Production of aflatoxin and cyclopiazonic acid by various aspergilli: An ELISA analysis

An enzyme-linked Immunosorbent assay (ELISA) was used to monitor a total of 153 fungi in theAspergillus flavus group, Including 130A. flavus, 15A. parasiticus and 8A. tamarii, for their ability to produce aflatoxins (AFs) and cyclopiazonic acid (CPA) in a mycologlcal broth-sucrose-yeast extract medium. Of 15A. parasiticus isolates, ten produced AFs In a range of 12.4 to 89.3 μg/vial (average 56.9 μg/vial); two isolates produced only trace amounts of AFs and three isolates produced none at all. Production of CPA was not demonstrated in anyA. parasiticus isolate. On the other hand, all A. tamarii isolates produced only CPA with a range of 310 to 1100 gmg/vial. Fifteen percent (14.6%) of theA. flavus isolates (19/130) produced more than 500 μg CPA/vial, but yielded no or little AF (less than 0.1 μg/vial). About 22.3% ofA. flavus (29/130) that produced less than 500 μg of CPA also yielded little or no aflatoxin. MostA. flavus isolates (44.6%) produced both CPA (50 to 300 μg/vial) and AFs (10 to 40 μg/vial). About 9.2% of theA. flavus are low CPA producers (less than 100 μg/vial) but yielded higher amounts of AFs. A small percentage (12/130 or 9.2%) of A. flavus isolates produced neither CPA nor aflatoxin. Excluding the isolates that produced neither AFs nor CPA, there is a negative correlation between the production of CPA and AFs by most A.flavus isolates. Data obtained from ELISA for the production of CPA were consistent with TLC results. Thus, the ELISA method for CPA and AFB could be applied to the screening of toxigenic fungi. Data on the simultaneous production of both toxins by a large percentage of the toxigenicA. flavus isolates suggest that there is a potential health hazard for co-existence of both toxins in foods and feeds.     

Aflatoxin B1 producing potential of isolates of Aspergillus flavus Link ex Fries from cotton,maize and wheat

Twenty-one isolates ofAspergillus flavus Link ex Fries obtained from cotton, maize and wheat were screened for their ability to produce aflatoxins on two liquid media. Of these, sixteen isolates were toxigenic and produced only aflatoxin B₁ as assessed by bioassay on okra seedlings and TLC method. For screening isolates ofA. flavus for aflatoxin formation, 0.7 % YES+ Salt medium was found to be good as also for obtaining higher yields of the toxin. Isolates ofA. flavus produced aflatoxin B₁ ranging from 0.85 to 17.2 mg/50 ml. Maximum yield of aflatoxin was obtained when rice was used as the substrate in case of toxigenic isolates L-27 and C-9, and on maize in isolate M-11.     

Clustered genes involved in cyclopiazonic acid production are next to the aflatoxin biosynthesis gene cluster in Aspergillus flavus

Cyclopiazonic acid (CPA), an indole-tetramic acid mycotoxin, is produced by many species of Aspergillus and Penicillium. In addition to CPA Aspergillus flavus produces polyketide-derived carcinogenic aflatoxins. Aflatoxin biosynthesis genes form a gene cluster in a subtelomeric region. Isolates of A. flavus lacking aflatoxin production due to the loss of the entire aflatoxin gene cluster and portions of the subtelomeric region are often unable to produce CPA, which suggests a physical link of genes involved in CPA biosynthesis to the aflatoxin gene cluster. Examining the subtelomeric region in A. flavus isolates of different chemotypes revealed a region possibly associated with CPA production. Disruption of three of the four genes present in this region predicted to encode a monoamine oxidase, a dimethylallyl tryptophan synthase, and a hybrid polyketide non-ribosomal peptide synthase abolished CPA production in an aflatoxigenic A. flavus strain. Therefore, some of the CPA biosynthesis genes are organized in a mini-gene cluster that is next to the aflatoxin gene cluster in A. flavus.     

