In vitro and in vivo formation of 7-(2'-carboxyethyl)guanine from the liver carcinogen 1-nitroso-5,6-dihydrouracil and its reactions with water and methanol

Base-catalyzed hydrolysis of the potent liver carcinogen 1-nitroso-5,6-dihydrouracil [(NDHU) CAS: 16813-36-8] afforded 3-hydroxypropionic acid and acrylic acid in 72 and 6% yield, respectively. The base-catalyzed methanolysis of NDHU gave quantitative yields of 3-methoxypropionic acid and methyl carbamate. These results indicate that base-catalyzed NDHU decomposition produces a 2-carboxyethyl carbonium-ion-type intermediate. When 3H-labeled NDHU was reacted at pH 8 with DNA and RNA, 7-(2'-carboxyethyl)guanine (CEG) was detected in the hydrolysate and was identified by its cochromatography with authentic CEG in five (for DNA) or three (for RNA) systems and by a reverse isotope-dilution procedure. Radioactively labeled CEG (identified as before) and five other labeled chromatographic fractions were present in liver DNA and RNA hydrolysates after [3H]NDHU was gavaged into MRC Wistar rats. These fractions persisted in the liver DNA for various times up to 33 days after the gavage. The CEG fraction was 94% of the radioactivity in DNA reacted in vitro, but it reached only 21% of the radioactivity in the liver DNA. The results are related to a study on single-strand breaks produced by NDHU in rat liver DNA.     

Induction of hyperplastic liver nodules in Wistar and MRC-Wistar rats by phenobarbital and the liver carcinogens acetoxime, 1-nitroso-5,6-dihydrouracil and 3-nitroso-2-oxazolidinone

We tested the ability of phenobarbital and two liver carcinogens, acetoxime and 1-nitroso-5,6-dihydrouracil (NDHU), to induce hyperplastic liver nodules (HLN) in MRC-Wistar and Wistar rats, using a system that included a single diethylnitrosamine (DEN) treatment, partial hepatectomy, and administration of the test compound in drinking water for 8 weeks. All three compounds induced significant HLN frequencies (number of HLN/cm2) in both rat strains. When the results for each strain were "normalized" for each compound and then combined, HLN frequency in MRC-Wistar rats was significantly lower (P less than 0.01) than that in Wistar rats. The weak liver carcinogen 3-nitroso-2-oxazolidinone (NOZ) did not induce a significant HLN frequency in MRC-Wistar rats. Acetoxime was highly volatile and was not mutagenic in the Ames test under a variety of conditions. The results for acetoxime are of interest because simple oximes are common constituents of oil paints. HLN induction by nitrosodihydrouracil is of interest because, unlike most liver carcinogens, this compound probably does not require metabolic activation and shows only a mild acute hepatoxicity.     

Carcinogenicity test of six nitrosamides and a nitrosocyanamide administered orally to rats.

Six nitrosamides [ethylnitrosourea (ENU), 2-hydroxyethylnitrosourea (HENU), carboxymethylnitrosourea, 1-nitroso-5,6-dihydrouracil (NDHU), 1-nitrosohydantoin, and N-methyl-N-nitrosobenzamide (MNB)] and ethylnitrosocyanamide (ENC) were administered chronically in sodium citrate-buffered drinking water to MRC Wistar rats. ENU induced tumors of the reticuloendothelial system (RES) (50% incidence), mammary glands, and large intestine. NDHU in drinking water produced hepatocellular carcinomas (96% incidence), but NDHU injected ip caused mostly tumors at the injection sites (54% incidence). HENU produced bone tumors (38% incidence) and RES tumors (28% incidence). ENC produced nasal cavity tumors (36% incidence). Papillomas and/or carcinomas of the forestomach, tongue, and pharynx were induced by most of the compounds, with the highest incidence in the forestomach (47% for MNB); these tumors were attributed to local action when the compounds were ingested. Carcinogenicity was not quantitatively correlated with direct mutagenicity for Salmonella typhimurium TA1535.     

