The microsomal activation of aflatoxin B1 and 2-(N-ethylcarbamoyloxymethyl)furan in vitro using a novel diffusion apparatus

The activation by rat liver microsomal systems in vitro of a naturally occurring and a synthetic furan-containing toxin, aflatoxin B₁ and 2-(N-ethylcarbamoyloxymethyl)furan (CMF) has been examined. Both compounds are metabolised to form products which bind covalently to DNA and microsomal protein, Using a specially designed two-chamber diffusion apparatus it has been demonstrated that the active metabolite of CMF is able to bind covalently to DNA separated by a membrane barrier from the microsomal site of activation. In the case of aflatoxin B₁ the DNA must be in physical contact with the microsomal system for the active metabolite of aflatoxin B₁ to bind covalently. Differences between the activation of the two compounds have also been found with regard to their relative efficiencies in binding to DNA and also the effects of the nucleophile GSH. These results have suggested that if the molecular mechanisms of activation of the two compounds be similar, other factors, for example differences in lipid solubility, may play important roles in determining the relative biological activaties of the compounds. The results suggested that the subcellular site of activation of aflatoxin B₁, unlike that of CMF, may need to be adjacent to the target DNA. It is proposed that this site might be the outer nuclear membrane. Alternatively a carrier molecular might exist for the activated aflatoxin B₁ metabolite in vivo.     

In vivo covalent binding of aflatoxin B1 and aflatoxin M1 to liver DNA of rat,mouse and pig

[¹⁴C]Aflatoxin B₁ (AFB₁) was isolated from cultures of Aspergillus parasiticus grown on [1-¹⁴C]sodium acetate. Covalent binding of AFB₁ to liver DNA of rat and mouse was determined 6–8 h after oral administration. The effectiveness of covalent binding, expressed as DNA binding per dose in the units of a ‘Covalent Binding Index’ (CBI), (μmol aflatoxin/mol DNA nucleotides)/(mmol aflatoxin/kg animal), was found to be 10 400 for rats and 240 for mice. These CBI partly explain the different susceptibility of the two species for the incidence of hepatic tumors.The corresponding values for pig liver DNA, 24 and 48 h after oral administration, were found to be as high as 19 100 and 13 300. DNA-binding has not so far been reported for this species although it could represent an appropriate animal model for studies where a human-like gastrointestinal tract physiology is desirable.Aflatoxin M₁ (AFM₁) is a metabolite found in the milk of cows that have been fed AFB₁-contaminated diet. [¹⁴C]AFM₁ was also found to be produced by cultures of A. parasiticus giving a yield of about 0.3% of the total aflatoxins. A test for covalent binding to rat liver DNA revealed a CBI of 2100 showing that AFM₁ must also be regarded as a strong hepatocarcinogen. It is concluded that AFB₁ contaminations should be avoided in dairy feed.     

Carcinogen-Nucleic Acid Interactions: Equilibrium Binding Studies of Aflatoxins B1 and B2 with DNA and the Oligodeoxynucleotide d(ATGCAT)2

