The use of short-term tests to measure the preventive action of reducing agents on formation and activation of carcinogenic nitroso compounds

The effect of reducing agents on the nitrosation of methylguanidine (MG) and on the in vitro activation of dimethylnitrosamine (DMN) was examined by measuring DNA-repair synthesis (unscheduled incorporation of [3h]TdR), shifts in alkaline sucrose gradients, frequency of chromosome aberrations, and clone-forming capacity of cultured human fibroblasts. The reducing agents examined were sodium ascorbate, cysteine, cysteamine, and propyl gallate. Since the short-term bioassays used can be quantitated, it has become relatively easy to detect the inhibitory action of reducing compounds on the nitrosation reaction of MG and metabolic activation (with S-9 preparation) of the precarcinogen DMN, to measure their effective dose range, and to establish the most effective ratios between inhibitory agent and reactant. The results indicate that DNA-repair synthesis is a suitable short-term test for studying the numerous combinations and premutations between several carcinogenic or non-carcinogenic agents, and for estimating the capacity of inhibitory agents to affect formation and activation of chemical carcinogens.     

Comparison of the continuous rat hepatoma cell line 2sFou with primary rat hepatocyte cultures for the induction of DNA repair synthesis by nitrosamines, benzo[a]pyrene and hydroxyurea

We have examined the suitability of the continuous rat hepatoma cell line 2sFou for testing the genotoxicity of chemicals in comparison with that of primary rat hepatocyte cultures (HPC). The capacity of the cells for metabolic activation was assessed by measuring induction of DNA-repair synthesis and inhibition of replicative DNA synthesis by the test compounds dimethylnitrosamine (DMN), diethylnitrosamine (DEN), hydroxyurea (HU) and benzo[a]pyrene (BaP), which are substrates for major hepatic and extrahepatic forms of cytochrome P-450 dependent monooxygenases. The cellular capacity for DNA-repair synthesis was assessed using UV-light as a DNA-damaging agent. Repair-specific incorporation of [3H]deoxycytidine (3H-dCyd) caused by UV-light was higher in 2sFou cells than in HPC. In contrast, background repair incorporation of 3H-dCyd in 2sFou cells was only 1/3 that found in HPC. All the test agents induced DNA repair and inhibited DNA synthesis in both 2sFou cells and HPC. The two nitrosamines were more effective in HPC than in 2sFou cells. HU and BaP affected DNA repair and DNA synthesis in the two cell systems at a similar range of concentrations. In general, DNA repair in the 2sFou cells increased near linearly with the concentrations of the test compounds. The data indicate that 2sFou cells are capable of activating hepatotropic pro-mutagens/carcinogens such as dialkylnitrosamines, and are sensitive indicators of DNA damage. In contrast, BaP, a non-hepatotoxic compound, caused only little DNA repair in these cells. Thus, continuously growing cells, such as 2sFou, show a qualitatively similar response to genotoxic chemicals as HPC and offer a potential alternative to HPC for genotoxicity testing.     

Age-related variation in the DNA-repair synthesis after UV-C irradiation in unstimulated lymphocytes of healthy blood donors

UV-C light-induced DNA-repair synthesis was studied in unstimulated lymphocytes of 51 healthy blood donors aged between 17 and 74 years. Repair synthesis was measured by the incorporation of [³H]thymidine after a 2-h incubation period in the presence of 2 mM hydroxyurea. The evaluation included (1)the spontaneous DNA-synthesis in unirradiated lymphocytes with and without hydroxyurea, (2) the DNA-repair synthesis in lymphocytes irradiated with UV-light.The interindividual variation was significantly higher than the methodological variation ascertained in 24 persons in whom 2 determinations were carried out.In blood donors aged between 17 and 39 years, the spontaneous DNA synthesis, both with and without hydroxyurea, was significantly lower than in older individualsThe DNA-repair synthesis was dependent on the dose of UV-C light between 2 and 16 J/M². There were no significant differences in DNA-repair synthesis in the age range 17–74 years. The variations in rate of DNA-repair synthesis (greater or lesser degree of [³H]thymidine incorporation beyond the 99% confidence range) were wider in older (44–74 years), than in younger individuals.     