Tumorigenic effects of direct- and indirect-acting chemical carcinogens in rats on a restricted diet

The influence of diet restriction on induction of intestinal tumors in Sprague-Dawley rats by two unique carcinogenic agents was investigated: methylazoxymethanol acetate [(MAM) CAS: 592-62-1], which requires metabolic activation, and N-methylnitrosourea [(MNU) CAS: 684-93-5], which is a direct-acting carcinogen. Most of the tumors induced by MAM developed in the small intestine and less frequently in the colon, but MNU produced tumors predominantly in the colon. Among rats fed the restricted diet (12 g/day), the production of tumors by MAM was significantly reduced compared to that of counterpart rats on the ad libitum diet. However, dietary restriction did not modify the production of tumors in rats by MNU. The same relationship of diet restriction to tumor induction was demonstrable when MAM and MNU were administered to the same test rats: Numbers of MAM-related tumors, especially in the small intestine, were reduced and numbers of MNU-related tumors in the colon were unchanged. Dietary restriction modified the tumorigenic response of rats to MAM but not to MNU.     

Ascorbate potentiates DNA damage by 1-methyl-1-nitrosourea in vivo and generates DNA strand breaks in vitro

Ascorbic acid (vitamin C) is an important intracellular reducingagent. It also has been suggested to be (i) a protective agentagainst development of cancer, (ii) a therapeutic agent formalignancies and (iii) a mutagen. We have found that high concentrationsof ascorbate leads to DNA damage in several in vivo and in vitrosituations. Guinea-pigs receiving oral 1-methyl-1-nitrosourea(MNU) were used as a whole animal model. Administration of sodiumascorbate prior to MNU increased strand breakage in pancreaticDNA. Concentrations of ascorbate >0.5 mM increased the frequencyof DNA strand breaks caused by MNU in both L1210 murine leukemiacells and guinea-pig pancreatic cells in tissue culture; ascorbatealone led to DNA strand breaks in the latter cells. Investigationsof the mechanism of DNA damage were carried out with purifiedDNA. Ascorbate produced single- and double-strand breaks inplasmid DNA. Cleavage was catalyzed by copper (II), inhibitedby catalase and blocked by the presence of thiols. We concludethat superoxide and hydrogen peroxide produced during the oxidationof ascorbate leads to generation of hydroxyl free radicals thatcan mediate DNA strand scissions and potentiate the effectsof alkylating carcinogens.     

Comparative tumor-promoting activities of phenobarbital, amobarbital, barbital sodium, and barbituric acid on livers and other organs of male F344/NCr rats following initiation with N-nitrosodiethylamine

Tumor-promoting abilities of four barbiturates, phenobarbital [(PB) CAS: 50-06-6], amobarbital [(AB) CAS: 57-43-2], barbital sodium [(BB) CAS: 144-02-5], and barbituric acid [(BA) CAS: 67-52-7], on the development of neoplasms in livers and other organs of rats following initiation with N-nitrosodiethylamine [(DENA) CAS: 55-18-5] were compared. Four-week-old F344/NCr male rats were given a single ip injection of 75 mg DENA/kg body weight. Beginning 2 weeks later, they were given either tap water (group 1) or drinking water containing 500 ppm of PB (group 2), the sodium salt of BB (group 3), AB (group 4), or BA (group 5) for the remaining experimental period. Control groups (groups 6-10) received an ip injection of saline alone and 2 weeks later were given either tap water or drinking water containing barbiturates as listed above. Animals were sacrificed at either 52 weeks or 78 weeks. None of the barbiturates altered the growth and survival of animals. PB and BB increased liver weights and significantly enhanced the development of hepatocellular foci and hepatocellular adenomas at 52 weeks and hepatocellular foci, hepatocellular adenomas, and trabecular carcinomas at 78 weeks in DENA-treated rats. No such enhancing effects were observed with AB or BA. PB or BB did not significantly enhance the incidence of nonhepatic tumors at 52 weeks. However, at 78 weeks BB significantly enhanced the development of renal tubular adenomas and carcinomas, while PB enhanced the development of thyroid follicular cell neoplasms in DENA-treated rats. These results clearly showed that barbiturates exhibited structure-promoting activity relationships and that their promoting abilities were not restricted to liver alone. Substitution of both hydrogen atoms at the C-5 position of the pyrimidine ring by alkyl or aryl groups appears to be essential but not sufficient for tumor-promoting activity of barbiturates.     

