Mutagenicities of styrene oxide derivatives on bacterial test systems: relationship between mutagenic potencies and chemical reactivity

Critical review of styrene genotoxicity focused on the mutagenicity/clastogenicity literature and using current organization of economic cooperation and development guidance

Styrene is an important high production volume chemical used to manufacture polymeric products. In 2018, International Agency for Research on Cancer classified styrene as probably carcinogenic to humans; National Toxicology Program lists styrene as reasonably anticipated to be a human carcinogen. The genotoxicity literature for styrene and its primary metabolite, styrene 7,8-oxide (SO), begins in the 1970s. Organization of Economic Cooperation and Development (OECD) recently updated most genotoxicity test guidelines, making substantial new recommendations for assay conduct and data evaluation for the standard mutagenicity/clastogenicity assays. Thus, a critical review of the in vitro and in vivo rodent mutagenicity/clastogenicity studies for styrene and SO, based on the latest OECD recommendations, is timely. This critical review considered whether a study was optimally designed, conducted, and interpreted and provides a critical assessment of the evidence for the mutagenicity/clastogenicity of styrene/SO. Information on the ability of styrene/SO to induce other types of genotoxicity endpoints is summarized but not critically reviewed. We conclude that when styrene is metabolized to SO, it can form DNA adducts, and positive in vitro mutagenicity/clastogenicity results can be obtained. SO is mutagenic in bacteria and the in vitro mouse lymphoma gene mutation assay. No rodent in vivo mutation studies were identified. SO is clastogenic in cultured mammalian cells. Although the in vitro assays gave positive responses, styrene/SO is not clastogenic/aneugenic in vivo in rodents. In addition to providing updated information for styrene, this review demonstrates the application of the new OECD guidelines for chemicals with large genetic toxicology databases where published results may or may not be reliable. Environ. Mol. Mutagen. 2019. © 2019 Wiley Periodicals, Inc.

Alkylating potential of styrene oxide: reactions and factors involved in the alkylation process

The chemical reactivity of styrene-7,8-oxide (SO), an alkylating agent with high affinity for the guanine–N7 position and a probable carcinogen for humans, with 4-(p-nitrobenzyl)pyridine (NBP), a trap for alkylating agents with nucleophilic characteristics similar to those of DNA bases, was investigated kinetically in water/dioxane media. UV–vis spectrophotometry and ultrafast liquid chromatography were used to monitor the reactions involved. It was found that in the alkylation process four reactions occur simultaneously: (a) the formation of a β-NBP–SO adduct through an SN2 mechanism; (b) the acid-catalyzed formation of the stable α-NBP–SO adduct through an SN2′ mechanism; (c) the base-catalyzed hydrolysis of the β-adduct, and (d) the acid-catalyzed hydrolysis of SO. At 37.5 °C and pH = 7.0 (in 7:3 water/dioxane medium), the values of the respective reaction rate constants were as follows: kalkβ = (2.1 ± 0.3) × 10–4 M–1 s–1, kalkα = (1.0 ± 0.1) × 10–4 M–1 s–1, khydAD = (3.06 ± 0.09) × 10–6 s–1, and khyd = (4.2 ± 0.9) × 10–6 s–1. These values show that, in order to determine the alkylating potential of SO, none of the four reactions involved can be neglected. Temperature and pH were found to exert a strong influence on the values of some parameters that may be useful to investigate possible chemicobiological correlations (e.g., in the pH 5.81–7.69 range, the fraction of total adducts formed increased from 24% to 90% of the initial SO, whereas the adduct lifetime of the unstable β-adduct, which gives an idea of the permanence of the adduct over time, decreased from 32358 to 13313 min). A consequence of these results is that the conclusions drawn in studies addressing alkylation reactions at temperatures and/or pH far from those of biological conditions should be considered with some reserve.

