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).     

Aflatoxin is degraded by mycelia from toxigenic and nontoxigenic strains of aspergilli grown on different substrates

The ability of 9-day-old mycelia of Aspergillus parasiticus NRRL 2999 to degrade aflatoxin varied depending on the substrate used to grow the mold. Substrates which allowed substantial mycelial growth yielded mycelia which actively degraded aflatoxin. Substrates which allowed minimal growth of mycelia yielded mycelia with little ability to degrade aflatoxin. Biodegradation of aflatoxin was also strain-dependent. A. parasiticus NRRL 2999 and NRRL 3000 actively degraded aflatoxin, A. flavus NRRL 3353 was less active, and A. flavus NRRL 482 and A. parasiticus NRRL 3315 degraded minimal amounts of aflatoxins. Those aspergilli producing greatest amounts of aflatoxin also degraded aflatoxins most rapidly, whereas those strains which produced minimal amounts of aflatoxin generally degraded aflatoxins less effectively. Substrates which allowed maximum aflatoxin production also yielded mycelia which actively degraded aflatoxins, whereas media which allowed limited production of aflatoxin generally yielded mycelia with minimal ability to degrade the toxin. Although exceptions exist, generally as aflatoxin production increased so did the ability of mycelia to degrade the toxin.     

Peroxidase activity in mycelia of Aspergillus parasiticus that degrade aflatoxin

Summary Extracts of 9-day-old mycelia of Aspergillus parasiticus NRRL 2999 were assayed for peroxidase activity and for their ability to degrade aflatoxin. A positive relationship existed between rates of aflatoxin degradation and amount of peroxidase activity in these extracts. The supernatant fluid of homogenates from mycelia grown under similar conditions varied in amount of peroxidase present (170 to 2215 U/g). The fraction obtained, by precipitation with (NH₄)₂SO₄ at 45% of saturation, from six different homogenates prepared from three mycelial mats contained peroxidase and degraded aflatoxin. Rates of aflatoxin degradation by and amounts of peroxidase activity in each sample obtained from mycelial homogenates with (NH₄)₂SO₄ at 60% of saturation varied; however, when increased amounts of peroxidase activity were present, more aflatoxin was degraded and vice versa. Relatively little peroxidase activity was present in the fraction obtained with (NH₄)₂SO₄ at 30% of saturation and little or no aflatoxin was degraded by this precipitate. Trends for degradation of aflatoxin when more or less peroxidase activity was present in mycelial preparations suggest that the enzyme may be involved in degradation of aflatoxin by the Aspergillus.     

Effect of temperature on production of aflatoxin on rice by Aspergillus flavus

Summary The effect of temperature on formation of aflatoxin on solid substrate (rice) byAspergillus flavus NRRL 2999 has been studied in some detail. The optimum temperature for production of both aflatoxin B₁ and G₁ under the conditions employed is 28° C. Comparable yields of B₁ were obtained at 32° C, but considerably less G₁ was produced at this temperature. Both B₁ and G₁ were found in lesser amounts at temperatures above 32° C, and the aflatoxin content of rice incubated at 37° C was low (300–700 ppb) even though growth was good.Reducing the temperature from 28° to 15° C resulted in progressively less aflatoxin, but 100 ppb of B₁ was detected in cultures incubated 3 weeks at 11° C. No aflatoxin was produced at 8° C.The ratio of the four aflatoxins is affected by temperature. At the lower temperatures, essentially equal amounts of aflatoxin B₁ and G₁ were produced, whereas at 28° C, approximately four times as much B₁ was detected as G₁. At the higher temperatures, relatively less G was formed, until at 37° C, less than 10 ppb was detected.This is a laboratory of the Northern Utilization Research and Development Division, Agricultural Research Service, U.S. Department of Agriculture.     

Experimental short time production of aflatoxins by Aspergillus parasiticus in mixed feeds as related to various moisture contents

Experimental short time production of aflatoxins in mixed feeds at 22, 28 and 37 °C as related to various moisture contents was studied. Growth of Aspergillus parasiticus was not observed in the meals with a moisture content ranging around 15% (22, 28 and 37 °C); the lowest quantifiable total aflatoxins at the fourth day was detected at 22 °C with 19.4% of moisture content; the higher total quantity of aflatoxins (113 mg/kg) was produced at 28 °C with 29.3% of moisture content. The ratio aflatoxin B₁/aflatoxin G₁ increased as the temperature raised.     

