Effect of F-2 and T-2 fusariotoxins on experimental Cryptosporidium baileyi infection in chickens

The course of Cryptosporidium baileyi infection in chickens fed with different doses of fusariotoxins was compared with that of control groups. F-2 toxin levels of 0.187–1.5 mg kg⁻¹ and T-2 toxin levels of 0.187–6.0 mg kg⁻¹ were investigated. The experimental amimals were orally infected with 6 × 10⁵ C. baileyi oocysts at 1 week of age. Total daily oocyst output was monitored by a quantitative method. Acquired immunity was tested at the age of 4 weeks, by ELISA and by a challenge infection with an equal number of oocysts, upon recovery from the primary infection. The results show that in chickens kept on the lower doses of F-2 and T-2 toxins, the parasite infection ran a similar course to that in the control groups, and the animals became resistant to re-infection. However, when higher doses (2.0–6.0 mg kg⁻¹) of T-2 toxin were used, a depression of weight gain was observed with some other physiological parameters (PCV, weight of bursa, weight of thymus, skin thickness in PHA-P skin test) also indicating toxic effect and, simultaneously, the oocyst output decreased significantly and the patent period was slightly prolonged. Although certain modifications of the immune response could be revealed, the chickens became resistant to re-infection. Only early (1 week of age) parasite infection and 6 mg kg⁻¹ T-2 toxin in the feed significantly depressed body weight gain and immunity.     

Influence of Selenium on the Production of T-2 Toxin by <Emphasis Type="Italic">Fusarium poae</Emphasis>

The objective of this study was to investigate the effects of selenium on the production of T-2 toxin by a Fusarium poae strain cultured in a synthetic medium containing different concentrations of selenium. The T-2 toxin contents in fermentative products were evaluated by a high performance liquid chromatography (HPLC). The results showed that the production of T-2 toxin was correlated with the concentration of selenium added to the medium. In all three treatments, the addition of 1 mg/L selenium to the medium resulted in a lower toxin yield than the control (0 mg/L); the yield of the toxin began to increase when selenium concentration was 10 mg/L, while it decreased again at 20 mg/L. In summary, T-2 toxin yield in the fermentative product was affected by the addition of selenium to the medium, and a selenium concentration of 20 mg/L produced the maximum inhibitory effect of T-2 toxin yield in the fermentative product of F. poae.     

Immunotoxicity of repeated low level exposure to T-2 toxin,a trichothecene mycotoxin,in CD-1 mice

Male CD-1 mice were gavaged with T-2 toxin (0.0–5.0 mg/kg body weight) every third day. Body weight gain was depressed by exposure to 2.5 mg/kg, or greater, T-2 toxin; this was not associated with decreased food intake. The weights of the liver, kidney, spleen, and thymus were affected by two weeks exposure to T-2 toxin. However, a persistent effect after four weeks was observed only for the thymus. Peripheral leucocyte counts were elevated in the highest dose groups after two and four weeks. Thymidine uptake by cells not simultaneously exposed to mitogen was increased in splenic cell cultures of mice exposed to 2.5 mg/kg T-2 toxin for two or four weeks. Phytohemagglutinin stimulation of splenic lymphocytes following two weeks of exposure was depressed in the 2.5 mg/kg dose group; this phenomenon was not observed after four weeks exposure. Response to pokeweed mitogen increased after four weeks of exposure to 2.5 mg/kg T-2 toxin. A delayed-type hypersensitivity response decreased following two weeks exposure to levels greater than 0.02 mg/kg. Production of I g M class antibodies by splenic lymphocytes, evaluated by a hemolytic plaque response to sheep erythrocytes, was depressed in the 2.5 mg/kg dose group after two weeks exposure to T-2 toxin. The sensitivity and specificity of T-2 toxin immunotoxicity was indicated by the various parameters evaluated.     

