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.     

adhA in Aspergillus parasiticus Is Involved in Conversion of 5′-Hydroxyaverantin to Averufin

Two routes for the conversion of 5′-hydroxyaverantin (HAVN) to averufin (AVF) in the synthesis of aflatoxin have been proposed. One involves the dehydration of HAVN to the lactone averufanin (AVNN), which is then oxidized to AVF. Another requires dehydrogenation of HAVN to 5′-ketoaverantin, the open-chain form of AVF, which then cyclizes spontaneously to AVF. We isolated a gene, adhA, from the aflatoxin gene cluster of Aspergillus parasiticus SU-1. The deduced ADHA amino acid sequence contained two conserved motifs found in short-chain alcohol dehydrogenases—a glycine-rich loop (GXXXGXG) that is necessary for interaction with NAD⁺-NADP⁺, and the motif YXXXK, which is found at the active site. A. parasiticus SU-1, which produces aflatoxins, has two copies of adhA (adhA1), whereas A. parasiticus SRRC 2043, a strain that accumulates O-methylsterigmatocystin (OMST), has only one copy. Disruption of adhA in SRRC 2043 resulted in a strain that accumulates predominantly HAVN. This result suggests that ADHA is involved in the dehydrogenation of HAVN to AVF. Those adhA disruptants that still made small amounts of OMST also accumulated other metabolites, including AVNN, after prolonged culture.     

Aflatoxin Biosynthesis Cluster Gene cypA Is Required for G Aflatoxin Formation

Aspergillus flavus isolates produce only aflatoxins B1 and B2, while Aspergillus parasiticus and Aspergillus nomius produce aflatoxins B1, B2, G1, and G2. Sequence comparison of the aflatoxin biosynthesis pathway gene cluster upstream from the polyketide synthase gene, pksA, revealed that A. flavus isolates are missing portions of genes (cypA and norB) predicted to encode, respectively, a cytochrome P450 monooxygenase and an aryl alcohol dehydrogenase. Insertional disruption of cypA in A. parasiticus yielded transformants that lack the ability to produce G aflatoxins but not B aflatoxins. The enzyme encoded by cypA has highest amino acid identity to Gibberella zeae Tri4 (38%), a P450 monooxygenase previously shown to be involved in trichodiene epoxidation. The substrate for CypA may be an intermediate formed by oxidative cleavage of the A ring of O-methylsterigmatocystin by OrdA, the P450 monooxygenase required for formation of aflatoxins B1 and B2.     

Involvement of the nadA gene in formation of G-group aflatoxins in Aspergillus parasiticus

The nadA gene is present at the end of the aflatoxin gene cluster in the genome of Aspergillus parasiticus as well as in Aspergillus flavus. RT-PCR analyses showed that the nadA gene was expressed in an aflatoxin-inducible YES medium, but not in an aflatoxin-non-inducible YEP medium. The nadA gene was not expressed in the aflR gene-deletion mutant, irrespective of the culture medium used. To clarify the nadA gene’s function, we disrupted the gene in aflatoxigenic A. parasiticus. The four nadA-deletion mutants that were isolated commonly accumulated a novel yellow-fluorescent pigment (named NADA) in mycelia as well as in culture medium. When the mutants and the wild-type strain were cultured for 3 days in YES medium, the mutants each produced about 50% of the amounts of G-group aflatoxins that the wild-type strain produced. In contrast, the amounts of B-group aflatoxins did not significantly differ between the mutants and the wild-type strain. The NADA pigment was so unstable that it could non-enzymatically change to aflatoxin G₁ (AFG₁). LC–MS measurement showed that the molecular mass of NADA was 360, which is 32 higher than that of AFG₁. We previously reported that at least one cytosol enzyme, together with two other microsome enzymes, is necessary for the formation of AFG₁ from O-methylsterigmatocystin (OMST) in the cell-free system of A. parasiticus. The present study confirmed that the cytosol fraction of the wild-type A. parasiticus strain significantly enhanced the AFG₁ formation from OMST, whereas the cytosol fraction of the nadA-deletion mutant did not show the same activity. Furthermore, the cytosol fraction of the wild-type strain showed the enzyme activity catalyzing the reaction from NADA to AFG₁, which required NADPH or NADH, indicating that NADA is a precursor of AFG₁; in contrast, the cytosol fraction of the nadA-deletion mutant did not show the same enzyme activity. These results demonstrated that the NadA protein is the cytosol enzyme required for G-aflatoxin biosynthesis from OMST, and that it catalyzes the reaction from NADA to AFG₁, the last step in G-aflatoxin biosynthesis.     

