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Query: UMLS:C0023418 (leukemia)
 93,477 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Toxicology and carcinogenesis studies were conducted by administering hydroquinone (more than 99% pure) by gavage to groups of F344/N rats and B6C3F1 mice of each sex for 14 days, 13 wk or 2 yr. 14-day studies were conducted by administering hydroquinone in corn oil to rats at doses ranging from 63 to 1000 mg/kg body weight and to mice at doses ranging from 31 to 500 mg/kg, 5 days/wk. In the 13-wk studies, doses for rats and mice ranged from 25 to 400 mg/kg. At those doses showing some indication of toxicity in the 14-day and 13-wk studies, the central nervous system, forestomach and liver were identified as target organs in both species and renal toxicity was observed in rats. Based on these results, 2-yr studies were conducted by administering 0, 25 or 50 mg hydroquinone/kg in deionized water by gavage to groups of 65 rats of each sex, 5 days/wk. Groups of 65 mice of each sex were given 0, 50 or 100 mg/kg on the same schedule. 10 rats and 10 mice from each group were killed and evaluated after 15 months. Mean body weights of high-dose male rats and high-dose mice were approx. 5-14% lower than those of controls during the second half of the study. No differences in survival were observed between dosed and control groups of rats or mice. Nearly all male rats and most female rats in all vehicle control and exposed groups had nephropathy, which was judged to be more severe in high-dose male rats. Hyperplasia of the renal pelvic transitional epithelium and renal cortical cysts were increased in male rats. Tubular cell hyperplasia of the kidney was seen in two high-dose male rats, and renal tubular adenomas were seen in 4/55 low-dose and 8/55 high-dose male rats; none was seen in vehicle controls or in female rats. Mononuclear cell leukaemia in female rats occurred with increased incidences in the dosed groups (vehicle control, 9/55; low dose, 15/55; high dose, 22/55). Compound-related lesions observed in the liver of high-dose male mice included anisokaryosis, syncytial alteration and basophilic foci. The incidences of hepatocellular neoplasms, primarily adenomas, were increased in dosed female mice (3/55; 16/55; 13/55). Follicular cell hyperplasia of the thyroid gland was increased in dosed mice.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Toxicity and carcinogenicity of hydroquinone in F344/N rats and B6C3F1 mice. 792 84

Ethylene glycol ethers and their acetate derivatives were analyzed for their toxicity in vitro on several hemopoietic cell lines, either growth-factor-dependent or leukemic, in mouse, rat, and human species. Considering the concentrations that reduced the cell viability in culture by 50%, most of the ethylene glycol ethers and in particular ethylene glycol monoethyl ether (EGEE) or ethylene glycol monobutyl ether (EGBE) should be considered as hemopoietic toxins. EGBE was found to be the most potent toxin on the human promyelocytic cell line, NB4 (median inhibitory concentration (IC50) 5 mM at 6 h; IC50 0.1 mM at 96 h) but also on the factor-dependent cell line DA1 (IC50 80 microM at 48 h). Factor-dependent cell lines were not significantly more sensitive than leukemic cell lines. The toxicity of these compounds falls in the same range of concentration as benzene or phenol, but hydroquinone was significantly more toxic in the same assay (IC50 3-15 microM at 48 h). Toxic effects increased linearly with time. The toxicity of ethylene glycol ethers was confirmed by both assays for colony-forming units in culture medium (CFU-C) (human blood cord cells) and murine bone marrow long-term culture (IC50 5-10 mM). Stromal cells in the adherent layer were more resistant than hemopoietic cells. An all or none toxicity was found within a narrow range of concentration (2-5 mM for EGBE), and chronic exposure over two months did not show cumulative effects on the culture cellularity. The possibility that fibroblastic or macrophage cells worked at the detoxification of the culture is suggested. Results are discussed with regard to epidemiological and in vivo experimental data presently available.
Leukemia 1992 Apr
PMID:Ethylene glycol ethers as hemopoietic toxins--in vitro studies of acute exposure. 820 72

