A yeast bioassay for T-2 toxin

A disk diffusion type bioassay was developed for T-2 toxin using the yeast Kluyveromyces fragilis. The lower limit of detection for this in 0.2 μg of T-2 toxin. The growth of this yeast was sensitive to other trichothecenes such as verrucarin A (0.01 μg). Aflatoxin B₁ (50 μg) and zearalanone (20 μg) did not inhibit the growth of this yeast.     

New process for T-2 toxin production.

Strains of Fusarium produced high levels of T-2 toxin when cultured on certain media absorbed into vermiculite. Modified Gregory medium was nutritionally complex (2% soya meal, 0.5% corn steep liquor, 10% glucose) and, when inoculated with the appropriate fungal strain, yielded maximum T-2 toxin within 24 days of incubation at 19 degrees C. On Vogel synthetic medium N (H. J. Vogel, Microb. Genet, Bull. 13:42-43, 1956) supplemented with 5% glucose, optimal toxin levels were synthesized after incubation for 12 to 14 days at 15 degrees C. Fusarium tricinctum T-340 produced 714 and 353 mg/liter on modified Gregory medium and Vogel synthetic medium N plus 5% glucose, respectively. Improved analytical procedures were developed and involved aqueous methanol extraction, purification by liquid-liquid partitions, and gas-chromatographic quantitation.     

Cross-reactivity of antibodies against T-2 with deepoxide T-2 toxin

Two types of antibodies raised against T-2 toxin, namely anti-T-2-HS-BSA and anti-3 -Ac -NEOS-HS -BSA, showed good cross-reactivity with deepoxy T-2 toxin. Our results indicate that the epoxide is not an important epitope for the production of antibody against T-2 toxin     

T-2 toxin degradation by micromycetes

The biodegradation of T-2 toxin was studied by strains of micromycetes which were isolated from the environment. The 26 tested strains were divided into three groups. Group contains strains which degraded T-2 toxin very fast. This toxin could not be chromatographically determined in the medium even after 48 hours of incubation and the antifungal activity of residua against Kluyveromyces fragilis CCY-51-1-2 was low or zero. There were strains of Alternaria sp., Ulocladium sp., Aspergillus candidus, Cladosporium cladosporioides, Rhodotorula sp., Aspergillus flavus and Cladosporium macrocarpum. Group II contains with a low activity and in group III the results were variable and non stable.     

Metabolic effects of trichothecene T-2 toxin

Cereals and other agricultural products contaminated with trichothecene mycotoxins are unfit for consumption. Until recently, the metabolic effects of T-2 toxin (T-2) were thought to reside in its ability to inhibit protein synthesis. It is now clear that trichothecenes have multiple effects, including inhibition of DNA, RNA, and protein synthesis in several cellular systems, inhibition of in vitro protein synthesis, inhibition of mitochondrial functions, effects on cell division, normal cell shape, and hemolysis of erythrocytes. It is argued that these effects are pleiotropic responses of the cell's biosynthetic network to protein synthesis inhibition. However, in studies with erythrocytes, which lack nuclei and protein synthesis, changes in cell shape and lytic response towards T-2 are observed. Susceptibility to lysis is species dependent and correlates with the presence of phosphatidylcholine. Owing to their amphipathic nature, T-2 and other trichothecenes could exert their cytotoxicity by acting on cell membranes. As for cell energetics, T-2 inhibits the mitochondrial electron transport system, with succinic dehydrogenase as one site of action. Although initial investigations of the metabolic effects of T-2 mediated cytotoxicity suggested the inhibition of protein synthesis as the principal site of action, current thought suggests that the effects of trichothecenes are much more diverse.     

A monoclonal antibody to T-2 toxin

A specific, high affinity monoclonal antibody to T-2 toxin of Fusarium has been produced. The monoclonal antibody was conjugated to horse-radish peroxidase and employed to develop a direct competitive enzyme-linked immunosorbent assay (ELISA) for the toxin. The sensitivity of the ELISA was 10 ng/ml with a working range up to 500 ng/ml. The antibody cross-reacted with HT-2 toxin (25%) but did not bind to any other trichothecene tested.     

Production of antibody against T-2 toxin.

