Mutagenic activity of 6-azido deoxyhexoses and azido alcohols in Salmonella typhimurium and its inhibition by a structure-similar carbon source in the medium

6-Azido-6-deoxy (AZd) derivatives of D-glucose, D-mannose, D-altrose, D-allose, L-idose, D-galactose, D-galactonic acid and D-galactitol, 3-azido-1,2-propanediol (azidoglycerol), 3,1-diazido-2-propanol (diazidoglycerol) and (at much higher doses) 2-azidoethanol were mutagenic in Salmonella typhimurium strains TA100 and TA1535. The mutagenic response was similar to that induced by sodium azide, i.e., the azido compounds failed to induce mutations in strain TA98, and mutagenesis was independent of plasmid pKM101, and independent of external activation. The specific mutagenicity (his+ rev/mmole) of AZd-glucose and AZd-galactose was decreased with increasing concentrations of D-glucose or D-galactose in the minimal agar medium and enhanced 100-fold or more when 0.2% citrate rather than 0.2% glucose served as the carbon source in the medium. Similarly, the mutagenic efficiency of azidoglycerol was inhibited by glycerol but not by D-glucose or D-galactose; however, the mutagenicity of sodium azide was not influenced by any of these carbon sources in the medium. The inhibition of the mutagenic action of azido hexoses and azido alcohols by non-azido structural analogs is assumed to reside in competition in transmembrane transport or for the metabolic pathways.     

Effects of pH on the mutagenicity of sodium azide in Neurospora crassa and Salmonella typhimurium

Sodium azide at various pH values did not cause a significant increase in the frequency of forward mutation above the control frequency at the adenine-3 (ad-3) region in resting conidia and in conidia from growing cultures of heterokaryons 12 and 59 of Neurospora crassa. Conidia from ad-3 mutants were plated with sodium azide at various pH values, and no obvious increase in reverse mutation above the controls was observed. Data are presented showing that sodium azide at pH 3 is inactivating conidia by interacting with the cytoplasma rather than the nucleus, and this may be the primary reasons that no mutation at the ad-3 region was detected. The dependence of sodium azide mutagenicity on pH was investigated in histidine-requiring mutants of Salmonella typhimurium using a suspension test. There were no significant differences in the reversion frequencies among the pH values (3-8) tested. Thus, no pH dependence is associated with sodium azide mutagenicity, nor are growth and/or DNA replication required for mutagenicity by sodium azide, in S. typhimurium.     

Effect of glutathione L-cystein and L-djenkolic acid in the synthesis and mutagenicity of azide metabolite in Bacillus subtilis ATCC 6633 strain.

The Bacillus subtilis ATCC 6633 strain synthesizes a mutagenic metabolite from sodium azide and O-acetylserine. Mutagenicity of azide was decreased in growth media containing 10(-4) M glutathione, L-cysteine or L-djenkolic acid whereas dithiothritol (DTT) added at the same concentration did not reduce the mutagenicity of azide. Likewise, glutathione, L-cysteine, L-djenkolic acid, and DTT were found to have no effect in reducing the mutagenicity of the in vitro produced metabolite using bacterial cell-free extract. These results suggest that O-acetyl-serine sulfhydrylase catalyzes the reaction of azide and O-acetylserine to form a mutagenic metabolite, which is ninhydrin positive and migrates in TLC to an Rf value similar to that of azidoalanine in both acidic and basic solvent systems.     

New fluorogenic, photoactivable, heterobifunctional crosslinking thiol reagents

Properties of newly synthesized crosslinking reagents (ACM) and their applications to proteins are studied (ACM is the abbreviation for a series of photoactivable and heterobifunctional crosslinking thiol reagents, each of which has two reactive groups, maleimide and azide). These reagents bind specifically to the sulfhydryl residues of proteins in the first reaction step. Upon photoactivation, the azide group of the coumarin ring reacts with side or main chains of the proteins, and thus intra- or intermolecular crosslinking can be elicited. In addition, the coumarin moiety of the reagents becomes highly fluorescent after photolysis. Therefore, the crosslinking products can be detected by fluorometry with high sensitivity in the pattern of sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Reaction of ACM with rabbit muscle aldolase led to extensive crosslinking between subunits of the enzyme and maximally 25% of the total subunits were found to be crosslinked to the dimer.     

