DNA polymerase-mediated nucleotide incorporation adjacent to hydrocarbon-deoxyadenosine and hydrocarbon-deoxyguanosine adducts

To examine the effect of DNA adducts on nucleotide incorporation by DNA polymerase at 3' neighboring bases, synthetic oligonucleotides (16mers) containing a purine at position 13 from the 3' end and any one of the four possible bases at position 12 were prepared and reacted with 7-bromomethylbenz[a]anthracene. Using HPLC, unmodified oligonucleotide was separated from oligonucleotide containing a single adduct, at either an adenine or a guanine residue. These products were annealed with a 32P 5'-end labeled primer (11mer) and incubated with modified T7 DNA polymerase (Sequence, version 2.0) in the presence of deoxyribonucleoside 5'-triphosphates. Analysis by gel electrophoresis showed that unmodified oligonucleotide template allowed the primer to be rapidly extended to the entire length of the template. However, the presence of an adduct caused primer extension to stop at the base 3' to the adduct. While correct base pairing occurred at this termination site with most adducted templates, there was a high frequency of misincorporation of guanine opposite a thymine located 3' to an adenine adduct. This result suggest that some bulky carcinogen--DNA adducts may lead to base mismatches at neighboring bases.     

DNA polymerase action on bulky deoxyguanosine and deoxyadenosine adducts

In order to determine how individual hydrocarbon-DNA adducts give rise to specific mutations, a single-stranded oligonucleotide, 5'-T8GT10AT8C2T4CT3CT-3', was reacted with the carcinogen 7-bromomethylbenz[a]anthracene which generates both deoxyguanosine and deoxyadenosine adducts in DNA. The products were separated by HPLC to yield unmodified oligonucleotide and oligonucleotide modified either at the single guanine, or at the single adenine, residue. Incubation of these products with 32P-5'-end-labeled primer, 5'-AGA3GA4G2-3', modified T7 DNA polymerase (Sequenase) and deoxyribonucleoside-5'-triphosphates followed by gel electrophoretic analysis indicated that unmodified oligonucleotide template allowed the primer to be rapidly extended to give species of the same length as the template (40 nucleotides) and of 41 nucleotides in length. However, primer extension for the templates containing the guanine and adenine adducts was held up initially (1 min) at the nucleotide preceding the adduct. At longer times (up to 15 min) a nucleotide was added opposite the adduct and, to a lesser extent, another nucleotide was added beyond this. Some full-length oligonucleotide was also synthesized with these carcinogen-modified templates. When synthesis was allowed to proceed only to the nucleotide preceding the adduct, and this template-extended primer complex incubated with individual nucleotide triphosphates plus Sequenase, it was found that deoxyadenosine residues were most readily incorporated opposite the adduct irrespective of whether it was a deoxyguanosine or deoxyadenosine adduct. These results, which suggest that G.C----T.A and A.T----T.A transversions would be the mutagenic consequences of formation of bulky hydrocarbon adducts at guanines and adenines respectively, are consistent with the most frequent hydrocarbon-induced mutational changes reported thus far.     

Translesional synthesis on DNA templates containing site-specifically placed deoxyadenosine and deoxyguanosine adducts formed by the plant carcinogen aristolochic acid

