Binding of nitrosamines to cytochrome P-450 of liver microsomes.

The interactions of 5 carcinogenic and 1 non-carcinogenic nitrosamines with hepatic microsomal cytochrome (cyt.) P-450 were investigated, using both optical difference and electron paramagnetic resonance (EPR) spectroscopic methods. Liver microsomes from phenobarbital (PB)-pretreated mice and 3-methylcholanthrene (3-MC)-pretreated rats were used, in order to have an increased specific content of cyt. P-450 and cyt. P-448 respectively. The optical and EPR spectral data obtained in the oxidised state suggest that nitrosamines are able to bind both as substrates and as ligands to the hemoprotein cyt. P-450, depending on the concentration of nitrosamine, its chemical identity and the cytochrome species present. After reduction with dithionite or NADPH in the optical difference spectrum a Soret band developed between 444 and 453 nm to an extent, which is dependent on the particular nitrosamine present. This initial nitrosamine-induced spectrum might represent a ferrous nitric oxide (NO)-cyt. P-450 complex. It appears unstable and is converted kinetically into a spectrum lacking a Soret band, but with a predominant absorbance minimum at about 425 nm. A visible band is located at 585 nm. In the EPR spectrum a sharp 3-line signal around g = 2.01 appears concomitantly. Both spectral parameters are typical of a NO-cyt. P-420 complex. These results, in conjunction with metabolic studies, indicate that nitrosamines are denitrosated by a reductive process in which cyt. P-450 appears to be involved. The resulting NO-cyt. P-450 complex denatures to a NO-cyt. P-420 complex when the dioxygen level is not sufficiently high to complete successfully.     

Molecular effects of nitrosamine toxicity.

Nitrosamines are toxic chemical compounds found low in quantity, but widespread in the environment. This work investigated the kinetics of chemical reaction of activated nitrosamines with various organic substrates. The mechanism by which nitrosamines react demonstrates possible pathways in which the toxicity is expressed. Once activated nitrosamines are very reactive. Chemical compounds which can act as nucleophilic substrates may be alkylated by the activated nitrosamines. A broad category of chemical compounds are shown to be suitable substrates for nitrosamine induced alkylation. This large category of substrates suggests a substantial potential for toxic activity in vivo. By investigating the reaction kinetics of activated nitrosamines a greater understanding of their toxic effects may be possible.     

Nasal cavity carcinogenesis by N-nitrosamines: a critical appraisal

This review is a critical appraisal of our current knowledge on nasal cavity carcinogenesis by nitrosamines. The pathology and pathogenesis of nitrosamine-induced tumors in the nasal cavity of rodents is summarized while controversies on the underlying molecular mechanisms are discussed in more detail. Investigations on the distribution of metabolically competent cell types, the cellular site(s) of nitrosamine metabolism, as well as reports on the cellular distribution and persistence of DNA-adducts strongly suggest that DNA-adducts formed from reactive metabolites are not immediately responsible for the genesis of nasal cavity tumors. A preexisting high proliferative ability has also been suggested as a factor rendering certain cell types more susceptible to the carcinogenic actions of nitrosamines in the nasal cavity. However, this hypothesis has been clearly rejected by more recent investigations. Recent studies have shown that nitrosamines can stimulate the secretion of growth factors via interaction with neurotransmitter receptors in the lungs and that this molecular mechanism is an important factor in determining the histological phenotype of the developing lung tumors. In light of the fact that secretory cells are the main sites of DNA-adduct accumulation and toxic lesions in the nasal cavities of nitrosamine treated rodents, it is suggested that similar mechanisms may mediate the genesis of nitrosamine-induced nasal cavity tumors.     

7-azabicyclo[2.2.1]heptane as a structural motif to block mutagenicity of nitrosamines

Nitrosamines are potent carcinogens and toxicants in the rat and potential genotoxins in humans. They are metabolically activated by hydroxylation at an α-carbon atom with respect to the nitrosoamino group, catalyzed by cytochrome P450. However, there has been little systematic investigation of the structure-mutagenic activity relationship of N-nitrosamines. Herein, we evaluated the mutagenicity of a series of 7-azabicyclo[2.2.1]heptane N-nitrosamines and related monocyclic nitrosamines by using the Ames assay. Our results show that the N-nitrosamine functionality embedded in the bicyclic 7-azabicylo[2.2.1]heptane structure lacks mutagenicity, that is, it is inert to α-hydroxylation, which is the trigger of mutagenic events. Further, the calculated α-C-H bond dissociation energies of the bicyclic nitrosamines are larger in magnitude than those of the corresponding monocyclic nitrosamines and N-nitrosodimethylamine by as much as 20-30 kcal/mol. These results are consistent with lower α-C-H bond reactivity of the bicyclic nitrosamines. Thus, the 7-azabicyclo[2.2.1]heptane structural motif may be useful for the design of nongenotoxic nitrosamine compounds with potential biological/medicinal applications.     

