Anthony Dipple

Reactivity and Tumorigenicity of Bay-Region Diol Epoxides Derived from Polycyclic Aromatic Hydrocarbons

During the past decade substantial progress has been made in elucidating factors that determine the tumorigenic activity of bay-region diol epoxides, major ultimate carcinogenic metabolites derived from polycyclic aromatic hydrocarbons. Neither high nor low chemical reactivity of the diol epoxides (as measured by rates of uncatalyzed solvolysis) is required for high tumorigenic response. In contrast, aspects of molecular structure such as conformation and absolute configuration strongly influence tumorigenic activity. The role of conformation is illustrated by the observation that those diol epoxides whose hydroxyl groups are pseudoaxial are weak or inactive as tumorigens. Absolute configuration is an important determinant of biological activity of bay-region diol epoxides: in all cases studied to date, the predominantly formed (R,S)-diol-(S,R)-epoxides are generally the most tumorigenic of the four metabolically possible configurational isomers. In the course of investigating the effects of structural factors on tumorigenic activity, we identified the (4R,3S)-diol-(2S,1R)-epoxide of benzo(c)phenanthrene as the most potent tumorigen (in initiation-promotion experiments on mouse skin) of the diol epoxides studied to date. Studies of all four configurationally isomeric diol epoxides derived from benzo(c)phenanthrene led to the striking observation that these diol epoxides exhibit an exceptionally high efficiency of covalent binding, relative to hydrolysis, when allowed to react with calf thymus DNA in aqueous solution. Thus, these diol epoxides should provide an excellent tool for the detailed study of such binding. When the four isomeric benzo(c)phenanthrene diol epoxides are compared, there appears to be no simple correlation between tumorigenic response and either the extent of binding to DNA or the major types of deoxyribonucleoside adducts formed. Deoxyribonucleoside adducts of benzo(c)phenanthrene diol epoxide have also been identified from the DNA of cultured rodent embryo cells after treatment of the cells with tritium-labeled benzo(c)phenanthrene. The distribution of adducts is consistent with predominant metabolic formation of the (4R,3S)-diol-(2S,1R)-epoxide; deoxyadenosine is the major site in the cellular DNA attacked by this epoxide, just as it is in DNA in solution. Further experiments are in progress which we hope will identify more subtle aspects of the DNA binding of benzo(c)phenanthrene diol epoxides that may be uniquely correlated with their tumorigenic activity.

MECHANISM OF ACTION OF FOOD-ASSOCIATED POLYCYCLIC AROMATIC HYDROCARBON CARCINOGENS

The polycyclic aromatic hydrocarbon carcinogens are formed in the inefficient combustion of organic matter and contaminate foods through direct deposition from the atmosphere or during cooking or smoking of foods. These potent carcinogens and mutagens require metabolism to dihydrodiol epoxide metabolites in order to express their biological activities. In vitro studies show that these reactive metabolites can react with the bases in DNA with different specificities depending upon the hydrocarbon from which they are derived. Thus, the more potent carcinogens react more extensively with adenine residues in DNA than do the less potent carcinogens, with the result that mutation at A . T base pairs is enhanced for the more potent carcinogens. In the past few years, considerable clarification of the mechanism of metabolic activation have been achieved and the focus for the immediate future is expected to be on how the reactive metabolites actually bring about biological responses.

Separation and identification of positively charged and neutral nucleoside adducts by capillary electrochromatography-microelectrospray mass spectrometry

Capillary electrochromatography (CEC) is shown to be capable of separating mixtures containing both positively charged and neutral styrene oxide–adenosine adducts. In a study of the mechanism of deamination of positively charged 1-(2-hydroxy-1-phenylethyl) adenosine using 18O-labeled water, possible contamination of the chromatographically purified deamination product, 1-(2-hydroxy-1-phenylethyl) inosine, with the positively charged 1-(2-hydroxy-1-phenylethyl) adenosine was observed. Because the deamination product and the presumed contamination have the same molecular weights and similar structures, CEC-microelectrospray mass spectrometry (CEC-μESI/MS) was used to confirm the presence and identity of the suspected impurity. A trace amount of the positively charged 1-(2-hydroxy-1-phenylethyl) adenosine, which could not be observed by either HPLC-UV or CEC-UV, was detected by CEC-μESI/MS. This discriminatory ability of CEC-μESI/MS is attributed to the fact that positive ion mode ESI-MS is a more sensitive detector for a positively charged compound than a UV detector, and that the combination of electroosmotic and electrophoretic flows and hydrophobic interactions with the stationary phase contributes to the separation of the positively charged compound. As a result, the positively charged compound was observed to elute much earlier and with much sharper peaks than the neutral compounds for which electroosmotic flow is the only “pumping” force for the solvent.

