Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0596263 (carcinogenesis)
 64,820 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A comparative study of three in vitro metabolising systems was performed in combination with Chinese hamster V79 cells, at which point mutation to 6-thioguanine resistance was scored. The three metabolising systems used were: (1) rat liver microsomal fraction (S9-mix); (2) feeder layer of primary embryonic golden hamster cells, according to Hubermann's system; (3) in vitro perfusion of rat liver according to the system of Beije et al. As model substances dimethylnitrosamine (DMN) and benzo[a]pyrene (BP) was used. The liver perfusion was more efficient than S9-mix as an activating system of DMN, while the feeder layer of embryonic cells was unable to activate this compound. The activation of DMN with S9-mix was dependent on the presence of NADP. By exposing the target cells in the liver perfusion at different distances from the liver the biological half life of the active metabolite of DMN could be estimated to less than 5 s. With BP the three metabolising systems showed reversed results as compared with DMN--both the feeder layer cells and S9-mix activated BP, the feeder layer cells being most efficient. With liver perfusion, the perfusate itself was totally negative. Only the bile showed a week mutagenic effect. These results are in accordance with the notion that intact liver cells perform both an activation and a subsequent deactivation of BP. Because of the importance of hepatic bio-transformation in chemical mutagenesis and carcinogenesis it is emphasied that a liver perfusion system could be used in a testing protocol for genotoxic effects as a valuable tool in order to analyse the mechanism of action of mutagenic and carcinogenic compounds detected in other test systems, for instance bacterial/microsomal tests.
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PMID:Mutagenicity testing on chinese hamster V79 cells treated in the in vitro liver perfusion system. Comparative investigation of different in vitro metabolising systems with dimethylnitrosamine and benzo[a]pyrene. 47 53

Dihydrodiol dehydrogenase (DD; EC 1.3.1.20) purified to homogeneity from rat liver cytosol will catalyze the NAD(P)(+)-dependent oxidation of (+/-)-trans-7,8-dihydroxy-7,8-dihydrobenzo[a]pyrene (B[a]P-diol) to yield benzo[a]pyrene-7,8-dione (BPQ). To verify that BPQ is a metabolite of B[a]P-diol in rat liver, an S100 fraction was supplemented with NAD+ and NADP+, and the formation of BPQ was followed by reverse-phase HPLC. The identity of BPQ was established by co-chromatography with an authentic standard (under different solvent conditions) and by RP-HPLC using a diode-array detector which established that the metabolite shared spectral identity with BPQ. The formation of BPQ in the S100 fraction was blocked by either a competitive inhibitor (indomethacin) or a suicide substrate [1-(4-nitrophenyl)-propen-1-ol] for DD, indicating that BPQ was being formed by this enzyme. To assess the contribution of DD to the metabolism of [3H]B[a]P-diol, subcellular fractions obtained from uninduced rat liver were fortified with co-factors to optimize the activity of enzymes that would compete for this proximate carcinogen. Under these conditions, S100 fractions fortified with NAD+ and NADP+ metabolized 25% of the B[a]P-diol, producing 731 +/- 154 pmol of BPQ. In contrast, rat liver microsomes fortified with an NADPH generating system metabolize 75% of the B[a]P-diol producing 2614 +/- 379 pmoles of benzo[a]pyrene-tetrahydrotetrols. Rat liver homogenates (S10) fortified with either uridine diphosphoglucuronic acid or phosphoadenosine phosphosulfate produced 180 +/- 56 and 95 +/- 31 pmoles of conjugates respectively, which were recovered as B[a]P-diol after treatment of the aqueous phase with either beta-glucuronidase or aryl sulfatase. Of the metabolites analyzed BPQ was formed in the second largest amount. These studies show that in uninduced rat liver DD may play a significant role in the metabolism of B[a]P-diol. The metabolic fate of BPQ remains to be determined.
Carcinogenesis 1992 Sep
PMID:Contribution of dihydrodiol dehydrogenase to the metabolism of (+/-)-trans-7,8-dihydroxy-7,8-dihydrobenzo[a]pyrene in fortified rat liver subcellular fractions. 139 42