Ovarian consequences of low dose peroral Fusarium (T-2) toxin in a ewe and heifer model

The effect of low dose peroral Fusarium produced T-2 toxin intake upon the ovarian function was evaluated in ewes (n = 30; Trial 1) and heifers (n = 7; Trial 2). Half of the ewes and all of the heifers were fed rich, acidosis-inducing concentrate. The 30 ewes were divided into 6 groups of 5 animals each. They were given 0, 0.3 or 0.9 mg/day (0, 5 or 15 ug/kg) purified T-2 toxin per os for 21 days (3x2 factorial design). Four of the 7 heifers were fed 9 mg/day (25 ug/kg) of the same purified T-2 toxin for 20 days while 3 remained untreated. The estrus cycles in all animals were synchronized prior to the trials and the T-2 exposure was started in the mid-luteal phase. The acidic condition in the rumen was estimated by the determination of urinary net acid-base excretion. The ovarian activity was followed with blood sampling for progesterone on alternate days (Trial 1) or with ultrasonography and sampling for progesterone daily (Trial 2). All of the heifers and concentrate-fed ewes showed a compensated acidosis, during first two thirds of T-2 exposure. In Trial 1, ovarian malfunction manifested as lower P4 peak concentration in the midluteal phase, shortening of the CL lifespan and prolonged follicular phases. These malfunctions were detected in 3 and 3 ewes fed concentrate and 0.3 mg and 0.9 mg T-2 toxin. Lower P4 peak concentration was observed in 1 ewe fed regular diet and 0.9 mg T-2 toxin. None of the control and acidotic groups (0 mg T-2), or ewes fed regular diet with 0.3 mg T-2 showed any ovarian malfunction. In Trial 2, after PGF2, administration the ovulation occured later and the plasma progesterone level remained low (< 3 nmol/l) for a longer period in T-2 treated heifers, than their untreated control mates (5.0+/-0.7 vs 3.7+/-0.5 d, P<0.05 and 8.3+/-0.4 vs 6.3+/-0.9 d, P<0.01, respectively). These results show that the peroral T-2 intake can significantly retard the folliculus maturation and ovulation and perhaps the subsequent luteinisation also in ruminants kept on concentrate-rich diet.     

Subclinic effect of the administration of T-2 Toxin and Nivalenol in mice

Four experiments using T-2 toxin and nivalenol at different dosage, which represented the 25% and 40% of the LD50 (experiment A: 1.04 mg of T-2 toxin per kilogram of body weight, experiment B: 2.34 mg of T-2 toxin/kg b.w., experiment C: 1.04 mg of T-2 toxin/kg b. w. and 2.34 mg of T-2 toxin/kg b.w.; experiment D: 0.82 mg of nivalenol/kg b.w. and 1.845 mg of nivalenol/kg b.w.) were conducted on 400 mice. Both toxins were administered to mice of different ages (experiments A and B were adults, experiment C and D were young) by intraperitoneal single injection, and the clinical signs, hematological variables and histoanatomo pathological changes were studied. All animals survived. No changes anatomo-histopathological nor significative differences in weight gain were observed. Different behaviors were found for nivalenol and T-2 toxin. The most significant change was the increase in the level of monocytes in old animals, so this could be a biological indicator for T-2 toxin subclinical intoxication.     

T-2 toxin impairment of murine response to Salmonella typhimurium: a histopathologic assessment

T-2 toxin and other trichothecene mycotoxins experimentally impair normal immune function and may predispose humans and animals to infectious disease. In this study, the histopathologic effects of Salmonella typhimurium challenge concurrently with sublethal T-2 toxin exposure were examined in the Salmonella-resistant C3H/HeN mouse. Oral administration of T-2 toxin (1 mg/kg) every other day for 10 d had little effect on the tissues examined when compared to control animals. Mice challenged with S. typhimurium and then treated with T-2 toxin every other day for 10 d had markedly larger and more bacterial-related lesions in the spleens, kidneys, and livers than animals challenged with S. typhimurium alone. Differences in bone marrow, Peyer's patches and ileal tissues were less discernable between S. typhimurium and S. typhimurium plus T-2 toxin treated groups. These results were consistent with previous findings that T-2 toxin compromised murine resistance to S. typhimurium infection and ultimately caused death in animals challenged with a sublethal dose of the organism.     