Synthetic oligonucleotides (18-mers) containing either a singledeoxyadenosine residue or a single deoxyguanosine residue weretreated with aristolochic acid I (AAI) or aristolochic acidII (AAII), the main components of theplant carcinogen aristolochicacid (AA). These reactions resulted in the formation of site-specificallyadducted oligonucleotides containing the two known AAI—DNAadducts (dA—AAI, dG—AAI) or the two known AAII—DNAadducts (dA—AAII, dG—AAII) at position 15 from the3'end. Using HPLC chromatography, the oligonucleotides werepurified and subsequently shown to contain the adducts of interestby ³²P-postlabelling. The adducted oligonucleotides were usedas templates in primer (11-mer) extension reactions catalysedby modified bacteriophage T7 DNA polymerase (Sequenase). Regardlessof the type of DNA adduct examined, DNA synthesis was blockedpredominantly (80–90%) at the nucleotide 3' to each adduct,although primer extension to the full length of the templatewas noted with unmodified control templates. However, 15 nucleotideproducts, indicating blocking of DNA synthesis after incorporationof a nucleotide opposite the adduct and translesional synthesisproducts were formed in all cases in different amounts, dependingon the adduct structure. When a 14-mer primer together withhigh dNTP concentrations was used to examine nucleotide incorporationdirectly across from the four different purine adducts we foundthat the deoxyadenosine adducts (dA–AAI and dA–AAII)allowed incorporation of dAMP and dTMP equally well, whereasthe deoxyguanosine adducts (dG–AAI and dG–AAII)allowed preferential incorporation of dCMP. Molecular dynamicsimulations showed that the aristolactam moiety of all adductsexhibit a strong stacking, with the adenine residue at the 3'end of the 14-mer primer. These studies demonstrate that allAA purine adducts provide severe blocks to DNA replication andthat the guanine adducts may not be very efficient mutageniclesions. In contrast, the translesional bypass past adenineadducts of the aristolochic acids suggests a mutagenic potentialresulting from dAMP incorporation by polymerase. AT     

Accurate in vitro translesion synthesis by Escherichia coli DNA polymerase I (large fragment) on a site-specific, aminofluorene-modified oligonucleotide

We have measured the accuracy of in vitro synthesis by DNA polymerase I (large fragment) during translesion synthesis past an aminofluorene (AF) adduct. These studies were carried out using a site-specifically modified template which contained a single AF adduct. The template was prepared by first modifying the lone guanine in a 17 base long oligonucleotide and extensively purifying and characterizing this product. The modified 17mer was then ligated to a synthetic duplex to produce a 31 nucleotide long template strand containing the AF adduct annealed to a 14mer, such that the 3'-hydroxyl primer terminus was four nucleotides before the modified guanine. Synthesis on this template by DNA polymerase I efficiently bypassed the AF adduct and produced full-length duplex 31mers. T7 DNA polymerase, on the other hand, was unable to utilize the AF-modified template though it was active on an identical unmodified one. The strand synthesized by DNA polymerase I was then separated from the modified strand, annealed to a complementary oligonucleotide, and the resulting heteroduplex cloned into M13. Each of the 49 clones isolated had sequences which indicated that cytidine had been incorporated opposite the AF-modified guanine.     

Using polymerase arrest to detect DNA binding specificity of aristolochic acid in the mouse H-ras gene

The distribution of DNA adducts formed by the two main components, aristolochic acid I (AAI) and aristolochic acid II (AAII), of the carcinogenic plant extract aristolochic acid (AA) was examined in a plasmid containing exon 2 of the mouse c-H-ras gene by a polymerase arrest assay. AAI and AAII were reacted with plasmid DNA by reductive activation and the resulting DNA adducts were identified as the previously characterized adenine adducts (dA-AAI and dA-AAII) and guanine adducts (dG-AAI and dG-AAII) by the (32)P-post-labeling method. In addition, a structurally unknown adduct was detected in AAII-modified DNA and shown to be derived from reaction with cytosine (dC-AAII). Sites at which DNA polymerase progress along the template was blocked were assumed to be at the nucleotide 3' to the adduct. Polymerase arrest spectra showed a preference for reaction with purine bases in the mouse H-ras gene for both activated compounds, consistent with previous results that purine adducts are the principal reaction products of AAI and AAII with DNA. Despite the structural similarities among AAI-DNA and AAII-DNA adducts, however, the polymerase arrest spectra produced by the AAs were different. According to the (32)P-post-labeling analyses reductively activated AAI showed a strong preference for reacting with guanine residues in plasmid DNA, however, the polymerase arrest assay revealed arrest sites preferentially at adenine residues. In contrast, activated AAII reacted preferentially with adenine rather than guanine residues and to a lesser extent with cytosine but DNA polymerase was arrested at guanine as well as adenine and cytosine residues with nearly the same average relative intensity. Thus, the polymerase arrest spectra obtained with the AA-adducted ras sequence do not reflect the DNA adduct distribution in plasmid DNA as determined by (32)P-post-labeling. Arrest sites of DNA polymerase associated with cytosine residues confirmed the presence of a cytosine adduct in DNA modified by AAII. For both compounds adduct distribution was not random; instead, regions with adduct hot spots and cold spots were observed. Results from nearest neighbor binding analysis indicated that flanking pyrimidines displayed the greatest effect on polymerase arrest and therefore on DNA binding by AA.     