Repair synthesis and sedimentation analysis of DNA of human cells exposed to dimethylnitrosamine and activated dimethylnitrosamine

The capacity of dimethylnitrosamine(DMN), and of DMN activated by a NADPH-fortified mouse liver microsomal preparation, to elicit DNA alterations in cultured human fibroblasts was examined. A maximum induction of DNA repair synthesis, estimated by unscheduled incorporation of tritiated thymidine, occurred following 60-minute incubation of the human cells with DMN activated by a NADPH-fortified mouse liver microsomal preparation. A low level of DNA repair activity followed exposure to DMN alone, or to DMN mixed with the microsomal preparation without NADPH or without O₂. The extent of DNA damage, estimated by velocity sedimentation of DNA through alkaline sucrose gradients, was maximum following treatment with DMN mixed with the NADPH-fortified microsomal preparation. The combined application of $\text{in vitro}$ activation systems and estimation of DNA repair synthesis in cultured cells may be exploited in the detection of precarcinogens.     

Inhibition of protein and DNA synthesis in tissue culture cells by a derivative of methyl glyoxal and ascorbate

The inhibitory effect of a methyl glyoxal-ascorbate (MGA) adduct (NFCR 278021) on protein and DNA synthesis in monolayer cultures of GPK epithelial cells has been compared with the inhibitory action of methyl glyoxal (MG). GPK cells exhibited an ID₅₀ of 0.98 μM MG for both protein and DNA synthesis compared with an ID₅₀ of 0.92 mM for the adduct. Hill plots demonstrate that the characteristics of the receptor saturation are the same for MG and MGA, suggesting that the action of the two agents is mediated through the MG moiety which is modified by the presence of the ascorbate portion of the molecule in MGA. It is shown that MGA undergoes spontaneous oxidation in solution and is a substrate for ascorbate oxidase, but that no additional MG activity is released by total enzymic oxidation of MGA, and oxidised MGA possesses the same inhibitory characteristics as MGA. Inhibition of protein synthesis by ascorbate or dehydroascorbate were not demonstrated in the dose range employed for MGA. The inhibitory effect of the adduct on protein synthesis was found to be diminished in the presence of glutathione and glyoxalase I (Glo I) and II (Glo II).     