Benzene, a common industrial chemical and a component of gasoline, is radiomimetic and exposure may lead progressively to aplastic anaemia, leukaemia, and multiple myeloma. Although benzene has been shown to cause many types of genetic damage, it has consistently been classified as a non-mutagen in the Ames test, possibly because of the inadequacy of the S9 microsomal activation system. The metabolism of benzene is complex, yielding glucuronide and sulphate conjugates of phenol, quinol, and catechol, L-phenylmercapturic acid, and muconaldehyde and trans, trans-muconic acid by ring scission. Quinol is oxidised to p-benzoquinone, which binds to vital cellular components or undergoes redox cycling to generate oxygen radicals; muconaldehyde, like p-benzoquinone, is toxic through depletion of intracellular glutathione. Exposure to benzene may also induce the microsomal mixed function oxidase, cytochrome P450 IIE1, which is probably responsible for the oxygenation of benzene, but also has a propensity to generate oxygen radicals. The radiomimetic nature of benzene and its ability to induce different sites of neoplasia indicate that formation of oxygen radicals is a major cause of benzene toxicity, which involves multiple mechanisms including synergism between arylating and glutathione-depleting reactive metabolites and oxygen radicals. The occupational exposure limit in the United Kingdom (MEL) and the United States (PEL) was 10 ppm based on the association of benzene exposure with aplastic anaemia, but recently was lowered to 5 ppm and 1 ppm respectively, reflecting a concern for the risk of neoplasia. The American Conference of Governmental Industrial Hygienists (ACGIH) has even more recently recommended that, as benzene is considered an A1 carcinogen, the threshold limit value (TLV) should be decreased to 0.1 ppm. Only one study in man, based on nine cases of benzene associated fatal neoplasia, has been considered suitable for risk assessment. Recent re-evaluation of these data indicated that past assessments may have overestimated the risk, and different authors have considered that lifetime exposure to benzene at 1 ppm would result in an excess of leukaemia deaths of 9.5 to 1.0 per 1000. Although in this study, deaths at low levels of benzene exposure were associated with multiple myeloma and a long latency period, instead of leukaemia, which might justify further lowering of the exposure limit, the risk assessment model has been found to be non-significant for response at low levels of exposure. The paucity of data for man, the complexity of the metabolic activation of benzene, the interactive and synergistic mechanisms of benzene toxicity and carcinogenicity, the different disease endpoints (aplastic anaemia, leukaemia, and multiple myeloma), and different individual susceptibilities, all indicate that in such a complex scenario, regulators should proceed with caution before making further changes to the exposure limit for this chemical.
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PMID:The toxicity of benzene and its metabolism and molecular pathology in human risk assessment. 185 46

The influence of sesquiterpene quinones and of a sesquiterpene hydroquinone, isolated from the sponge Smenospongia sp. on normal and tumour cells, was investigated. Most showed cytotoxic effects on L1210 leukemia cells. However, their activity on normal cells, such as murine spleen lymphocytes and human peripheral lymphocytes, revealed different behaviours: some of them inhibited, while other enhanced mitogen-stimulated lymphocyte proliferation. These biological studies revealed products modulating immune responses.
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PMID:Sesquiterpene quinones as immunomodulating agents. 205 Apr 43

A mixture of two benzene metabolites, hydroquinone and catechol, produces a striking synergistic genotoxic response in cultured human lymphocytes. This was demonstrated using an anti-kinetochore antibody modification of the micronucleus assay. Treatment with hydroquinone alone or in combination with phenol produced a 3-fold increase in micronucleated cells over background. Treatment with catechol or phenol alone and in combination produced only minor increases in the number of micronucleated cells. In contrast, simultaneous treatment with equimolar (75 microM) concentrations of hydroquinone and catechol resulted in a greater than 16-fold induction of micronucleated cells. Given an additivity model, 20 additional micronucleated cells would be expected (after correcting for background frequencies), yet 140 were observed. Further analysis revealed that over 90% of the micronucleated cells stained positively for kinetochores, indicating a high probability that these micronuclei contain entire chromosomes. This synergistic response appears to occur only at equimolar levels of hydroquinone and catechol. These results suggest that these metabolites are acting together to disrupt the mitotic spindle and interfere with chromosome segregation. These data provide further support for the hypothesis that multiple metabolites acting in concert are involved in the benzene-induced genotoxicity and leukemia in humans.
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PMID:Two benzene metabolites, catechol and hydroquinone, produce a synergistic induction of micronuclei and toxicity in cultured human lymphocytes. 206 33