Antibody against T-2 toxin was obtained after immunization of rabbits with bovine serum albumin-T-2 hemisuccinate conjugate. The antibody had greatest binding efficiency for T-2 toxin, less efficiency for HT-2, and least for T-2 triol. Cross-reaction of antibody with neosolaniol, T-2 tetraol, and 8-acetyl-neosolaniol was very weak. Diacetoxyscirpenol, trichodermin, vomitoxin, and verrucarin A essentially gave no cross-reaction with the antibody. The sensitivity of the binding assay for T-2 toxin detection was in the range of 1 to 20 ng per assay. Detailed methods for the preparation of the conjugate and the production of immune serum and methods for antibody determination are described.     

Characterisation of hemolysis induced by T-2 toxin

The erythrocyte constitutes a good model system for the study of membrane-associated toxicity events caused by the trichothecene mycotoxin, T-2. This study confirms that T-2 has a direct lytic effect on erythrocytes. Lysis of guinea pig red cells requires approx. 10(10) molecules/cell and reaches plateau values after 4-6 h. An activation energy, Ea approximately equal to 4.5 kcal was derived from the Arrhenius equation. By use of osmotic blockers of differing Stokes' radii, the functional size of the membrane lesion caused by T-2 toxin was shown to be smaller than 5.5 A. It is concluded that T-2 toxin may exert its toxic effects via the cell membrane.     

Interaction of T-2 toxin with murine lymphocytes

T-2 toxin is taken up by lymphocytes in 10–15 min in a saturable manner. Uptake is dependent on temperature and partially on the availability of energy. Approx. 10⁵ molecules of T-2 toxin are bound per cell, having a mean affinity constant, K_a = 1.6·10⁷ M^?1. The toxin is rapidly dissociated from the cell to leave approx. 10–15% of the original loading in 1 h. It is concluded that T-2 toxin uptake and release do not follow conventional mechanisms.     

T-2 toxin inhibits mitochondrial function in yeast

T-2 toxin inhibits oxygen consumption of whole cells and purified mitochondria of Saccharomyces cerevisiae. Inhibition of mitochondrial respiration is not relieved by 2, 4-dinitrophenol, indicating that T-2 toxin inhibits mitochondrial function at the level of the electron transport chain. T-2 toxin inhibition of state 3 respiration (with succinate) is overcome by N, N, N', N'-tetramethyl-p-phenylenediamine, indicating inhibition of site II of the electron transport chain. T-2 toxin inhibits mitochondrial succinate dehydrogenase activity and increases mitochondrial NADH dehydrogenase activity.     

A microbiological assay for sterigmatocystin,T-2 toxin and zearalenone

A survey was done to find microorganisms useful for assaying sterigmatocystin; T-2 toxin and zearalenone.Staphylococcus aureus was found to be sensitive to T-2 toxin and zearalenone;Bacillus cereus was found to be sensitive to T-2 toxin only; andEscherichia coli was sensitive to sterigmatocystin. The response of the organisms to sterigmatocystin; T-2 toxin and zearalenone was found to be linear between 4 and 100 μg with sterigmatocystin toE. coli; between 2 and 25 μg with T-2 toxin toStaph, aureus andB. cereus; and between 4 and 100 μg with zearalenone toStaph, aureus. The lower limits of sensitivity of the test were 2 μg T-2 toxin and zearalenone, and 4 μg sterigmatocystin. The assay is rapid (15–17 hrs); simple and inexpensive; and can be used to verify the toxicity of samples and to confirm thin layer chromatographic results.     

Detection of T-2 toxin by an improved radioimmunoassay

T-2 toxin in serum, urine, and saline was analyzed by a modified radioimmunoassay procedure. The specimens were added directly to the assay tubes without extraction steps. The reaction between antibody and ligands was optimal at 1 h. Albumin-coated charcoal was used to separate bound from free radioactivity. Quenching, which occurred with hemolyzed specimens, was corrected by a wet oxidation process with 60% perchloric acid and 30% hydrogen peroxide. The shorter incubation times resulted in an assay that takes less than 6 h to complete. The average affinity constant of the antibody (Km) was 1.75 X 10(10) liters/mol. The sensitivity was 1 ng per assay or 10 ng/ml. Among the other trichothecenes tested, only H-T-2 cross-reacted significantly (10.3%).     