Induction of repair synthesis of DNA in primary cultures of rat urothelial cells by derivatives of the bladder carcinogen, N-n-butyl-N-(4-hydroxybutyl)nitrosamine

Urinary metabolites of N-n-butyl-N-(4-hydroxybutyl)nitrosamine (BHBN) which have been identified thus far did not induce repair synthesis of DNA in cultured rat urothelial cells. Urine of rats which had been administered with BHBN or BCPN did not induce repair synthesis of DNA either. However, all the synthetic nitrosamines that can produce 1-hydroxyalkylnitrosamine intermediates induced repair synthesis of DNA. The results suggest that rat urothelial cells, at best, may only have very limited capability of activating nitrosamines.     

Photolysis of nitrosamines and nitrosamides at neutral pH: a spin-trap study

A model system has been used to study the types of radicals formed on denitrosation of N-nitroso compounds. Free radicals were formed at room temperature (22 degrees-23 degrees C) and neutral pH by photolytic cleavage of N-nitroso bonds and were partially characterized following their addition to the spin traps 5,5-dimethyl-1-pyrroline-N-oxide (DMPO) and N-tert-butyl-alpha-phenyl-nitrone (PBN). Carbon-centered radical adducts were obtained during nitrosamine photolysis and nitrogen-centered radical adducts during nitrosamide photolysis. Since both the nitrosamines and nitrosamides initially form nitrogen-centered radicals on photolysis, a secondary reaction or rearrangement must occur after initial N-nitroso bond cleavage in the nitrosamines. Mechanisms are proposed to account for these results.     

Protein-ligand interactions: interaction of nitrosamines with nicotinic acetylcholine receptor

Fluorimetry and spectrophotometry have been used to study the binding of dimethyl, dipropyl, dibutyl and diphenylnitrosamine to nicotinic acetylcholine receptor isolated, and purified, from Torpedo fuscomaculata. Scatchard analysis indicates that all four ligands are true agonists of the receptor exhibiting positive cooperative binding with the existence of more than one class of binding site. The number of binding sites for the nitrosamines approximates 2. Diphenylnitrosamine binds to the receptor more tightly at low concentrations (Kd1 = 1.3 microM) than the aliphatic nitrosamine (Kd1 = 8-12 microM). Yet at high concentrations all nitrosamines behaved with similar Kd values (27-38 microM).     

Degradation of N-Nitrosamines by Intestinal Bacteria

A major proportion of bacterial types, common in the gastrointestinal tract of many animals and man, were active in degrading diphenylnitrosamine and dimethylnitrosamine, the former being degraded more rapidly than the latter. At low nitrosamine concentrations (<0.05 μmol/ml), approximately 55% of added diphenylnitrosamine, 30% of N-nitrosopyrrolidine, and 4% of dimethylnitrosamine were degraded. The route of nitrosamine metabolism by bacteria appears to be different from that proposed for breakdown by mammalian enzyme systems in that carbon dioxide and formate were not produced. In bacteria, the nitrosamines were converted to the parent amine and nitrite ion and, in addition, certain unidentified volatile metabolites were produced from dimethylnitrosamine by bacteria. The importance of bacteria in reducing the potential hazard to man of nitrosamines is discussed.     

Metabolic activation capabilities of S9 and hepatocytes from uninduced rats to convert carcinogenic N-nitrosamines to mutagens

6 carcinogenic nitrosamines were studied in Salmonella typhimurium TA1535 after activation by S9 and by hepatocytes. All nitrosamines were activated by S9 from induced rats, regardless of their organotropy. The hepatocarcinogenic nitrosamines (N-nitrosodimethylamine, NDMA; N-nitrosodiethylamine, NDEA; N-nitrosomorpholine, NM and N-nitrosodibutylamine, NDBA) were activated to mutagens by S9 and by hepatocytes both derived from noninduced rat livers, NDMA and NM inducing more his+ revertants in the presence of hepatocytes. The oesophageal carcinogenic nitrosamine N-nitrosomethylbenzylamine (NMBeA) and bladder organotrophic N-nitroso(4-hydroxybutyl)butylamine(NBBOH) were neither converted by liver preparations of uninduced rats into mutagenic intermediates nor by hepatocytes. This study indicates that isolated cells derived from untreated animals may be better suited to study liver specific activation in vitro than disrupted subcellular metabolizing systems from induced animals.     