Abstract

Equilibrium binding is believed to play an important role in directing the subsequent covalent attachment of many carcinogens to DNA. We have utilized UV spectroscopy to examine the non-covalent interactions of aflatoxin B₁ and B₂ with calf thymus DNA, poly(dAdT):poly(dAdT), and poly(dGdC):poly(dGdC), and have utilized NMR spectroscopy to examine non-covalent interactions of aflatoxin B₂ with the oligodeoxynucleotide d(ATGCAT)₂. UV-VIS binding isotherms suggest a greater binding affinity for calf thymus DNA and poly(dAdT):poly(dAdT) than for poly(dGdC):poly(dGdC). Scatchard analysis of aflatoxin B₁ binding to calf thymus DNA in 0.1 M NaCl buffer indicates that binding of the carcinogen at levels of bound aflatoxin ? 1 carcinogen per 200 base pairs occurs with positive cooperativity. The cooperative binding effect is dependent on the ionic strength of the medium; when the NaCl concentration is reduced to 0.01 M, positive cooperativity is observed at carcinogen levels ? 1 carcinogen per 500 base pairs. The Scatchard data may be fit using a “two-site” binding model [L.S. Rosenberg, M J. Carvlin, and T.R. Krugh, Biochemistry 25, 1002–1008 (1986)]. This model assumes two independent sets of binding sites on the DNA lattice, one a high affinity site which binds the carcinogen with positive cooperativity, the second consisting of lower affinity binding sites to which non-specific binding occurs. NMR analysis of aflatoxin B₂ binding to d(ATGCAT)₂ indicates that the aflatoxin B₂/oligodeoxynucleotide complex is in fast exchange on the NMR time scale. Upfield chemical shifts of 0.1–0.5 ppm are observed for the aflatoxin B₂ 4-OCH₃, H5, and H6a protons. Much smaller chemical shift changes ? 0.06 ppm) are observed for the oligodeoxynucleotide protons. The greatest effect for the oligodeoxynucleotide protons is observed for the adenine H2 protons, located in the minor groove. Nonselective T₁ experiments demonstrate a 15–25 % decrease in the relaxation time for the adenine H2 protons when aflatoxin B₂ is added to the solution. This result suggests that aflatoxin B₂ protons in the bound state may be in close proximity to these protons, providing a source of dipolar relaxation. Further experiments are in progress to probe the nature of the aflatoxin B₁ and B₂ complexes with polymeric DNA and oligodeoxynucleotides, and to establish the relationship between the non-covalent DNA-carcinogen complexes observed in these experiments, and covalent aflatoxin B₁,-guanine N7 DNA adducts.     

Surface Binding of Aflatoxin B1 by Lactic Acid Bacteria

Specific lactic acid bacterial strains remove toxins from liquid media by physical binding. The stability of the aflatoxin B₁ complexes formed with 12 bacterial strains in both viable and nonviable (heat- or acid-treated) forms was assessed by repetitive aqueous extraction. By the fifth extraction, up to 71% of the total aflatoxin B₁ remained bound. Nonviable bacteria retained the highest amount of aflatoxin B₁. Lactobacillus rhamnosus strain GG (ATCC 53103) and L. rhamnosus strain LC-705 (DSM 7061) removed aflatoxin B₁ from solution most efficiently and were selected for further study. The accessibility of bound aflatoxin B₁ to an antibody in an indirect competitive inhibition enzyme-linked immunosorbent assay suggests that surface components of these bacteria are involved in binding. Further evidence is the recovery of around 90% of the bound aflatoxin from the bacteria by solvent extraction. Autoclaving and sonication did not release any detectable aflatoxin B₁. Variation in temperature (4 to 37°C) and pH (2 to 10) did not have any significant effect on the amount of aflatoxin B₁ released. Binding of aflatoxin B₁ appears to be predominantly extracellular for viable and heat-treated bacteria. Acid treatment may permit intracellular binding. In all cases, binding is of a reversible nature, but the stability of the complexes formed depends on strain, treatment, and environmental conditions.     

Aflatoxin B1 and DNA Adducts. Proposed Model for Surface Noncovalent and Covalent Complexes with N(7) of Guanine. II.

Abstract

An alternate model for surface noncovalent and surface covalent binding of aflatoxin B₁ to N(7) of guanine in DNA is proposed. This model considers the out-of-plane motions of C(8) of aflatoxin B₁ in those interactions.

The covalent intercalated fit of aflatoxin B₁ into DNA arises from steric adjustments made by DNA at the covalent intercalation site as well as local strain in the bond angles about N(7) of guanine and C(8) of aflatoxin B₁. The bond angle about N(7) deviates modestly from the sp² value toward the sp³ value.

This study suggests that the surface covalent aflatoxin B₁ -DNA complex serves only a minor role in aflatoxin's precarcinogenic interaction with DNA and is a likely correctable error.     