The significance of the nonspecific esterases of human mononuclear leukocytes (HMLs) in arylamine carcinogenesis is suggested by data showing that the metabolically formed hydroxamic acid derivative of 2-acetylaminofluorene, N-hydroxy-2-acetylaminofluorene, is a substrate for this class of enzymes. A viable cell assay for the nonspecific esterases using alpha-naphthyl acetate as substrate is described, and data showing this activity to be sensitive to already known substrates for HML esterases as measured by three previously described assays are presented. All four assays of the same esterase activity are shown to be highly sensitive to up- and down-regulation by addition of NADPH or NADP to viable HML cultures. Selective activation of a purified rabbit nonspecific esterase by NADPH, but not by the other cellular reductants, NADH and glutathione, was demonstrated. Cytosols prepared from normal human tissue samples of liver, breast, colon, and brain were also activated by the presence of NADPH. These data do not indicate that steroidal nonspecific esterases are redox-modulated by the presence of mixed disulfides in their structure. Instead, they support the direct and specific influence of NADPH as a widespread activator of esterase activity by a mechanism not yet understood.
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PMID:Steroidal nonspecific esterase metabolism of N-hydroxy-2-acetylaminofluorene: evidence for selective activation by the cellular reductant NADPH. 143 49

Aldehydes are highly reactive molecules that may have a variety of effects on biological systems. They can be generated from a virtually limitless number of endogenous and exogenous sources. Although some aldehyde-mediated effects such as vision are beneficial, many effects are deleterious, including cytotoxicity, mutagenicity, and carcinogenicity. A variety of enzymes have evolved to metabolize aldehydes to less reactive forms. Among the most effective pathways for aldehyde metabolism is their oxidation to carboxylic acids by aldehyde dehydrogenases (ALDHs). ALDHs are a family of NADP-dependent enzymes with common structural and functional features that catalyze the oxidation of a broad spectrum of aliphatic and aromatic aldehydes. Based on primary sequence analysis, three major classes of mammalian ALDHs--1, 2, and 3--have been identified. Classes 1 and 3 contain both constitutively expressed and inducible cytosolic forms. Class 2 consists of constitutive mitochondrial enzymes. Each class appears to oxidize a variety of substrates that may be derived either from endogenous sources such as amino acid, biogenic amine, or lipid metabolism or from exogenous sources, including aldehydes derived from xenobiotic metabolism. Changes in ALDH activity have been observed during experimental liver and urinary bladder carcinogenesis and in a number of human tumors, including some liver, colon, and mammary cancers. Changes in ALDH define at least one population of preneoplastic cells having a high probability of progressing to overt neoplasms. The most common change is the appearance of class 3 ALDH dehydrogenase activity in tumors arising in tissues that normally do not express this form. The changes in enzyme activity occur early in tumorigenesis and are the result of permanent changes in ALDH gene expression. This review discusses several aspects of ALDH expression during carcinogenesis. A brief introduction examines the variety of sources of aldehydes. This is followed by a discussion of the mammalian ALDHs. Because the ALDHs are a relatively understudied family of enzymes, this section presents what is currently known about the general structural and functional properties of the enzymes and the interrelationships of the various forms. The remainder of the review discusses various aspects of the ALDHs in relation to tumorigenesis. The expression of ALDH during experimental carcinogenesis and what is known about the molecular mechanisms underlying those changes are discussed. This is followed by an extended discussion of the potential roles for ALDH in tumorigenesis. The role of ALDH in the metabolism of cyclophosphamidelike chemotherapeutic agents is described. This work suggests that modulation of ALDH activity may an important determinant of the effectiveness of certain chemotherapeutic agents.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Aldehyde dehydrogenases and their role in carcinogenesis. 152 60