Destruction of aflatoxins B1 and G1 in bread making

The effect of processing steps as well preservatives used in French bread making namely propionic acid and/or potassium sorbate (0.2%) on the destruction of aflatoxins B₁ and G₁ was studied. Mixing and baking processes showed marked destruction of aflatoxins B₁ and G₁; being 71.2% and 52.5% for aflatoxin B₁ after mixing and baking steps, while reaching 73.9% and 54.5% for aflatoxin G₁. Fermentation step caused additional 15.3% and 15.0% destruction of aflatoxins B₁ and G₁. On the other hand, aflatoxin B₁ destruction was 79.2% and 50.7% when propionic acid was used and 75.3 and 56.7% in the presence of potassium sorbate and after mixing and baking steps respectively. Concerning aflatoxins G₁ it was found that mixing and baking steps showed destruction of 81.9% and 53.4% in the presence of propionic acid and 75.1 and 49.4% in the presence of potassium sorbate in this respective order. Generally, it can be concluded that using propionic acid as preservative appeared to be more effective on the destruction of aflatoxins B₁ and G₁ than potassium sorbate in French bread making.     

Identification of O-methylsterigmatocystin as an aflatoxin B1 and G1 precursor in Aspergillus parasiticus.

An isolate of Aspergillus parasiticus CP461 (SRRC 2043) produced no detectable aflatoxins, but accumulated O-methylsterigmatocystin (OMST). When sterigmatocystin (ST) was fed to this isolate in a low-sugar medium, there was an increase in the accumulation of OMST, without aflatoxin synthesis. When radiolabeled [14C]OMST was fed to resting mycelia of a non-aflatoxin-, non-ST-, and non-OMST-producing mutant of A. parasiticus AVN-1 (SRRC 163), 14C-labeled aflatoxins B1 and G1 were produced; 10 nmol of OMST produced 7.8 nmol of B1 and 1.0 nmol of G1, while 10 nmol of ST produced 6.4 nmol of B1 and 0.6 nmol of G1. A time course study of aflatoxin synthesis in ST feeding experiments with AVN-1 revealed that OMST is synthesized by the mold during the onset of aflatoxin synthesis. The total amount of aflatoxins recovered from OMST feeding experiments was higher than from experiments in which ST was fed to the resting mycelia. These results suggest that OMST is a true metabolite in the aflatoxin biosynthetic pathway between sterigmatocystin and aflatoxins B1 and G1 and is not a shunt metabolite, as thought previously.     

Enzymes in atlatoxin B1 biosynthesis: Strategies for identifying pertinent genes

Recent work on the aflatoxin biosynthetic pathway is reviewed, with special emphasis on the enzymes of the late stages of the pathway involving conversion of sterigmatocystin (ST) to aflatoxin B₁ (AFB₁) through an O-methylsterigmatocystin intermediate. Two enzyme activities were discovered in subcellular fractions of cell-free extracts of a mutant strain ofAspergillus parasiticus (SRRC 163): 1)A post-microsomal methyltransferase (MT) catalyzed conversion of ST to OMST, and 2) a microsomal-associated activity (oxido-reductase) converted OMST to AFB₁. The 168 KDa, anionic MT was purified to homogeneity and characterized (two subunits, 110 KDa and 58 KDa). Preliminary evidence indicated the presence of a cationic isozyme of the MT in mycelial extracts. The oxido-reductase has been partially purified and characterized. Polyclonal antibodies were prepared to the anionic MT and the enzyme's amino acid composition determined. A cDNA library has been constructed from mRNA isolated fromAspergillus parasiticus mycelia during the onset of AFB₁ biosynthesis for the purpose of identifying the genes responsible for aflatoxin biosynthesis.     

Production of extracellular enzymes and aflatoxins in solid substrate fermentation with aflatoxigenic<Emphasis Type="Italic">Aspergillus</Emphasis> spp.

AflatoxigenicAspergillus flavus andAspergillus parasiticus were subjected to solid substrate fermentation process for 6 days to determine the formation of aflatoxins and production of extracellular enzymes (amyloglucosidase, cellulase, invertase and proteinase). Both organisms produced enzymes which generally increased with fermentation.Aspergillus flavus produced four enzymes whereasA. parasiticus produced three with no proteinase activity.Aspergillus parasiticus produced aflatoxins B₁, B₂ and G₁ but no G₂ andA. flavus produced aflatoxins B₁ and B₂. Invertase showed the highest activity withA. parasiticus and that corresponded with the highest total toxin produced. The enzyme activities were higher withA. parasiticus thanA. flavus although total toxins produced byA. parasiticus were lower than total toxins produced byA. flavus under the same environmental conditions.     

