Comparative transcriptomic analyses to scrutinize the assumption that genotoxic PAHs exert effects via a common mode of action.

In this study, the accuracy of the assumption that genotoxic, carcinogenic polycyclic aromatic hydrocarbons (PAHs) act via similar mechanisms of action as benzo(a)pyrene (BaP), the reference PAH used in the human health risk assessment of PAH-containing complex mixtures, was investigated. Adult male Muta™Mouse were gavaged for 28 days with seven individual, genotoxic PAHs. Global gene expression profiles in forestomach, liver, and lung (target tissues of exposure) were determined at 3 days post-exposure. The results are compared with our previously published results from mice exposed to BaP via the same exposure regimen. Although all PAHs showed enhanced ethoxyresorufin-O-deethylase activity, DNA adduct formation, and lacZ mutant frequency in the lungs, the unsupervised cluster analysis of differentially expressed genes revealed that the transcriptional changes are both PAH- and tissue-specific, with lung showing the most response. Further bioinformatics-/pathway-based analysis revealed that all PAHs induce expression of genes associated with carcinogenic processes, including DNA damage response, immune/inflammatory response, or cell signaling processes; however, the type of pathways and the magnitude of change varied for each PAH and were not the same as those observed for BaP. Benchmark dose modeling showed transcriptomic data closely reflected the known tumor incidence for the individual PAHs in each tissue. Collectively, the results suggest that the underlying mechanisms of PAH-induced toxicity leading to tumorigenesis are tissue-specific and not the same for all PAHs; based on the tissue type considered, use of BaP as a reference chemical may overestimate or underestimate the carcinogenic potential of PAHs.

3-Nitrobenzanthrone and 3-aminobenzanthrone induce DNA damage and cell signalling in Hepa1c1c7 cells.

3-Nitrobenzanthrone (3-NBA) is a mutagenic and carcinogenic environmental pollutant found in diesel exhaust and urban air pollution. In the present work we have characterised the effects of 3-NBA and its metabolite 3-aminobenzanthrone (3-ABA) on cell death and cytokine release in mouse hepatoma Hepa1c1c7 cells. These effects were related to induced DNA damage and changes in cell signalling pathways. 3-NBA resulted in cell death and caused most DNA damage as judged by the amount of DNA adducts ((32)P-postlabelling assay), single strand (ss)DNA breaks and oxidative DNA lesions (comet assay) detected. An increased phosphorylation of H2AX, chk1, chk2 and partly ATM was observed using flow cytometry and/or Western blotting. Both compounds increased phosphorylation of p53 and MAPKs (ERK, p38 and JNK). However, only 3-NBA caused an accumulation of p53 in the nucleus and a translocation of Bax to the mitochondria. The p53 inhibitor pifithrin-alpha inhibited 3-NBA-induced apoptosis, indicating that cell death was a result of the triggering of DNA signalling pathways. The highest phosphorylation of Akt and degradation of IkappaB-alpha (suggesting activation of NF-kappaB) were also seen after treatment with 3-NBA. In contrast 3-ABA increased IL-6 release, but caused little or no toxicity. Cytokine release was inhibited by PD98059 and curcumin, suggesting that ERK and NF-kappaB play a role in this process. In conclusion, 3-NBA seems to have a higher potency to induce DNA damage compatible with its cytotoxic effects, while 3-ABA seems to have a greater effect on the immune system.

Biotransformation enzymes in development of renal injury and urothelial cancer caused by aristolochic acid.

Ingestion of aristolochic acid (AA) is associated with the development of AA-nephropathy and Balkan endemic nephropathy, which are characterized by chronic renal failure, tubulointerstitial fibrosis, and urothelial cancer. Understanding which enzymes are involved in AA activation and/or detoxification is important in assessing susceptibility to AA. Xiao et al. demonstrate that hepatic cytochrome P450s in mice detoxicate AA and thereby protect kidney from injury. The relative contribution of enzymes activating AA to induce urothelial cancer in humans remains to be resolved.