Benzene is an established human leukemogen. Workers occupationally exposed to benzene exhibit increased frequencies of both structural and numerical chromosomal aberrations in their peripheral blood lymphocytes. The metabolite(s) responsible for these chromosomal aberrations has not yet been identified. Using a modified micronucleus assay, we have examined the ability of the metabolites of benzene to induce chromosomal damage in human lymphocytes. An antikinetochore antibody was used to distinguish micronuclei that have a high probability of containing a whole chromosome (kinetochore positive) from those containing acentric fragments (kinetochore negative). In vitro treatments with the benzene metabolites hydroquinone, 1,4-benzoquinone, phenol, and catechol resulted in significant increases in micronuclei formation. Phenol, catechol, and 1,4-benzoquinone treatments resulted in moderate (2- to 5-fold) increases in micronuclei, whereas hydroquinone treatments resulted in a larger (11-fold) increase in micronuclei. Significant dose-related increases in kinetochore-positive micronucleated cells were not observed following 1,4-benzoquinone treatment but were observed following treatment with phenol, catechol, and hydroquinone. The higher efficacy of hydroquinone in inducing both total micronuclei and kinetochore-positive micronucleated cells when compared with catechol, phenol, and 1,4-benzoquinone suggests that hydroquinone is a major contributor to the clastogenicity and aneuploidy observed in the lymphocytes of benzene-exposed workers. Other metabolites may also contribute, however, to the genotoxic effects of benzene. Since consistent chromosomal aberrations are often observed in human leukemias, the ability of the phenolic metabolites of benzene to induce chromosomal damage in human cells also implicates them in benzene-induced leukemia.
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PMID:Characterization of micronuclei induced in human lymphocytes by benzene metabolites. 229 79

Avarol is a sesquiterpenoid hydroquinone, which displays no inhibitory potencies on mammalian DNA polymerases alpha, beta, and gamma, on mammalian RNA polymerases I, II, and III, or on reverse transcriptases from Moloney murine leukemia virus (Mo-MuLV) and from HIV. For a further elucidation of the antiviral effect of Avarol, we used NIH-3T3 cells infected with Mo-MuLV as a model system. The results show that in uninfected NIH-3T3 cells Avarol (i) causes a 50% reduction of the growth rate only at the high concentration of 29.6 microM and (ii) is accumulated in the cytoplasm close to the nucleus. At the much lower concentrations of 1-3 microM, Avarol causes an almost complete inhibition of viral progeny release. Moreover, it is shown that at 3 microM Avarol, the increase of the Mo-MuLV-induced UAG suppressor glutamine tRNA (tRNA(UmUGGln) was reduced to the normal level. Dot blot hybridization studies revealed that Avarol displays no inhibitory activity on cellular and viral mRNA synthesis. Taking the processing pathway of viral polyprotein Pr180gag,pol to p80 (reverse transcriptase) as an example, our Western blotting experiments showed that the final maturation process, conversion of p110 to p80, is inhibited in Avarol-treated cells. From these data we conclude that Avarol prevents the suppression of the UAG termination codon at the gag-pol junction of the retroviral genome. The functional consequence of this event is very likely an inhibition of the readthrough of the retroviral protease gene which overlaps the pol and gag genes, resulting in the reduction of the protease synthesis which is necessary for the viral proliferation.
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PMID:Selective inhibition of formation of suppressor glutamine tRNA in Moloney murine leukemia virus-infected NIH-3T3 cells by Avarol. 245 80