T-2 toxin and diacetoxyscirpenol metabolism by Baccharis spp

Hybrids resulting from crosses between Baccharis sarothroides and B. pilularis (FS1), B. sarothroides (FS2) and B. megapotamica (FS3) were tested for their tolerance to trichothecenes as well as their ability to metabolize the toxins. B. sarothroides (desert broom) was placed in an aqueous solution containing 500 ppm of T-2 toxin and showed visible signs of toxicity on the twigs at 21 h after exposure but not at 6 h, indicating some resistance. Samples of the twigs harvested 6 and 21 h after treatment contained, respectively, T-2 (0.03 and 2.2 micrograms/g), HT-2 (0.09 and 7.6 micrograms/g), and T-2-tetraol (2.1 and 2.6 micrograms/g). The hybrid FS1 showed no signs of toxicity 6 h after treatment, and its twigs contained T-2 (0.8 micrograms/g), HT-2 (10.2 micrograms/g), and T-2-tetraol (10.8 micrograms/g). The leaves at 6 h contained 0.5 micrograms of T-2, 1.7 micrograms of HT-2, 0.01 microgram of 3'-hydroxy-HT-2, and 41 micrograms of T-2-tetraol per g. At 21 h, toxic signs were apparent and the twigs contained T-2 (39 micrograms/g), HT-2 (62 micrograms/g), 3'-hydroxy-HT-2 (0.8 microgram/g), and T-2-tetraol (22 micrograms/g).(ABSTRACT TRUNCATED AT 250 WORDS)     

T-2 metabolites in the excreta of broiler chickens administered 3H-labeled T-2 toxin.

A method for the detection of T-2 metabolites was developed and applied to analysis of metabolites in excreta of broiler chickens administered 3H-labeled T-2 toxin. The method used acetonitrile extraction and partitioning with petroleum ether followed by chromatography on Amberlite XAD-2, Florisil, and Sep-Pak C18. The recovery of T-2 toxin added to the chicken excreta was 73% at a concentration of 0.2 microgram/g. About 80% of orally administered 3H-labeled T-2 toxin was rapidly metabolized to more polar derivatives and eliminated in the excreta within 48 h. T-2 toxin, HT-2 toxin, neosolaniol, and T-2 tetraol were detected at 0.06 to 1.13% of the total dose, 48 h after administration. Eight unknown derivatives, named TB-1 to TB-8, were quantitatively more significant than the metabolites above. TB-3 and TB-9 represented about 12 and 25% of the total dose, respectively. One of the metabolites (TB-6), 1.5% of the total dose, was identified as 4-deacetylneosolaniol (15-acetyl-3 alpha, 4 beta, 8 alpha-trihydroxy-12, 13-epoxytrichothec-9-ene).     

Immunoenzyme assay for detection of T-2 toxin in contaminated grain]

Based on indirect solid-phase competitive enzyme immunoassay, a method for determination of T-2 toxin in grain was designed. Determination errors were measured on samples of contaminated grain. The method makes allows determination of the toxin levels ranging from 30 to 1000 ng/g.     

Comparative effects of trichothecene mycotoxins on bovine platelet function: Acetyl T-2 toxin,a more potent inhibitor than T-2 toxin

The effects of the trichothecene mycotoxins (acetyl T-2 toxin, T-2 toxin, HT-2 toxin, palmityl T-2 toxin, diacetoxyscirpenol (DAS), deoxynivalenol (DON), and T-2 tetraol) on bovine platelet function were examined in homologous plasma stimulated with platelet activating factor (PAF). The mycotoxins inhibited platelet function with the following order of potency: acetyl T-2 toxin > palmityl T-2 toxin = DAS > HT-2 toxin = T-2 toxin. While T-2 tetraol was completely ineffective as an inhibitor, DON exhibited minimal inhibitory activity at concentrations above 10×10^?4M. The stability of the platelet aggregates formed was significantly reduced in all mycotoxin treated platelets compared to that of the untreated PAF controls. It is suggested that the increased sensitivity of PAF stimulated bovine platelets to the more lipophilic mycotoxins may be related to their more efficient partitioning into the platelet membrane compared to the more hydrophilic compounds.     