The effect of vitamin E supplementation on reduction of lymphocyte DNA damage induced by T-2 toxin and deoxynivalenol in weaned pigs

The objective of the present study was to establish the effect of deoxynivalenol (DON) and T-2 toxin on lipid peroxidation, lymphocyte DNA fragmentation and immunoglobulin production in weaned pigs, and furthermore, to evaluate the potential of vitamin E (α-tocopheryl acetate) in prevention of toxin mediated changes. Forty-eight weaned castrated male crossbred pigs (mean live weight at the beginning of the experimental period was 11.7 kg) were randomly assigned to five experimental groups: control (without toxin and vitamin E), T-2 (3 mg/kg T-2 toxin), T-2 + E (3 mg/kg T-2 toxin + 100 mg/kg vitamin E), DON (4 mg/kg DON) and DON + E (4 mg/kg DON + 100 mg/kg vitamin E). After 14 days of treatment blood was collected for analysis. Lipid peroxidation was studied by assays of malondialdehyde (MDA), total antioxidant status (TAS) of plasma and erythrocyte glutathione peroxidase (GPx). DNA damage in lymphocytes was measured by comet assay. Serum immunoglobulin levels were evaluated by enzyme-linked immunosorbent assay (ELISA) and the hepatotoxicity was studied by measuring plasma liver enzyme levels (alanine aminotransferase (ALT), aspartate aminotransferase (AST) and γ-glutamyl-transferase (GGT). Production parameters of both DON groups were significantly impaired in comparison to the control. DON significantly increased the amount of DNA damage in lymphocytes by 28%. Moreover, the levels of TAS were lowered by addition of DON. T-2 toxin significantly impaired daily live weight gain and feed conversion, increased the amount of DNA damage in lymphocytes by 27%, decreased total serum IgG and did not alter plasma TAS. Plasma and 24-h urinary malondialdehyde (MDA) excretion rate and erythrocyte Gpx levels did not differ among the groups. Supplementation with vitamin E did not improve production parameters impaired by DON and T-2 toxin and only partially protected lymphocyte DNA from toxin impact. To our knowledge, these are the first data on genotoxic effects of moderate doses of DON and T-2 toxin on pig lymphocytes. The effect of DON and T-2 toxin on the immune system was reflected as a change in immunoglobulin synthesis, which might be toxin and species specific. According to other results no major induction of oxidative stress could be proven. Enhancement of antioxidant status with vitamin E in the case of DON and T-2 toxin intoxication can be beneficial for remaining the lymphocyte DNA integrity.     

Comparative yields of T-2 toxin and related trichothecenes from five toxicologically important strains of Fusarium sporotrichioides.

The range and comparative yields of T-2 toxin and related trichothecenes from five toxicologically important strains of Fusarium sporotrichioides, i.e., NRRL 3299, NRRL 3510, M-1-1, HPB 071178-13, and F-38, were determined. Lyophilized cultures of the five strains maintained in the International Toxic Fusarium Reference Collection were used to inoculate autoclaved corn kernels. Corn cultures were incubated at 15 degrees C for 21 days and analyzed for trichothecenes by thin-layer chromatography and capillary gas chromatography. All five strains produced T-2 toxin, HT-2 toxin, T-2 triol, and neosolaniol. Two strains also produced T-2 tetraol, and two others produced diacetoxyscirpenol. The highest producer of T-2 toxin (1,300 mg/kg), HT-2 toxin (200 mg/kg), T-2 triol (1.9 mg/kg), and neosolaniol (170 mg/kg) was NRRL 3510, which was originally isolated from millet associated with outbreaks of alimentary toxic aleukia in the USSR. The second highest producer of T-2 toxin (930 mg/kg) was NRRL 3299. The other three strains produced T-2 toxin at levels ranging from 130 to 660 mg/kg. Thus, the five strains differed considerably in the amounts of T-2 toxin and other trichothecenes produced under identical laboratory conditions. These strains are being maintained under optimal conditions for the preservation of Fusarium cultures and are available from the Fusarium Research Center, The Pennsylvania State University, University Park.     