Further studies with a cell immortalization assay to investigate the mutation signature of aristolochic acid in human p53 sequences.

To test hypotheses on the origins of p53 mutations in human tumors, novel strategies are needed for generating mutation spectra experimentally. To this end we developed an assay employing Hupki (Human p53 knock-in) mouse embryonic fibroblasts (HUFs). Here we examine p53 mutations induced by aristolochic acid I (AAI)), the carcinogen probably responsible for Chinese herbal nephropathy. Six immortalized cultures (cell lines) from 18 HUF primary cultures exposed at passage 1 for 48 h to 50 microM AAI harbored p53 mutations in the human DNA binding domain sequence of the Hupki p53 tumor suppressor gene. The most frequently observed mutation was A to T transversion, corroborating our previous mutation study with AAI, and consistent with the presence of persistent AAI-adenine adducts found both in DNA of exposed patients and in DNA of AAI-exposed HUF cells. One of the mutations was identical in position (codon 139) and base change (A to T on the non-transcribed strand) to the single p53 mutation that has thus far been characterized in a urothelial tumor of a nephropathy patient with documented AAI exposure. Of the seven p53 mutations identified thus far in >60 HUF cell lines that immortalized spontaneously (no carcinogen treatment), none were A:T to T:A transversions. In addition, no A to T substitutions were identified among the previously reported set of 18 mutations in HUF cell lines derived from B(a)P treatment in which transversions at G:C base pairs predominated.

Detection of DNA adducts formed by aristolochic acid in renal tissue from patients with Chinese herbs nephropathy.

A unique type of rapidly progressive renal fibrosis, designated Chinese herbs nephropathy (CHN), has been described in young Belgian women who had followed a slimming regimen including recently introduced Chinese herbs (Stephania tetrandra and Magnolia officinalis). Aristolochic acid (AA), a known nephrotoxin and carcinogen, was suspected as its causal factor. To substantiate this hypothesis, renal tissue from five patients with CHN and six patients with other renal diseases was analyzed for the presence of AA-derived DNA adducts, a described biomarker of AA exposure associated with its carcinogenic and mutagenic activity. Using the 32P-postlabeling method, a major distinct DNA adduct spot was found in all five cases of CHN and identified by cochromatographic analyses with authentic markers as the deoxyadenosine adduct of AA-I [7-(deoxyadenosin-N6-yl)-aristolactam I], the major component of the plant extract AA. This DNA adduct was absent in the six control cases. The 7-(deoxyadenosin-N6-yl)-aristolactam I adduct levels in CHN ranged from 0.7 to 5.3/10(7) nucleotides. Our data demonstrate that AA is implicated in CHN. They suggest a mechanism for the urothelial atypia and cancers observed in this disease and raise the possibility that a DNA mutation is responsible for the kidney-destructive fibrotic process.

Aristolochic acid activates ras genes in rat tumors at deoxyadenosine residues.

Aristolochic acid I (AAI), a nitrophenanthrene derivative, is the major component of the carcinogenic plant extract aristolochic acid, which has been used as a medicine since antiquity. Long term oral administration of AAI to male Wistar rats induces multiple tumors, mainly in the forestomach, ear duct, and small intestine. The presence of activated transforming genes was investigated in various tumors of 18 AAI treated rats, namely in 14 squamous cell carcinomas of the forestomach, 7 squamous cell carcinomas of the ear duct, 8 tumors of the small intestine, 3 tumors of the pancreas, 1 adenocarcinoma of the kidney, 1 lymphoma, and 2 metastases in the lung and the pancreas. By utilizing the tumorigenicity assay and Southern blot analysis, we have detected an activated c-Ha-ras gene in the DNAs of 5 of 5 squamous cell carcinomas of the forestomach. Direct sequencing of amplified material revealed an AT----TA transversion mutation at the second position of codon 61 of the c-Ha-ras gene (CAA to CTA) in all transfectants as well as in the 5 original rat tumors. Enzymatic amplification of ras sequences followed by selective oligonucleotide hybridization detected identical mutations in 93% (13 of 14) of forestomach tumors, in 100% (7 of 7) of ear duct tumors, and in the lung metastasis. Among those tumors tested, we had 4 cases in which the forestomach tumors and the ear duct tumors originated from the same rat, showing the same mutation in both tissues. Moreover, similar mutations were demonstrated at c-Ki-ras codon 61 in 1 of 7 ear duct tumors (CAA to CAT) and in 1 of 8 tumors of the small intestine (CAA to CTA) as well as at c-N-ras 61 (CAA to CTA) in a pancreatic metastasis. Additional transfection experiments of some tumors scoring negative for ras gene mutations in dot blot analyses revealed a CAA to CTA transversion at codon 61 of the c-Ha-ras gene in 1 forestomach tumor as well as at codon 61 of the c-N-ras in 1 hyperplasia of the pancreas and in 1 lymphoma. The apparent selectivity for mutations at adenine residues in AAI induced tumors is consistent with the identification of an N6-deoxyadenosine-AAI adduct formed by reaction of AAI with DNA in vitro, suggesting that carcinogen-deoxyadenosine adducts are the critical lesions in the tumor initiation by aristolochic acid.