The nonmutagenic (R)- and (S)-beta-(N(6)-adenyl)styrene oxide adducts are oriented in the major groove and show little perturbation to DNA structure

Conformations of (R)-beta-(N(6)-adenyl)styrene oxide and (S)-beta-(N(6)-adenyl)styrene oxide adducts at position X(6) in d(CGGACXAGAAG).d(CTTCTTGTCCG), incorporating codons 60, 61 (underlined), and 62 of the human N-ras protooncogene, were refined from (1)H NMR data. These were designated as the beta-R(61,2) and beta-S(61,2) adducts. A total of 533 distance restraints and 162 dihedral restraints were used for the molecular dynamics calculations of the beta-S(61,2) adduct, while 518 distances and 163 dihedrals were used for the beta-R(61,2) adduct. The increased tether length of the beta-adducts results in two significant changes in adduct structure as compared to the corresponding alpha-styrenyl adducts [Stone, M. P., and Feng, B. (1996) Magn. Reson. Chem. 34, S105-S114]. First, it reduces the distortion introduced into the DNA duplex. For both the beta-R(61,2) and beta-S(61,2) adducts, the styrenyl moiety was positioned in the major groove of the duplex with little steric hindrance. Second, it mutes the influence of stereochemistry at the alpha-carbon such that both the beta-R(61,2) and beta-S(61,2) adducts exhibit similar conformations. The results were correlated with site-specific mutagenesis experiments that revealed the beta-R(61,2) and beta-S(61,2) adducts were not mutagenic and did not block polymerase bypass.

Formation of deaminated products in styrene oxide reactions with deoxycytidine

The reaction of racemic styrene oxide with deoxycytidine under aqueous conditions was studied. The four principal products isolated were a pair of diastereomeric N(4)-(2-hydroxy-1-phenylethyl)deoxycytidines ( approximately 20% of the products) and a pair of diastereomeric 3-(2-hydroxy-2-phenylethyl)deoxyuridines ( approximately 80% of the products). Reactions with optically active styrene oxides allowed the configurations of the 3-(2-hydroxy-2-phenylethyl)deoxyuridines to be assigned, and these structures were confirmed by an independent synthesis from deoxyuridine. Also, it was possible to tentatively assign the configurations of the N(4)-(2-hydroxy-1-phenylethyl)deoxycytidines that had undergone some racemization during the reaction (the ratio of the retained to inverted configuration of the products was approximately 1:7).

Frontier orbital energies, hydrophobicity and steric factors as physical QSAR descriptors of molecular mutagenicity. A review with a case study: MX compounds

A review on QSARs (Quantitative Structure-Activity Relationships) in modelling molecular mutagenicity is given. The importance of hydrophobicity, frontier orbital (HOMO and LUMO) energies and steric factors as physical descriptors of mutagenicity is emphasized. In addition, some possible connections between QSAR models and the general electrophilic theory of genotoxic activity are discussed. As a detailed example, QSARs for the Ames Salmonella typhimurium TA100 mutagenicity of halogenated hydroxyfuranones including MX, one of the most potent bacterial mutagens ever identified, are discussed and a plausible mechanism for their mutagenic activity is proposed.

Deamination and Dimroth rearrangement of deoxyadenosine-styrene oxide adducts in DNA

In reactions between styrene oxide and the ring nitrogen at the 1-position of deoxyadenosine, the epoxide is opened at both the alpha- (benzylic) and beta-carbons. The 1-substituted nucleosides formed are unstable and subsequently undergo either Dimroth rearrangement to give N6-substituted deoxyadenosines or deamination to give 1-substituted deoxyinosines. alphaN6-Substituted compounds are also formed from direct reaction at the exocyclic nitrogen. Kinetic experiments revealed that relative rates of deamination of 1-substituted deoxyadenosine-styrene oxides and 1-substituted adenosine-styrene oxides were similar. However, the rate of Dimroth rearrangement in beta1-substituted adenosine-styrene oxides was approximately 2.3-fold greater than that of beta1-substituted deoxyadenosine-styrene oxides and approximately 1.5-fold greater in alpha1-substituted adenosine-styrene oxides relative to alpha1-substituted deoxyadenosine-styrene oxides. Analysis of the products formed from reactions of styrene oxide with [3H]deoxyadenosine and [3H]deoxyadenosine incorporated into native and denatured DNA showed that the double-helical DNA structure reduced the levels of adducts formed 5-fold relative to denatured DNA but did not present a complete barrier to formation of either N6-substituted deoxyadenosine- or 1-substituted deoxyinosine-styrene oxide adducts in native DNA. Additionally, in denatured and native DNA the product distributions were altered in favor of formation of beta1-substituted deoxyinosine-styrene oxide adducts with respect to reactions of the nucleoside. The ratio of retained to inverted configuration of alphaN6-substituted products was higher in DNA than in nucleoside reactions. These experiments indicate that in addition to the N6-position, the ring nitrogen at the 1-position of deoxyadenosine is available, to some extent, for reaction in native DNA. In styrene oxide-DNA reactions, formation of 1-substituted adenines can lead to deaminated products where both Watson-Crick hydrogen-bonding sites are disrupted.