Synthesis and properties of bifunctional chloroalkyl nitrosamines with an intercalating moiety

Three N-nitroso-N-(arylcarbonyloxymethyl)-3-chloropropylamines were synthesized, and their chemical and biological properties were studied. All arylcarboxylates intercalated with double-stranded DNA, and their mutagenicity and DNA cross-linking activity were affected by their ring structure. The DNA interstrand cross-link formation increased dose dependently after treatment with the acridine analog. The anthraquinone analog showed the highest bacterial mutagenicity among the three nitrosamines in Salmonella typhimurium TA100, while in Salmonella typhimurium TA92, which can detect cross-linking agents, the acridine analog showed the highest mutagenicity. This agreed with the result of a cross-linking assay. These results suggest that the three-ring aromatic moiety gives DNA-intercalating ability to cross-linkable chloropropyl nitrosamine, and the acridine analog is considered as a possible new antitumor lead compound.     

Interaction and inhibition of acetylcholinesterase from Electrophorus electricus by nitrosamines

Kinetic analysis has shown that dimethylnitrosamine, dipropylnitrosamine, dibutylnitrosamine, and diphenylnitrosamine initially act as reversible competitive inhibitors with respect to the substrate, acetylthiocholine chloride. The inhibitor constants Ki vary from 21-30 microM for the aliphatic nitrosamines to 8.2 microM for the aromatic diphenylnitrosamine. With time they act as irreversible covalent inhibitors with dimethylnitrosamine producing 82% inactivation after 40 min. Pseudo-first-order kinetics are observed with the rate constant being proportional to the concentration of the nitrosamine and the order of reaction being equal to one. Fluorometry, gel chromatography, and equilibrium dialysis have been used to study the binding of the nitrosamines with acetylcholinesterase. Scatchard analysis indicates that dimethyl-, dipropyl-, and dibutylnitrosamine have a weaker affinity for the enzyme (Kd 5.6-8.08 microM) compared to diphenylnitrosamine (Kd 2.32 microM). In all cases the number of binding sites was four.     

Molecular modeling of nitrosamines adsorbed on H-ZSM-5 zeolite: An ONIOM study

Binding energies of nitrosamine compounds, N-nitrosamine (NA), N-methyl-N-nitrososamine (NMA), N-ethyl-N-nitrososamine (NEA), N,N-dimethyl-N-nitrosoamine (NDMA), N-ethyl-N-methyl-N-nitrosoamine (NEMA) and N,N-diethyl-N-nitrosoamine (NDEA) on the H-ZSM-5 zeolite were obtained using the ONIOM(B3LYP/6–31G(d):AM1) approach. Based on amino and imino isomers of nitrosamines, there are two adsorption configurations on the H-ZSM-5 for NA (as NA_a and NA_i), NMA (as NMA_a and NMA_i) and NEA (as NEA_a and NEA_i). The relative binding energies of nitrosamines are in order: NA_a > NMA_a ~ NEA_a > NA_i > NMA_i ~ NEA_i > NEMA ~ NDEA > NDMA. The order of adsorption selectivity for nitrosamines of the H-ZSM-5 is NA_a ~ NA_i >> NMA_a ~ NEA_a > NDMA ~ NMA_i ~ NEMA > NDEA ~ NEA_i. The selective recognition of the NA by the H-ZSM-5 was obviously found. Figure The optimized structures of adsorption complexes with the most stable conformers of the N-methyl-N-nitrososamine (NMA), N-ethyl-N-nitrososamine (NEA), N,N-dimethyl-N-nitrososamine (NDMA), N-ethyl-N-methyl-N-nitrososamine (NEMA) and N,N-diethyl-N-nitrososamine (NDEA) on the H-ZSM-5 zeolite     

The rat-liver carcinogen N-nitrosomorpholine initiates unscheduled DNA synthesis and induces micronuclei in the rat liver in vivo

Alkylation of DNA is generally accepted as the primary event in the carcinogenicity of nitrosamines. However, the cyclic nitrosamine N-nitrosomorpholine (NMOR), a potent rat hepatocarcinogen, has been reported as binding at very low levels to the liver DNA of treated rats. This led us to investigate the activity of NMOR in two in vivo rat-liver genotoxicity assays--for the induction of unscheduled DNA synthesis (UDS) and the production of micronucleated hepatocytes in the liver micronucleus assay (LMN). Rats treated with oral doses of NMOR (10-200 mg/kg) gave a positive liver UDS response either 2.5 h or 12 h after dosing. Similarly, treatment with oral doses of NMOR (10 or 100 mg/kg) followed by mitogenic stimulation with 4-acetylaminofluorene (4AAF) resulted in high incidences of micronucleated hepatocytes in the LMN assay. These data confirm that the genotoxicity reported for NMOR in vitro can be reproduced in vivo and that NMOR interacts with liver DNA of treated rats. Earlier reports of only very weak binding of radiolabelled NMOR to rat liver DNA in vivo are discussed within the context of these data.     