Activating mutations at codon 61 of the c-Ha-ras gene in thin-tissue sections of tumors induced by aristolochic acid in rats and mice.

The plant extract aristolochic acid, which consists mainly of aristolochic acid I (AAI) and aristolochic acid II (AAII), induces tumors in rats and mice. Thin-tissue sections of rat tumors induced by AAI and of mouse tumors induced by aristolochic acid, were analyzed for c-Ha-ras mutations in codon 61. Areas of neoplastic and histologically normal tissue were manually scraped out and separated. Using the polymerase chain reaction (PCR) and mutation detection by selective oligonucleotide hybridization, we observed AT----TA transversion mutations in DNA of neoplastic portions, but not in DNA of adjacent normal tissue in both rat and mouse tumors.

Effect of site-specifically located aristolochic acid DNA adducts on in vitro DNA synthesis by human DNA polymerase alpha.

In order to examine the effect of purine adducts of the plant carcinogen aristolochic acid (AA) on DNA replication four 30-mer templates were prepared which contained single site-specific AA lesions. The oligonucleotides were isolated by HPLC and shown to contain the two known aristolochic acid I-DNA adducts (dA-AAI, dG-AAI) or the two known aristolochic acid II-DNA adducts (dA-AAII, dG-AAII) at position 27 from the 3' end by 32P-postlabeling. These adducts templates were replicated in primer (23-mer) extension reactions catalysed by human DNA polymerase alpha. Both AAI-DNA adducts (dA-AAI, dG-AAI) blocked DNA synthesis predominantly (80-95%) at the nucleotide 3' to the adduct, although primer extension to the full length of the template was found with unmodified control templates. Increasing dNTP concentrations had only a small effect on the DNA synthesis and translesional synthesis was negligible. In contrast, both AAII-DNA adducts showed marked differences in primer extension reactions. Blocking of DNA synthesis by the dA-AAII adduct was strongly dNTP dependent. With increasing dNTP concentrations 27 and 28 nucleotide products, indicating termination of DNA synthesis after incorporation of a nucleotide opposite this adduct and incorporation of an additional nucleotide accumulated. Only the dG-AAII adducted template allowed substantial translesional synthesis to the full length of the template (up to 25%). When a 26-mer primer was used to examine nucleotide incorporation directly across from the four purine adducts, we found no detectable incorporation of nucleotides for the dA-AAI adduct, whereas the dG-AAI adduct and both AAII-adducts (dA-AAII and dG-AAII) allowed preferential incorporation of the correct nucleotide. These results indicate that for human polymerase alpha three AA purine adducts (dA-AAI, dG-AAI and dA-AAII) provide severe blocks to DNA replication and that dG-AAII, which allows translesional synthesis, may not be a very efficient mutagenic lesion.

Prostaglandin H synthase-medicated oxidation and binding to DNA of a detoxication metabolite of carcinogenic Sudan I, 1-(phenylazo)-2,6-dihydroxynaphthalene.