Spectroscopic characteristics and site I/site II classification of cis and trans benzo[a]pyrene diolepoxide enantiomer-guanosine adducts in oligonucleotides and polynucleotides

The highly tumorigenic isomer (+)-7,8-dihydroxy-anti-9, 10-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene [(+)-anti-BPDE] and its non-tumorigenic enantiomer (-)-anti-BPDE are known to react predominantly with the exocyclic amino group (N2) of deoxyguanine in DNA and to form adducts of different conformations. The spectroscopic characteristics (UV absorbance, fluorescence and circular dichroism) of stereochemically defined (+)-trans, (-)-trans, (+)-cis and (-)-cis d(5'-CACATGBPDETACAC) adducts in the single-stranded form, or complexed with the complementary strand d(5'-GTGTACATGTG) in aqueous solution, were investigated. The spectroscopic characteristics of the double-stranded d(5'-CACATGBPDETACAC).d(5'-GTGTACATGTG) adducts can be interpreted in terms of two types of conformations. In site I-type conformations, there is an approximately 10 nm red shift in the absorption maxima, which is attributed to significant pyrenyl residue-base interactions; in site II-type adducts, the red shift is only approximately 2-3 nm, and the pyrene ring system is located at external, solvent-exposed binding sites. The spectroscopic characteristics of the BPDE-modified duplexes are of the site II type for the (+)- and (-)-trans, and of the site I type for the (+)- and (-)-cis adducts. In adducts derived from the binding of (+)-anti-BPDE to poly(dG-dC).(dG-dC) and poly(dG).(dC), the trans/cis BPDE-N2-dG adduct ratio is 6 +/- 1; in the case of (-)-anti-BPDE this ratio is only 0.4 +/- 0.1 and 0.6 +/- 0.15 in poly(dG-dC).(dG-dC) and poly(dG).(dC) respectively. The spectroscopic properties of these BPDE-modified polynucleotide adducts are consistent with those of the BPDE-modified oligonucleotide complexes; the cis adducts are correlated with site I adduct conformations, while the trans adducts are of the site II type. The correlations between adduct characteristics and biological activities of the two BPDE enantiomers are discussed.     

Preparation and isolation of adducts in high yield derived from the binding of two benzo[a]pyrene-7,8-dihydroxy-9,10-oxide stereoisomers to the oligonucleotide d(ATATGTATA)

The reaction of the (+)- and (-)-enantiomers of BDPE trans-7,8-dihydroxy-anti-9,10-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene) with the oligodeoxynucleotide d(ATATGTATA) in aqueous buffer solutions gives rise predominantly to trans and cis addition products at the exocyclic amino group of the single deoxyguanosine residue. The trans/cis ratios are 7:1 in the case of (+)-BPDE, and 2:1 in the case of (-)-BPDE, while the reaction yields correspond to 34 and 15% respectively, of modified strands. These relatively high reaction efficiencies, at least for this particular type of oligonucleotide sequence, offer the possibilities of synthesizing relatively large amounts of well-defined covalent BPDE-oligonucleotide adducts (with different sequences of nucleotides flanking the modified base) for detailed spectroscopic and biochemical studies.     