Co-occurrence of aflatoxin B<Subscript>1</Subscript> and cyclopiazonic acid in sour lime (<Emphasis Type="Italic">Citrus aurantifolia Swingle</Emphasis>) during post-harvest pathogenesis by <Emphasis Type="Italic">Aspergillus flavus</Emphasis>

During hot and humid seasons, extensive rot of sour lime was observed to be caused by Aspergillus flavus. In view of this, investigations were undertaken to obtain data on the production of various toxins by A. flavus during post harvest pathogenesis of sour lime. Sixty percent of the pathogenic A. flavus isolates were detected to be aflatoxin B₁ producers in sour lime tissue. It was also noted that thirty three percent of aflatoxigenic A. flavus isolates had the potential to coproduce cyclopiazonic acid (CPA). Such aflatoxigenic isolates produced quantitatively more CPA (ranging from 250.0 to 2501.3 g/kg) than aflatoxin B₁ (ranging from 141.3 to 811.7 g/kg) in the affected sour lime. This study demonstrates for the first time that sour lime are a favourable substrate for aflatoxin B₁ and cyclopiazonic acid production by A. flavus isolates. This is of great concern to the health of consumers.     

Cyclopiazonic acid production by aflatoxigenic and non-aflatoxigenic strains of aspergillus flavus

Twenty-eight of 54 isolates of Aspergillus flavus grown on autoclaved agricultural commodities such as wheat, rice and corn were found to produce the mycotoxin cyclopiazonic acid. Eighteen of the A. flavus isolates produced aflatoxin, and fourteen isolates produced both cyclopiazonic acid and aflatoxin. A preliminary screening of some aflatoxin-contaminated corn samples revealed for the first time the natural occurrence of cyclopiazonic acid in agricultural commodities.     

Use of propolis and ultragriseofulvin to inhibit aflatoxigenic fungi

Propolis ethanolic extract (PEE) at 3 and 4 g/L and ultragriseofulvin (UG) at 0.75 and 1 g/L reduced the percentage of conidia germination in twoAspergillus flavus isolates. PEE at 1–4 g/L decreased the mycelial dry mass ofA. flavus isolates by 11–80%, and aflatoxin B₁ production by 34–100%. UG concentrations of 0.25–1 g/L reduced the growth and aflatoxin B₁ production of the isolates by 16–88 and 48–98%, respectively. Any increase in PEE and UG concentration was accompanied by a clear decrease in the per cent conidia germination, growth and aflatoxin B₁ production. At equal concentration, UG was about 4-times more effective than PEE.     

A rapid extraction method for detecting aflatoxin producing isolates

A rapid extraction method for screening aflatoxin producing potential ofAspergillus flavus group isolates is described. The method is performed using a moist wheat medium with ca. five infected grains extracted with 2 mL of chloroform, and using thin layer chromatography. This method was proved with 95A. flavus isolates from animal feeds.     

Aflatoxigenic Isolates of Aspergillus flavus from Pecans

Of 120 isolates of the Aspergillus flavus group from pecans used in bakery products, 85 were shown to produce aflatoxin on yeast extract sucrose medium. Extracts from moldy sections of raw pecans obtained commercially at the retail level showed aflatoxin-like spots on thin-layer chromatography. Cooked (autoclaved) pecans inoculated with toxigenic isolates of A. flavus were also good substrates for aflatoxin production.     

Mycotoxigenic potential ofAspergillus flavus strains isolated from groundnuts growing in Israel