The metabolite of the carcinogenic azo dye Sudan I, 1-(phenylazo)-2,6-dihydroxynaphthalene (6-OH-Sudan I), which is considered to be the detoxification product of this dye is metabolized by prostaglandin H synthase (PHS) in the presence of arachidonic acid or H2O2 in vitro. The apparent Michaelis constant value for 6-OH-Sudan I as a substrate is 98.9 microM. 1-(Phenylazo)-2,6-naphthoquinone is a principal product of the 6-OH-Sudan I oxidation. This oxidation is inhibited by radical scavengers nitrosobenzene, ascorbate, glutathione and NADH. This indicates that PHS metabolizes 6-OH-Sudan I through a one-electron oxidation mechanism, giving rise to free radicals. During the PHS-mediated reaction, 6-OH-Sudan I is activated to metabolites binding to protein and DNA. The 32P-postlabeling analysis of DNA modified by activated 6-OH-Sudan I provides evidence that covalent binding to DNA is the principal type of DNA modification. The PHS-mediated binding of 6-OH-Sudan I to DNA presumably proceeds through formation of 1-(phenylazo)-2,6-naphthoquinone. The results suggest strongly that the C-hydroxylated derivative of Sudan I (6-OH-Sudan I) should be evaluated as a proximate carcinogenic metabolite, which may participate in the initiation of Sudan I-carcinogenesis in the urinary bladder.

Mutagenicity of the two main components of commercially available carcinogenic aristolochic acid in Salmonella typhimurium.

One of the 2 main components of the commercially available carcinogenic aristolochic acid (AA) was isolated, the other was enriched. Three different aristolochic acid samples (AAI 99% pure; AAI 65% + AAII 35%; AAI 32% + AAII 68%) were assayed for mutagenic activity in Salmonella typhimurium TA1537, TA100 and TA100 NR with and without the addition of a metabolizing mixture. The two main components (AAI and AAII) were direct mutagens in Salmonella strains TA1537 and TA100 with almost equal mutagenic potency. In TA100 NR the aristolochic acid samples showed no or only a very low level of biological activity, indicating the necessity of nitroreduction for the bioactivation of the samples. These findings suggest that both AAI as well as AAII can be used in further studies to elucidate the metabolism of aristolochic acid.

Detoxication products of the carcinogenic azodye Sudan I (solvent yellow 14) bind to nucleic acids after activation by peroxidase.

The C-hydroxyderivatives of the carcinogenic dye Sudan I, 1-phenylazo-2,6-dihydroxynaphthalene and 1-(4-hydroxyphenylazo)-2-hydroxynaphthalene, which are considered to be detoxication products of this dye bind to DNA or tRNA after oxidation into active metabolites by peroxidase and H2O2 in vitro. The 32P-postlabeling analysis of DNA modified by active metabolites of both Sudan I derivatives provides evidence that the covalent binding to DNA is the principal type of DNA modification. Since the urinary bladder is rich in peroxidases, the participation of these enzymes in activation of detoxicating products of Sudan I may be involved in the initiation of Sudan I-carcinogenesis in this organ.

Peroxidase oxidizes N-nitrosomethylaniline to ultimate carcinogens(s) binding to DNA and transfer RNA in vitro.

Carcinogenic N-nitrosomethylaniline is oxidized in vitro by horseradish peroxidase in the presence of H2O2 to ultimate carcinogens, which bind to DNA and transfer RNA (tRNA). tRNA is more accessible for modification by the activated carcinogen studied. The modification of nucleic acid by N-nitrosomethylaniline metabolite(s) formed by peroxidase is inhibited by some compounds of physiological importance (ascorbate, glutathine) and by radical trapping agents (nitrosobenzene, methyl viologen). 32P-postlabeling assay of DNA and tRNA modified by N-nitrosomethylaniline activated by peroxidase shows covalent adduct formation with nucleic acids. The role of peroxidases in the activation of N-nitrosamines leading to organ and/or cell specificity of these carcinogens is discussed.