Covalent binding of ethinylestradiol and estrone to rat liver DNA in vivo

The covalent binding of [6,7-³H] ethinylestradiol (EE) and [6,7-³H] estrone (E) to liver DNA of 200 g female rats was measured 8 h after the administration of 80 μg (9.2 mCi) estrogen by gavage. The binding is 1.5 for EE and 1.1 for E, expressed as binding to DNA/dose, in units of μmol hormone/mol DNA phosphate/mmole hormone/kg body wt. It is in the same order of magnitude as for benzene and about 10 000 times below the binding of typical liver carcinogens, such as aflatoxin B₁ or N,N-dimethylnitrosamine.     

A review of the dose-response induction of DNA adducts by aflatoxin B1 and its implications to quantitative cancer-risk assessment

The induction of DNA adducts by aflatoxin B₁ in the liver has been extensively reviewed in a quantitative cancer-risk assessment of aflatoxins (CDHS, 1990). Rat is the most sensitive species for aflatoxin tumorigenesis and liver is the most sensitive site. In vitro DNA-adduct studies were mostly on adduct identification and specificity of binding. In vivo studies provided dose-response relationship of aflatoxin B₁, binding to DNA and DNA-adduct formation. Most in vivo studies were conducted in rats. The dose-response curves of DNA-adduct induction after ingestion or injection treatments in this species were reviewed. A linear dose-response relationship was observed in both injection and ingestion studies at low doses. For cancer-risk assessment, this observation is consistent with the assumption of the linear dose-response risk-assessment model for genotoxic agents, and justifies the use of this model for quantitative cancer-risk assessment for aflatoxins.     

Exposure to Mitochondrial Genotoxins and Dopaminergic Neurodegeneration in Caenorhabditis elegans

Neurodegeneration has been correlated with mitochondrial DNA (mtDNA) damage and exposure to environmental toxins, but causation is unclear. We investigated the ability of several known environmental genotoxins and neurotoxins to cause mtDNA damage, mtDNA depletion, and neurodegeneration in Caenorhabditis elegans. We found that paraquat, cadmium chloride and aflatoxin B₁ caused more mitochondrial than nuclear DNA damage, and paraquat and aflatoxin B₁ also caused dopaminergic neurodegeneration. 6-hydroxydopamine (6-OHDA) caused similar levels of mitochondrial and nuclear DNA damage. To further test whether the neurodegeneration could be attributed to the observed mtDNA damage, C. elegans were exposed to repeated low-dose ultraviolet C radiation (UVC) that resulted in persistent mtDNA damage; this exposure also resulted in dopaminergic neurodegeneration. Damage to GABAergic neurons and pharyngeal muscle cells was not detected. We also found that fasting at the first larval stage was protective in dopaminergic neurons against 6-OHDA-induced neurodegeneration. Finally, we found that dopaminergic neurons in C. elegans are capable of regeneration after laser surgery. Our findings are consistent with a causal role for mitochondrial DNA damage in neurodegeneration, but also support non mtDNA-mediated mechanisms.     

Aflatoxin inhibition of glucocorticoid binding capacity of rat liver nuclei

The effect of aflatoxin B₁ on the binding capacity of rat liver cytoplasmic glucocorticoid receptors and the nuclear binding of the activated receptor complex was investigated. No alterations in the kinetics of [³H]dexamethasonccytosol receptor complex formation were noted 2 h after treatment with 1 mg/kg aflatoxin B₁. However, a 33% decrease in the concentration of nuclear acceptor sites and a 24% decrease in the glucocorticoid receptor-nuclear binding equilibrium constant of dissociation was observed. This response was near maximal at 2 h and persisted for at least 36 h. Inhibition of nuclear binding capacity was directly related to aflatoxin B₁ dose, with a correlation coefficient of 0.99. Actinomycin D treatment (0.1 mg/kg) resulted in a slight reduction (16%) in the concentration of nuclear acceptor sites but had no effect on the nuclear binding dissociation constant.Administration of [³H]dexamethasone to aflatoxin B₁-treated rats produced a similar pattern of glucocortocoid binding distribution in vivo to that observed in vitro. No differences in [³H]dexamethasone-cytoplasmic receptor binding between control and aflatoxin B₁-treated rats were found, whereas nuclear [³H]dexamethasone binding was reduced 34% by aflatoxin B₁ treatment.     