Role of caffeine and tannin in anti-toxigenic properties of coffee and tea

Aflatoxins B₁, B₂, G₁ and G₂ produced by Aspergillus parasiticus var. globosus IMI 120920 in detannin-caffeinated coffee and black tea were five times more concentrated than in normal tea and coffee. Extracts of normal coffee and tea powders significantly reduced aflatoxins production in liquid broth at 1 and 3 % concentrations, with tea extract. having a more pronounced effect than coffee extract Relevant anti-aflatoxigenic properties appear to be due to tannin and caffeine. These induced 95 % inhibition in aflatoxins at 0.3 % and 0.6 %, respectively. Roasting of contaminated coffee beans at 200 °C for 20 min is effective in the reduction of aflatoxins.     

Inhibitory effect of hena (Lawsonia inermis leaves) and carrot root on aflatoxin production byAspergillus parasiticus

Experiments were undertaken to evaluate the effect of some natural products (hena, and carrot root) on growth and aflatoxins production byAspergillus parasiticus FRR 2752. Powdered hena (0.5 and 5%) inhibited mycelial growth and delayed 1 sporulation ofA parasiticus during 7 days. The inhibition of growth was increased with increasing the added amount. Aflatoxins production byA parasiticus was reduced with 40–100% in the presence of hena (Lawsonia inermis leaves). Carrot root extract stimulated the fungal growth and aflatoxin production, whereas carrot root fibers slightly enriched fungal growth, inhibited aflatoxins production (B₁, G₁, and G₂), but there was no inhibition of aflatoxin B₂ production byA parasiticus.     

Aflatoxin is degraded by heated and unheated mycelia,filtrates of homogenized mycelia and filtrates of broth cultures of Aspergillus parasiticus

Steaming one-half of a lot of 9-day-old mycelia of Aspergillus parasiticus NRRL 2999 for 6 min resulted in little or no subsequent degradation of aflatoxin B₁ or G₁ by these mycelia. The other half of these mycelia was not heat-treated and degraded aflatoxins B₁ and G₁ Filtrates of the growth substrate which remained after the mycelium was removed from 8- to 15-day old cultures of A. parasiticus NRRL 2999 did not degrade substantial amounts of aflatoxin B₁ or G₁, whereas mycelia originally produced on these filtrates degraded substantial amounts of both aflatoxins. The supernatant fluid from homogenates of 9-day-old mycelia of A. parasiticus NRRL 2999 degraded aflatoxins B₁ and G₁ when 0.1 M or 1.0 M phosphate buffer, pH 6.5, was used to suspend the homogenate. These data support the hypothesis that the aflatoxin degrading factor(s) present in the mycelium of A. purasiticus is/are enzyme(s) or at least influenced by enzyme(s).     

Association of aflatoxin biosynthesis and sclerotialdevelopment in Aspergillus parasiticus

Secondary metabolism in fungi is frequently associated with asexual and sexual development. Aspergillus parasiticus produces aflatoxins known to contaminate a variety of agricultural commodities. This strictly mitotic fungus, besides producing conidia asexually, produces sclerotia, structures resistant to harsh conditions and for propagation. Sclerotia are considered to be derived from the sexual structure, cleistothecia, and may represent a vestige of ascospore production. Introduction of the aflatoxin pathway-specific regulatory gene, aflR, and aflJ, which encoded a putative co-activator, into an O-methylsterigmatocystin (OMST)-accumulating strain,A. parasiticus SRRC 2043, resulted in elevated levels of accumulation of major aflatoxin precursors, including norsolorinic acid (NOR), averantin (AVN), versicolorin A (VERA) and OMST. The total amount of these aflatoxin precursors, NOR, VERA, AVN and OMST, produced by the aflR plus aflJ transformants was two to three-fold that produced by the aflR transformants. This increase indicated a synergisticeffect of aflR and aflJ on the synthesis of aflatoxin precursors. Increased production of the aflatoxin precursors was associated with progressive decrease in sclerotial size, alteration in sclerotial shape and weakening in the sclerotial structure of the transformants. The results showed that sclerotial development and aflatoxin biosynthesis are closely related. We proposed that competition for a common substrate, such as acetate, by the aflatoxin biosynthetic pathway could adversely affect sclerotial development in A. parasiticus. This revised version was published online in June 2006 with corrections to the Cover Date.     