Unscheduled DNA synthesis of rat hepatocytes in monolayer culture

Monolayer cultures of rat hepatocytes activated tris(2,3-dibromopropyl)phosphate (Tris-BP) more efficiently than 2-acetylaminofluorene (AAF), to genotoxic products which caused mutations in co-cultures of S. typhimurium. In contrast, AAF caused a greater genotoxic response in the hepatocytes than Tris-BP, as judged by the increase in DNA-repair synthesis measured by liquid scintillation counting of ³H-TdR incorporated into DNA isolated from the nuclei of the hepatocytes. Covalent binding of 0.05 mM ³H-Tris-BP to cellular proteins occurred at a similar rate as covalent binding of 0.25 mM ¹⁴C-AAF. Tris-BP was the more cytotoxic of the two compounds as determined by leakage of cellular lactate dehydrogenase into the culture medium. The observed differences in the cytotoxic and genotoxic responses between Tris-BP and AAF were probably caused by differences in the nature of their reactive metabolites with respect to stability, lipophilicity and/or their interactions with variuos cellular nucleophilic sites. The relative DNA-repair synthesis induced by an AAF exposure for 18 h decreased with time after plating of isolated hepatocytes. Tris-BP first caused an increase in the relative DNA-repair synthesis up to 27 h after plating, whereafter the response declined reaching control values using cultures 75 h after plating. In parallel with the decreased relative response in DNA-repair synthesis with time, the background radioactivity in isolated nuclei from untreated cells increased both when the hepatocytes were incubated in the presence or absence of hydroxyurea to inhibit replicative DNA synthesis. Increased DNA-repair synthesis was demonstrated as early as 3 h after commencing exposure to the test substances. While the induced DNA-repair synthesis caused by Tris-BP remained constant after 6 h of exposure, the response caused by AAF increased with increased exposure time beyond 6 h. To assess the role of different metabolic pathways in the genotoxic and cytotoxic responses of Tris-BP and AAF, the hepatocytes were exposed to test substances in the presence of various metabolic inhibitors for 3 h, whereafter the cell medium was removed and replaced by cell-culture medium containing ³H-TdR and hydroxyurea. The cytochrome P-450 inhibitor metyrapone decreased both the genotoxic and cytotoxic effects of Tris-BP, while α-naphthoflavone reduced the genotoxic effect of AAF. The addition of glutathione (GSH) or N-acetylcysteine decreased both the cytotoxic and genotoxic effects of Tris-BP, while cellular depletion of GSH by diethylmaleate increased these effects. Manipulations in the cellular levels of sulhydryl-containing substances in the hepatocytes by these agents had little effects on the DNA-repair synthesis caused by AAF. The results indicate that such a hepatocyte culture system may be very useful as a tool to study mechanisms involved in the formation of cytotoxic and/or genotoxic metabolites from various xenobiotics.     

The effect of humic acids,fractionated according to molecular mass,on the formation and mutagenicity of N-methyl-N-nitrosourea

Fractions of humic acids (HA-K⁺) of molecular mass between 500 and 300 000 and exceeding 300 000 showed a very high nitrite depleting ability, whereas the fraction of HA-K⁺ with molecular mass lower than 500 had little or no such effect. Autoclaving HA-K⁺ (121 °C, 20 min) decreased the nitrite-depleting ability to about a half. This observation correlates with the results of mutagenic studies in Arabidopsis thaliana, demonstrating the inhibitory effect of HA-K⁺ and its fractions on the formation of mutagenic N-methyl-N-nitrosourea (MNU) from the nitrosation mixture of N-methylurea and nitrite. Nonfractionated HA-K⁺ had no inhibitory effect towards the mutagenic activity of preformed direct acting MNU or towards the activation of the promutagen N-nitrosodimethylamine to a mutagenic product.     

DNA damage, DNA repair and chromosome aberrations of xeroderma pigmentosum cells and controls following exposure to nitrosation products of methylguanidine

Nitrosation of methylguanidine (MG) led to products that caused DNA fragmentation (shift in sedimentation profiles of velocity centrifugation through alkaline sucrose gradients), a DNA repair synthesis (unscheduled uptake of (³H]TdR), chromosome aberrations and a lethal effect of cultured human fibroblasts. The response of repair-deficient xeroderma pigmentosum cells did not differ from that of controls. The nitrosation of MG must be carried out at a pH level below 3, in order to obtain products that react with cellular DNA. The results show that a DNA repair synthesis of human fibroblasts appear to be a sensitive assay for carcinogenic and mutagenic nitrosation products which may be formed within an organism from non-carcinogenic compounds.     

Measurement of genotoxic activity in multiple tissues following inhalation exposure to dimethylnitrosamine

Chemically-induced DNA repair was measured as unscheduled DNA synthesis (UDS) in selected tissues isolated from rats following in vivo exposure to inhaled dimethylnitrosamine (DMN). UDS was evaluated in epithelial cells from rat nasal turbinates and trachea, in hepatocytes and in pachytene spermatocytes from the same treated animal. At nominal concentrations of 500 and 1000 ppm of DMN in air, chemically-induced DNA repair was observed in the epithelial cells of the upper respiratory system. DMN also entered the circulation, as evidenced by a strong DNA-repair response in hepatocytes. No DNA repair was observed in pachytene spermatocytes indicating either that DMN or its active metabolites did not reach the testes in sufficient concentration to induce DNA repair or that the testes lacked the capability to metabolically activate the compound. These results illustrate the potential of this approach to assess the organ-specific genotoxicity of environmental chemicals.     