Synergistic effect ofSacoglottis gabonensis bark extract,

Aflatoxin B₁ metabolism was studied using microsomal and cytosolic fractions isolated from weanling male Fischer F344 rats given in drinking water for 7 days an aqueous extract ofSacoglottis gabonensis bark, 0.1% ethanol solution, or a solution containing both extract and ethanolad libitum. Microsomal production of aflatoxin B₁-dihydrodiol, aflatoxin Q₁, aflatoxin M₁, aflatoxin Pi and proteinaflatoxin adduct formation, and cytosolic aflatoxin B₁-glutathione conjugation were assayed. Pretreatment with the extract alone or together with ethanol caused significant increases in aflatoxin M₁ production as compared to controls given only water, but aflatoxin Q₁ production was enhanced only by pretreatment with both extract and ethanol. All the three treatments caused significant reductions in liver glutathione content. The highest aflatoxin B₁ metabolising activity as determined by aflatoxin M₁ and aflatoxin Q₁ production was observed in rats pretreated with both ethanol and the extract, suggesting synergism. The findings suggest that at relatively mild doses,S. gabonensis extract alone or in concert with ethanol may influence response to aflatoxin.     

Domain structure and quaternary organization of the bacteriophage P22 Erf protein

The structure and activities of the recombination-promoting P22 Erf protein were examined in vitro. Treatment of the protein with elastase produces a stable aminoterminal fragment, consisting of amino acid residues 1 to (approximately) 136. We have purified this fragment, designated fragment B, to apparent homogeneity by gel filtration chromatography. Fragment B retains the oligomeric structure and single-stranded DNA binding specificity of intact Erf. It differs, however, in lacking the ability of intact Erf to bind single-stranded DNA into large aggregates following mild heat treatment of the protein. In addition, its binding to DNA may be weaker than that of intact Erf. Intact Erf sediments through a sucrose gradient as a discrete species with an apparent s_20,w of approximately 11.7 S. Its sedimentation behavior is affected little, if at all, by concentration. Fragment B also sediments as a discrete species at approximately 10.4 S. In the electron microscope, intact Erf appears as rings, with 10 to 14 small projecting structures resembling the teeth of a gear. Fragment B is similar, except that it appears to lack the peripheral structures. From these observations, we conclude that Erf consists of at least two structurally and functionally distinct domains, and that it has a discrete ring-like oligomeric structure.     

Mutagenicity and cytotoxicity of the carcinogen-mutagen aflatoxin B1 in Streptococcus pneumoniae (Pneumococcus) and Salmonella typhimurium: dependence on DNA repair functions

Strains R6, R6x and R6uvr-1 of Streptococcus pneumoniae (Pneumococcus) are sensitive to the cytotoxic effects of the mutagen/carcinogen aflatoxin B₁ (AFB₁). R6uvr-1 is more prone to the cytotoxic effects of AFB₁ than the repair-proficient parental strain, R6. The same differential susceptibility of strains R6, R6x and R6uvr-1 was observed when UV light replaced metabolically activated AFB₁. All pneumococcal strains were immutable by AFB₁. AFB₁ mutagenesis in Salmonella typhimurium strains was dependent on a functional RecA gene product. The enhancing effects of ΔuvrB and plasmid pKM101 were found to be additive. Data presented are consistent with the following: (i) AFB₁ toxic effects are due mainly to DNA binding of AFB₁; (ii) AFB₁ mutagenesis is dependent on error-prone DNA repair; (iii) Pneumococcus lacks an active error-prone (SOS) DNA-repair system.     