People exposed to benzene, an important industrial solvent and a common pollutant, can develop aplastic anemia and leukemia. The objectives of this study were to develop a physiological model for the metabolism of benzene, based on studies in laboratory animals, and to use this model to predict benzene metabolism in people to concentrations near the current permissible exposure limits. Model simulations predicted that for 8-h inhalation exposures to below 10 ppm, hydroquinone metabolites would predominate. Hydroquinone is associated with pathways leading to the formation of the putative toxic metabolite, benzoquinone. Lower levels of muconic acid, a marker for the putative toxic metabolite, muconaldehyde, were predicted. At concentrations above 10 ppm, detoxification metabolites such as the phenyl conjugates predominate. Predictions of benzene metabolism in humans based on our physiological model may have important implications for risk assessment. Because there may be preferential production of a putative toxic metabolite at low exposure concentrations, linear extrapolation of toxicity observed at high concentrations may underestimate risk at low exposure concentrations.
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PMID:A toxikinetic model for simulation of benzene metabolism. 263 46

Two melanotic human melanoma cell lines, IRE 1 and IRE 2, and the lymphoma- and leukaemia-derived cell lines Raji and K 562, were exposed to different concentrations (from 5 X 10(-3) M to 10(-5) M) of phenols, both substrates (s) and non-substrates (ns) of tyrosinase, in the presence or absence of the oxygen-radical-scavenger enzymes superoxide dismutase, catalase and peroxidase. Monophenols were tyrosine (s), 4-hydroxyanisole (s) and butylated hydroxyanisole (ns); diphenols were L-3,4-dihydroxyphenylalanine (s), dopamine (3,4-dihydroxyphenethylamine) (s), terbutylcatechol (s), hydroquinone (s) and resorcinol (ns); triphenols were 6-hydroxydopa (3,4,6-trihydroxyphenylalanine) (s) and methyl gallate (s). Triphenols and o- and p-diphenols underwent complete oxidation in culture medium within 24 h of incubation and were significantly more toxic than monophenols and the m-diphenol resorcinol, which, under the same cultural conditions, were much more stable. No significant differences in percentage survival were found among the different cell lines for each drug tested. The major component of toxicity up to 24 h of di- and tri-phenols is due to toxic oxygen species acting outside the cells and not to cellular uptake of these phenols as such. In fact the addition of oxygen-radical-scavenger enzymes significantly (P less than 0.01) decreased the adverse effect of these drugs on all cell lines. The lower toxicity of monophenols and resorcinol as compared with that of di- and tri-phenols is due, in our opinion, to the fact that they are less oxidized under the conditions existing in the culture medium, and therefore do not produce sufficient levels of oxygen radicals. For these compounds, a primary intracellular action has to be taken into account to explain their cytotoxicity.
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PMID:Comparative cytotoxicity of phenols in vitro. 282 25

Benzene is a heavily used industrial chemical, a petroleum byproduct, an additive in unleaded gas, and a ubiquitous environmental pollutant. Benzene is also a genotoxin, hematotoxin, and carcinogen. Chronic exposure causes aplastic anemia in humans and animals and is associated with increased incidence of leukemia in humans and lymphomas and certain solid tumors in rodents. Bioactivation of benzene is required for toxicity. In the liver, the major site of benzene metabolism, benzene is converted by a cytochrome P-450-mediated pathway to phenol, the major metabolite, and the secondary metabolites, hydroquinone and catechol. The target organ of benzene toxicity, the hematopoietically active bone marrow, metabolizes benzene to a very limited extent. Phenol is metabolized in the marrow cells by a peroxidase-mediated pathway to hydroquinone and catechol, and ultimately to quinones, the putative toxic metabolites. Benzene and its metabolites appear to be nonmutagenic, but they cause myeloclastogenic effects such as micronuclei, chromosome aberrations, and sister chromatid exchange. It is unknown whether these genomic changes, or the ability of the quinone metabolites to form adducts with DNA, are involved in benzene carcinogenicity. Benzene, through its active metabolites, appears to exert its hematological effects on the bone marrow stromal microenvironment by preventing stromal cells from supporting hemopoiesis of the various progenitor cells. Recent advances in our understanding of the mechanisms by which benzene exerts its genotoxic, hematotoxic, and carcinogenic effects are detailed in this review.
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PMID:Recent advances in the metabolism and toxicity of benzene. 331 42


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