Application of mixed mobile phases and a step gradient method in capillary electrochromatography for the separation of isomeric polycyclic aromatic hydrocarbon-deoxyribonucleoside adduct mixtures prepared in vitro

Capillary electrochromatography (CEC) was used for the analysis of mixtures of neutral isomeric compounds derived from the reaction of carcinogenic hydrocarbon (benzo[g]chrysene and 5,6-dimethylchrysene) dihydrodiol epoxides with calf thymus deoxyribonucleic acid (DNA). The CEC analysis demonstrated higher resolution, greater speed and lower analyte consumption than high-performance liquid chromatography (HPLC) in the analysis of the same samples using the same type of stationary phase. Proper selection of the mixed mobile phases was critical for the separation of these complex mixtures with enhanced speed and selectivity. The use of a step gradient further improved the speed of the CEC analysis resulting in electrochromatograms that required only 25-70% of the corresponding HPLC analysis times.

Nitrite-induced mutations in a forward mutation assay: Influence of nitrite concentration and pH☆

The mutagenicity of sodium nitrite at three pHs (7.4, 6.4 and 5.4) has been investigated by treating a shuttle vector plasmid in vitro and assaying for mutations within the supF target gene following replication of the damaged plasmid in human Ad293 cells. Mutation frequency increased with increasing nitrite concentration and decreasing pH. Among treatments from which a significant number of mutants could be collected, the most commonly induced mutations were GC-->AT transitions (44-56% of total mutations), followed by GC-->TA transversions (24-30%). The types of mutations induced at different nitrite concentrations and different pHs were similar, though some differences in their distribution throughout the supF gene were noted. These results provide information on the types of mutations that may be produced following the processing of nitrite-induced DNA damage in human cells.

Lack of p53-Mediated G1 Arrest in Response to an Environmental Carcinogen

The environmental carcinogen, 5-methylchrysene, is a component of cigarette smoke. Its reactive metabolite, anti-5-methylchrysene-1,2-dihydrodiol-3,4-epoxide (5-MeCDE) mainly reacts with the N2-position of guanine residues in the DNA molecule. In this study, we demonstrate that the tumor suppressor protein p53 is stabilized in response to DNA damage by 5-MeCDE but fails to induce the cells’ protective mechanism of G1 arrest in the human breast carcinoma cell line, MCF-7. In contrast, actinomycin D treatment of these cells did lead to G1 arrest. Western analyses revealed that, though both actinomycin D and 5-MeCDE treatment stabilized p53, only trace levels of p21waf1/cip1 were seen in the latter case. This lack of p21waf1/cip1 expression in 5-MeCDE-treated cells is attributed to a stealth characteristic of this environmental carcinogen that allows it to damage DNA and still escape the p53-mediated cellular defense mechanism of G1 arrest.

Mutational spectra for polycyclic aromatic hydrocarbons in the supF target gene.

An SV40-based shuttle vector system was used to identify the types of mutational changes and the sites of mutation within the supF DNA sequence generated by the four stereoisomers of benzo[c]phenanthrene 3,4-dihydrodiol 1,2-epoxide (B[c]PhDE), by racemic mixtures of bay or fjord region dihydrodiol epoxides (DE) of 5-methylchrysene, of 5, 6-dimethylchrysene, of benzo[g]chrysene and of 7-methylbenz[a]anthracene and by two direct acting polycyclic aromatic hydrocarbon carcinogens, 7-bromomethylbenz[a]anthracene (7-BrMeBA) and 7-bromomethyl-12-methylbenz[a]anthracene (7-BrMe-12-MeBA). The results of these studies demonstrated that the predominant type of mutation induced by these compounds is the base substitution. The chemical preference for reaction at deoxyadenosine (dAdo) or deoxyguanosine (dGuo) residues in DNA, which is in general correlated with the spatial structure (planar or non-planar) of the reactive polycyclic aromatic hydrocarbon, is reflected in the preference for mutation at A&z.ccirf;T or G&z.ccirf;C pairs. In addition, if the ability to react with DNA in vivo is taken into account, the relative mutagenic potencies of the B[c]PhDE stereoisomers are consistent with the higher tumorigenic activity associated with non-planar polycyclic aromatic hydrocarbons and their extensive reaction with dAdo residues in DNA. Comparison of the types of mutations generated by polycyclic aromatic hydrocarbons and other bulky carcinogens in this shuttle vector system suggests that all bulky lesions may be processed by a similar mechanism related to that involved in replication past apurinic sites. However, inspection of the distribution of mutations over the target gene induced by the different compounds demonstrated that individual polycyclic aromatic hydrocarbons induce unique patterns of mutational hotspots within the target gene. A polymerase arrest assay was used to determine the sequence specificity of the interaction of reactive polycyclic aromatic hydrocarbons with the shuttle vector DNA. The results of these assays revealed a divergence between mutational hotspots and polymerase arrest sites for all compounds investigated, i.e., sites of mutational hotspots do not correspond to sites where high levels of adduct formation occur, and suggested that some association between specific adducts and sequence context may be required to constitute a premutagenic lesion. A site-specific mutagenesis system employing a single-stranded vector (M13mp7L2) was used to investigate the mutational events a single benzo[a]pyrene or benzo[c]phenanthrene dihydrodiol epoxide-DNA adduct elicits within specific sequence contexts. These studies showed that sequence context can cause striking differences in mutagenic frequencies for given adducts. In addition, these sequence context effects do not originate only from nucleotides immediately adjacent to the adduct, but are also modulated by more distal nucleotides. The implications of these results for mechanisms of polycyclic aromatic hydrocarbon-induced mutagenesis and carcinogenesis are discussed.