Aralkylation of guanosine with para-substituted styrene oxides

To probe mechanisms of nucleoside aralkylation, product distributions and product stereochemistries were determined in reactions of optically active p-methyl- and p-bromostyrene oxide with guanosine. The proportion of 7-, N2-, and O6-substituted guanosine products was approximately 0.32:0.62:0.06 in neutral, aqueous reactions with the (R)-p-methylstyrene oxide and approximately 0.85: 0.09:0.04 in reactions with the (R)-p-bromostyrene oxide. The exocyclic positions opened the epoxide at the alpha-carbon. Epoxide ring opening by the nitrogen at the 7-position showed little preference for the alpha- or beta-carbons in reactions with p-methylstyrene oxide. However, the p-bromostyrene oxide favored reaction at the beta-carbon almost 4-fold over reaction at the alpha-carbon. Almost total inversion of stereochemistry was found to occur in reactions at the 7-position. In contrast, the ratio of inversion to retention of configuration in N2- and O6-substituted products was approximately 2:1 and approximately 1:1 for reactions with the p-methylstyrene oxide and approximately 6:1 and approximately 3:1 for reactions with p-bromostyrene oxide, respectively. These experiments suggest that an SN2 mechanism is in effect with reactions at the 7-position, whereas substrates of an increasingly ionic nature are involved in reactions at the N2- and O6-positions, respectively.

Biotransformation of diethenylbenzenes, V. Identification of urinary metabolites of 1,2-diethenylbenzene in the rat

1. Biotransformation of 1,2-diethenylbenzene (1) in rat was studied. Five urinary metabolites were isolated by extraction of acid hydrolysed urine and identified by nmr and mass spectroscopy, namely, 1-(2-ethenylphenyl)ethane-1,2-diol (2) 2-ethenylmandelic acid (3), 2-ethenylphenylglyoxylic acid (4), 2-ethenylphenylacetylglycine (5) N-acetyl-S-[1-(2-ethenylphenyl)-2-hydroxyethyl]cysteine (6) and N-acetyl-S-[2-(2-ethenylphenyl)-2-hydroxy-ethyl]cysteine (7). 2. In addition, minor metabolites, namely, 2-ethenylbenzoic acid (8) and 2-ethenylphenyl-acetic acid (9) were identified by glc-mass spectral analysis of the hydrolysed urine extract treated subsequently with diazomethane, hydroxylamine and a trimethyl-silylating reagent. Several compounds, which could arise from biotransformation of both ethenyl groups in the molecule of 1, were detected but not identified unequivocally. 3. A glucuronide was detected by tlc analysis of urine as a blue spot after spraying with naphthoresorcinol. Compounds showing molecular fragments indicating the glucuronide moiety were also detected by glc-mass spectroscopy in non-hydrolysed urine samples. 4. The total thioether excretion amounted to 5.3 +/- 2.4, 5.1 +/- 3.4 and 5.0 +/- 1.9% of the dose at 500, 300 and 100 mg/kg, respectively (mean +/- SD; n = 5). 5. Like styrene and other diethenylbenzene isomers, 1,2-diethenylbenzene is metabolically activated to a reactive epoxide intermediate, 2-ethenylphenyloxirane (10), which is further converted to the urinary metabolites mentioned above. The main detoxification pathways are hydrolysis to the glycol 2 followed by several oxidation steps, and conjugation with glutathione. The latter reaction is both regioselective and stereoselective. 6. The ratio of mercapturic acids 6:7 was 83:17. Each regioisomer consists of two diastereomers which show distinct resonance signals in the 13C-nmr. The diastereomer ratio was 82:28 and 79:21 for 6 and 7 respectively.