Reduced nucleotide excision repair and GSTM1-null genotypes influence anti-B[a]PDE-DNA adduct levels in mononuclear white blood cells of highly PAH-exposed coke oven workers

It is important to identify the potential genetic-susceptible factors that are able to modulate individual responses to exposure to carcinogenic polycyclic aromatic hydrocarbons (PAHs). In the present study we evaluated the influence of four polymorphisms of nucleotide excision repair (NER) genes [xeroderma pigmentosum-C (XPC)-PAT +/-, xeroderma pigmentosum-A (XPA) 5' non-coding region-A23G, XPD-exon 23 A35931C Lys751Gln, xeroderma pigmentosum-D (XPD)-exon 10 G23591A Asp312Asn] and that of glutathione S-transferase mu1 (GSTM1-active or -null) on benzo[a]pyrene diol epoxide (B[a]PDE)-DNA adduct levels from the lympho-monocyte fraction (LMF) of highly PAH benzo[a]pyrene (B[a]P)-exposed Polish coke oven workers (n = 67, 67% current smokers) with individual urinary post-shift excretion of 1-pyrenol exceeding the proposed biological exposure index (BEI) (2.28 micromol/mol creatinine). The bulky (+/-)-r-7,t-8-dihydroxy-t-9,10-oxy-7,8,9,10-tetrahydrobenzo[a]pyrene (anti-B[a]PDE)-DNA adduct levels were detected by high-performance liquid chromatography (HPLC)/fluorescence analysis and genotypes by polymerase chain reaction. We found that workers with the low DNA repair capacity of XPC-PAT+/+ and XPA-A23A genotypes had significantly increased anti-B[a]PDE-DNA adduct levels (Mann-Whitney U-test, z = 2.24, P = 0.02 and z = 2.65, P = 0.01). Moreover, DNA adducts were also raised in workers without GSTM1 activity (GSTM1-null genotype) (Mann-Whitney U-test, z = 2.25, P = 0.0246). Workers with unfavourable XPC-PAT+/+ and XPA-A23A NER genotypes, alone (approximately 65% of workers) or combined with GSTM1-null genotype (approximately 75% of workers) were in the tertile with the highest adduct level, i.e. >4.11 adducts/10(8) nt (chi2 = 5.85, P = 0.0156 and chi2 = 5.40, P = 0.01). The increase in anti-B[a]PDE-DNA adduct levels (ln values) was significantly related in a multiple linear regression analysis to PAH exposure (i.e. urinary post-shift excretion of 1-pyrenol) (t = 2.61, P = 0.0115), lack of GSTM1 activity (t = 2.41, P = 0.0192) and to low DNA repair capacity of the XPC-PAT+/+ genotype (t = 2.34, P = 0.0226). The influence of the XPA-A23A genotype was not evident in this statistical analysis, and no associations with XPD polymorphisms, dietary habits or tobacco smoking were found. The modulation of anti-B[a]PDE-DNA adducts in the LMF by GSTM1-null and some low-activity NER genotypes may be considered as a potential genetic susceptibility factor capable of modulating individual responses to PAH (B[a]P) genotoxic exposure and the consequent risk of cancer in coke oven workers.     

Unrepaired fjord region polycyclic aromatic hydrocarbon-DNA adducts in ras codon 61 mutational hot spots

The fjord region diol-epoxide metabolites of polycyclic aromatic hydrocarbons display stronger tumorigenic activities in rodent studies than comparable bay region diol-epoxides, but the molecular basis for this difference between fjord and bay region derivatives is not understood. Here we tested whether the variable effects of these genotoxic metabolites of polycyclic aromatic hydrocarbons may result from different DNA repair reactions. In particular, we compared the repairability of DNA adducts formed by bay region benzo[a]pyrene (B[a]P) diol-epoxides and the structurally similar but significantly more tumorigenic fjord region diol-epoxide metabolites of benzo[c]phenanthrene (B[c]Ph). For that purpose, we incorporated both types of polycyclic aromatic hydrocarbon adducts into known hot spot sites for carcinogen-induced proto-oncogene activation. Synthetic DNA substrates were assembled using a portion of human N-ras or H-ras that includes codon 61, and stereospecific B[a]P or B[c]Ph adducts were synthesized on adenine N6 at the second position of these two ras codon 61 sequences. DNA repair was determined by incubating the site-directed substrates in human cell extracts, followed by electrophoretic visualization of radiolabeled oligonucleotide excision products. These cell-free assays showed that all tested bay region B[a]P-N6-dA adducts are removed by the human nucleotide excision repair system, although excision efficiency varied with the particular stereochemical configuration of each B[a]P residue. In contrast, all fjord region B[c]Ph-N6-dA adducts located in the identical sequence context and with exactly the same stereochemical properties as the corresponding B[a]P lesions were refractory to the nucleotide excision repair process. These findings indicate that the exceptional tumorigenic potency of B[c]Ph or related fjord region diol-epoxides may be attributed, at least in part, to slow repair of the stable base adducts deriving from the reaction of these compounds with DNA.     