Comparative yields of T-2 toxin and related trichothecenes from five toxicologically important strains of Fusarium sporotrichioides

The range and comparative yields of T-2 toxin and related trichothecenes from five toxicologically important strains of Fusarium sporotrichioides, i.e., NRRL 3299, NRRL 3510, M-1-1, HPB 071178-13, and F-38, were determined. Lyophilized cultures of the five strains maintained in the International Toxic Fusarium Reference Collection were used to inoculate autoclaved corn kernels. Corn cultures were incubated at 15 degrees C for 21 days and analyzed for trichothecenes by thin-layer chromatography and capillary gas chromatography. All five strains produced T-2 toxin, HT-2 toxin, T-2 triol, and neosolaniol. Two strains also produced T-2 tetraol, and two others produced diacetoxyscirpenol. The highest producer of T-2 toxin (1,300 mg/kg), HT-2 toxin (200 mg/kg), T-2 triol (1.9 mg/kg), and neosolaniol (170 mg/kg) was NRRL 3510, which was originally isolated from millet associated with outbreaks of alimentary toxic aleukia in the USSR. The second highest producer of T-2 toxin (930 mg/kg) was NRRL 3299. The other three strains produced T-2 toxin at levels ranging from 130 to 660 mg/kg. Thus, the five strains differed considerably in the amounts of T-2 toxin and other trichothecenes produced under identical laboratory conditions. These strains are being maintained under optimal conditions for the preservation of Fusarium cultures and are available from the Fusarium Research Center, The Pennsylvania State University, University Park.     

T-2 toxin metabolism by ruminal bacteria and its effect on their growth

The effect of T-2 toxin on the growth rates of different bacteria was used as a measure of its toxicity. Toxin levels of 10 micrograms/ml did not decrease the growth rate of Selenomonas ruminantium and Anaerovibrio lipolytica, whereas the growth rate of Butyrivibrio fibrisolvens was uninhibited at toxin levels as high as 1 mg/ml. There was, however, a noticeable increase in the growth rate of B. fibrisolvens CE46 and CE51 and S. ruminantium in the presence of low concentrations (10 micrograms/ml) of T-2 toxin, which may indicate the assimilation of the toxin as an energy source by these bacteria. Three tributyrin-hydrolyzing bacterial isolates did not grow at all in the presence of T-2 toxin (10 micrograms/ml). The growth rate of a fourth tributyrin-hydrolyzing bacterial isolate was unaffected. B. fibrisolvens CE51 degraded T-2 toxin to HT-2 toxin (22%), T-2 triol (3%), and neosolaniol (10%), whereas A. lipolytica and S. ruminantium degraded the toxin to HT-2 toxin (22 and 18%, respectively) and T-2 triol (7 and 10%, respectively) only. These results have been explained in terms of the presence of two different toxin-hydrolyzing enzyme systems. Studies with B. fibrisolvens showed the presence of a T-2 toxin-degrading enzyme fraction in a bacterial membrane preparation. This fraction had an approximate molecular weight of 65,000 and showed esterase activity (395.6 mumol of p-nitrophenol formed per min per mg of protein with p-nitrophenylacetate as the substrate.     

T-2 toxin metabolism by ruminal bacteria and its effect on their growth.

The effect of T-2 toxin on the growth rates of different bacteria was used as a measure of its toxicity. Toxin levels of 10 micrograms/ml did not decrease the growth rate of Selenomonas ruminantium and Anaerovibrio lipolytica, whereas the growth rate of Butyrivibrio fibrisolvens was uninhibited at toxin levels as high as 1 mg/ml. There was, however, a noticeable increase in the growth rate of B. fibrisolvens CE46 and CE51 and S. ruminantium in the presence of low concentrations (10 micrograms/ml) of T-2 toxin, which may indicate the assimilation of the toxin as an energy source by these bacteria. Three tributyrin-hydrolyzing bacterial isolates did not grow at all in the presence of T-2 toxin (10 micrograms/ml). The growth rate of a fourth tributyrin-hydrolyzing bacterial isolate was unaffected. B. fibrisolvens CE51 degraded T-2 toxin to HT-2 toxin (22%), T-2 triol (3%), and neosolaniol (10%), whereas A. lipolytica and S. ruminantium degraded the toxin to HT-2 toxin (22 and 18%, respectively) and T-2 triol (7 and 10%, respectively) only. These results have been explained in terms of the presence of two different toxin-hydrolyzing enzyme systems. Studies with B. fibrisolvens showed the presence of a T-2 toxin-degrading enzyme fraction in a bacterial membrane preparation. This fraction had an approximate molecular weight of 65,000 and showed esterase activity (395.6 mumol of p-nitrophenol formed per min per mg of protein with p-nitrophenylacetate as the substrate.     