Lack of induction of single-strand breaks in mammalian cells by sodium azide and its proximal mutagen

The mutagenicity of sodium azide in both higher plants and bacteria is well documented. However, in mammalian cells, research on the effects of azide on gene mutations has produced conflicting results. Furthermore, no research has been conducted on the effects of azide and its proximal mutagen (mutagenic metabolite) on DNA single-strand breaks. Experiments were designed to overcome this lack of information on azide mutagenicity and to evaluate the potential hazard of azide exposure to man.Chinese hamster V79 cells were treated with either azide or its proximal mutagen(s) for 2 or 6 h, respectively, and analyzed by alkaline elution for single-strand breaks. The data showed that neither azide nor the proximal mutagen(s) induced single-strand DNA breaks or DNA-protein cross-links.Therefore it appears that neither azide nor its proximal mutagen(s) interact directly with DNA and this suggests that azide may be an indirect-acting mutagen. Furthermore, this lack of interaction with DNA may account for azide's lack of carcinogenicity.     

Antimutagenicity of propionic acid bacteria.

The antimutagenic effect of dialysed cell extracts of 4 strains of propionic acid bacteria was examined against the mutagenicity of sodium azide in the TA1535 tester strain of Salmonella typhimurium using the Ames test. It was noted that dialysates of 2 strains of Propionibacterium shermanii, P. pentosaceum and P. acnes, significantly reduced sodium azide-induced revertants. The dialysate of propionic acid cocci did not show an antimutagenic effect. The inhibitory activity was enhanced if the mutagen and extract were coincubated for 20 min prior to performing the mutagenicity assay. Antimutagenicity of dialysates from P. shermanii VKM-103 against MNNG and 9-aminoacridine was shown in S. typhimurium strains TA1535 and TA97. The antimutagenic activity was found in the protein fraction of the cell extract of P. shermanii. The proteins of the dialysate of P. shermanii were separated using a Toyopearl gel column into 3 main peaks according to their molecular weights. The antimutagenic activity towards sodium azide was found in the second and the third peaks. We suggest that dialysates of the cells of propionic acid bacteria contain several kinds of antimutagenic substances with different molecular weights.     

Differential metabolism of sodium azide in maize callus and germinating embryos

Sodium azide is a potent mutagen of maize (Zea mays L.) kernels that may have potential as a point mutagen for inducing biochemical mutations in maize tissue cultures. Azide mutagenicity was evaluated in friable, embryogenic maize callus and a nonregenerable maize suspension culture by determining the number of resistant variant cell lines able to grow on media containing inhibitory concentrations of lysine plus threonine (LT). The number of LT-resistant variants selected from either culture type did not increase in response to azide treatment. In addition, there was no increase in somatic mutations in more than 100 plants regenerated from azide treated LT-resistant lines. The levels of mutagenic metabolite of azide (presumably azidoalanine), were determined by bioassay in the two azide-treated maize callus types and compared to levels of mutagenic metabolite in embryos isolated from azide-treated kernels. The two types of maize tissue cultures and isolated embryos contained similar levels of mutagenic metabolite 4 h after azide treatment indicating similar uptake and conversion of azide to mutagenic metabolite in the three tissues. Mutagenic metabolite in azide-treated embryos did not significantly decrease after 40 h. However, mutagenic metabolite levels in both azide-treated tissue cultures decreased to near background levels within 20 h providing evidence for rapid metabolism of the azide mutagenic metabolite. The lack of evidence for azide mutagenicity in maize callus and its known potent mutagenicity in kernels appears to be associated with specific differences in azide metabolism between callus tissues and kernel embryos.     

Antimutagenicity of some citrus fruits in Salmonella typhimurium

The antimutagenic effect of 10 citrus fruit juices was observed against the mutagenicity of N-nitro-o-phenylenediamine (NPD) in TA97a and sodium azide in TA100 tester strains of Salmonella typhimurium using the Ames test. It was noticed that the juices of all these fruits reduced significantly the NPD and sodium azide induced revertant colonies. The inhibitory activity was enhanced if the mutagen and juice were co-incubated for about 30 min at 37 degrees C prior to performing the mutagenicity assay. Dilution with distilled water led to the reduction in the inhibitory activity. The antimutagenic activity of synthetic ascorbic acid or citric acid or combined ascorbic acid and citric acid was also seen. But the results with fruit juices tempted us to believe that in addition to ascorbic acid and citric acid, the presence of other factor(s) possessing antimutagenic properties cannot be ruled out.     