Mutagenicity of Maillard browning reaction products from various nitrosated amino acid-glucose mixtures

Ten different amino acid-glucose Maillard browning products before and after reaction with nitrite were evaluated by the Ames mutagenicity assay. No mutagenic response was observed in the methylene chloride extracts of any browning products tested before nitrosation. However, mutagenicity was showed in most of the browning mixtures, e.g., glycine-glucose, lysine-glucose (I), arginine-glucose, phenylalanine-glucose (II), and methionine-glucose after nitrosation when examined by Salmonella typhimurium strains TA98 and TA100 either with or without S-9 metabolic activation. Among the browning mixtures, (I) and (II) showed the greatest mutagenic activity after reaction with nitrite. The mutagenicity of lysine-glucose with nitrite was dependent on browning intensity, nitrosation pH, nitrosation time, nitrite level and blocking agents.     

N G,N G -Dimethyl-l-arginine,a dominant precursor of endogenous dimethylamine in rats

Summary The metabolic significance ofN ^G ,N ^G -dimethyl-l-arginine (DMA) as a precursor of endogenous dimethylamine (DMN) in rats was examined in connection with the wide distribution and active operation of dimethylargininase (EC3.5.3.18) in rat tissues (Kimoto et al., 1993). When [methyl-¹⁴C]DMA was administered intraperitoneally to rats, the radioactive DMN was detected in various tissues as a major radioactive metabolite one hour after injection, and about 65% of the radioactivity administered was recovered in the first 12-h urine as DMN. In the case of the [¹⁴C] DMN-injected rats, almost all the radioactivity was excreted in the 12-h urine as DMN, except for a negligible amount of radioactivity found in urea. The time-dependent decrease in the specific radioactivity of DMA and DMN in urine showed that dimethylargininase was significantly involved in thein vivo formation of DMN by the hydrolytic cleavage of DMA released from methylated proteins and that DMA is a dominant precursor of endogenous DMN in rats.     

Sensitization of rad mutants of Dictyostelium discoideum to ultraviolet light by postirradiation treatment with caffeine

The capacity of normal human cells to regulate DNA-repair pathways was examined. Synchronous populations of WI-38 human diploid fibroblasts were used to determine whether base-excision repair was increased as a function of the cell cycle. 2 parameters of the base-excision repair pathway were examined: (1) The induction of the DNA-repair enzyme uracil DNA glycosylase which functions in an initial step in base excision repair: (2) cell-mediated base-excision repair as measured by unscheduled DNA synthesis after exposure to sodium bisulfite or to methyl methanesulfonate. The glycosylase activity was increased 5-fold during cell proliferation; unscheduled DNA synthesis was enhanced 4- to 30-fold in a similar fashion. Equivalent results were observed where repair replication was quantitated using density-gradient analysis in the absence of hydroxyurea. The increase of the activity of the uracil DNA glycosylase and the enhancement of DNA repair occurred prior to the induction of DNA replication. Furthermore, at the maximal stimulation of DNA replication both glycosylase activity and DNA repair had substantially diminished. As the cells entered the second cell cycle, the glycosylase activity was again increased and then was again diminished. These results suggest that human cells actively modulate this DNA-repair pathway. The temporal stimulation of base-excision repair suggests the possibility that a DNA-repair complex may be formed prior to DNA replication to prescreen DNA and thus ensure the transfer of the correct genetic information to daughter cells.     