Direct evidence for the formation of deoxyribonucleotide adducts from carcinogenic N-nitroso-N-methylaniline revealed by the 32P-postlabeling technique.

N-Nitroso-N-methylaniline (NMA) is an esophageal carcinogen in the rat. NMA forms a benzenediazonium ion (BDI) during microsomal cytochrome P-450 2B1 (CYP2B1) catalyzed metabolism. Using the nuclease P1-enhanced version of the 32P-postlabeling assay we investigated the formation of adducts by NMA with deoxyadenosine 3'-monophosphate (dAp) and deoxyguanosine 3'-monophosphate (dGp). 32P-postlabeling analysis of dAp and dGp, which were modified by NMA activated with microsomes of rats pretreated with phenobarbital (PB), and directly labeled resulted in each case in the appearance of one single adduct spot. Quantitative analysis of adducts revealed that the extent of dGp modification by activated NMA was more than 23 times greater than the extent of modification of dAp. The results suggest strongly that BDI, derived from NMA by CYP2B1 present in PB microsomes, participates in the formation of dAp and dGp adducts.

Aristolochic acid nephropathy in a Chinese patient: time to abandon the term "Chinese herbs nephropathy"?

The causal role of aristolochic acid (AA) in the so-called Chinese herbs nephropathy (CHN) has been conclusively demonstrated only in the Belgian epidemic. We report a biopsy-proven hypocellular interstitial fibrosing nephropathy in a Chinese patient who had ingested a Chinese herbal preparation bought in Shanghai. The identification of AA in the preparation and of AA-DNA adducts in the kidney tissue unequivocally demonstrates, for the first time, the causal role of AA outside the Belgian epidemic. Because the ingested preparation is very popular in China as an over-the-counter product, our observation raises the possibility that many such cases due to AA might be currently unrecognized in China. AA should be banned from herbal preparations worldwide. All cases of the so-called CHN, in which the causal role of AA has been thoroughly documented, should be further identified as aristolochic acid nephropathy (AAN). The term phytotherapy-associated interstitial nephritis (PAIN) might refer to the other cases associated with phytotherapy without identification, as yet, of the causal agent.

Oxidation of xenobiotics by plant microsomes, a reconstituted cytochrome P450 system and peroxidase: a comparative study.

The microsomal fraction from tulip bulbs (Tulipa fosteriana, L.) contains cytochrome P450 (CYP3, EC 1.14.14.1) and peroxidase (EC 1.11.1.7.) enzymes catalyzing the NADPH--and hydrogen peroxide--dependent oxidation of the xenobiotic substrates, N-nitrosodimethylamine (NDMA), N-nitrosomethylaniline (NMA), aminopyrine and 1-phenylazo 2-hydroxynaphthalene (Sudan I), respectively. Oxidation of these model xenobiotics has also been assessed in a reconstituted electron-transport chain with a partially purified CYP fraction, phospholipid and isolated tulip NADPH:CYP reductase (EC 1.6.2.4.). Peroxidase isolated from tulip bulbs (isoenzyme C) oxidizes these xenobiotics, too. Values of kinetic parameters (Km, Vmax), requirements for cofactors (NADPH, hydrogen peroxide), the effect of inhibitors and identification of products formed from the xenobiotics by the microsomal fraction, partially purified CYP and peroxidase C were determined. These data were used to estimate the participation of the CYP preparation and peroxidase C in oxidation of two out of the four studied xenobiotics (NMA, Sudan I) in tulip microsomes. Using such detailed study, we found that the CYP-dependent enzyme system is responsible for the oxidation of these xenobiotics in the microsomal fraction of tulip bulbs. The results demonstrate the progress in resolving the role of plant CYP and peroxidase enzymes in oxidation of xenobiotics.

Analyses of DNA adducts formed by ochratoxin A and aristolochic acid in patients with Chinese herbs nephropathy.