Differential induction of DNA strand breaks by nitrosamines in the rat liver and esophagus

Hepatic and esophageal nuclei were isolated from Sprague-Dawley rats treated with 5 mg/kg dimethylnitrosamine (DMN), 100 mg/kg diethylnitrosamine (DEN) and 2.5 mg and 10 mg/kg methylbenzylnitrosamine (MBN) and subjected to alkaline elution to determine DNA strand breaks and their subsequent repair. Results obtained showed that hepatic nuclei isolated from rats 4 h after treatment by either DMN or DEN had about 60% of the DNA eluting through the filter. However, at 12 h post treatment, while about 50% of the single-strand breaks in dimethylnitrosamine treated rats were repaired, only about 10-15% of such breaks induced by DEN were repaired in the liver. That DEN is a more effective inducer of hepatic preneoplastic lesions could thus be attributed to this slow repair of the DEN induced lesions. Strand breaks were neither induced by DMN in the esophagus nor by MBN in the liver, the nontarget tissues. More surprising, however, was the finding that MBN induced little or no single-strand breaks in its target tissue, the esophagus. Furthermore, there was no evidence for DNA-protein cross-linking or alkali labile sites in the esophageal DNA. The results indicate that DNA damage induced by the initiating carcinogen in the target tissue may not necessarily involve strand breaks.     

Effect of carcinogen dose and age at administration on induction of mammary carcinogenesis by 1-methyl-1-nitrosourea.

The objective of the work reported in this paper was to determine if the tumorigenic response to 1-methyl-1-nitrosourea (MNU) in the mammary gland varied with age of administration and was dose dependent when the carcinogen was injected prior to 50 days of age. Using a recently developed method for mammary tumor induction, MNU was injected i.p. at doses ranging from 25 to 75 mg/kg at 35 days of age or 50 mg/kg at 28, 35 or 42 days of age. Treatment with MNU resulted in induction of both benign and malignant mammary tumors. The incidence of mammary gland adenocarcinomas was 100% at and above the 50 mg/kg dose of MNU, irrespective of the age at which carcinogen was administered. The number of cancers increased in proportion to carcinogen dose, whereas cancer latency decreased as the MNU dose increased. In rats injected with 50 mg MNU/kg body weight at 28, 35 or 42 days of age, differences among groups in cancer incidence, number or latency were not statistically significant. Metastases of mammary neoplasms to lung, liver and spleen were observed in rats injected with MNU at 35 or 42 days of age. These data indicate (i) the dose responsiveness of MNU-induced mammary carcinogenesis in rats initiated prior to 50 days of age; (ii) the lack of effect of age at initiation if prior to 50 days on final tumor outcome; and (iii) that the age at which MNU is injected may affect the metastatic potential of the mammary carcinomas that are induced.     

Modulation by glutathione of DNA strand breaks induced by 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone and its aldehyde metabolites in rat hepatocytes.

Activation of the tobacco carcinogen 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) produced methylating species and two aldehydes: formaldehyde and 4-oxo-4-(3-pyridyl)-butanal (OPB). We investigated the modulation by glutathione of single-strand breaks (SSB) generated by N-methyl-N-nitrosourea (MNU) and the two aldehydes. Hepatocytes were simultaneously exposed to 0.2 mM MNU and to 0-2.00 mM formaldehyde or OPB for 4 h. Both aldehydes induced SSB in a dose-dependent manner. Formaldehyde and OPB exerted a synergistic effect on the formation of DNA SSB by MNU. It is postulated that both aldehydes interfere with DNA repair processes and thus increase the genotoxic effect of DNA methylating species. We investigated whether glutathione (GSH) could protect DNA from NNK-derived intermediates. Formaldehyde (2 mM) and OPB (2 mM) decreased intracellular GSH contents to 60 and 86% of control respectively. DL-Buthionine-[S,R]-sulfoximine (BSO) treatment reduced the GSH contents of hepatocytes to 19% of control but did not reduce the content of cytochrome P450 nor the metabolism of NNK. The frequency of DNA SSB induced by NNK, formaldehyde or OPB was significantly higher in GSH-depleted hepatocytes. GSH repletion with GSH monoethyl ester returned NNK-induced SSB to its initial frequency. OPB but not NNK nor formaldehyde induced double-strand breaks. We conclude that OPB and formaldehyde inhibit the repair of DNA damage induced by methylating species and that GSH reduces the level of DNA damage induced by NNK-derived reactive metabolites.     