Effect of mycotoxin T-2 on bioluminescence intensity of bacteria

The acute and chronic toxicity of T-2 was studied by bioluminescent method with the use of two strains of luminous bacteria--P. phosphorum Sq3 u V. fischeri F1 as biological objects. It was shown that in acute experiments after 10 min incubation of bacteria in the presence of T-2 the bioluminescence inhibition on the 50% level was observed at the toxin concentration equal to 12 mg/mL. In chronic experiments such a level of bioluminescence inhibition was registered after 16 hours incubation at the toxin concentration of 18 mg/mL. T-2 toxicity was also investigated in the presence of different serum albumin concentrations. It decreases with the increase of albumin concentration at the short term of incubation (5 min) of the mixture to be analyzed. In case of the longer term of incubation (up to 30 min) of this mixture T-2 toxicity was restored. Probably, it is a result of destruction of protein-toxin complex, which is, evidently, reversible and may be characterized by some index. It is necessary to emphasize that the sensitivity of T-2 analysis increases under the decrease of pH value up to lower bacterial physiological level, i.e. to 5-5.5. The revealed abilities of T-2 toxin effect on the intensity of bacterial bioluminescence may be used under the development of instrumental analytical approach on the basis of biosensor technology for testing this toxin in the environment. Taking into account the analysis simplicity and rapidity, such analytical device may have a perspective for wide practical application.     

Elevation of thiobarbituric acid values in the rat liver intoxicated by T-2 toxin

In the present study we first demonstrated that T-2 toxin markedly stimulated lipid peroxidation specifically in the liver of rats. The amount of lipid peroxides in the liver, estimated by the thiobarbituric acid (TBA) method, increased dose dependently, being proportional to the extent of its acute toxicity measured by various parameters in rats fed a commercial diet. Further, to elucidate the mechanism of lipid peroxidation and its role in hepatic injury caused by T-2 toxin, time-course studies on the correlation between lipid peroxide content and some biological and histopathological data were undertaken in rats given 4 mg of the toxin/kg perorally. The TBA reactive substances in the liver began to increase after 6 hr. However, much earlier than this there were some other alterations, which included decreases in the amount of cytochrome P-450 in the liver, of GPT (thereafter an increase) and phospholipids in the plasma, and of basophilic masses in the hepatocytes (arrayed as a rough endoplasmic reticulum in the electron micrograph). The vitamin E-deficient study showed that vitamin E markedly inhibited the stimulative effect of T-2 toxin on lipid peroxidation, but not diminish any other measured parameters of the injury. The toxin-induced stimulation of lipid peroxidation does not appear to be caused by activation of microsomal NADPH-cytochrome c reductase nor by a decrease in the level of cytosolic glutathione peroxidase. These results suggest that T-2 toxin might induce some alteration of the membrane structure and consequently might stimulate lipid peroxidation in situ.     

Subsequent effect of subacute T-2 toxicosis on spermatozoa, seminal plasma and testosterone production in rabbits