Inhibition of benzo[a]pyrene-DNA adduct formation by Aloe barbadensis Miller

The antigenotoxic and chemopreventive effect of Aloe barbadensis Miller (polysaccharide fraction) on benzo[a]pyrene (B[a]P)-DNA adducts was investigated in vitro and in vivo. Aloe showed a time-course and dose- dependent inhibition of [3H]B[a]P-DNA adduct formation in primary rat hepatocytes (1x10(6) cells/ml) treated with [3H]B[a]P (4 nmol/ml). At concentrations of 0.4-250 microg/ml aloe, the binding of [3H]B[a]P metabolites to rat hepatocyte DNA was inhibited by 9.1-47.9%. Also, in rat hepatocytes cultured for 3-48 h with aloe (250 microg/ml) and [3H]B[a]P (4 nmol/ml), [3H]B[a]P-DNA adducts were significantly reduced by 36% compared with [3H]B[a]P alone. Aloe also inhibited cellular uptake of [3H]B[a]P in a dose-dependent manner at a concentration of 0.4-250 microg/ml by 6.3-34.1%. After a single oral administration of B[a]P to male ICR mice (10 mg/mouse), benzo[a]pyrene diol epoxide I (BPDE-I)-DNA adduct formation and persistence for 16 days following daily treatment with aloe (50 mg/mouse) were quantitated by enzyme- linked immunosorbent assay using monoclonal antibody 8E11. In this animal model, BPDE-I-DNA adduct formation was significantly inhibited in various organs (liver, kidney, forestomach and lung) (P < 0.001). When mice were pretreated with aloe for 16 days before B[a]P treatment, inhibition of BPDE-I-DNA adduct formation and persistence was enhanced. Glutathione S-transferase activity was slightly increased in the liver but cytochrome P450 content was not affected by aloe. These results suggest that the inhibitory effect of aloe on BPDE-I-DNA adduct formation might have a chemopreventive effect by inhibition of B[a]P absorption.      

Identification of (+) and (-) anti benzo[a]pyrene dihydrodiol epoxide-nucleic acid adducts by the 32P-postlabeling assay

Purine deoxyribonucleoside 3'-phosphates were reacted with the (+)- and (-)-enantiomers of the anti dihydrodiol epoxide of benzo[a]pyrene. Products from cis and trans opening of the epoxide ring were separated by HPLC and they were identified by comparison of their CD spectra with those known for the corresponding nucleoside adducts. Thereafter, the eight known benzo[a]pyrene-purine deoxyribonucleoside-3'-phosphate adducts were postlabeled with [32P]ATP and T4 kinase and the positions of these individual bisphosphates were mapped by TLC. Though all eight adducts migrated to the same general region of the thin layer plates, the four possible adducts from each enantiomeric dihydrodiol epoxide were resolved.     