Similar carcinogenic effects in rats of 1-ethyl-1-nitroso-3-hydroxyethylurea and 1-hydroxyethyl-1-nitroso-3-ethylurea

The two isomeric N-nitroso derivatives of the dialkylurea, 1-ethyl-3-(2-hydroxyethyl)urea,were given by gavage to 20 male F344 rats for 30 weeks at equimolardoses. The tumorigenic responses were compared with those toa similar dose of nitrosoethylurea or nitroso-2-hydroxyethylurea.Each of the nitrosomonoalkylureas caused death from tumors morerapidly than the analogous nitrosodialkylurea. Each of the nitrosodialkylureasinduced a broader spectrum of tumors in the rats than did eithernitrosoethylurea or nitroso-2-hydroxyethylurea, including neoplasmsof the thyroid, lung, skin, colon, mesotheliomas and neoplasmsof the brain and liver in high incidence, the last two of whichwere not seen in animals given the nitrosomonoalkylureas. Onthe other hand, there were fewer tumors of the forestomach inrats given the nitrosodialkylureas than with the nitrosomo-noalkylureas.The major difference between 1-nitroso-1-eth-yl-3-hydroxyethylureaand 1-nitroso-1-hydroxyethyl-3-ethyl- urea was that the formerinduced only neoplastic nodules in the,liver of 30% of the rats,while the latter induced hepatocellular carcinomas in 55% ofthe rats; approximately half of the rats given either compoundhad brain neoplasms, which included astrocytomas, gliomas andoligoden drogliomas.     

Carcinogenicity of 1-(2-hydroxyethyl)-1-nitrosourea and 3-nitroso-2-oxazolidinone administered in drinking water to male MRC-Wistar rats: induction of bone, hematopoietic, intestinal, and liver tumors

A previous report was made on the carcinogenicity of 1-(2-hydroxyethyl)-1-nitrosourea [(HENU) CAS: 13743-07-2] in rats. Because the cyclic nitrosocarbamate 3-nitroso-2-oxazolidinone (NOZ) is readily produced during the synthesis of HENU and can be confused with HENU, HENU was retested and NOZ was tested for carcinogenicity. Improved syntheses of both compounds are described. They were administered in drinking water to male MRC-Wistar rats for 1 year, starting at 3 or 9 weeks of age. The HENU-treated rats showed incidences of 48% for bone tumors, 32% for intestinal tumors (mostly duodenal adenocarcinomas), and 53% for lymphoma-leukemia. Of the bone tumors, which were evaluated microscopically and radiologically, 68% were osteosarcomas and 32% were osteoblastomas. The skeletal distribution of these tumors was similar to that of human osteosarcoma, with the tumors occurring most frequently in the lower limbs near the knees. Of the hematopoietic tumors, the majority were lymphoblastic lymphoma-leukemia, which showed a diffuse organ distribution resembling human B-cell (Burkitt's-like) lymphoblastic lymphoma-leukemia, and differed from the usual type of convoluted T-cell lymphoma-leukemia induced by other nitrosoureas in rats and mice. NOZ induced intestinal tumors (mostly duodenal adenocarcinomas) in 80% and liver tumors (mostly hepatocellular adenomas) in 53% of the rats.     

Target tissue DNA damage in inbred mouse strains with different susceptibility to the colon carcinogen 1, 2-dimethylhydrazine

We have compared liver, kidney and colon DNA damage, as singlestrand breaks, in mice with different strain-dependent susceptibilityto the colon-specific carcinogen 1, 2-dimethylhydrazine (DMH).The mouse strains studied were: AKR/J, DBA2 totally resistant;CD1, C57BL/6N moderately susceptible; SWR/J very susceptibleto DMH-induced carcinogenesis. DNA breaks were estimated fromthe elution rate constant (K) according to the alkaline elutiontechnique. At 4 h after carcinogen administration a substantialand comparable DNA damage was found in liver and kidney in allthe strains examined. The DNA fragmentation index, however,reached a maximum value at 2 h after treatment in the liverof the most susceptible strain (SWR/J). About 50% of the liverDNA damage detected in all five strains 4 h after DMH administrationpersisted at 24 h after treatment and was totally repaired at72 h. Kidney DNA damage decreased in 48 h toward the range ofcontrol values. In colon epithelial cells (the carcinogen targettissue) 2 and 4 h after DMH administration the amount of DNAsingle strand breaks was correletable with the strain sensitivityto the carcinogen. In the time interval studied (2–72h after DMH administration) the decrease of colon DNA damagewas linear in the resistant strains. In contrast, in the moresusceptible strain (SWR/J), the amount of DNA breaks remainedhigh up to 24 h after treatment and returned to background levelat 72 h.     