Pannon White (n=12) male rabbits (weight: 4050 to 4500 g, age: 9 months) received 2 ml of a suspension containing purified T-2 toxin by gavage for 3 days. The daily toxin intake was 4 mg/animal (0.78 to 0.99 mg/kg body weight (BW)). Control animals (n=12) received toxin-free suspension for 3 days. Since a feed-refusal effect was observed on the second day after T-2 administration, a group of bucks (n=10) were kept as controls (no toxin treatment) but on a restricted feeding schedule, that is, the same amount of feed was provided to them as was consumed by the exposed animals. On day 51 of the experiment (i.e. 48 days after the 3-day toxin treatment), semen was collected, and pH, concentration, motility and morphology of the spermatozoa, as well as concentration of citric acid, zinc and fructose in the seminal plasma, were measured. After gonadotropin-releasing hormone (GnRH) analogue treatment, the testosterone level was examined. One day of T-2 toxin treatment dramatically decreased voluntary feed intake (by 27% compared to control, P<0.05) and remained lower (P<0.05) during the first 2 weeks after the withdrawal of the toxin. BW of the contaminated rabbits decreased by 88% on days 17 and 29 compared to controls (P<0.05). No effect of toxin treatment was detected on pH and quantity of the semen or concentration of spermatozoa. The ratio of spermatozoa showing progressive forward motility decreased from 65% to 53% in the semen samples of toxin-treated animals compared to controls (P>0.05). The ratio of spermatozoa with abnormal morphology increased (P<0.05) in the ejaculates collected from the toxin-treated animals. T-2 toxin applied in high doses decreased the concentration of citric acid in seminal plasma (P<0.05). No effect of T-2 toxin on the concentrations of the other seminal plasma parameters (fructose and zinc) was observed. T-2 toxin decreased the basic testosterone level by 45% compared to control (P<0.01) and resulted in lower (P<0.05) GnRH-induced testosterone concentration. Feed restriction, that is, less nutrient intake, resulted in more morphologically abnormal spermatozoa in the semen, but it did not cause significant loss in BW, motility of the spermatozoa, composition of the seminal plasma or testosterone concentration--its effect needs further examination.     

The enzymes of the metabolism of exogenous compounds in the comparative assessment of the toxicity of trichothecene mycotoxins

Moderate clinical, biochemical and hematologic signs of intoxication were observed in mice after single administration of HT-2 toxin (deacetylated derivative of T-2 toxin) in LD50 of 12.75 mg/kg or in 1/5 of LD50 for 7 days. The toxin produced no toxic effect when 1/10 and 1/50 of LD50 were administered for 14 days. With the dose exceeding 1/50 of LD50 a reduction in cytochrome P-450 content, carboxylesterase activity and increased activity of UDP-glucuronosyltransferase and glutathione transferase were recorded. T-2 toxin produced a more pronounced toxic effect, inhibited UDP-glucuronosyltransferase and insignificantly stimulated glutathione transferase activity. Lower HT-2 toxin toxicity is believed to depend on its ability to activate conjugation reactions to a greater extent than T-2 toxin.     

Effect of 4-week feeding of deoxynivalenol- or T-2-toxin-contaminated diet on lipid peroxidation and glutathione redox system in the hepatopancreas of common carp (<Emphasis Type="Italic">Cyprinus carpio</Emphasis> L.)

The purpose of study was to investigate the effects of T-2 toxin (4.11 mg T-2 toxin and 0.45 mg HT-2 toxin kg^?1 feed) and deoxynivalenol (5.96 and 0.33 mg 15-acetyl deoxynivalenol (DON)?kg^?1 feed) in 1-year-old common carp juveniles in a 4-week feeding trial. The exposure of mycotoxins resulted in increased mortality in both groups consuming mycotoxin-contaminated diet. Parameters of lipid peroxidation were not affected during the trial, and antioxidant defence also did not show response to oxidative stress; however, glutatione peroxidase activity slightly, but significantly, decreased in the T-2 toxin group. Glutathione S-transferase activity showed moderate decrease as effect of T-2 toxin, which suggests its effect on xenobiotic transformation. Reduced glutathione concentration showed moderate changes as effect of DON exposure, but T-2 toxin has no effect. Expression of phospholipid hydroperoxide glutathione peroxidase (GPx4) genes showed different response to mycotoxin exposure. T-2 toxin caused dual response in the expression of gpx4a (early and late downregulation and mid-term upregulation), but continuous upregulation was found as effect of deoxynivalenol. Expression of the other gene, gpx4b, was upregulated by both trichothecenes during the whole period. The results suggested that trichothecenes have some effect on free radical formation and antioxidant defence, but the changes depend on the duration of exposure and the dose applied, and in case of glutathione peroxidase, there was no correlation between expression of genes and enzyme activity.     