Human saliva inactivates mutagenicity of carcinogens

Mutagenicities of AF-2, MNNG, 4NQO, aflatoxin B₁, benzo[a]pyrene P-1 with or without metabolic activation, were inactivated by treatment with human saliva to a great extent in the Ames test with salmonella typhimurium test strains TA98 and TA100. Mutagenic activities of quercetin, pyrolsates of beef, salmon and sodium glutamate, and condensate of cigarette smoke were also decreased to some extent by saliva treatment, but no significant effect was found on the activity of MMS and pyrolysate of polypeptone. These effects showed individual variations.The inhibition of AF-2 mutagenicity by saliva varied with temperature in TA100 but not in TA98 cultures. Boiled saliva inactivated AF-2 mutagenicity in TA98 to some extent but not in TA100 cultures. Inactivation of AF-2 mutagenicity by saliva treatment was completed within 30 sec.Complex mechanisms may be involed in the inactivation of mutagenicity of carcinogens by saliva, including biochemical reactions with enzymes, vitamins, etc. and/or adsorption with high molecular weight substances in saliva such as proteins, bacterial cells, mucous materials, etc.     

The effects of sodium azide on mammalian cells cultivated in vitro

Sodium azide acted cytostatically to cytotoxically on 2 lines of mammalian cells. After application of the substance in an acid environment the highest cytostatic effect was noted. The results of the DNA-synthesis inhibition test suggest that sodium azide does not damage the DNA of the observed fibroblasts with any of the tested modes of application. In Chinese hamster cells, neither 20-h treatment in medium nor 60-min treatment in an acid environment gave rise to significantly increased occurrence of 6-TG-resistant mutations.The results of the DNA-synthesis inhibition test, as well as the mutagenicity testing, do not suggest the possibility that treatment with sodium azide might induce DNA damage in the observed human and Chinese hamster cells. The cytostatic effect of sodium azide on the fibroblasts studied is probably not accompanied by a genotoxic effect.     

Assessment of the genotoxic potential of riboflavin and lumiflavin. B. Effect of light.

On exposure to visible light, riboflavin and lumiflavin produced reactive oxygen species such as singlet oxygen and superoxide radicals. The reaction was found to be time- and concentration-dependent. Both riboflavin and lumiflavin, upon illumination, showed mutagenic response in the umu test as well as in the Ames/Salmonella assay with Salmonella typhimurium TA102. The mutagenic response was partially abolished by superoxide dismutase while sodium azide did not have any effect. No mutagenicity was observed if the compounds were not illuminated. The results suggested the involvement of superoxide radicals in light-induced mutagenicity of riboflavin as well as lumiflavin.     

The antimutagenic activity of biomass extracts from the cultured cells of medicinal plants in the Ames test

Antimutagenic activity of 20 and 40% ethanol extracts from the biomass of Rhodiola rosea, Polyscias filicifolia, Panax ginseng and Ungernia victoris cultured cells have been studied. DDDTDP, ethidium bromide, benz(a)pyrene, benzidine served as model mutagens for Salmonella typhimurium TA 98 strain (the latter two were tested in presence of metabolic activation system); for S. typhimurium TA 100 strain these were tio-tefa, bichromate potassium and sodium azide and heavy metal compounds (chlorides of manganese, zinc, cadmium, lead acetate) for both strains. Higher capacity of the extracts from the biomass of R. rosea and P. filicifolia to counteract gene mutations induced by various mutagens was demonstrated (ca. 90% inhibition in isolated cases). In the experiment with the metabolic activation most effective proved to be the extracts from the P. ginseng biomass (up to 34% and 47% mutagenicity inhibition).     

Protein Synthesis by Bradyrhizobium japonicum Bacteroids Declines as a Function of Nodule Age

Isolated bacteroids of Bradyrhizobium japonicum accumulated exogenously supplied [(sup35)S]methionine or [(sup3)H]leucine and incorporated them into cytosolic proteins. The accumulation of these labeled amino acids was inhibited by azide. Only 3 to 6% of these accumulated amino acids were incorporated into protein. Protein synthesis was not stimulated by incubation of bacteroids in the presence of potassium salts, malate, or amino acids, but azide, chloramphenicol, and acridine did inhibit the process. No prominent differences were observed in autoradiograms after sodium dodecyl sulfate-polyacrylamide gel electrophoresis of (sup35)S-labeled bacteroid proteins as a function of nodule age. The rates of protein synthesis and protein turnover declined during nodule development. Protein synthesis declined about 60% between 14 and 20 days after planting, which is the period of a rapid increase in acetylene reduction activity. This correlation suggests a metabolic mechanism by which significant amounts of cellular energy are diverted to the nitrogen fixation process.     