The inhibitory effect of whole and deproteinized saliva on mutagenicity and clastogenicity resulting from a model nitrosation reaction

The objective of this study was to simulate in vitro at least some of the conditions that prevail in man during ingestion of nitrate and nitrosable compounds. Human saliva has been chosen because most chemicals ingested through food will interact with saliva. The nitrosation of methylurea was used as a model because the nitrosation products can be readily detected by their mutagenic (his+ revertants of S. typhimurium) and clastogenic (chromosome aberrations in CHO cells) properties. The results show that human saliva inhibits the formation of mutagenic and clastogenic nitrosation products when present during nitrosation. A 50% inhibition of mutagenicity results from the addition of a saliva sample diluted at 5% of the original concentration. In the test system used a similar inhibitory effect was obtained by 2.5 mM ascorbic acid or 2.0 mM chlorogenic acid. The main inhibitory agents seem to reside in a deproteinized fraction which was filtered through an ultrafilter UM2 (greater than 1000 MW). At strong acid levels (below pH 2) the saliva loses its inhibitory effect on the nitrosation of methylurea. The contribution of saliva to the inhibition of endogenous nitrosation within the oral cavity or stomach is discussed.     

Importance of pH and disulfide bridges on the structural and binding properties of human α₁-acid glycoprotein

Human α₁-acid glycoprotein (AGP) is an acute phase plasma glycoprotein containing two disulfide bridges. As a member of the lipocalin superfamily, it binds and transports several basic and neutral ligands, but a number of other activities have also been described. Thanks to its binding properties, AGP is also a good candidate for the development of biosensors and affinity chromatography media, and in this context detailed structural information is needed. The structural properties of AGP at different p²Hs and under reducing conditions were analysed by FT-IR spectroscopy. The obtained data indicate that AGP, when denatured, does not aggregate at neutral or basic p²Hs whilst it does at acidic p²Hs. Under reducing conditions the protein is remarkably less thermostable than its oxidized counterpart and presents an enhanced tendency to aggregate, even at neutral p²H. A heat-induced molten globule-like state (MG) was detected at 55 °C at p²H 7.4 and 5.5. At p²H 4.5 the MG occurred at 45 °C with an onset of formation at 40 °C. The MG was not observed under reducing conditions. A lower affinity of chlorpromazine and progesterone for the MG formed at p²H 4.5 and 40 °C was observed, suggesting that ligand(s) may be released near the negative surfaces of biological membranes. Furthermore, the reduced AGP displays an enhanced affinity for progesterone, indicating the importance of disulfide bonds for the binding capacity of AGP.     

Corticosteroids inhibit the delivery of short-term activational pulses of phorbol ester and calcium ionophore to human peripheral T cells.

Although there is evidence that corticosteroids inhibit receptor-ligand-induced phospholipid hydrolysis, the immunosuppressive effects of these agents downstream of protein kinase C (PK-C) activation and cytosolic Ca2+ mobilization is unclear. Previous studies indicated that T cell proliferative activation could be achieved with simultaneous short-term (e.g., 15-120 min) exposure to agents activating PK-C and elevating cytosolic Ca2+. In the studies reported here, similar procedures were utilized for determining whether corticosteroids alter T cell activation signals downstream of second messenger events. Dexamethasone interfered with T cell activation induced by short-term exposure to phorbol 12,13-dibutyrate (PDBu) and the calcium ionophore, ionomycin. The inhibitory effect was evident with as little as 15 min of exposure to dexamethasone and T cell activating agents, making mechanisms involving de novo protein synthesis unlikely. Dexamethasone's effects in this system were blocked by the steroid receptor antagonist RU-486, indicating that the inhibition was mediated through the glucocorticoid receptor. The inclusion of recombinant interleukin-2 (IL-2) only partially overcame the dexamethasone inhibitory effect. Long-term (i.e., 48 hr) direct stimulation of PK-C with either PDBu or the non-tumor-promoting PK-C activator, bryostatin 1, also substantially overcame dexamethasone's effects, resulting in a recovery of IL-2 production and significant restoration of the T-cell proliferative response. These observations suggest that treatment with a PK-C-activating agent such as bryostatin 1 could reduce glucocorticosteroid-induced immunosuppression.     