Metabolic activation of aflatoxins related to their mutagenicity.

Rat hepatic microsome-mediated DNA-binding and mutagenesis to Salmonella typhimurium strain Ta-100 by various aflatoxins and some mixed function oxygenase-mediated metabolites of aflatoxin B₁ were studied. The data indicated a good correlation between the DNA-binding and mutagenesis; a requirement for the intact C₂–C₃ double bond in parent aflatoxins B₁ and G₁; and relative inactivity of aflatoxin B₁ metabolites with an otherwise intact C₂–C₃ double bond.     

The production of aflatoxin B1 or G1 by Aspergillus parasiticus at various combinations of temperature and water activity is related to the ratio of aflS to aflR expression

The influence of varying combinations of water activity (a_w) and temperature on growth, aflatoxin biosynthesis and aflR/aflS expression of Aspergillus parasiticus was analysed in the ranges 17–42°C and 0.90–0.99 a_w. Optimum growth was at 35°C. At each temperature studied, growth increased from 0.90 to 0.99 a_w. Temperatures of 17 and 42°C only supported marginal growth. The external conditions had a differential effect on aflatoxin B₁ or G₁ biosynthesis. The temperature optima of aflatoxin B₁ and G₁ were not at the temperature which supported optimal growth (35°C) but either below (aflatoxin G₁, 20–30°C) or above (aflatoxin B₁, 37°C). Interestingly, the expression of the two regulatory genes aflR and aflS showed an expression profile which corresponded to the biosynthesis profile of either B₁ (aflR) or G₁ (aflS). The ratios of the expression data between aflS:aflR were calculated. High ratios at a range between 17 and 30°C corresponded with the production profile of aflatoxin G₁ biosynthesis. A low ratio was observed at >30°C, which was related to aflatoxin B₁ biosynthesis. The results revealed that the temperature was the key parameter for aflatoxin B₁, whereas it was water activity for G₁ biosynthesis. These differences in regulation may be attributed to variable conditions of the ecological niche in which these species occur.     

Enzymatic Formation of G-Group Aflatoxins and Biosynthetic Relationship between G- and B-Group Aflatoxins

We detected biosynthetic activity for aflatoxins G₁ and G₂ in cell extracts of Aspergillus parasiticus NIAH-26. We found that in the presence of NADPH, aflatoxins G₁ and G₂ were produced from O-methylsterigmatocystin and dihydro-O-methylsterigmatocystin, respectively. No G-group aflatoxins were produced from aflatoxin B₁, aflatoxin B₂, 5-methoxysterigmatocystin, dimethoxysterigmatocystin, or sterigmatin, confirming that B-group aflatoxins are not the precursors of G-group aflatoxins and that G- and B-group aflatoxins are independently produced from the same substrates (O-methylsterigmatocystin and dihydro-O-methylsterigmatocystin). In competition experiments in which the cell-free system was used, formation of aflatoxin G₂ from dihydro-O-methylsterigmatocystin was suppressed when O-methylsterigmatocystin was added to the reaction mixture, whereas aflatoxin G₁ was newly formed. This result indicates that the same enzymes can catalyze the formation of aflatoxins G₁ and G₂. Inhibition of G-group aflatoxin formation by methyrapone, SKF-525A, or imidazole indicated that a cytochrome P-450 monooxygenase may be involved in the formation of G-group aflatoxins. Both the microsome fraction and a cytosol protein with a native mass of 220 kDa were necessary for the formation of G-group aflatoxins. Due to instability of the microsome fraction, G-group aflatoxin formation was less stable than B-group aflatoxin formation. The ordA gene product, which may catalyze the formation of B-group aflatoxins, also may be required for G-group aflatoxin biosynthesis. We concluded that at least three reactions, catalyzed by the ordA gene product, an unstable microsome enzyme, and a 220-kDa cytosol protein, are involved in the enzymatic formation of G-group aflatoxins from either O-methylsterigmatocystin or dihydro-O-methylsterigmatocystin.     