A model of liver hyperplastic noduligenesis was induced in rats in vivo by long-term administration of thioacetamide (TAM; 100 mg/kg day i.p.). Three doses of 50 mg/kg of an antitumoral rhodium(III) complex were administered at 14, 9 and 5 days before the end of TAM treatment. Blood and liver were obtained from either TAM, Rh(III) complex or TAM plus Rh(III) complex-treated rats in order to determine the interaction of both (tumoral and antitumoral) substances with the biochemical pathways related to glutathione redox cycle, enzyme activities involved in the oxidative stress coupled to the NADPH/NADP pair and enzymes related to the mono-oxygenase P450 system. The results showed that TAM induced an imbalance between the activities of glutathione-coupled enzymes. Glutathione reductase activity increased along with the intoxication, while glutathione peroxidase activity decreased. Alterations in the activity of soluble glutathione peroxidase were parallel to those of catalase. These results, together with decreased activities of enzymes related to cytochrome P450 mono-oxygenase system, NADPH cytochrome P450 reductase and NADH cytochrome b5 reductase, suggest that liver cells are not protected against the peroxidative stress produced by chronic administration of TAM. The Rh(III) complex did not produce significant changes in the parameters assayed when administered alone. When this complex was administered to TAM-treated rats, significant restoration of the following activities was observed: those of NADPH-generating enzymes (glucose-6-phosphate dehydrogenase and malic enzyme), that of glutathione reductase (NADPH-consuming enzyme), NADPH-cytochrome P450 reductase and total catalase. These results, together with others in previous studies, suggest that the altered liver function induced by chronic administration of TAM can be partially restored by this rhodium complex. The mechanisms by which this complex counteracts the TAM-induced changes have not yet been established.
Carcinogenesis 1991 Feb
PMID:Alterations in hepatic peroxidation mechanisms in thioacetamide-induced tumors in rats. Effect of a rhodium(III) complex. 167 54

The effect of di(2-ethylhexyl)phthalate (DEHP) on diethylnitrosamine (DEN)-initiated preneoplastic liver lesions with expression of gamma-glutamyltranspeptidase (GGTase) and loss of adenosine triphosphatase (ATPase) as well as alterations of hepatic carbohydrate metabolism in male and female Sprague-Dawley rats have been investigated. Two treatment schedules have been compared with respect to their sensitivity by the histochemical demonstration of preneoplastic islands and by the biochemical determination of alterations in enzyme activities of liver homogenates and of serum, the last indicating hepatotoxicity. For initiation, a single dose of DEN was given, followed by treatment with various doses of DEHP given three times weekly by gavage for 7 or 11 consecutive weeks. As histochemical enzyme markers, the expression of positive GGTase as well as the deficiency in ATPase were used for identification of liver foci. The weanling female rats (protocol A) were found to be more sensitive to the carcinogenic effect of DEN in view of foci incidence than the mature male rats which underwent partial hepatectomy prior to DEN application. The administration of 200 mg DEHP/kg body wt increased the incidence of ATPase-deficient foci in both male and female rats; however, concentrations of 1000 and 2000 mg DEHP/kg decreased the incidence of liver foci. The number of foci with expression of GGTase was only slightly increased in female rats following a DEHP concentration of 50 mg/kg, and 200 mg/kg body wt. DEHP alone did not induce preneoplastic lesions that could be identified by these two markers. Biochemical investigations indicate that DEHP alters the metabolic pattern in liver. An increase of the NADP-linked enzymes glucose-6-phosphate dehydrogenase (G6PDH), malic enzyme, extra-mitochondrial ICDH as well as an enhancement of NAD-dependent alpha-G3PDH and lactate dehydrogenase were found following DEHP administration. On the other hand the glycolytic enzymes pyruvate kinase (PK) and enolase as well as the gluconeogenetic enzyme fructose-1,6-bisphosphatase (FBPase) were significantly reduced. In protocol B (male rats) the reactions of PK, FBPase and malic enzyme were more altered after DEHP exposure than in protocol A, while the activity of G6PDH was more increased in protocol A. Most enzymes being involved in the carbohydrate metabolism are influenced by DEHP in a dose-dependent manner. There was no increase in serum FBPase activity in both male and female rats after DEHP treatment but a reduction of glutamate-oxalate-transaminase and glutamate-pyruvate-transaminase activities was observed.(ABSTRACT TRUNCATED AT 400 WORDS)
Carcinogenesis 1990 Dec
PMID:Di(2-ethylhexyl)phthalate alters carbohydrate enzyme activities and foci incidence in rat liver. 197 36