Oxidation of N-Nitrosoalkylamines by Human Cytochrome P450 2A6: SEQUENTIAL OXIDATION TO ALDEHYDES AND CARBOXYLIC ACIDS AND ANALYSIS OF REACTION STEPS*

Cytochrome P450 (P450) 2A6 activates nitrosamines, including N,N-dimethylnitrosamine (DMN) and N,N-diethylnitrosamine (DEN), to alkyl diazohydroxides (which are DNA-alkylating agents) and also aldehydes (HCHO from DMN and CH₃CHO from DEN). The N-dealkylation of DMN had a high intrinsic kinetic deuterium isotope effect (^Dk_app ∼ 10), which was highly expressed in a variety of competitive and non-competitive experiments. The ^Dk_app for DEN was ∼3 and not expressed in non-competitive experiments. DMN and DEN were also oxidized to HCO₂H and CH₃CO₂H, respectively. In neither case was a lag observed, which was unexpected considering the k_cat and K_m parameters measured for oxidation of DMN and DEN to the aldehydes and for oxidation of the aldehydes to the carboxylic acids. Spectral analysis did not indicate strong affinity of the aldehydes for P450 2A6, but pulse-chase experiments showed only limited exchange with added (unlabeled) aldehydes in the oxidations of DMN and DEN to carboxylic acids. Substoichiometric kinetic bursts were observed in the pre-steady-state oxidations of DMN and DEN to aldehydes. A minimal kinetic model was developed that was consistent with all of the observed phenomena and involves a conformational change of P450 2A6 following substrate binding, equilibrium of the P450-substrate complex with a non-productive form, and oxidation of the aldehydes to carboxylic acids in a process that avoids relaxation of the conformation following the first oxidation (i.e. of DMN or DEN to an aldehyde).     

Abnormal response of glycolipid synthesis to temperature in transformed BHK cells thermosensitive for growth control.

In DMN4B cells, a line of chemically mutagenized BHK hamster cells which exhibit transformed behavior at 38.5°C but not at 32°C, [¹⁴C]-palmitate incorporation into mono-, di-, and trihexosylceramides was unimpaired at 32°C when compared with incorporation rates in untransformed BHK cells. At 38.5°C, labeling of these glycolipids increased greatly in the BHK cells, but failed to increase comparably in the DMN4B cells. Assay of cell-free preparations of the galactosyltransferase which catalyzes trihexosylceramide synthesis revealed a stimulatory effect of increased temperature on activity of the BHK enzyme, but not the DMN4B enzyme. The results suggest that transformation can result from a mutation affecting glycolipid synthesis.     

Passive knee movement-induced modulation of the soleus H-reflex and alteration in the fascicle length of the medial gastrocnemius muscle in humans

In humans, an inhibitory via Ia afferent pathway from the medial gastrocnemius (MG) to the soleus (SOL) motoneuron pool has been suggested. Herein, we examined the relation between MG fascicle length changes and the SOL H-reflex modulation during passive knee movement. Twelve subjects performed static and passive (5° s^?1) knee movement tasks with the ankle immobilized using an isokinetic dynamometer in sitting posture. The maximal H- and M-waves were measured at four target angles (20°, 40°, 60°, and 80° flexion from full knee extension). The MG fascicles length and velocity were measured using a B-mode ultrasonic apparatus. Results demonstrated that the SOL Hmax/Mmax; i.e., ratio of the maximal H- to M-waves, was attenuated with increasing MG fascicle length in static tasks. The SOL Hmax/Mmax at 20° was significantly attenuated compared with 60° and 80° with increasing MG fascicle length and lengthening velocity in passive knee extension. However, no significant differences in the SOL Hmax/Mmax were found across the target angles in the passive knee flexion task. In conclusion, as muscle spindles increase their discharge with lengthening fascicle velocity, but keep silent when fascicles shorten, our data suggest that lengthening the MG facilitates an inhibitory Ia pathway from MG to SOL, and modulates SOL motoneuron activity during movements.