Reaction kinetics of alkyl epoxides with DNA and other nucleophiles

1,2-Epoxy alkanes from C3 to C8 were reacted with DNA, deoxyguanosine and 4-(p-nitrobenzyl) pyridine (NBP). DNA was hydrolyzed at neutral pH to release 7-alkylguanines. The products were analyzed by HPLC. The epoxides reacted largely according to the chain length, shorter epoxides being more reactive. Substitutions through carbon 1 predominated. Reactivity with NBP was almost equal between the epoxides.

Biotransformation of diethenylbenzenes. III: Identification of metabolites of 1,3-diethenylbenzene in rat

1. Biotransformation of 1,3-diethenylbenzene (1) in rat gave four major metabolites, namely, 3-ethenylphenylglyoxylic acid (2), 3-ethenylmandelic acid (3), N-acetyl-S-[2-(3-ethenylphenyl)-2-hydroxyethyl]-L-cysteine (4) and N-acetyl-S-[1-(3-ethenylphenyl)-2-hydroxyethyl]-L-cysteine (5) were isolated from urine and identified by n.m.r. and mass spectrometry. 2. Four minor metabolites, 3-ethenylbenzoic acid (6), 3-ethenylphenylacetic acid (7), 3-ethenylbenzoylglycine (8) and 2-(3-ethenylphenyl)ethanol (9) were identified by g.l.c.-mass spectrometric analysis of urine extract derivatized in two different ways. 3. All identified metabolites are derived from 3-ethenylphenyloxirane (10), a reactive metabolic intermediate. No product of any metabolic transformation of second ethenyl group has been identified. However, several minor unidentified metabolites were detected by g.l.c.-mass spectrometry. 4. Total thioether excretion in 24 h urine after a single i.p. dose of 1 amounted to 28.3 +/- 3.5 dose (mean +/- SD). No significant differences in the thioether fraction were observed in the dose range 100-300 mg/kg. 5. Thioether metabolites consisted mainly of mercapturic acids 4 and 5. The ratio of metabolites 5 to 4 was 62:38. Each mercapturic acid consisted of two diastereomers. Their ratio, as determined by quantitative 13C-n.m.r. measurement was 95:5 and 79:21 for mercapturic acids 4 and 5, respectively.

Structure-activity relationships of epoxides: induction of sister-chromatid exchanges in Chinese hamster V79 cells

Analysis of SCE frequencies in Chinese hamster V79 cells was used to investigate structure-activity relationships of epoxides in mammalian cells. For this purpose the SCE-inducing potency of 58 epoxides was determined. Of these, 16 failed to induce SCE in V79 cells. According to the substitution of the oxirane ring the results show general agreement with results obtained in the Ames test. Mono-substituted epoxides had the highest genotoxic potency compared to di- and tri-substituted epoxides. In detail, there are differences in genotoxic potency between bacteria and mammalian cells which can be explained by differences in the cellular uptake of the compounds and by detoxification reactions.

Epoxides: comparison of the induction of SOS repair in Escherichia coli PQ37 and the bacterial mutagenicity in the Ames test

The genotoxicity of 51 epoxides is studied with the SOS-Chromotest using Escherichia coli PQ37 as tester strain. The results obtained with this test system are compared with results of the Ames test. Out of 51 epoxides, 39 are shown to be mutagenic in Salmonella typhimurium whereas only 27 mutagenic epoxides induced the SOS response in Escherichia coli PQ37.