Induction and suppression of N-nitrosomethylbenzylamine activation by microsomes from rat liver and esophagus

Male Sprague-Dawley rats were pretreated with various chemicals to determine their effects on the microsomal activation of the esophageal carcinogen N-nitrosomethylbenzylamine [( NMBzA ) CAS: 937-40-6; N-methyl-N- nitrosobenzylamine ] in the rat esophagus and, for comparative purposes, in the rat liver. When rats were pretreated with NMBzA , little change in hepatic NMBzA - debenzylase activity was observed. In contrast, NMBzA metabolism in the esophagus was significantly (60-65%) reduced. Similarly, pretreatment of rats with disulfiram [CAS: 97-77-8; bis( diethylthiocarbamoyl )disulfide] caused a 40% decrease in esophageal metabolism, but it had no significant effect in the liver. Pretreatments with the methylenedioxybenzenes safrole [CAS: 94-59-7; 4-allyl-1,2-(methylenedioxy)benzene], isosafrole [CAS: 120-58-1; 1,2-(methylenedioxy)-4-propenylbenzene], and dihydrosafrole (CAS: 94-58-6; 1,2-(methylenedioxy)-4- propylbenzene ) caused a marked induction (twofold to fivefold) of the hepatic metabolism of NMBzA , but again esophageal metabolism was suppressed. The results indicate that esophageal metabolism of NMBzA is either unchanged or suppressed by the various chemical pretreatments, but hepatic metabolism of the nitrosamine is induced by the methylenedioxybenzenes .     

Effects of phenobarbital and secondary bile acids on liver, gallbladder, and pancreas carcinogenesis initiated by N-nitrosobis (2-hydroxypropyl)amine in hamsters

The effects of dietary administration of phenobarbital [(PB) CAS: 50-06-6] or the secondary bile acids, deoxycholic acid [(DCA) CAS: 83-44-3] and lithocholic acid [(LCA) CAS: 434-13-9], on tumorigenesis in the liver, gallbladder, and pancreas were investigated in male Syrian golden hamsters after carcinogenic initiation by N-nitrosobis(2-hydroxypropyl)amine [(BHP) CAS: 53609-64-6]. BHP [500 mg/kg (body wt)] was injected sc once weekly for 5 weeks. The animals were then maintained on a basal diet or a diet containing either 0.05% PB, 0.1% DCA, 0.5% DCA, or 0.5% LCA for 30 weeks. DCA enhanced the development of cholangiocarcinomas without influencing that of hepatocellular lesions. PB promoted the induction of hepatocellular carcinomas but not that of cholangiocarcinomas. LCA was without effect on the induction of either hepatocellular carcinomas or cholangiocarcinomas. DCA at a dose of 0.5% enhanced the induction of polyps in the gallbladder. Both DCA, at a dose of 0.1%, and LCA significantly enhanced the induction of pancreas carcinomas. PB had no effect on the induction of polyps in the gallbladder or of pancreas carcinomas. These data document that different tumors may be differentially promoted following initiation with a common carcinogen.     