The influence of inhibitors on the repair of benzo[a]pyrene-damaged DNA in hamster tracheal epithelial cells

We investigated, in a cloned hamster tracheal epithelial cell line HTE-B, the effects of inhibitors of DNA topoisomerase, novobiocin and nalidixic acid; of DNA polymerase, 1-beta-arabinofuranosylcytosine (ara-C) and 2',3'-dideoxythymidine; of ribonucleotide reductase, hydroxyurea; and of poly(ADP-ribose)synthetase, 3-aminobenzamide, upon the removal of benzo[a]pyrene adducted to DNA [B[a]P--DNA]. A substantial reduction in the rate of removal of the polycyclic hydrocarbon-adducts occurred when nalidixic acid was added to the HTE-B cells that had been previously incubated with B[a]P for 8 h. Novobiocin produced a similar, but less marked, effect. The rate of disappearance of the individual B[a]P--DNA adducts was measured by analysis of the h.p.l.c. profiles. Of the 5 major adducts observed under the h.p.l.c. conditions, 4 were reduced in control cells to 30% of the original levels by 24 h after removal of the B[a]P from the medium; adduct 5 was almost completely removed. In the presence of nalidixic acid, during the 24 h repair period, only the removal of adduct 5 was unimpaired; the removal of the other 4 adducts was significantly retarded. On the other hand, 3-aminobenzamide addition did not affect the rate of removal of B[a]P--DNA adducts from the HTE-B cells. We employed the combinations of ara-C and dideoxythymidine or ara-C and hydroxyurea to allow the accumulation of single strand breaks after incubation of the HTE-B cells with B[a]P. These breaks were assayed by alkaline elution analysis. Inclusion of these inhibitors during the 2 h after removal of the B[a]P from the medium resulted in the accumulation of 4-5 single strand breaks/10(10) daltons of HTE-B DNA. This compares with a minimum estimate of the number of adducts removed during this period of 3 adducts/10(7) daltons. This discrepancy may indicate that the majority of lesions are not repaired by a pathway sensitive to polymerase inhibitors. In the presence of 3-aminobenzamide, we routinely observed a 10% increase in the alkaline elution of the DNA obtained from B[a]P-treated cells (1-2 breaks/10(10) daltons). Our results indicate that an excision repair process may be involved in the removal of at least some of the B[a]P-induced damage to DNA. However, the repair of the multiple adducts is complex and may involve pathways other than classical excision repair.     

Chemical stability of oligonucleotides containing the acetylated and deacetylated adducts of the carcinogen N-2-acetylaminofluorene

We have prepared and characterized the single-stranded oligonucleotideheptamer 5'-ATCCGTC-3' in which the lone guanine of the oligonucleotideis modified at the C8 position with either the acetylated ordeacetylated form of the carcinogenic adduct 2-aminofluorene.These two lesions represent the two major adducts formed uponthe in vivo administration of the potent experimental carcinogenN-2-acetylaminofluorene. The stability of the adducts was comparedby analyzing the oligonucleotide for strand scission or depurinationby polyacrylamide gel etectrophoresis following treatment undereither neutral, acidic or basic conditions or incubation inthe presence of piperidine. The results show that both adductsare stable near neutral pH but that the deacetylated adductis less stable than the acetylated adduct to either bask oracidic conditions. Both adducts are equally susceptible to piperidine.The method of analysis described here could prove useful forcharacterizing other adduct structures, thus providing a generalprocedure to determine the stability of a variety of lesionsin DNA.     

Syntheses of DNA adducts of two heterocyclic amines, 2-amino-3-methyl-9H-pyrido[2,3-b]indole (MeAalphaC) and 2-amino-9H-pyrido[2,3-b]indole (AalphaC) and identification of DNA adducts in organs from rats dosed with MeAalphaC