Effects of sodium selenite and caffeine on mutagenesis induced by N-methyl-N-nitrosourea, N-methyl-N'-nitro-N-nitrosoguanidine and aflatoxin B1 in S. typhimurium.

Pre-treatment, co-treatment, and post-treatment procedures were comparatively used in order to assess the modulation of mutagenicity in S. typhimurium his- strains. Pre-treatment of bacteria with sodium selenite had no effect on sodium azide mutagenicity. Irrespective of the procedure used neither selenite nor caffeine had any influence on the S9-mediated mutagenicity of aflatoxin B1. In contrast, the mutagenicity of N-methyl-N-nitrosourea (MNU) and N-methyl-N'-nitro-N- nitrosoguanidine (MNNG) was variably affected, depending on the sequence of exposures of target bacterial cells to mutagens and modulators. In particular, pre-treatment of bacteria with either selenite or caffeine or their combination generally resulted in a potentiation of MNU and MNNG mutagenicity. However, co-incubation of these alkylating agents and test modulators with bacterial cells yielded an evident inhibition of mutagenicity, the methylxanthine being more effective in this case. Caffeine exhibited an an antimutagenic effect towards MNU also when assayed in a post-treatment procedure. Thus, in dependence on the test conditions, selenite and caffeine could act in the same mutagenicity assay as co-mutagens, antimutagens or agents without effect on mutagenesis. These opposite trends reflect the complexity of the mechanisms of action of both mutagens and modulators tested, and underscore the variable outcome of their interactions, also depending on topological and chronological factors. The data reported emphasize the need for a multiple methodological approach in studies investigating the modulation of mutagenicity.     

Requirement for a macromolecular factor for sodium azide activation of guanulate cyclase.

Sodium azide, a highly nucleophilic agent and a potent metabolic inhibitor, markedly increased guanylate cyclase activity from supernatant fractions of rat liver homogenates. The effect of sodium azide was not observed with partially purified guanulate cyclase from liver or crude soluble guanylate cyclase from cerebral cortex. However, the effect of sodium azide could be restored by the readdition of a fraction isolated from rat liver homogenates. The macromolecular factor required for the sodium azide effect was separated from soluble guanylate cyclase of rat liver with DEAE-cellulose column chromatography, and some of its properties were examined. The factor was nondialyzable and heat labile.     

Photometric analysis of antifading reagents for immunofluorescence with laser and conventional illumination sources

Bleaching of stained objects is a major problem in immunofluorescence. The prevention of fluorescence fading would allow longer observation times, photographic documentation, fluorometry, and pattern recognition. Fluorescein kinetics and fluorescence intensities (FI) of fluorescein isothiocyanate (FITC) conjugate-stained Sephadex beads were studied with previously described "antibleaching" reagents using an argon laser as the excitation light source. Eight antibleaching reagents were tested (sodium azide (NaN3), sodium iodide (NaI), polyvinyl pyrrolidone (PVP), polyvinyl alcohol (PVA), 1,4-di-azobicyclo-(2,2,2)-octane (DABCO), p-phenylenediamine (PPD), n-propylgallate, and sodium dithionite (Na2S2O4]. Sodium azide and sodium iodide were found to increase FI. This was likewise found with mercury arc illumination and hence they may prove useful for routine immunofluorescence tests. PPD was found to accumulate on the surface of the beads and to disturb immunofluorescence by autofluorescence. The value of any of the other reagents in immunofluorescence is questionable.     

Carotenoids in roots indicated the level of stress induced by mannitol and sodium azide treatment during the early stages of maize germination

Chemical mutagens, such as sodium azide, have attracted the interest of plant breeders. Azide creates DNA point mutations and affects plant growth and development, disturbs metabolic activity and inhibits protein and DNA replication, whereas mannitol is used to simulate drought stresses in tissue culture. To identify biochemical markers for stress tolerance, maize seeds were germinated under mannitol and sodium azide induced stress in controlled conditions for 7 days. Then levels of chlorophyll, carotenoids, phenolics and aldehydes produced were subsequently determined. Germination percentage was not affected by either mannitol or sodium azide and was always above 85%. However, total fresh weight decreased by 50% with the application of 153.4 mM mannitol and 0.26 mM azide in combination. This treatment significantly reduced plantlet growth from 0.94 g in the control to 0.53 g in the treated materials. Root weight reduced by 68.1%, cotyledons by 14.3%, stems by 65.0% and leaves by 70.0% in treated samples. The level of carotenoids in roots was the clearest biochemical indicator of stress produced by the mannitol and sodium azide treatment. Carotenoids increased from 0.01 µg g^??1 fresh weight in the control to 9.03 µg g^??1 fresh weight in the treated materials. A large-scale seed treatment with mannitol and sodium azide was carried out. 2296 seeds were placed in magenta containers with 153.4 mM mannitol and 0.26 mM NaN₃. At 7 days of germination, the heaviest seedlings (450) (450/2296?=?20%) were transferred to soil environment. Forty-two plants (42/450?=?9.3%) were off-type phenotypes at 45 days. Genetic variants may have been obtained following the novel procedure described here which combines chronic treatment with sodium azide and selection pressure with mannitol to simulate drought conditions.     