Inhalation carcinogenesis of various alkylating agents

A series of earlier studies showed that inhalation exposures of rats to three water-reactive electrophilic compounds produced brisk yields of nasal cancer even when the animals were exposed for only 30 days (6 hr/day X 5 day/wk). In addition, carcinogenic potencies of the compounds appeared to relate to their chemical reactivities as measured by hydrolysis rates. For a further study of this phenomenon, inhalation exposures were conducted with five additional water-reactive compounds: beta-propiolactone [(BPL) CAS: 57-57-8], methylmethane sulfonate [(MMS) CAS: 66-27-3], ethylchloroformate [(ECF) CAS: 541-41-3], dichloroacetyl chloride [(DCAC) CAS: 79-36-7], and propylene oxide [(PO) CAS: 75-56-9] on male Sprague-Dawley rats. The hydrolysis rates of these compounds span 6 orders of magnitude. The compounds were administered for 30 days (6 hr/day X 5 days/wk) with the use of exposure concentrations that were inversely proportional to the respective hydrolysis rates. With this protocol, all compounds except PO (the slowest reacting compound) produced nasal cancer in rats. The concentrations of MMS and BPL employed in the studies produced similar nasal cancer yields, indicating that the carcinogenic potencies of these compounds in rat nasal mucosa were proportional to their hydrolysis rates. The nasal cancer yields of DCAC and ECF were less than expected. DCAC hydrolyzes so rapidly at in vivo temperatures (half-life much less than 0.01 min) that it may not reach target DNA in reactive form. Why the exposures to ECF produced yields of nasal cancer not predicted by its reactivity is currently under investigation. These results combined with our earlier results demonstrate that the carcinogenic potencies of some inhaled reactive electrophilic compounds are related to their hydrolysis rates.     

Comparative molecular pharmacology in leukemic L1210 cells of the anthracene anticancer drugs mitoxantrone and bisantrene

1,4-Dihydroxy-5,8-bis(2-[(2-hydroxyethyl)aminoethyl]amino)-9, 10-anthracenedione (mitoxantrone) and 9,10-anthracenedicarboxaldehyde bis[(4,5-dihydro-1H-imidazol-2y)hydrazone] dihydrochloride (bisantrene) were evaluated for their abilities to cause cytotoxicity and interact with cellular DNA using leukemic L1210 cells. On a molar basis mitoxantrone has been found to be 7-fold more toxic than bisantrene. Using a nucleoid sedimentation technique, bisantrene caused changes in DNA supercoiling which were characteristic of an intercalating drug, but mitoxantrone did not induce these changes. Both drugs were found to interact with cellular DNA with tight but noncovalent binding. Both drugs also induced protein-associated double- and single-strand DNA breaks, but with mitoxantrone only some of the DNA single-strand breaks were protein associated, whereas with bisantrene all the DNA single-strand breaks were protein associated. The cytotoxicity produced by bisantrene at a given frequency of protein-associated DNA strand breaks was low. However, with mitoxantrone at an equivalent DNA strand break frequency, the cytotoxicity was high. Treatment of isolated L1210 nuclei with either drug did not result in DNA single-strand breaks. It can be concluded that bisantrene binds DNA in whole cells by an intercalative mechanism, whereas mitoxantrone binds DNA by a nonintercalative, electrostatic interaction and induces non-protein-associated DNA strand breaks.     

Dose-responsive induction of mammary gland carcinomas by the intraperitoneal injection of 1-methyl-1-nitrosourea

Dose-response relationships for the induction of mammary tumors by a single i.p. injection of 1-methyl-1-nitrosourea (MNU) were studied. Groups of 30 female Sprague-Dawley rats were given i.p. injections of 50, 37.5, 25, 12.5, or 0 mg MNU/kg body weight at 50 days of age. Animals were palpated for tumor detection twice weekly throughout a 28-week observation period. Administration of MNU i.p. caused no acute toxicity. Both benign and malignant mammary tumors were induced by MNU, but malignant tumors appeared earlier and at a faster rate than benign tumors. The incidence and numbers of mammary carcinomas increased whereas median cancer-free time decreased with increasing dose of MNU. Approximately twice as many mammary cancers were observed in the cervical-thoracic as in the abdominal-inguinal mammary gland chains irrespective of carcinogen dose, while the frequency of tumor occurrence in the left versus right chains was similar. Tumor latency decreased with increasing dose of MNU, but the quartiles for time to detection of all tumors within each carcinogen dose group were similar irrespective of anatomical region in which the tumors occurred. The mammary tumor response attained via i.p. injection was similar but the coefficient of variation for tumor multiplicity within a carcinogen dose group was lower in comparison to that observed when MNU was administered i.v. or s.c. Among these techniques for carcinogen injection, the i.p. route is the most rapid method and offers an added advantage of ease of administration with quantitative, reproducible delivery of the desired amount of carcinogen and a decrease in variability of tumor response among animals within a treatment group. This method is well suited for the technically less experienced investigator and for those in need for a rapid method of injecting MNU to large numbers of animals.     