T－2毒素对心肌细胞三型钙通道的阻滞作用

用膜片钳连细胞电压钳法, 在培养的Wistar大鼠单个心肌细胞上记录了T-2毒素对B、L和T三型Ca²⁺通道单通道电活动的影响. 结果表明, T-2毒素浓度为10mg/L时, 心肌细胞B、L和T三型Ca²⁺通道均受到明显的阻滞, 其阻滞作用表现为使Ca²⁺通道的开放概率减小, 开放时间缩短, 关闭时间延长, 而对流过Ca²⁺通道的Ba²⁺流幅值无影响.     

Study on the Apoptosis Mechanism Induced by T-2 Toxin

T-2 toxin is known to induce apoptosis in mammalian cells. The mechanism of apoptosis induced by T-2 toxin has been proposed to be linked with oxidative stress and mitochondrial pathway. In the current study, the toxic effect of T-2 on Hela, Bel-7402, and Chang liver cells was examined in dose-dependent and time-dependent manner by MTT assay. Caspase-3 was found to be up-regulated under T-2 toxin stress, which suggested that T-2 toxin induced cell apoptosis. Endogenous GSH and MDA levels in all three cell lines were found down- and up-regulated respectively, which indicated the link between toxic effect of T-2 toxin and intracellular oxidative stress. It was also found by MTT assay that NAC, which maintained the level of GSH in cells, could protect cells from death. Western-blot result showed that the level of both activated Caspase-8 and Caspase-9 increased when cells were treated by T-2 toxin. Caspase-9 was found to be activated earlier than Caspase-8. It was also found that p53 was up-regulated under T-2 toxin stress in the study. These results implied that the effect of T-2 toxin on cells was apoptosis rather than necrosis, and it was probably induced through mitochondrial pathway. To the best of our knowledge, the present study is the first to show that JunD is down-regulated in T-2 toxin induced apoptosis. By construction of an over-expression vector for the JunD gene, we observed that the survival ratio of JunD over-expressed cells obviously increased under T-2 toxin stress. These results suggested that the mechanism of T-2 induced cell death was closely connected with oxidative stress, and that JunD plays an important role in the defensive process against T-2 toxin stress.     

The Role of Mitochondria in T-2 Toxin-Induced Human Chondrocytes Apoptosis

T-2 toxin, a mycotoxin produced by Fusarium species, has been shown to cause diverse toxic effects in animals and is also a possible pathogenic factor of Kashin–Beck disease (KBD). The role of mitochondria in KBD is recognized in our recent research. The aim of this study was to evaluate the role of mitochondria in T-2 toxin-induced human chondrocytes apoptosis to understand the pathogenesis of KBD. T-2 toxin decreased chondrocytes viabilities in concentration- and time-dependent manners. Exposure to T-2 toxin can reduce activities of mitochondrial complexes III, IV and V, ΔΨm and the cellular ATP, while intracellular ROS increased following treatment with T-2 toxin. Furthermore, mitochondrial cytochrome c release, caspase-9 and 3 activation and chondrocytes apoptosis were also obviously observed. Interestingly, Selenium (Se) can partly block T-2 toxin -induced mitochondria dysfunction, oxidative damage and chondrocytes apoptosis. These results suggest that the effect of T-2 toxin on human chondrocytes apoptosis may be mediated by a mitochondrial pathway, which is highly consistent with the chondrocytes changes in KBD.     

Metabolism of T-2 toxin in Curtobacterium sp. strain 114-2.

The metabolic pathway of T-2 toxin in Curtobacterium sp. strain 114, one of the T-2 toxin-assimilating soil bacteria, was investigated by thin-layer and gas-liquid chromatographic analyses. T-2 toxin added to the basal medium as a single carbon and energy source was biotransformed into HT-2 toxin and an unknown metabolite. Infrared, mass spectrum, proton magnetic resonance, and other physico-chemical analyses identified this new metabolite as T-2 triol. T-2 toxin was first deacetylated by the bacterium into HT-2 toxin, and this metabolite was then biotransformed into T-2 triol without formation of neosolaniol and T-2 tetraol. No trichothecenes remained in the culture medium after prolonged culture. Some properties of T-2 toxin-hydrolyzing enzymes were observed with whole cells, the cell-free soluble fraction, and the culture filtrate. Besides T-2 toxin, trichothecenes such as diacetoxyscirpenol, neosolaniol, nivalenol, and fusarenon-X were also assimilated by this bacterium.