Purification and characterisation of a novel DNA methyltransferase,M.AhdI

We have cloned the M and S genes of the restriction-modification (R-M) system AhdI and have purified the resulting methyltransferase to homogeneity. M.AhdI is found to form a 170 kDa tetrameric enzyme having a subunit stoichiometry M₂S₂ (where the M and S subunits are responsible for methylation and DNA sequence specificity, respectively). Sedimentation equilibrium experiments show that the tetrameric enzyme dissociates to form a heterodimer at low concentration, with K_d ≈ 2 µM. The intact (tetrameric) enzyme binds specifically to a 30 bp DNA duplex containing the AhdI recognition sequence GACN₅GTC with high affinity (K_d ≈ 50 nM), but at low enzyme concentration the DNA binding activity is governed by the dissociation of the tetramer into dimers, leading to a sigmoidal DNA binding curve. In contrast, only non-specific binding is observed if the duplex lacks the recognition sequence. Methylation activity of the purified enzyme was assessed by its ability to prevent restriction by the cognate endonuclease. The subunit structure of the M.AhdI methyltransferase resembles that of type I MTases, in contrast to the R.AhdI endonuclease which is typical of type II systems. AhdI appears to be a novel R-M system with properties intermediate between simple type II systems and more complex type I systems, and may represent an intermediate in the evolution of R-M systems.     

Production of aflatoxin on rice

A method has been developed for the production of aflatoxin by growing Aspergillus flavus strain NRRL 2999 on the solid substrate rice. Optimal yields, more than 1 mg of aflatoxin B₁ per g of starting material, were obtained in 5 days at 28 C. A crude product containing aflatoxins was isolated by chloroform extraction and precipitation with hexane from concentrated solutions. The crude product consisted of 50% aflatoxin in the following ratio: B₁-B₂-G₁-G₂, 100:0.15:0.22:0.02. Aflatoxin B₁ was separated from almost all the impurities and from the other aflatoxins by chromatography on silica gel with 1% ethyl alcohol in chloroform. Analytically pure aflatoxin B₁ was recrystallized from chloroform-hexane mixtures.     

Bleomycin interactions with DNA studies on the role of the C-terminal cationic group of bleomycin A2 in association with and degradation of DNA

The role of the cationic dimethylsulfonium group of Abeomycin A₂ in the binding of the drug to poly(dA-dT) has been investigated b proton NMR studies on the S-demethyated derivative. In contrast to the parent drug, the demethyl congener shows no intercalation of the aromatic bithiazole group which is adjacent to the former cationic group. However, chemical studies show that the demethyl derivative retains the capability to degrade DNA in the presence of iron(II), albeit at a reduced rate and to a lesser extent than the intact bleomycin A₂. Thus, the cationic group is necessary for the intercalation of the bithiazole portion of the drug molecule; however, intercalation is not essential for the degradation of DNA.     

Study of interactions between DNA and aflatoxin B1 using electrochemical and fluorescence methods

In this study, a carbon paste electrode modified with N-butylpyridinium hexafluorophosphate (BPPF₆) ionic liquid and DNA was introduced as an electrochemical biosensor to study the interaction between DNA and aflatoxin B1 molecules. For this purpose, variations in oxidation peak current of guanine in various concentrations of aflatoxin B1 were measured by using the differential pulse voltammetry (DPV) method. According to this study, the binding constant of DNA–aflatoxin B1 was found to be 3.5 × 10⁶ M⁻¹. This modified electrode was also used for determination of low concentrations of aflatoxin B1 by using differential pulse voltammetry. A linear dynamic range from 8.00 × 10⁻⁸ to 5.91 × 10⁻⁷ M and a limit of detection of 2.00 × 10⁻⁸ M resulted from DPV measurements. To confirm our results, a fluorescence study was also performed. It resulted in a binding constant of 2.8 × 10⁶ M⁻¹, which is in good agreement with that obtained from electrochemical study.