The role of nitric oxide on DNA damage induced by benzene metabolites

Benzene, a tobacco constituent, is a leukemogen in humans and a carcinogen in rodents. Several benzene metabolites generate superoxide anion (O(2)(.-)) and induce nitric oxide synthase in the bone marrow of mice. We hypothesized that the reaction of nitric oxide (*NO) with O(2)(.-) leads to the formation of peroxynitrite as an intermediate during benzene metabolism. This hypothesis was supported by demonstrating that the exposure of mice to benzene produced nitrated metabolites and enhanced the levels of protein-bound 3-nitrotyrosine in the bone marrow of mice in vivo. In the current study, we investigated the influence of nitric oxide, generated from sodium 1-(N,N-diethylamino)diazen-1-ium-1,2-diolate, on DNA strand breaks induced by each single or binary benzene metabolite at different doses and compared the levels of the DNA damage induced by each benzene metabolite in the presence of nitric oxide with the levels of DNA strand breaks induced by peroxynitrite at similar doses in vitro. We found that among benzene metabolites only 1,2,4-trihydroxybenzene (BT) can induce significant DNA damage in the absence of nitric oxide. While 1,4-dihydroxybenzene (HQ), 1,4-benzoquinone (BQ) and 1,2-dihydroxybenzene (CAT) require .NO to induce DNA strand breaks, hydroquinone was the most potent DNA-damaging benzene metabolite in the presence of *NO. The order of DNA breaks by benzene metabolites in the presence of *NO is: Peroxynitrite = HQ > BT > BQ > CAT. The *NO and O(2)(.-) scavengers inhibited DNA damage induced by [HQ+*NO]. Benzene, trans,trans-muconaldehyde, and phenol, do not induce DNA strand breaks either in the absence or presence of *NO. However, adding phenol to [HQ+*NO] leads to greater DNA damage than [HQ+*NO] alone. Collectively, these results suggest that nitric oxide is an important factor in DNA damage induced by certain benzene metabolites, probably via the formation of the peroxynitrite intermediate. Phenol, the major benzene metabolite that does not induce DNA damage alone and is inactive in vivo, synergistically enhances DNA damage induced by potent benzene metabolite in the presence of nitric oxide.     

Promotion of N-methyl-N-nitrosourea-induced thyroid tumors by iodine deficiency in F344/NCr rats

Six-week-old male F344 rats were each given an injection once iv of N-methyl-N-nitrosourea [(MNU) CAS: 684-93-5] at a dose of 41.2 mg/kg body weight. Two weeks later, groups of rats were placed on iodine-deficient (ID) or iodine-adequate (IA) diets and then sacrificed at 20 and 33 weeks. Other groups received ID or IA diets without MNU. For localizing thyroid-stimulating hormone (TSH) and prolactin, sections of pituitary glands were stained by the avidin-biotin-peroxidase complex technique with the use of anti-rat TSH or prolactin antibody. At 20 weeks, rats receiving MNU and ID diets had a 100% incidence of diffuse follicular goiter and multiple follicular adenomas of the thyroid. Focal proliferative thyroid follicular lesions including focal hyperplasias and adenomas per square centimeter of thyroid gland were significantly increased in rats given MNU and ID diets in comparison with rats given MNU and IA diets. At 33 weeks, all MNU rats on ID diets had a significantly increased incidence of thyroid carcinoma of the follicular or papillary types and diffuse pituitary thyrotroph hyperplasia, hypertrophy, and vacuolar degeneration. Rats fed ID diets without MNU had diffuse follicular goiter but no tumors at any time period. MNU given alone in rats fed IA diets induced a 10% incidence of single thyroid adenomas at 20 weeks and 70% at 33 weeks and a 10% incidence of thyroid carcinoma at 33 weeks. Tumors induced in other organs by MNU were not affected by the ID diets. Thus this experiment provided evidence that ID diets are potent promoters of thyroid tumors in this system, but the ID diet itself without carcinogen was not carcinogenic under the conditions of the study.