Mutagenicity of aromatic glycidyl ethers with Salmonella

6 aromatic glycidyl ethers containing naphthyl, biphenyl or benzylphenyl substituents were synthesized. These epoxides together with the commercially available compounds 2-biphenylyl glycidyl ether were examined for dose-mutagenicity relationships using the plate incorporation Ames test with Salmonella typhimurium strains TA100 and TA1535. Structure-mutagenicity relationships were further examined for these compounds and 3 phenyl glycidyl ethers by concurrent testing at a single dose with strain TA100. Meaningful correlations could not be established for the mutagenicity of these epoxides to their molecular volumes, partition values, nor to their reactivities with the model nucleophile, 4-(4-nitrobenzyl) pyridine. However, it was noted that increased conjugated aromatic unsaturation with its resulting planarity led to increased mutagenicity and that this effect decreased when it was further removed from the epoxide moiety.

Glutathione conjugation and bacterial mutagenicity of racemic and enantiomerically pure cis- and trans-methyl epoxycinnamates

This paper describes the ability of racemic, and enantiomerically pure cis- and trans-methyl epoxycinnamates (methyl 3-phenyl-2,3-epoxy-propanoates) to undergo glutathione conjugation and subsequent excretion as mercapturic acid and on the mutagenicities of these epoxy esters in the Ames assay. In incubation mixtures containing rat liver cytosol (9,000 g), the decrease of glutathione due to the epoxy esters occurred enzymatically. The highest glutathione depletion was found for the cis-epoxy cinnamic esters. Adult male rats administered a single i.p. dose of racemic trans- and cis-epoxy cinnamates (0.7 mmol/kg, n = 4) excreted thioethers in urine. Higher urinary thioether excretion was found after the cis-epoxy ester dosing. The structures of the thioether metabolites isolated from the urinary extracts were identified by TLC and confirmed by synthesis and mass spectrometry (FAB+). The thioethers appeared to be hydroxy mercapturic acids. The N-alkylating potential of the racemic epoxy esters was determined using 4-(p-nitrobenzyl)pyridine (= NBP). The trans-epoxy ester appeared to react much better with NBP than the cis-compound. Mutagenic effects of racemic trans-epoxy cinnamate as well as the enantiomerically pure trans-epoxy cinnamates were observed in the Ames test with S. typhimurium strains TA1535, TA1537, TA1538 and TA100 without metabolic activation. No mutagenic responses were detected using any of the epoxy cinnamates with S9 activation. By comparing the mutagenicity and the enzymatically catalyzed glutathione conjugation it follows that the activity of the respective enantiomeric methyl cinnamates goes in the opposite order. Glutathione conjugation plays a protective role in the detoxication in living organism of the potentially toxic methyl epoxy cinnamates.

Depurination and imidazole ring-opening in nucleosides and DNA alkylated by styrene oxide

Styrene-7,8-oxide was reacted with guanosine and deoxyguanosine and four isomeric 7-alkylguanosines were isolated, two of each being substitutions through the alpha and beta carbon of styrene oxide. The diastereomeric adducts imidazole ring-opened at an identical rate but the alpha- and beta-adducts differed (half-lives 90 and 56 min, respectively, pH 10, 24 degrees C). The 7-beta alkyl-deoxyguanosine derivatives ring-opened at a six times slower rate, which was similar to 7-methyldeoxyguanosine. The diastereomeric guanosine products also depurinated at the same rate but the beta-derivatives depurinated faster than the alpha-derivatives (t1/2 35 vs. 79 min, respectively, pH 1, 70 degrees C). The differences in the ring-opening and depurination of the alpha- and beta-isomers corresponded to their respective pK alpha values (7.31-7.32 vs. 7.16-7.19). The 7-alkyldeoxyguanosine derivatives of styrene oxide depurinated equally fast as 7-methyldeoxyguanosine. By contrast, the depurination of 7-alkylguanine was 15 times slower in the single-stranded DNA and 55 times slower in the double-stranded DNA.

Mutagenicity of aryl propylene and butylene oxides with salmonella

10 aryl propylene oxides and 6 aryl butylene oxides were synthesized. Dose-mutagenicity relationships were studied for these compounds and for 1,2-epoxybutane, using both the preincubation and plate incorporation Ames tests with Salmonella typhimurium strains TA100 and TA1535. Structure-mutagenicity relationships were further examined by concurrent testing at single doses with the plate incorporation assay in strain TA100. In both series of compounds, mutagenicity showed very correlation to chemical reactivity, molar volume and partition values. However, all compounds were mutagenic in at least one system with the propylene oxides being more mutagenic than the corresponding butylene oxide derivatives. The naphthyl derivatives in each series were the most mutagenic.