Two hundred strains of the Aspergillus flavus group isolated from groundnuts (peanuts) growing in Israel were examined for their ability to produce mycotoxins in potato dextrose (PD) broth. Almost 77% of the isolates produced aflatoxin; aflatoxins B₁ and B₂ were formed by most of the isolates. Simultaneous production of aflatoxins of groups B and G was detected in only 0.5% of the isolates. Microscopic examination revealed that 98% of the isolates wereA. flavus and only 2%A. parasiticus. Cyclopiazonic acid (CPA) was detected in 22.5% of the isolates, including 3.5% that produced only CPA. Sterigmatocystin was detected in only 2% of the isolates and only one isolate produced aflatoxin simultaneously with CPA and sterigmatocysin. The dry weight (DW) of mycelium, 7 days after inoculating the medium, was between 71–110 mg/30 ml medium in more than 70% of the isolates. A general decrease in the pH was observed and 75% of the isolates reduced the pH to 4.5 or below. After 14 days, a small increase in DW and an increase in the pH toward neutrality was observed. On PD agar, 30% of the isolates produced sclerotia, including 5% that produced them profusely. No correlation between mycelial growth, changes in pH of the medium, sclerotium formation, and aflatoxin accumulation could be observed. The mycotoxigenic potential of theA. flavus strains isolated from groundnuts seems to be relatively high and may present a potential threat to human and animal health.Contribution from the Agricultural Research Organization, The Volcani Center, Bet Dagan 50250, Israel. No. 3559-E.     

Incidence of aflatoxin producing strains and aflatoxin contamination in dry fruit slices of quinces (Cydonia oblonga Mill.) from the Indian State of Jammu and Kashmir

An investigation was undertaken to obtain data on the occurrence of aflatoxins and the aflatoxin producing potential of Aspergillus flavus strains isolated from dry fruit slices of quinces produced in jammu and Kashmir, India. A total of 147 A. flavus isolates recovered from dr fruit slices were grown in liquid rice flour medium and screened for the production of various aflatoxins by thin layer chromatography. The results showed that 23.14% of the tested isolates were aflatoxigenic, producing aflatoxins B₁and B₂ in varying amounts. Aflatoxins G₁ and G₂ were not detected. All 25 of the investigated market samples were also found to be aflatoxin B₁ positive and the level of contamination ranged from 96 to 8164 g/kg of the dry fruit which is quite high in comparison to the permissible level of 30 ppb. As per these results biochemical composition of dry fruit slices of quinces, along with climatic conditions seem to be very favourable for aflatoxin production by the toxigenic A. flavus strains. Therefore,monitoring of aflatoxins in dry fruit slices of quincesis recommended for this region.This revised version was published online in October 2005 with corrections to the Cover Date.     

Divergence of West African and North American Communities of Aspergillus Section Flavi

West African Aspergillus flavus S isolates differed from North American isolates. Both produced aflatoxin B₁. However, 40 and 100% of West African isolates also produced aflatoxin G₁ in NH₄ medium and urea medium, respectively. No North American S strain isolate produced aflatoxin G₁. This geographical and physiological divergence may influence aflatoxin management.     

Regional Differences in Production of Aflatoxin B1 and Cyclopiazonic Acid by Soil Isolates of Aspergillus flavus along a Transect within the United States

Soil isolates of Aspergillus flavus from a transect extending from eastern New Mexico through Georgia to eastern Virginia were examined for production of aflatoxin B₁ and cyclopiazonic acid in a liquid medium. Peanut fields from major peanut-growing regions (western Texas; central Texas; Georgia and Alabama; and Virginia and North Carolina) were sampled, and fields with other crops were sampled in regions where peanuts are not commonly grown. The A. flavus isolates were identified as members of either the L strain (n = 774), which produces sclerotia that are >400 μm in diameter, or the S strain (n = 309), which produces numerous small sclerotia that are <400 μm in diameter. The S-strain isolates generally produced high levels of aflatoxin B₁, whereas the L-strain isolates were more variable in aflatoxin production; variation in cyclopiazonic acid production also was greater in the L strain than in the S strain. There was a positive correlation between aflatoxin B₁ production and cyclopiazonic acid production in both strains, although 12% of the L-strain isolates produced only cyclopiazonic acid. Significant differences in production of aflatoxin B₁ and cyclopiazonic acid by the L-strain isolates were detected among regions. In the western half of Texas and the peanut-growing region of Georgia and Alabama, 62 to 94% of the isolates produced >10 μg of aflatoxin B₁ per ml. The percentages of isolates producing >10 μg of aflatoxin B₁ per ml ranged from 0 to 52% in the remaining regions of the transect; other isolates were often nonaflatoxigenic. A total of 53 of the 126 L-strain isolates that did not produce aflatoxin B₁ or cyclopiazonic acid were placed in 17 vegetative compatibility groups. Several of these groups contained isolates from widely separated regions of the transect.     