Chinese herbs nephropathy (CHN), a unique type of nephropathy has been associated with the intake of weight-reducing pills containing the Chinese herb Aristolochia fangchi. Moreover, an association between the use of A. fangchi and urothelial cancer in CHN patients has been reported indicating that aristolochic acid (AA) the major alkaloid of A. fangchi might be the causal agent. Similarities of CHN to the Balkan endemic nephropathy (BEN) have led to the hypothesis of a common etiological agent for both diseases. Evidence has accumulated that BEN is an environmentally-induced disease strongly associated with the fungal mycotoxin ochratoxin A (OTA). Both, AA and OTA are nephrotoxic and carcinogenic and induce the formation of DNA adducts. As OTA has been suspected as fungal contaminant in the herbal batches used for the preparation of the weight-reducing pills we analysed tissues from CHN patients by the 32P-postlabeling procedure for the presence of DNA adducts related to both OTA and AA exposure. Whereas, AA-specific DNA adducts were detected in all five urinary tract tissues from five patients (total RAL: 32-251 adducts per 10(9) nucleotides), OTA-related DNA adducts were detectable in two kidneys and one ureter only (total RAL: 1.5-3.7 adducts per 10(9) nucleotides). Thus, OTA-related DNA adduct levels were about 50 times lower than AA-DNA adduct levels. In female and male rats that were treated with the slimming regimen in the same way like the CHN patients except that the amount of Chinese herbs was 10 times higher, AA-DNA adducts were found in kidney tissues (total RAL ranging from 51 to 83 adducts per 10(9) nucleotides) but adducts derived from OTA were not observed. These results demonstrate that OTA-related DNA adducts do not play a key role in CHN or CHN-associated urothelial cancer.

Evidence for reductive activation of carcinogenic aristolochic acids by prostaglandin H synthase -- (32)P-postlabeling analysis of DNA adduct formation.

Aristolochic acid (AA), a naturally occurring nephrotoxin and carcinogen, is implicated in an unique type of renal fibrosis, designated Chinese herbs nephropathy (CHN), which can develop to urothelial cancer. Understanding which enzymes are involved in AA activation and/or detoxication is important in the assessment of an individual susceptibility to this natural carcinogen. We examined the ability of prostaglandin H synthase (PHS) to activate AA to metabolites forming DNA adducts with the nuclease P1 and 1-butanol extraction enrichment procedure of the (32)P-postlabeling assay. PHS is a prominent enzyme in the kidney and urothelial tissues. Ram seminal vesicle (RSV) microsomes, which contain high levels of PHS, generated AA-DNA adduct patterns reproducing those found in renal tissues in CHN patients. 7-(Deoxyadenosin-N(6)-yl)aristolactam I, 7-(deoxyguanosin-N(2)-yl)aristolactam I and 7-(deoxyadenosin-N(6)-yl)aristolactam II were identified as AA-DNA adducts formed by AAI. Two adducts, 7-(deoxyguanosin-N(2)-yl)aristolactam II and 7-(deoxyadenosin-N(6)-yl)aristolactam II, were generated from AAII. According to the structures of the DNA adducts identified, nitroreduction is the crucial pathway in the metabolic activation of AA. The identity of PHS as the activating enzyme in RSV microsomes was proven with different cofactors and inhibitors. Only indomethacin, a selective inhibitor of PHS, significantly decreased the amount of adducts formed by RSV microsomes. The inhibitor of NADPH:CYP reductase (alpha-lipoic acid) and some selective inhibitors of cytochromes P450 (CYP) were not effective. Likewise, only cofactors of PHS, arachidonic acid and hydrogen peroxide, supported the DNA adduct formation of AAI and AAII, while NADPH and NADH were ineffective. These results demonstrate a key role of PHS in the activation pathway of AAI and AAII in the RSV microsomal system and were corroborated with the purified enzyme, namely ovine PHS-1. The results presented here are the first report demonstrating a reductive activation of nitroaromatic compounds by PHS-1.

DNA adduct formation from the mutagenic air pollutant 3-nitrobenzanthrone.