Characterization of reaction products between styrene oxide and deoxynucleosides and DNA

Styrene oxide was reacted with deoxynucleosides and DNA in aqueous buffer at pH 7.4. The products were purified by HPLC, characterized by UV spectroscopy and by chemical ionization mass spectrometry. The main products identified were 7-alkyl-, N2-alkyl- and O6-alkyldeoxyguanosine, 1-alkyl-, and N6-alkyldeoxyadenosine, N4-alkyl-, 3-alkyl- and O2-alkyldeoxycytidine and 3-alkylthymidine. The relative yields of alkylated deoxynucleosides were dG greater than dC greater than dA greater than T. In the reactions of styrene oxide with DNA the dominant product isolated was 7-alkylguanine but N2-alkylguanine was also detected.

DNA adducts in experimental cancer research

The role of DNA adducts in the initiation of cancer is scrutinized in this presentation. Work on the activation of oncogenes, particularly on ras, has provided new evidence to link DNA adducts and tumour formation. Polycyclic hydrocarbons and nitroso compounds can cause activation of ras oncogenes through a defined point mutation. The properties of two DNA binding agents, styrene oxide and cisplatin are discussed. Styrene oxide is a versatile electrophile causing numerous adducts; cisplatin has a high specificity towards guanine-N-7 and cross-link formation. Finally, the relation of specific adducts to carcinogenic potency as defined by TD50 values is investigated. For small alkyl groups, O-alkylation of bases correlates with potency but among others, particularly the bulky carcinogens, 7-alkylguanines appear as correlates of potency. Most such potent agents forming 7-alkylguanines induce depurination and imidazole ring-opening.

Mutagenicity of para-substituted alpha-methylstyrene oxide derivatives with Salmonella

A series of 5 para-substituted alpha-methylstyrene oxide derivatives have been synthesized and together with alpha-methylstyrene oxide as well as styrene oxide have been studied as to their mutagenicity with the TA100 and TA1535 strains of Salmonella typhimurium. A multiple regression analysis model has been developed which describes the mutagenicity of the alpha-methylstyrene oxides in TA100. An increase in van der Waals volume was the most important variable in the model with greater improvement occurring with inclusion of the Hammett values for the para substituents on the compounds. The alpha-methylstyrene oxides were less active alkylating agents with 4-(p-nitrobenzyl)pyridine than styrene oxide and with pyridine all reactivity was at the beta-epoxide carbon. However all the alpha-methylstyrene oxide derivatives, except for the bromo compound where toxicity was evident, showed mutagenicity values either greater or comparable to that of styrene oxide. These studies would indicate that reactivity at the beta-carbon should also be a factor in describing the mutagenicity of the parent styrene oxide series.

Stability of 7-alkyldeoxyguanosines of trichloropropylene oxide, epichlorohydrin and glycidol

Deoxyguanosine was reacted with trichloropropylene oxide (TCPO), epichlorohydrin and glycidol in aqueous solution and the products were isolated by high pressure liquid chromatography (HPLC). For each compound 7-alkyldeoxyguanosine was the main adduct; TPCO reacted about 3 times faster than epichlorohydrin and about 10 times faster than glycidol. The pKa's of the 7-alkyldeoxyguanosines were 6.7, 6.8 and 6.9 for the TCPO-, epichlorohydrin-, and glycidol-adducts, respectively. The respective half-lives of imidazole ring-opening were 6.3, 15 and 27 hrs (pH 8.5, 28 degrees) and those of depurination 1.9, 3.4 and 4.4 hrs (pH 5.5, 28 degrees).