Aflatoxin Production by Aspergillus flavus as Related to Various Temperatures

Two aflatoxin-producing isolates of Aspergillus flavus were grown for 5 days on Wort media at 2, 7, 13, 18, 24, 29, 35, 41, 46, and 52 C. Maximal production of aflatoxins occurred at 24 C. Maximal growth of A. flavus isolates occurred at 29 and 35 C. The ratio of the production of aflatoxin B₁ to aflatoxin G₁ varied with temperature. Aflatoxin production was not related to growth rate of A. flavus; one isolate at 41 C, at almost maximal growth of A. flavus, produced no aflatoxins. At 5 days, no aflatoxins were produced at temperatures lower than 18 C or higher than 35 C. Color of CHCl₃ extracts appeared to be directly correlated with aflatoxin concentrations. A. flavus isolates grown at 2, 7, and 41 C for 12 weeks produced no aflatoxins. At 13 C, both isolates produced aflatoxins in 3 weeks, and one isolate produced increasing amounts with time. The second isolate produced increasing amounts through 6 weeks, but at 12 weeks smaller amounts of aflatoxins were recovered than at 6 weeks.     

Study on pectinase and sclerotium producing abilities of two kinds ofAspergillus flavus isolates from Zhejiang

Pectinase and sclerotium production by strains ofAspergillus flavus were determined with a pectinase culture plate assay and a Cz 3% NaNO₃ medium plate assay. In theA. flavus population, 51% of isolates produced sclerotia, the toxigenic strains showing a tendency to have smaller sclerotia. Strains producing both abundant small sclerotia and a large quantity of aflatoxin were not found. There was no linear correlation between the amount of aflatoxin produced and the number of sclerotia. Levels of pectinase produced by the toxigenic strains were higher than that of the non-toxigenic strains, and this character was more obvious in the sclerotium-producing strains than in the non-sclerotium-prodcing strains. In theA. flavus population from Zhejiang in which the toxigenic strain rate was low, toxigenic strains may require higher levels of pectinase to compete with the non-toxigenic strains when infecting foodstuffs.     

Effect of Aeration on Growth and Aflatoxin Production by Aspergillus flavus in Submerged Culture

Aspergillus flavus ATCC 15517 produced up to 212 mg per liter of total aflatoxin in submerged culture in aerated (3,000, 6,000, 9,000, and 12,000 ml/min) and agitated medium in 14-liter fermentors with 10 liters of medium consisting of 2% yeast extract and 10% sucrose. Aflatoxin production increased with time. A maximum of 212 mg/liter was produced at 9,000 ml/min aeration, whereas the yield decreased substantially at the lower aeration rates. Two other strains of A. flavus synthesized aflatoxin in smaller quantities.     

β-Carotene inhibition of aflatoxin biosynthesis amongAspergillus flavus genotypes from Illinois corn

Thirty-nineAspergillus flavus genotypes (DNA fingerprinting) isolated from corn grown in a field near Kilbourne, Illinois were evaluated for their sensitivity to β-carotene (50 μg/ml) inhibition of aflatoxin B₁ biosynthesis. Inhibition of aflatoxin was greater than 90% for 28 of the genotypes and >70% for 38 of the 39 genotypes. FiveA. flavus strains (4 fingerprint groups) isolated from molded raw peanuts, NRRL 3239, NRRL 3357, NRRL 6514, NRRL 6515 and NRRL 13135, produced greater quantities of aflatoxin than all 39 genotypes isolated from corn, and were less sensitive to β-carotene inhibition.Aspergillus flavus NRRL 3357 is commonly used as inoculum in variety trials for aflatoxin resistance. Isolate identity and sensitivity to potential inhibitors in corn can be critical in assessing corn resistance to aflatoxin.     