The time courses of induction of liver cytosolic aldehyde dehydrogenases using benzaldehyde and propionaldehyde as substrates and NADP and NAD as co-factors after i.p. and intragastric (i.g.) administration of 2-acetylaminofluorene (2-AAF), 20-methylcholanthrene (20-MC), beta-naphthoflavone (beta-NF) and benzo[alpha]pyrene (B[alpha]P) were investigated in male Wistar rats. 2-AAF did not induce the aldehyde dehydrogenase activities with any substrate:co-factor combination. The other three inducers all induced the oxidation of the aldehydes in a reversible manner. With an i.p. route of administration (one daily dose for four consecutive days) (20-MC) was the most potent inducer giving a 240-fold increase of benzaldehyde: NADP activity on the ninth day. beta-NF elevated the activity 20-fold with peak activity at day 7, while B[alpha]P gave maximal induction on day 5 with a 60-fold increase in activity over the corresponding value for normal liver. The i.g. administration resulted in a weaker but coordinated induction of activity with peak activity on the sixth day for the different inducers. The activity ratio benzaldehyde:NADP/propionaldehyde:NAD, 0.78 in normal rats, was altered in all induced states to a level close to 4. The interpretation of our work supports the hypothesis that the inducers in this respect use the same mechanisms of induction. The differences noted can be explained by variations in the exposure of the liver to the administered dose and/or by differences in receptor affinity. The inducibility of benzaldehyde:NADP aldehyde dehydrogenase in rat liver exceeds by orders of magnitude the ability of the same inducers to increase the amount of the activity of other drug metabolizing enzymes such as glutathione S-transferase, cytochrome P450 and cytochrome b5. The reversible, drug-dependent induction characterized in normal rat liver in this work differs entirely from the persistent constitutive elevation of the same enzymes in preneoplastic liver nodules.
Carcinogenesis 1991 May
PMID:Kinetics of induction of cytosolic benzaldehyde: NADP and propionaldehyde: NAD aldehyde dehydrogenase activities in rat livers from male Wistar rats. 202 38

Topical application on rat oral mucosa of the chemical 4-nitroquinoline 1-oxide (4NQO) has been shown to produce squamous cell carcinomas on the posterior tongue and/or the posterior hard palate. 4NQO is broken down in vivo by a diaphorase, 4NQO reductase (E.C.1.6.99.2), to produce an active molecule believed to be responsible for carcinogenesis. It has been shown that there are higher concentrations of 4NQO reductase in oesophageal mucosa compared with elsewhere in the gastrointestinal tract. The purpose of these experiments was to compare the distribution of certain diaphorases in the oral mucosa. Samples of rat tongue and cheek epithelia were homogenized, then ultracentrifuged to provide mixed cytosol and microsome fractions from the epithelial cells. A spectrophotometer was used to measure the variation in absorbance at 340 nm of NADH consumed by reduction of 4NQO by enzymes present in the tissue extracts. A histochemical technique was used to compare the activity of NADH diaphorase, NADP diaphorase and glucose-6-phosphate dehydrogenase at different sites of the oral mucosa. Statistical analysis showed that there were significant (P less than 0.01) differences between the activities of all three enzymes at different sites of the oral mucosa. In each case, a higher activity was found at the sites of high incidence of squamous cell carcinoma. A lower activity was found at sites where carcinomas did not occur.
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PMID:A relationship found between intra-oral sites of 4NQO reductase activity and chemical carcinogenesis. 211 96