DNA adduct levels associated with p53 induction and delay of MCF-7 cells in S phase after exposure to benzo[g]chrysene dihydrodiol epoxide enantiomers.

Optically active isomers of a mammary carcinogen, anti‐benzo[g]chrysene 11,12‐dihydrodiol 13,14‐epoxide, react to different extents with DNA and generate DNA adducts that differ in their stereochemistry. In the study reported here, the effect of these two enantiomers on the progress of human breast carcinoma MCF‐7 cells through the cell cycle was investigated. Each enantiomer caused the cells to accumulate in the S phase, but a higher dose of the benzo[g]chrysene 11S,12R‐dihydrodiol 13R,14S‐epoxide than of its enantiomer was required to induce this effect. Similarly, induction of p53 also required a higher dose of benzo[g]chrysene 11S,12R‐dihydrodiol 13R,14S‐epoxide. Postlabeling studies indicated that the latter enantiomer also caused less modification of MCF‐7 cell DNA for a given level of exposure than did benzo[g]chrysene 11R,12S‐dihydrodiol 13S,14R‐epoxide. These results suggest that p53 induction and delay in the S phase are similarly related to DNA binding and that a level of binding of the order of 1 adduct per 105 nucleotides is associated with these effects. Mol. Carcinog. 23:115–120, 1998.

Benzo[c]phenanthrene-DNA adducts in mouse epidermis in relation to the tumorigenicities of four configurationally isomeric 3,4-dihydrodiol 1,2-epoxides.

P-Postlabeling assays were used to monitor the binding to epidermal DNA that resulted from the application of each of the four configurational isomers of benzo[c]phenanthrene 3,4-dihydrodiol 1,2-epoxide to mouse skin in vivo. For three of these configurational isomers, there was a reasonable correlation between the relative level of binding to epidermal DNA and the known tumorigenic effects of these compounds. However, for the 4(S),3(R)-dihydrodiol 2(S),1(R)-epoxide, the tumorigenic response was considerably greater in relation to the level of DNA modification than was the case for the other isomers. This greater tumorigenic response was consistent with previous observations indicating that this isomer was more mutagenic, at equivalent levels of DNA modification, than the other two tumorigenic dihydrodiol epoxides. Additionally, the 4(S),3(R)-dihydrodiol 2(S),1(R)-epoxide reacts with DNA to generate predominantly (approximately 80%) adducts on the amino group of adenine residues. These findings might imply a greater intrinsic biological effect of such adenine adducts with respect to the other major adduct formed on the amino group of guanine residues.

Effect of aflatoxin B1-8,9-epoxide-DNA adducts on transcription of a supF gene fragment

A linearized template, obtained from the vector pGEM-3Zf(+) containing a supF gene fragment, was treated with aflatoxin B1-8,9-epoxide (AFB1 epoxide) and transcription in vitro was then studied. The template functions of both strands of the supF gene were similarly inhibited as shown by transcription with both T7 and SP6 RNA polymerases. This inhibition was dose-dependent and affected the elongation step more extensively than the initiation step. Gel electrophoretic analysis of RNA formed by T7 RNA polymerase indicated that template treated with different AFB1 epoxide doses yielded the same three major truncated RNA fragments. Sequence analysis showed that these major sites of RNA truncation occurred in the vicinity of adjacent guanine residues in the template.