-nitrosopyrrolidine and alpha-acetoxy-N-nitrosopiperidine with deoxyguanosine: formation of N2-tetrahydrofuranyl and N2-tetrahydropyranyl adducts.

The goal of this study was to compare the reactions of alpha-acetoxy-N-nitrosopyrrolidine (alpha-acetoxyNPYR) and alpha-acetoxy-N-nitrosopiperidine (alpha-acetoxyNPIP) with deoxyguanosine (dG). alpha-AcetoxyNPYR and alpha-acetoxyNPIP are stable precursors to the alpha-hydroxynitrosamines which are formed metabolically from NPYR and NPIP. These alpha-hydroxynitrosamines are believed to be the proximate carcinogens of NPYR and NPIP. NPYR and NPIP, although structurally similar, have remarkably different carcinogenic properties, and a comparison of the reactions of their metabolically activated forms with dG and ultimately DNA could provide insights on their mechanisms of carcinogenicity. Reactions of alpha-acetoxyNPYR and alpha-acetoxyNPIP with dG were carried out at 37 degrees C and pH 7.0. The products were analyzed by HPLC and characterized by their spectral properties and by comparison to standards. In each reaction, one of the major products was a new type of dG adduct: N2-(tetrahydrofuran-2- yl)dG (THF-dG) from alpha-acetoxyNPYR and N2-(3,4,5,6-tetrahydro-2H-pyran-2-yl)dG (THP-dG) from alpha-acetoxyNPIP. THF-dG was synthesized independently by reaction of either 2-chlorotetrahydrofuran or 2,3-dihydrofuran with dG. Similarly, THP-dG was prepared by reaction of 2-chloro-3,4,5,6-tetrahydro-2H-pyran with dG. The structures of THF-dG and THP-dG were established by their UV and 1H-NMR spectra. THF-dG was less stable than THP-dG, but could be readily converted to a stable derivative, N2-(4-hydroxybutyl)dG, by reaction with NaBH4. THF-dG and THP-dG were converted to dG and 2-hydroxytetrahydrofuran or 2-hydroxy-3,4,5,6-tetrahydro-2H-pyran, respectively, upon neutral thermal or acid hydrolysis. This reaction was found to be reversible, with the adducts being produced in substantial amounts by reaction of 2-hydroxytetrahydrofuran or 2-hydroxy-3,4,5,6-tetrahydro-2H-pyran with dG. The latter reaction accounts for part of the THF-dG and THP-dG produced from the alpha-acetoxynitrosamines; stable oxonium ion-derived electrophiles may also be involved in the formation of THF-dG and THP-dG. Comparisons of the yields of various adducts in the reaction of alpha-acetoxyNPYR and alpha-acetoxyNPIP with dG showed some major differences. Whereas yields of THF-dG and THP-dG were similar, adducts formed from open chain diazonium ion or related intermediates were formed more extensively from alpha-acetoxyNPYR than from alpha-acetoxyNPIP. Adducts formed from enal products of the two nitrosamines were also different. Adduct formation as characterized in this study may account for some of the contrasting carcinogenic properties of NPYR and NPIP.