Comparison of the ability of three Aspergillus strains to form aflatoxins on bakery products and on nutrient agar

The growth of Aspergillus parasiticus NRRL 2999, A. parasiticus NRRL 3000 and A. flavus NRRL 3251 on whole wheat bread and on cake (Rührkuchen) was compared and the formation of the aflatoxins B₁, B₂, G₁, G₂ and M₁ on these substrates and, for purpose of comparison, on malt extract agar was determined. On cake the moulds grew better than on bread and formed the highest yields of aflatoxins. Malt extract agar was the most unfavourable substrate for toxin production. The ratio M₁/B₁ on bread and cake was in the order of 0.1–0.4 and was higher than the data reported for grains. The highest yields of aflatoxin B₁ (1.0 g/g) were produced by A. flavus NRRL 3251 on cake.     

Biochemical analysis of oxidative stress in the production of aflatoxin and its precursor intermediates

The relevance of oxidative stress in the production of aflatoxin and its precursors was examined in different mutants of Aspergillus parasiticus, which produce aflatoxin or its precursor intermediates, and compared with results obtained from a non-toxigenic strain. In comparison to the non-toxigenic strain (SRRC 255), an aflatoxin producing strain (NRRL 2999) or mutants that accumulate aflatoxin precursors such as norsolorinic acid (by SRRC 162) or versicolorin (by NRRL 6196) or O-methyl sterigmatocystin (by SRRC 2043) had greater oxygen requirements and higher contents of reactive oxygen species. These changes were in the graded order of NRRL 2999 > SRRC 2043 > NRRL 6196 > SRRC 162 > SRRC 255, indicating incremental accumulation of reactive oxygen species, being least in the non-toxigenic strain and increasing progressively during the ternary steps of aflatoxin formation. Oxidative stress in these strains was evident by increased activities of xanthine oxidase and free radical scavenging enzymes (superoxide dismutase and glutathione peroxidase) as compared to the non-toxigenic strain (SRRC 255). Culturing the toxigenic strain in presence of 0.1–10 μM H₂O₂ in the medium resulted in enhanced aflatoxin production, which could be related to dose-dependent increase in [¹⁴C]-acetate incorporation into aflatoxin B₁ and increased acetyl CoA carboxylase activity. The combined results suggest that formation of secondary metabolites such as aflatoxin and its precursors by A. parasiticus may occur as a compensatory response to reactive oxygen species accumulation.     

Development of Aspergillus parasiticus and formation of aflatoxin B1 under the influence of conidiogenesis affecting compounds

The influence of various inhibitors of hyphal growth, sporulation and biosynthesis of aflatoxin B₁ in Aspergillus parasiticus NRRL 2999 was studied. 6-Thioguanine, dl-ethionine, fluoroacetic acid and phenylboric acid, inhibitors of maturation of fungal conidiophores and of conidiogenesis, were added at various concentrations to malt extract agar. Lower concentrations of 6-thioguanine and dl-ethionine did not inhibit the growth of hyphae and the sporulation. Phenylboric acid reduced conidiogenesis more than hyphal growth. The yields of aflatoxin B₁ were significantly reduced. Additions of fluoroacetic acid did not greatly affect the growth of hyphae but totally inhibited the production of conidia and concurrently significantly reduced the formation of aflatoxin B₁. An interrelation between conidiogenesis and onset of secondary metabolism in A. parasiticus is evident.     

Examination of fungal growth and aflatoxin production on marihuana

Under favorable growth conditions,Aspergillus flavus andA. parasiticus produced aflatoxins on marihuana. Cultures ofA. flavus ATCC 15548 produced both aflat oxin B₁(AFB₁) and G₁(AFG₁). The production of AFG₁ was substantially greater than that of AFB₁. Cultures ofA. flavus NRRL 3251 andA. parasiticus NRRL 2999 produced only AFB₁. All natural flora cultures tested negative for aflatoxins. NoAspergilli sporulations were observed in these cultures. In the cultures inoculated with known toxigenic fungi, the highest mean level for total aflatoxins was 8.7 g/g of medium. Marihuana appears not to yield large quantities of these mycotoxins but sufficient levels are present to be a potential health hazard for both the user and the forensic analyst who is in daily contact with such plant material. Careful processing, storage, and sanitation procedures should be maintained with marihuana. If these conditions are disregarded due to the illicit status of marihuana, the potential for mycotoxin contamination must be considered.     

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.     