2-Amino-3-methyl-9H-pyrido[2,3-b]indole (MeAalphaC) and 2-amino-3-methyl-9H-pyrido[2,3-b]indole (AalphaC) are mutagenic and carcinogenic heterocyclic amines formed during ordinary cooking. MeAalphaC and AalphaC are activated to mutagenic metabolites by cytochrome P450-mediated N-oxidation to the corresponding N2-OH derivatives. The proximate mutagenic N2-OH derivatives of MeAalphaC and AalphaC did not react with deoxynucleosides or DNA. However, upon acetylation with acetic anhydride both reacted with 2'-deoxyguannosine and 3'-phospho-2'-deoxyguanosine, resulting in one adduct each, but not with other nucleosides or nucleotides. The adducts were identified as N2-(2'-deoxyguanosin-8-yl)-MeAalphaC, N2-(2'-deoxyguanosin-8-yl)-AalphaC, N2-(3'-phospho-2'-deoxyguanosin-8-yl)-MeAalphaC and N2-(3'-phospho-2'-deoxyguanosin-8-yl)-AalphaC by comparison with adducts of known structure obtained by reaction of the parent amines with acetylated guanine N3-oxide. N2-OH-MeAalphaC and N2-OH-AalphaC reacted with calf thymus DNA after addition of acetic anhydride. 32P-postlabelling analysis of modified DNA showed one major adduct co-migrating with N2-(3',5'-diphospho-2'-deoxyguanosin-8-yl)-MeAalphaC and N2-(3',5'-diphospho-2'-deoxyguanosin-8-yl)-AalphaC, respectively. Some minor adducts presumed to be undigested oligomers were also detected. 32P-postlabelling analysis of DNA from several organs of rats dosed orally with MeAalphaC showed that in vivo N2-(2'-deoxyguanosin-8-yl)-MeAalphaC also was the major adduct formed. Relative adduct level in DNA isolated from the liver of the rats was about 50.40 adducts/10(9) nt. The adduct levels were approximately 4-fold lower in the colon and the heart and approximately 12-fold lower in the kidney of the rats.     

Properties of aflatoxin-DNA adducts formed by photoactivation and characterization of the major photoadduct as aflatoxin-N7-guanine

Aflatoxin-DNA adducts were formed by microsomal and photoactivation, using nick-translated DNA labelled with 14C in each of the DNA bases [3H]AFB1 and [3H]AFB2. DNA adducts were analysed by HPLC of DNA hydrolysates, and were characterized as double labelled peaks with specific retention times. The only AF-DNA adducts which were detected in significant amounts were guanine adducts, irrespective of the type of aflatoxin used or the mode of its activation. No stable adduct with adenine, cytosine or thymine was detected. UV spectra, proton NMR spectroscopy and mass spectrometry are consistent with the notion that the major AFB1-DNA photoadduct is the N7-guanine adduct. This report provides direct evidence for the existence of aflatoxin photoadducts formed on DNA.     

Exposure-route-dependent DNA adduct formation by polycyclic aromatic hydrocarbons

Understanding the kinetics of aromatic-DNA adducts in target tissues and white blood cells (WBC) would enhance the applicability of DNA adducts in WBC as surrogate source of DNA in biomonitoring studies. In the present study, rats were acutely exposed to benzo[a]pyrene (B[a]P; 10 mg/kg body wt) via intratracheal (i.t.), dermal and oral administration. DNA adducts were analyzed in relevant target organs and WBC by nuclease P1 enriched (32)P-post-labeling at 1, 2, 4, 11 and 21 days after exposure. Additionally, the internal dose was assessed by measurement of urinary excretion of 3-hydroxy-B[a]P (3-OH-B[a]P). Total B[a]P-DNA adduct levels in WBC were highest after i.t. and oral administration, whereas DNA adducts were hardly detectable after dermal exposure. Highest adduct levels were reached at 2 days after exposure. In lung tissue, DNA adduct levels reached maximal values at 2 days and were highest after i.t., oral and dermal exposure, respectively. DNA adduct levels were significantly lower in WBC as compared with lung. Nonetheless, overall B[a]P-DNA adduct levels in WBC were significantly correlated with those in lung. In target organs, highest DNA adduct levels were observed in skin after topical application, and lowest in stomach after oral administration of B[a]P. Furthermore, DNA adduct levels in WBC were correlated with DNA adduct levels in skin after dermal exposure and stomach after oral administration of B[a]P. Two-fold higher levels of 3-OH-B[a]P were excreted after i.t. administration of B[a]P as compared with dermal or oral exposure. Urinary 3-OH-B[a]P concentrations were correlated with DNA adduct levels at the site of B[a]P application. Overall, it can be concluded that aromatic-DNA adduct levels in WBC can be applied as a surrogate source of DNA for the site of application of B[a]P and reflect binding to lung DNA, independently of the exposure route.