The role of metabolic energy in the lethal action of basic proteins on Candida albicans.

Comparative studies were made on the destructive effects of certain basic proteins on a strain of Candida albicans and two of its respiration-impaired mutants. Both by direct plate counts of survivors and by quantitative ultraviolet spectrophotometric analyses of released cellular constituents, the respiration-impaired mutants were less vulnerable to the destructive actions of the basic proteins than were ordinary wild-type cells. The lethal incidence and the ultraviolet absorbing cellular substances released from wild-type cells by the proteins were markedly decreased in the presence of the oxidative phosphorylation uncouplers sodium azide, 2,4-dinitrophenol, and salicylanide and approximately equal to the effects produced on an oxidative phosphorylation mutant not treated with the uncouplers. The heightened resistance of a culture through mutational or chemical impairment of its respiratory system suggests a role of metabolic energy in the destructive action of various basic proteins on yeast cells.     

A mutagenic metabolite synthesized by Salmonella typhimurium grown in the presence of azide is azidoalanine

A mutagenic azide metabolite was purified from the medium in which Salmonella typhimurium cells were grown in the presence of azide. This metabolite was identified to be azidoalanine based on infrared and mass spectroscopy and elemental analysis. This compound appeared to be identical to the mutagenic compound synthesized in vitro from azide and O-acetylserine by partially purified O-acetylserine sulfhydrylase. The metabolite (azidoalanine) mutagenic efficiency and spectrum in S. typhimurium was similar to that of inorganic azide. The compounds 2-azidoethylamine, 2-bromoethylamine, 3-bromopropionic acid and N-(azidomethyl) phthalimide were also mutagenic with a similar spectrum to azide and azidoalanine, but with lower efficiency. The compounds 3-azidopropylamine, 4-azidobutylamine, 3-chloroalanine and ethylamine were only weakly or nonmutagenic. Numerous other chloro, bromo and azido phthalimide derivatives tested were nonmutagenic. It is suggested that the lack of azide mutagenicity (and perhaps carcinogenicity) in mammalian cells may be due to their inability to convert azide to azidoalanine.     

Cell-free identification of novel N-myristoylated proteins from complementary DNA resources using bioorthogonal myristic acid analogues

To establish a non-radioactive, cell-free detection system for protein N-myristoylation, metabolic labeling in a cell-free protein synthesis system using bioorthogonal myristic acid analogues was performed. After Cu(I)-catalyzed azide–alkyne cycloaddition (CuAAC) with a biotin tag, the tagged proteins were separated by sodium dodecyl sulfate–polyacrylamide gel electrophoresis (SDS–PAGE) and blotted on a polyvinylidene fluoride (PVDF) membrane, and then protein N-myristoylation was detected by enhanced chemiluminescence (ECL) using horseradish peroxidase (HRP)-conjugated streptavidin. The results showed that metabolic labeling in an insect cell-free protein synthesis system using an azide analogue of myristic acid followed by CuAAC with alkynyl biotin was the most effective strategy for cell-free detection of protein N-myristoylation. To determine whether the newly developed detection method can be applied for the detection of novel N-myristoylated proteins from complementary DNA (cDNA) resources, four candidate cDNA clones were selected from a human cDNA resource and their susceptibility to protein N-myristoylation was evaluated using the newly developed strategy. As a result, the products of three cDNA clones were found to be novel N-myristoylated protein, and myristoylation-dependent specific intracellular localization was observed for two novel N-myristoylated proteins. Thus, the metabolic labeling in an insect cell-free protein synthesis system using bioorthogonal azide analogue of myristic acid was an effective strategy to identify novel N-myristoylated proteins from cDNA resources.