Binding of styrene oxide to amino acids, human serum proteins and hemoglobin

The covalent binding of 3H-styrene oxide to amino acids, and whole human blood was investigated in vitro. After reaction, serum, and red cells were separated, and proteins were digested into amino acids; styrene oxide derivatives were isolated by HPLC. The order of binding to free amino acids was cysteine much greater than histidine greater than lysine greater than serine. In serum proteins and hemoglobin cysteine-derivatives predominated. When styrene oxide was reacted with free cysteine and with proteins two isomers were observed. These were likely to present binding through the alpha and beta carbon of styrene oxide, and their abundance was about 2:1.

Reaction products of styrene oxide with deoxynucleosides and DNA in vitro

The reaction of styrene oxide with deoxynucleosides and DNA were carried out in aqueous conditions at pH 7.4 and in acetic acid, to prepare large quantities of reaction products. The purification of the products were performed by HPLC and characterized by UV spectra in neutral, acid and alkali pH. The main products identified were 7-, N2-, O6-alkyldeoxyguanosine, 1-, N6-alkyldeoxyadenosine, N4-, 3-, and O2-alkyldeoxycytidine. In acetic acid additionally 3-alkyladenine and O4-alkylthymidine were formed. In DNA incubations the dominant product isolated was 7-alkylguanine. N2-guanine was also detected.

Covalent binding of styrene and styrene-7,8-oxide to plasma proteins, hemoglobin and DNA in the mouse

The extent of covalent binding to plasma proteins, hemoglobin and guanine-N-7 in DNA was determined after intraperitoneal administration of radiolabelled styrene and styrene-7,8-oxide to mice. The degree of alkylation increased non-linearly with the dose. It was proportionally higher after the highest doses of styrene-7,8-oxide while the reverse was observed with respect to the ability of styrene to alkylate plasma proteins and DNA. Thus, a dose dependence was indicated in the elimination of both styrene and styrene-7,8-oxide. A comparison of the degree of alkylation of plasma proteins, hemoglobin and guanine-N-7 in DNA suggests that the two compounds are about equally effective as alkylating agents in vivo at moderate dose levels. At high doses styrene-7,8-oxide is the more effective alkylator. The alkylation of DNA in liver, brain and lung after administration of styrene-7,8-oxide exceeded that in spleen and testis.

Mutagenicity and chemical reactivity of epoxidic intermediates of the isoprene metabolism and other structurally related compounds

The mutagenic activities of the epoxidic intermediates of the isoprene biotransformation were investigated using Salmonella typhimurium and compared with those of other structurally related epoxides. The compound 2-methyl-1,2,3,4-diepoxybutane, chemically analogous to the well known carcinogenic 1,2,3,4-diepoxybutane, was found to be as mutagenic as the latter. Moreover, the mutagenic activities of oxiranes were correlated to their alkylating powers towards nicotinamide and to their half-lives for spontaneous hydrolysis. The relationship between alkylating power and mutagenicity was found to hold for the stable epoxides that react mainly by an SN2 substitution mechanism.

DNA binding of [14C]styrene in isolated rat hepatocytes

Incubation of hepatocytes from phenobarbital-pretreated rats with diethylmaleate (DEM) and 1 mM [14C]styrene for 3 to 5 hours did not result in binding of styrene 7,8-oxide (SO) to DNA as determined by ion exchange chromatography of enzymatic digests of DNA. The elution of substantial amounts of radioactivity together with natural nucleosides and bases suggests that styrene is partly metabolized via splitting of the vinyl bond and that incorporation of C1 fragments into DNA is most likely the result of repair DNA synthesis following DNA damage by styrene itself or one of its metabolites.

Formation of phosphodiesters in thymidine monophosphate by styrene oxide

Three products were isolated by high-performance liquid chromatography (HPLC) from the reaction between thymidine-5'-monophosphate (TMP) and styrene oxide in aqueous solution. None of the products was digested by alkaline phosphatase, but each was digested by vernom phosphodiesterase. The digestion products were identified by their mobility in HPLC and UV-spectra as phenylethylene glycol, thymidine, TMP, and hydroxyethylphenyl phosphoric acid, of which phenylethylene glycol and TMP were most abundant.