The environmental contaminant 3-nitrobenzanthrone (3-nitro-7H-benz[d, e]anthracen-7-one) was recently shown to be a very strong bacterial mutagen, suggesting a new class of mutagenic compounds present in airborne particulate matter and diesel exhaust. Using the 32P-postlabeling assay, we investigated the capacity for 3-nitrobenzanthrone to form DNA adducts in vitro. Calf thymus DNA was incubated with 3-nitrobenzanthrone and either xanthine oxidase, a mammalian nitroreductase or rat liver S9 or zinc. Under these conditions 3-nitrobenzanthrone formed a total of seven adducts detectable by 32P-postlabeling. Using enrichment by butanol extraction the highest level of DNA adduct formation was found with activation by zinc (RAL: 88.4+/-32 per 108 nucleotides) followed by activation with xanthine oxidase (RAL: 75.5+/-12) and activation by rat liver S9 (RAL: 48.6+/-8). Three of the seven adduct spots were detected in all activation systems, however different amounts of individual spots were obtained in the different in vitro systems. The adduct pattern observed for the enzymatic incubations consisted of three major spots and was essentially identical. Chemical reduction of 3-nitrobenzanthrone by zinc resulted in five adduct spots whose formation was found to be concentration dependent. All adducts of 3-nitrobenzanthrone observed in this study migrated primarily along a diagonal zone, typical for DNA adducts derived from extracts of airborne particulate matter. When butanol enrichment was compared with nuclease P1 enrichment one adduct was clearly sensitive to the 3'-monophosphatase activity of nuclease P1. Our results demonstrate that 3-nitrobenzanthrone binds covalently to DNA after metabolic activation, forming multiple DNA adducts in vitro all of which are reduction products. These adducts may contribute to the known genotoxicity and carcinogenicity of extracts from airborne particulates.

SOS induction of selected naturally occurring substances in Escherichia coli (SOS chromotest).

Naturally occurring substances were tested for genotoxicity using a modified laboratory protocol of the Escherichia coli PQ37 genotoxicity assay (SOS chromotest) in the presence and in the absence of an exogenous metabolizing system from rat liver S9-mix. Aristolochic acid I, II, the plant extract aristolochic acid and psoralene were genotoxic; cycasine, emodine, monocrotaline and retrorsine were classified as marginal genotoxic in the SOS chromotest in the absence of S9-mix. In the presence of an exogenous metabolizing system from rat liver S9-mix aristolochic acid I, the plant extract, beta-asarone, cycasin, monocrotaline, psoralen and retrorsine showed genotoxic effects; aristolochic acid II marginal genotoxic effects. Arecoline, benzyl acetate, coumarin, isatidine dihydrate, reserpine, safrole, sanguinarine chloride, senecionine, senkirkine, tannin and thiourea revealed no genotoxicity in the SOS chromotest either in the presence or in the absence of an exogenous metabolizing system from rat liver S9-mix. For 17 of 20 compounds, the results obtained in the SOS chromotest could be compared to those obtained in the Ames test. It was found that 12 (70.6%) of these compounds give similar responses in both tests (6 positive and 6 negative responses). The present investigation and those reported earlier, the SOS chromotest, using E. coli PQ37, was able to detect correctly most of the Salmonella mutagens and non-mutagens.

Evaluation of health risks caused by musk ketone.

Among the nitro musks, musk ketone (MK) as a synthetic compound with a typical musk odor is widely used in cosmetics. In the European Community the total amount used in fragrances has been reported to be 110 tons/a. Additionally, relevant amounts of MK are used in Indian joss sticks. As a result of its inherently low biodegradability MK has been detected in the aquatic environment (surface water, sediments, edible fish). Moreover, it has been shown that MK concentrates in human fatty tissue and breast milk, indicating that humans are constantly exposed. Several studies provided convincing evidence of lack of a genotoxic potential for MK. However, MK was identified as a strong inducer of phase I enzymes in rodents and a cogenotoxicant in vitro in human derived cells in rather low doses, suggesting that exposure to MK might increase the susceptibility to health hazards caused by carcinogens in humans.