Dihydrodiol dehydrogenase (DD; EC 1.3.1.20) will oxidize non-K-region trans-dihydrodiols of polycyclic aromatic hydrocarbons (PAHs), a reaction that can suppress the formation of PAHs) anti-diol epoxides or ultimate carcinogens. Using benzenedihydrodiol [(+/-)-trans-1,2-dihydroxy-3,5-cyclohexadiene] as a model substrate for trans-dihydrodiol metabolites of PAHs, 23 human liver and eight human lung samples were examined for enzyme activity. In human liver, enzyme activity could be measured spectrophotometrically and specific activities ranged from 0.16 to 6.1 nmol benzenedihydrodiol oxidized min/mg protein. Western blot analysis of human liver cytosol using rabbit anti-rat DD serum detected two bands of mol. wts 34,000 and 27,000. The former mol. wt is identical to that observed for the homogeneous rat liver enzyme. Gel-filtration experiments indicate that human liver DD activity elutes as a single peak and co-elutes with the purified rat liver enzyme, suggesting that the lower mol. wt species may be an artefact of degradation. Preparations of the human liver enzyme required NADP- for activity and were in general, insensitive to inhibition by dicoumarol, indomethacin and 6-medroxyprogesterone acetate. These properties distinguish the enzyme from alcohol dehydrogenase, quinone reductase and rat liver DD. In human lung, DD activity was barely detectable using a sensitive radiochemical assay in which the oxidation of benzenedihydrodiol to catechol is linked to catechol-O-methyl transferase using [3H]S-adenosyl methionine as methyl donor. Specific activities were approximately 1000th of that observed for human liver and ranged from 1 to 4 pmol benzenedihydrodiol oxidized/min/mg protein. Western blot analysis of lung cytosol detected three bands of mol. wts 34,000, 31,000 and 28,000. The relatively high levels of DD in human liver suggest that this enzyme may play an important role in PAH detoxication in this organ, while the low levels of DD in lung may contribute to the susceptibility of this tissue to PAH-induced carcinogenesis.
Carcinogenesis 1990 Jul
PMID:Characterization of dihydrodiol dehydrogenase in human liver and lung. 219 14

In a previous study of the metabolism of methyl-n-amylnitrosamine (MNAN) in the rat, 2- to 5-hydroxy-MNAN (HO-MNAN) were provisionally identified as metabolites and the identity of 4-HO-MNAN was confirmed by mass spectrometry. We now describe syntheses and mass and other spectra for 2- to 5-oxo-MNAN. Two previously unidentified MNAN metabolites were shown to be 3- and 4-oxo-MNAN. In addition to 4-HO-MNAN, we confirmed 3-HO-, 4-oxo- and (less certainly) 2-HO-MNAN as urinary MNAN metabolites by GLC-MS of HPLC fractions. Analysis with and without beta-glucuronidase treatment showed that the urinary HO-MNANs occurred as their beta-glucuronides. MNAN (25 mg/kg injected i.p.) had a blood half-life of 21 min in adult male rats. The blood also contained 4-HO- and 4-oxo-MNAN, which showed maximum levels that were 13 and 26% respectively of that for MNAN, and were cleared more slowly than MNAN. On incubation for 3 h with MNAN, rat esophagus produced 3- and 4-oxo-MNAN in yields that were 5% of those for the corresponding HO-MNANs. For MNAN metabolism, the 4-oxo-/4-HO-MNAN ratio of metabolites was 5% for adult rat liver and was 22% for adult hamster liver and 9-day-old rat liver. On incubation with 4-HO-MNAN for 3 h, oxidation to 4-oxo-MNAN was 16-25% for adult hamster or 9-day-old rat liver slices and for adult hamster liver homogenate. Homogenate activity was concentrated in the microsomal fraction, for which NAD was a more effective co-factor than NADP. A bacterial alcohol dehydrogenase oxidized 4-HO- to 4-oxo-MNAN in 38% yield/3 h. None of these preparations oxidized 2-HO- to 2-oxo-MNAN. It was concluded that 3- and 4-oxo-MNAN were metabolites of MNAN, apparently (for 4-oxo-MNAN) via HO-MNAN oxidation by a microsomal NAD-dependent enzyme, that 4-HO- and 4-oxo-MNAN formation was a major route of MNAN metabolism, and that 4-oxo-MNAN might play a role in MNAN carcinogenesis.
Carcinogenesis 1989 Dec
PMID:Ketonitrosamines as metabolites of methyl-n-amylnitrosamine (MNAN) and its hydroxy derivatives in the rat. 259 Oct 9


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