Aflatoxins in sunflower seeds: Influence of Alternaria alternata on aflatoxin production by Aspergillus parasiticus

The aim of the present work was to determine the influence of Alternaria alternata upon aflatoxin production by Aspergillus parasiticus.A mixture of spores of both strains was inoculated in sunflower seeds at 0,90 a_w, and incubated for 42 days at 28 °C ±1.The cultures were observed and analyzed every 7 days to determine the infection level of the seeds and the production of aflatoxins. Results showed that when the seeds were inoculated only with Aspergillus parasiticus, 100% were infected from the 7th day.When Aspergillus parasiticus and Alternaria alternata were simultaneously inoculated the infection level of the seeds was 100% for Aspergillus parasiticus following 7 days of inoculation and 0% for Alternaria alternata. After the 14th day of inoculation there was no significant difference in the infection percentage of both strains (approximately 80% of each one). As far as toxin production is concerned a remarkable decrease was observed when seeds were inoculated with both strains simultaneously.In accordance to the results, Alternaria alternata would not compete with Aspergillus parasiticus in colonization of seeds but would either degrade the aflatoxins by Aspergillus parasiticus or compete for aflatoxin biosynthesis precursors. Alternaria alternata could also secrete some substance that specifically inhibits aflatoxin synthesis.     

Survey of aflatoxins and ochratoxin A in stored tubers ofCyperus esculentus L.

The mold incidence, moisture contents, pH and levels of mycotoxins (aflatoxins B₁, G₁ and ochratoxin A) on/of/in rootstock snack (tubers ofCyperus esculentus L.) samples were monitored during a 150-day storage period. Whereas the mold incidence, moisture and mycotoxin levels increased with storage time, the pH declined during the same period. Altogether, 12 fungal species, mostly toxigenic, includingAspergillus flavus, A. parasiticus andA. ochraceus were isolated. At collection period only 3 of the 9 snack samples analysed contained trace amounts of aflatoxins. By 120th day, all the 9 samples were contaminated and the average levels were 454 and 80 ppb for aflatoxin B₁ and aflatoxin G₁ respectively on the 150th day. Ochratoxin A was not detected before 120th day and then only at low levels, occuring in a maximum of four samples and ranging between 10 and 80 ppb.     

Effect of phytate on aflatoxin formation by Aspergillus parasiticus and Aspergillus flavus in synthetic media

The effect of phytate on the production of aflatoxins by Aspergillus parasiticus and Aspergillus flavus grown on synthetic media was examined. In the absence of pH control (initial pH 4.5–6.5) for A. parasiticus, phytate (14.3 mM) caused a six-fold decrease in aflatoxins in the medium and a ten-fold decrease in those retained by the mycelia. When the initial pH of the medium was adjusted to 4.5 no effect on aflatoxin production was observed. With A. flavus or A. parasiticus grown on media with a higher initial pH value (6 to 7), the presence of phytate in the media caused an increase in aflatoxin production. These results are inconsistent with previous studies which indicated that phytate depresses aflatoxin production by rendering zinc, a necessary co-factor for aflatoxin biosynthesis, unavailable to the mold.     

Production of aflatoxin byAspergillus parasiticus and its control

The aim of the present work was to investigate the production of aflatoxin byAspergillus parasiticus and to find out the possible ways to control it. Of 40 food samples collected from Abha region, Saudi Arabia, only 25% were contaminated with aflatoxins. Oil-rich commodities had the highly contaminated commodities by fungi and aflatoxins while spices were free from aflatoxins.Bacillus megatertum andB cereus were suitable for microbiological assay of aflatoxins. Czapek’s-Dox medium was found a suitable medium for isolation of fungi from food samples. The optimal pH for the growth ofA. parasiticus and its productivity of aflatoxin B₁ was found at 6.0, while the best incubation conditions were found at 30°C for 10 days. D-glucose was the best carbon source for fungal growth, as well as aflatoxin production. Corn steep liquor, yeast extract and peptone were the best nitrogen sources for both fungal growth and toxin production (NH₄)₂HPO₄ (1.55 gL^-1) and NaNO₂ (1.6 gL^-1) reduced fungal growth and toxin production with 37.7% and 85%, respectively. Of ten amino acids tested, asparagine was the best for aflatoxin B₁ production. Zn²⁺ and Co²⁺ supported significantly both fungal growth, as well as, aflatoxin B₁ production at the different tested concentrations. Zn²⁺ was effective when added toA. parasiticus growth medium at the first two days of the culture age. The other tested metal ions expressed variable effects depending on the type of ion and its concentration. Water activity (a_w) was an important factor controlling the growth ofA. parasiticus and toxin production. The minimum a_w for the fungal growth was 0.8 on both coffee beans and rice grains, while a_w of 0.70 caused complete inhibition for the growth and aflatoxin B₁ production. H₂O₂ is a potent inhibitor for growth ofA. parasiticus and its productivity of toxins. NaHCO₃ and C₆H₅COONa converted aflatoxin B₁ to water-soluble form which returned to aflatoxin B₁ by acidity. Black pepper, ciliated heath, cuminum and curcuma were the most inhibitory spices on toxin production. Glutathione, quinine, EDTA, sodium azide, indole acetic acid, 2,4-dichlorophenoxy acetic acid, phenol and catechol were inhibitory for both growth, as well as, aflatoxin B₁ production. Stearic acid supported the fungal growth and decreased the productivity of AFB₁ gradually. Lauric acid is the most suppressive fatty acid for both fungal growth and aflatoxin production, but oleic acid was the most potent supporter. Vitamin A supported the growth but inhibited aflatoxin B₁ production. Vitamins C and D₂ were also repressive particularly for aflatoxin production The present study included studying the activities of some enzymes in relation to aflatoxin production during 20-days ofA. parasiticus age in 2-days intervals. Glycolytic enzymes and pyruvate-generating enzymes seems to be linked with aflatoxin B₁ production. Also, pentose-phosphate pathway enzymes may provide NADPH for aflatoxin B₁ synthesis. The decreased activities of TCA cycle enzymes particularly from 4th day of growth up to 10th day were associated with the increase of aflatoxin B₁ production. All the tested enzymes as well as aflatoxin B₁ production were inhibited by either catechol or phenol.     