A Survey on Distribution of Aspergillus Section Flavi in Corn Field Soils in Iran: Population Patterns Based on Aflatoxins, Cyclopiazonic Acid and Sclerotia Production

Soil isolates of Aspergillus section Flavi from Mazandaran and Semnan provinces with totally different climatic conditions in Iran were examined for aflatoxins (AFs; B and G types), cyclopiazonic acid (CPA) and sclerotia production. A total of 66 Aspergillus flavus group strains were identified from three species viz. Aspergillus flavus, Aspergillus parasiticus and Aspergillus nomius in both locations. A. flavus (87.9%) was found to be the prominent species followed by A. nomius (9.1%) and A. parasiticus (3.0%). Only 27.5% of A. flavus isolates were aflatoxigenic (B₁ or B₁ and B₂), out of which approximately 75% were capable to producing CPA. All the A. parasiticus and A. nomius isolates produced AFs of both B (B₁ and B₂) and G (G₁ and G₂) types, but did not produce CPA. Sclerotia production was observed in only 4 isolates of A. flavus among all 66 isolates from three identified species. A. flavus isolates were classified into various chemotypes based on the ability to produce aflatoxins and CPA. In this study, a new naturally occurring toxigenic A. flavus chemotype comprising of two strains capable of producing more AFB₂ than AFB₁ has been identified. A relatively larger proportion of aflatoxigenic A. flavus strains were isolated from corn field soils of Mazandaran province which indicate a possible relationship between high levels of relative humidity and the incidence of aflatoxin-producing fungi. The importance of incidence of Aspergillus section Flavi in corn field soils regard to their mycotoxin production profiles and crop contamination with special reference to climatic conditions is discussed.     

Considerations on the distribution of aflatoxigenic Aspergillus flavus in feeds

The distribution of aflatoxin producing isolates of the Aspergillus flavus group in feeds was studied. Aflatoxin production was investigated by a sequential method previously reported (fluorescence in Coconut Agar Medium, rapid extraction from a wheat medium, and total extraction from the same wheat medium). Twenty-seven of 32 samples contained A. flavus, and 21 of them had at least one aflatoxicogenic isolate of A. flavus. Of the 115 isolates analysed, 65 produced aflatoxins, mainly B aflatoxins.     

Influence of iturin A on mycelial weight and aflatoxin production byAspergillus flavus andAspergillus parasiticus in shake culture

Iturin A, a peptidolipid produced byBacillus subtilis, inhibits growth of a large number of fungi. In this study, the effects of iturin A were evaluated on nine isolates ofA. flavus and seven isolates ofA. parasiticus in liquid shake culture. The mycelial dry weight of theA. flavus isolates was not significantly influenced by iturin A, however, there was a significant reduction in mycelial dry weight for two of theA. parasiticus isolates. Aflatoxin production was significantly reduced in five of theA. flavus isolates and three of the six aflatoxigenicA. parasiticus isolates. For the other seven isolates, aflatoxin levels were either unchanged or significantly increased in the presence of iturin A. These results indicate that iturin A does not consistently reduce growth or aflatoxin production of these fungi in pure culture.     

Production of aflatoxin in corn by a large-scale solid-substrate fermentation process

Culturing of Aspergillus flavus was conducted in static flask cultures and 4 in. × 5 ft columns (containing 7–8 kg corn) to measure the effects of moisture, temperature, and air flow upon growth and the production of aflatoxin. Aflatoxin levels as high as 6200 ppb (dry basis) in 10 days were observed. Conditions were selected (ca. 20% moisture, 0.008 liter air/kg corn/min air flow with 1.5 liter/kg/min recirculated) for production of aflatoxin in 1200 bushels of corn in a 18-ft diam corrugated steel Butler storage bin for preparation of contaminated corn for animal feeding trials and for testing of an ammoniation process for decontamination of aflatoxin in corn. A target level of 1000 ppb aflatoxin was attained.