The Aspergillus parasiticus estA-Encoded Esterase Converts Versiconal Hemiacetal Acetate to Versiconal and Versiconol Acetate to Versiconol in Aflatoxin Biosynthesis

In aflatoxin biosynthesis, the pathway for the conversion of 1-hydroxyversicolorone to versiconal hemiacetal acetate (VHA) to versiconal (VHOH) is part of a metabolic grid. In the grid, the steps from VHA to VHOH and from versiconol acetate (VOAc) to versiconol (VOH) may be catalyzed by the same esterase. Several esterase activities are associated with the conversion of VHA to VHOH, but only one esterase gene (estA) is present in the complete aflatoxin gene cluster of Aspergillus parasiticus. We deleted the estA gene from A. parasiticus SRRC 2043, an O-methylsterigmatocystin (OMST)-accumulating strain. The estA-deleted mutants were pigmented and accumulated mainly VHA and versicolorin A (VA). A small amount of VOAc and other downstream aflatoxin intermediates, including VHOH, versicolorin B, and OMST, also were accumulated. In contrast, a VA-accumulating mutant, NIAH-9, accumulated VA exclusively and neither VHA nor VOAc were produced. Addition of the esterase inhibitor dichlorvos (dimethyl 2,2-dichlorovinylphosphate) to the transformation recipient strain RHN1, an estA-deleted mutant, or NIAH-9 resulted in the accumulation of only VHA and VOAc. In in vitro enzyme assays, the levels of the esterase activities catalyzing the conversion of VHA to VHOH in the cell extracts of two estA-deleted mutants were decreased to approximately 10% of that seen with RHN1. Similar decreases in the esterase activities catalyzing the conversion of VOAc to VOH were also obtained. Thus, the estA-encoded esterase catalyzes the conversion of both VHA to VHOH and VOAc to VOH during aflatoxin biosynthesis.     

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.     

Studies on the ability of mycotoxins to diffuse in bread

Summary The moulds Aspergillus parasiticus (aflatoxins B₁, B₂, G₁, G₂, and M₁), A. ochraceus (ochratoxin A) and Penicillium chrysogenum (citrinin) were grown on whole wheat bread either in the presence or absence of oxygen. In the presence of oxygen, both A. parasiticus and A. ochraceus developed dense colonies and formed considerable amounts of mycotoxins whereas Penicillium chrysogenum only grew and produced citrinin on the surface of the bread. In the absence of oxygen fungal growth did not occur and most of the toxins were undetectable even in regions of bread immediately adjacent to the moulds although a very slight diffusion of the aflatoxins B₁ and G₁ through 1 cm was observed. It is concluded that diffusion of the tested mycotoxins from hyphae into bread is not a problem for food safety.     

The effects of aflatoxin B1 and palmotoxins B0 and G0 on the germination and leaf colour of the cowpea (vigna sinensis)

Aflatoxin B₁, crude aflatoxins and palmotoxins B₀ and G₀ were tested for seed germination and chlorophyll formation using the cowpea. It was found that aflatoxin B and crude aflatoxins inhibited both chlorophyll formation and seed germination and palmotoxins inhibited these processes to a lesser extent. 3 — Indolylacetic acid reduced the inhibitory effects of the aflatoxins in seed germination and chlorophyll formation in the cowpea.     

Binding of aflatoxin B1, G1 and M to plasma albumin

The aflatoxins B₁, G₁ and their metabolites exist in the systemic blood as protein conjugate. This conjugation is specific to plasma albumin and proceeds enzymatically by liver and kidney cells. The aflatoxin-albumin conjugate is permanent and the conjugation is an irreversible one. This may interpret the acute liver damage of animal ingested a single dose of aflatoxin (3, 4). The existence of bound aflatoxin-albumin in the systematic blood could be considered as one factor of low excretions of aflatoxins and their metabolites in urine (5, 6, 7).     

Immunoaffinity column clean-up for the high-performance liquid chromatographic determination of aflatoxins B1, B2, G1, G2, M1 and Q1 in urine

A method for the determination of aflatoxins B₁, B₂, G₁, G₂, M₁ and Q₁ in human urine has been developed. The 10-ml urine samples were automatically cleaned up on immunoaffinity columns and analysed by high-performance liquid chromatography (HPLC), including post-column derivatization with bromine and fluorescence detection. Average aflatoxin recoveries were: B₁ 103%, B₂ 106%, G₁ 98% and G₂ 96% in the range 6.8–73 pg/ml of urine and M₁ 103% and Q₁ 100% in the range 18–97 pg/ml of urine. The relative standard deviations were all between 1% and 21%. The determination limits of aflatoxins in urine were 6.8 pg/ml for B₁, B₂, G₁ and G₂ and 18 pg/ml for M₁ and Q₁.     

Aflatoxins B1 and G1 solubility in standard solutions and stability during cold storage

In the present work we study the use of different solvents to store aflatoxins B₁ and G₁ standard solutions. We have obtained significant differences between aflatoxin B₁ and G₁ In ethyl acetate, methanol and water, with aflatoxin G₁ being less stable. We recommend chloroform as the election solvent to store the aflatoxin solutions. The fact that aflatoxins are highly stable in water may have a potential use in experiments of biological activity.