Carcinogenesis and nucleic acid alkylation by some oxygenated nitrosamines in rats and hamsters

A comparison has been made of the carcinogenic effects of nitroso-2,6-dimethylmorpholine and several hydroxylated acyclic nitrosodialkylamines derived from it or related to it in rats and Syrian hamsters. In rats nitrosodimethylmorpholine was the most potent, inducing mainly esophageal tumors. Nitrosodiethanolamine was the weakest of the five nitrosamines in both rats and hamsters. Tumors of the pancreas ducts were induced by four of the five compounds, but only in hamsters, and esophageal tumors appeared only in rats. Most of the nitrosamines induced tumors of liver and lung in both rats and hamsters. A study of alkylation of nucleic acids of the liver following treatment of rats and hamsters with the radiolabeled nitrosamines showed that nitrosodiethanolamine alkylated liver nucleic acids in rats to only a very small extent. The other four nitrosamines all gave rise to 7-methylation and O6-methylation of guanine residues in DNA of hamster liver and all but nitrosodimethylmorpholine in rat liver DNA, which corresponded quite well with the induction of liver tumors in the two species. Quantitatively, however, there was not a good correlation between liver DNA alkylation and the potency of the nitrosamine in inducing tumors.     

Mutagenicity arising from near-ultraviolet irradiation of N-nitrosomorpholine

When a mixture of N-nitrosomorpholine and S. typhimurium TA100 in saline was irradiated with near-ultraviolet light, mutagenesis of the bacteria took place. The same observation was made with S. typhimurium TA1535, E. coli WP2 uvrA, pKM101 and uvrA/pKM101. Several other nitrosamines showed ed the same, but weaker, effect. Evidence is presented to indicate that the mutagenicity arises from the cellular phosphate-mediated photochemical formation of direct-acting mutagen from the nitrosamine.     

顶羽菊提取物清除亚硝酸盐及阻断亚硝胺合成能力的研究

目的:测定顶羽菊不同提取物对亚硝酸钠的清除能力以及对亚硝胺合成的阻断能力。方法:通过索氏提取法和浸提法提取顶羽菊的活性成分,在模拟人体胃液条件下,采用分光光度法测定顶羽菊不同提取物对亚硝酸钠的清除能力和对亚硝胺合成的阻断能力,并与Vc进行了比较。结果:顶羽菊提取物对亚硝酸钠的清除率和对亚硝胺合成的阻断率与其浓度呈正相关,醇提物和水提物对亚硝酸钠的清除率分别可达60%、58%,对亚硝胺合成的阻断率可达86.6%、48.6%。结论:通过与Vc的对照分析可知,顶羽菊提取物具有较强的清除亚硝酸钠和阻断亚硝胺合成的能力。     

The human cytochrome P4507B1: catalytic activity studies

The cytochrome P4507B1 (P4507B1) in the human hippocampus is responsible for the production of 7alpha-hydroxylated derivatives of dehydroepiandrosterone (DHEA) and other 3beta-hydroxylated neurosteroids. Minor quantities of the 7beta-hydroxylated derivatives are also produced. Neuroprotective action of these 7-hydroxysteroids was reported. Recombinant human P4507B1 was prepared from yeast coexpressing the human hippocampal P450 cDNA and the human P450 reductase genes. Microsomal P4507B1 activity was tested in the presence of NADPH and (14)C-labeled steroid substrates to deduce kinetic parameters and to study inhibitor responses. The K(M) values obtained for DHEA, pregnenolone, epiandrosterone, 5alpha-androstane-3beta,17beta-diol and estrone were 1.90 +/- 0.06, 1.45 +/- 0.03, 1.05 +/- 0.12, 0.8 +/- 0.04 and 1.20 +/- 0.26 microM, respectively. Production of limited amounts of 7beta-hydroxylated derivatives was also observed, but only with DHEA, 5alpha-androstane-3beta,17beta-diol and epiandrosterone. K(M) values determined for 7beta-hydroxylation were identical to those for 7alpha-hydroxylation. The DHEA 7alpha-hydroxylation was inhibited by estrone and estradiol (mixed type inhibition) and by the [25-35] beta-amyloid peptide (non-competitive inhibition). These results indicate that in human, the 7-hydroxylation catalysed by P4507B1 preferentially takes place on DHEA, 5alpha-androstane-3beta,17beta-diol and epiandrosterone with major and minor formation of 7alpha- and 7beta-hydroxylated derivatives, respectively. Both estrogens and a beta-amyloid component inhibit the P4507B1-mediated production of the 7-hydroxysteroid metabolites.     