Aflatoxin production by Aspergillus parasiticus in a competitive environment

Aspergillus parasiticus NRRL 2999 was grown in the presence of Rhizopus nigricans, Saccharomyces cerevisiae, Acetobacter aceti, or Brevibacterium linens and aflatoxin concentration was determined after 3,5,7, and 10 days of incubation at 28C. R. nigricans and S. cerevisiae inhibited growth and aflatoxin production by A. parasiticus. B. linens caused slight inhibition and A. aceti stimulated growth and aflatoxin production by A. parasiticus.     

Growth and aflatoxin production by Aspergillus parasiticus when in the presence of Streptococcus lactis

Streptococcus lactis was grown with Aspergillus parasiticus in modified APT broth. Three inoculation procedures were used: (a) S. lactis was grown 3 days, then conidia of A. parasiticus were added (SLAP), (b) both organisms were added simultaneously (ST) and (c) A. parasiticus was grown 3 days, then S. lactis was added (APSL). At 3, 6 and 10 days of incubation, contents of flasks were analyzed for growth of each organism, pH of broth and aflatoxin content. S. lactis did not survive past 3 days when grown alone. In ST cultures, S. lactis grew to the same extent as in the control at 3 days; it remained viable at a low level through 10 days. In APSL cultures, S. lactis growth was inhibited at 3 days but the bacterium survived through 7 days (10 days of mold growth) at reduced numbers. At 3 days there were no appreciable differences in growth of A. parasiticus. At 6 days, in ST and SLAP cultures, growth of the mold was inhibited, while in the APSL culture growth increased over that in the control. At 10 days, growth of mold was somewhat increased over the control in all test conditions. The pH of broth in the A. parasiticus control and APSL culture was 6 at 3 days, dropped to 4.5–4.6 at 6 days and rose to 7 by 10 days. In ST and SLAP cultures, the pH was at 4.1 at 3 days and rose to pH 7 by 10 days. Aflatoxin (B₁ plus G₁) content was lowest at 3 days and increased at 6 days. Between 6 and 10 days two patterns were observed. In APSL and SLAP cultures, aflatoxin content decreased, while it increased in the ST culture. These patterns occurred when aflatoxin content was expressed on a total or per gram of dried mycelium basis. At 3 days the amounts of aflatoxin B₁ and G₁ were approximately equal. Between 3–6 days the amount of G₁ increased more rapidly than that of B₁. Between 6 and 10 days in the ST culture, the amount of G₁ increased at a slower rate than that of B₁ while in SLAP and APSL cultures, the amount of G₁ decreased more rapidly than that of B₁. When a different lot of the same medium was used, aflatoxin production was greatly reduced. The pH of broth at all test conditions rose through the incubation period.     

In situ absorption of aflatoxins in rat small intestine

To evaluate the rate at which the four main aflatoxins (aflatoxins B₁, B₂, G₁ and G₂) are able to cross the luminal membrane of the rat small intestine, a study about intestinal absorption kinetics of these mycotoxins has been made. In situ results obtained showed that the absorption of aflatoxins in rat small intestine is a very fast process that follows first-order kinetics, with an absorption rate constant (k _a ) of 5.84±0.05 (aflatoxin B₁), 4.06±0.09 (aflatoxin B₂), 2.09±0.03 (aflatoxin G₁) and 1.58±0.04 (aflatoxin G₂) h^–1, respectively.     

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.     

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.