T-2 toxin and diacetoxyscirpenol metabolism by Baccharis spp.

Hybrids resulting from crosses between Baccharis sarothroides and B. pilularis (FS1), B. sarothroides (FS2) and B. megapotamica (FS3) were tested for their tolerance to trichothecenes as well as their ability to metabolize the toxins. B. sarothroides (desert broom) was placed in an aqueous solution containing 500 ppm of T-2 toxin and showed visible signs of toxicity on the twigs at 21 h after exposure but not at 6 h, indicating some resistance. Samples of the twigs harvested 6 and 21 h after treatment contained, respectively, T-2 (0.03 and 2.2 micrograms/g), HT-2 (0.09 and 7.6 micrograms/g), and T-2-tetraol (2.1 and 2.6 micrograms/g). The hybrid FS1 showed no signs of toxicity 6 h after treatment, and its twigs contained T-2 (0.8 micrograms/g), HT-2 (10.2 micrograms/g), and T-2-tetraol (10.8 micrograms/g). The leaves at 6 h contained 0.5 micrograms of T-2, 1.7 micrograms of HT-2, 0.01 microgram of 3'-hydroxy-HT-2, and 41 micrograms of T-2-tetraol per g. At 21 h, toxic signs were apparent and the twigs contained T-2 (39 micrograms/g), HT-2 (62 micrograms/g), 3'-hydroxy-HT-2 (0.8 microgram/g), and T-2-tetraol (22 micrograms/g).(ABSTRACT TRUNCATED AT 250 WORDS)     

In vitro metabolism of T-2 toxin in rats.

T-2 toxin was rapidly converted in the 9,000 X g supernatant fraction of rat liver homogenate into HT-2 toxin, T-2 tetraol, and two unknown metabolites designated as TMR-1 and TMR-2. TMR-1 was characterized as 4-deacetylneosolaniol (15-acetoxy-3 alpha, 4 beta, 8 alpha-trihydroxy-12,13-epoxytrichothec-9-ene) by spectroscopic analyses. Since the same metabolites were also obtained from HT-2 toxin used as substrate, it was concluded that T-2 toxin was hydrolyzed preferentially at the C-4 position to give HT-2 toxin, which was then metabolized to T-2 tetraol via 4-deacetylneosolaniol. In addition to HT-2 toxin, 4-deacetylneosolaniol and T-2 tetraol, a trace amount of neosolaniol was transformed from T-2 toxin by rat intestinal strips. In vitro metabolic pathways for T-2 toxin in rats are proposed.     

Immunochromatographic assay of T-2 toxin using labeled anti-species antibodies

A new scheme of immunochromatographic assay was developed for the highly sensitive detection of low-molecular-weight analytes. This scheme includes the following two steps: the formation of complexes of free specific antibodies with an antigen and their detection by anti-species antibodies conjugated to gold nanoparticles as the label. This scheme was tested with mycotoxin T-2 toxin in maize extracts. The use of specific antibodies and a label as two individual components made it possible to independently vary their concentrations with a simultaneous decrease in the detection limit and an increase in the color intensity. The assay did not require additional reagents and manipulations. The instrumental and visual detection limits of the designed test system were 0.1 and 5.0 ng/mL, respectively (2 and 90 ng per gram of analytes), which are two orders of magnitude lower compared to conventional immunochromatography using the same reagents.     

Detection of T-2 toxin by an improved radioimmunoassay.

T-2 toxin in serum, urine, and saline was analyzed by a modified radioimmunoassay procedure. The specimens were added directly to the assay tubes without extraction steps. The reaction between antibody and ligands was optimal at 1 h. Albumin-coated charcoal was used to separate bound from free radioactivity. Quenching, which occurred with hemolyzed specimens, was corrected by a wet oxidation process with 60% perchloric acid and 30% hydrogen peroxide. The shorter incubation times resulted in an assay that takes less than 6 h to complete. The average affinity constant of the antibody (Km) was 1.75 X 10(10) liters/mol. The sensitivity was 1 ng per assay or 10 ng/ml. Among the other trichothecenes tested, only H-T-2 cross-reacted significantly (10.3%).