Acute biochemical and morphological effects of N-nitrosomorpholine in comparison to dimethyl- and diethylnitrosamine.

Some biochemical and ultrastructural changes induced in the livers of rats treated with N-nitrosomorpholine are described and compared with parallel observations in rats given dimethyl- or diethylnitrosamine. Hepatotoxic doses of the nitrosamines caused inhibition of incorporation of [14C]leucine into hepatic proteins, accompanied by progressive disaggregation of polysomes which paralleled the known time course of metabolism of each compound. Dimethylnitrosamine (DMN) and N-nitrosomorpholine (NM) inhibited incorporation of [14C]orotate into liver RNA but diethylnitrosamine (DEN) caused a slight stimulation of orotate incorporation. Electron microscopy revealed similar hepatic cytoplasmic changed induced by each nitrosamine, including dilation and degranulation of the rough surfaced endoplasmic reticulum and subsequent increase of the smooth endoplasmic reticulum. Nuclear changes differed with each compound, N-nitrosomorpholine having more marked effects than either dialkyl compound. The results are discussed with particular reference to the metabolism of N-nitrosomorpholine in the liver.     

Formation of epsilon-hydroxycaproate and epsilon-aminocaproate from N-nitrosohexamethyleneimine: evidence that microsomal alpha-hydroxylation of cyclic nitrosamines may not always involve the insertion of molecular oxygen into the substrate

The formation of the products of microsomal metabolism of the cyclic nitrosamine, nitrosohexamethyleneimine (NO-HEX) were studied. Information on the origins of the oxygen atoms in four major metabolites of NO-HEX was obtained by metabolizing this compound in an 18O2 atmosphere using microsomes and cytosol, beta- and gamma-Hydroxy-NO-HEX are formed as a result of the insertion of a hydroxyl group derived from molecular oxygen into NO-HEX. All of the oxygen atoms in epsilon-aminocaproate (EAC) were derived from water. Approximately half of the molecules of epsilon- hydroxycaproate ( EHC ) contain an 18O atom; thus, half of the alpha-hydroxy-NO-HEX formed incorporates a hydroxyl group derived from molecular oxygen with the remainder of the hydroxyls being from water. To account for the above data and the related metabolic origins of EAC and EHC ( Hecker and McClusky , Cancer Res., 42 (1982) 59; Hecker et al., Teratogen. Carcinogen. Mutagen (1982) in press), we have proposed a mechanism for the formation of these compounds from cyclic nitrosamines catalyzed by microsomal and cytosolic enzymes.     

Mutagenicity of nitrosamines in methyltransferase-deficient strains of Salmonella typhimurium coexpressing human cytochrome P450 2E1 and reductase

Although dialkylnitrosamines are environmentally significant carcinogens, the use of short-term bioassays to assess the mutagenic potential of these compounds is problematic. The Ames test, a mutagenicity assay based on the reversion of Salmonella typhimurium histidine auxotrophs, is the most widely used bioassay in genetic toxicology, but the traditional Ames tester strains are largely insensitive to dialkylnitrosamine mutagenicity. We have constructed two mutagenicity tester strains that co-express full-length human cytochrome P450 2E1 and P450 reductase in S. typhimurium lacking ogt and ada methyltransferases (YG7104ER, ogt- and YG7108ER, ogt-, ada-). These new strains are susceptible to dialkylnitrosamine mutagenicity in the absence of an exogenous metabolic activating system (S9 fraction). Mutagenicity is dependent upon the coexpression of P450 2E1 with P450 reductase and is similar to or greater than that obtained with the parental strains in the presence of S9 fraction from ethanol-induced rat liver. These strains were also sensitive to nitrosamines with longer alkyl side chains including diethylnitrosamine, dipropylnitrosamine and dibutylnitrosamine. Mutagenicity decreased with alkyl chain length, consistent with the stringency of the ada-encoded enzyme for methyl and ethyl DNA adducts. These new strains may prove useful in the evaluation of nitrosamine contamination of food and environmental samples.