Reactivity, SCE induction and mutagenicity of benzyl chloride derivatives

Benzyl chloride, benzyl bromide, p-methylbenzyl chloride, and p-nitrobenzyl chloride were used to study chemical reactivity with 4-(p-nitrobenzyl)-pyridine (NBP), and with guanosine in vitro, in relation to mutagenic potency in S. typhimurium and sister chromatid exchange (SCE) induction in CHO cells. Benzyl bromide was found to be the most reactive compound, followed by p-methylbenzyl chloride, benzyl chloride and p-nitrobenzyl chloride. The order of mutagenicity was p-nitrobenzyl chloride much greater than benzyl bromide greater than benzyl chloride approximately equal to p-methylbenzyl chloride. The compounds tested caused base-pair mutations only. The order of SCE-inducing ability decreased as follows: benzyl bromide greater than benzyl chloride approximately equal to p-nitrobenzyl chloride approximately equal to p-methylbenzyl chloride. The particularly high mutagenicity of p-nitrobenzyl chloride in bacteria may be due to reactions other than direct aralkylation, or it may react particularly actively with DNA. Among the other compounds, benzyl bromide was the most active aralkylating compound, mutagen and SCE inducer. The results suggested that reaction of N2 of guanine, as compared with N-7 of guanine, failed to show any remarkable mutagenicity or SCE induction, since p-methylbenzyl chloride, reacting preferentially at N2 of guanosine, failed to show unexceptional potency.

Mutagenicities of glycidyl ethers for Salmonella typhimurium: relationship between mutagenic potencies and chemical reactivity

The lethal and mutagenic effects of ethyl, benzyl, 1-naphthylmethyl, 2-naphthylmethyl, 1-naphthylethyl, 2-naphthylethyl and 9-anthrylmethyl glycidyl ethers on Salmonella typhimurium (TA100, TA1535, TA98 and TA1538) were investigated. LD30-value became smaller with an increase in compound hydrophobicity. The mutagenicities of these compounds in TA100 increased in the order: 1-naphthylethyl glycidyl ether less than 2-naphthylethyl glycidyl ether less than benzyl glycidyl ether less than 2-naphthylmethyl glycidyl ether less than 1-naphthylmethyl glycidyl ether less than 9-anthrylmethyl glycidyl ether. 1-Naphthylmethyl and 2-naphthylmethyl glycidyl ethers were mutagenic toward TA1535. In TA98, 1-naphthylmethyl and 9-anthrylmethyl glycidyl ethers showed mutagenic activity and 9-anthrylmethyl glycidyl ether was more mutagenic than 1-naphthylmethyl glycidyl ether. 9-Anthrylmethyl glycidyl ether was also active in TA1538. In the reaction of glycidyl ethers with deoxyguanosine and related compounds, glycidyl ethers attacked at only N-7 of guanine. The alkylation rates of glycidyl ethers toward guanine residues in DNA were determined and the exciplex-formation ability of 7-substituted guanines was studied. The reactivity of glycidyl ethers with guanine residues in DNA has not provided a sufficient explanation for the variation in mutagenic potencies of glycidyl ethers.

Induction of sister-chromatid exchanges by styrene analogues in cultured human lymphocytes

Styrene and 11 styrene analogues were tested for their ability to induce sister-chromatid exchanges (SCEs) by a 48-h treatment in human whole-blood lymphocyte cultures (72 h). Styrene, its methyl-substituted derivatives (substituted at 2-, 3-, 4-, 3,5- or beta-position) and two styrene oxides (3,5-dimethylstyrene-7,8-oxide and 4-nitrostyrene-7,8-oxide) induced a distinct dose-dependent increase in SCEs. Also, 4-methylstyrene-7,8-oxide and alpha-methylstyrene showed a positive effect, but were not able to double the mean number of SCEs/cell at the concentration ranges available. Ethylbenzene had a marginal effect on SCEs at the highest dose tested. 2-Phenylethanol did not increase SCEs. The results indicate that styrene and methylstyrenes are converted into reactive metabolites in the whole-blood lymphocyte cultures. The negative or weak effects of styrene analogues without a double bond in the side-chain (ethylbenzene and 2-phenylethanol) suggest that the reactive metabolites are derived from the conversion of the vinyl group and are styrene-7,8-oxides.