Systemic effects of topical application of T-2 toxin in mice

Dietary and Sentinel Factors Leading to Hemochromatosis

Although hereditary hemochromatosis is associated with the mutation of genes involved in iron transport and metabolism, secondary hemochromatosis is due to external factors, such as intended or unintended iron overload, hemolysis-linked iron exposure or other stress-impaired iron metabolism. The present review addresses diet-linked etiologies of hemochromatosis and their pathogenesis in the network of genes and nutrients. Although the mechanistic association to diet-linked etiologies can be complicated, the stress sentinels are pivotally involved in the pathological processes of secondary hemochromatosis in response to iron excess and other external stresses. Moreover, the mutations in these sentineling pathway-linked genes increase susceptibility to secondary hemochromatosis. Thus, the crosstalk between nutrients and genes would verify the complex procedures in the clinical outcomes of secondary hemochromatosis and chronic complications, such as malignancy. All of this evidence provides crucial insights into comprehensive clinical or nutritional interventions for hemochromatosis.

Role of mycotoxins in herds with and without problems with tail necrosis in neonatal pigs

This study aimed to investigate a possible involvement of mycotoxins in neonatal tail necrosis in piglets. Ten affected and 10 non-affected farms were selected. Sow feed samples were analysed for the presence of 23 mycotoxins by liquid chromatography-tandem mass spectrometry (LC-MS/MS). Blood plasma samples of sows and their piglets were analysed for the presence of deoxynivalenol (DON), de-epoxydeoxynivalenol, T-2 and HT-2 toxin, zearalenone, alfa-zearalenol, and beta-zearalenol, using LC-MS/MS. Additionally, high-resolution mass spectrometry (HRMS) was performed to detect DON-glucuronide (DON-Glca). There was a significant difference between case herds and control herds for mean DON concentrations in feed and sow plasma. For piglet samples, concentrations of DON were above the limit of quantification of 0.1 ng/ml in only 12 samples. Positive correlations were found between DON concentrations in sow feed and plasma of sows; DON concentration in sow feed and DON-Glca concentration in plasma of sows; and between DON and DON-Glca concentration in sow-plasma. In conclusion, high prevalence of DON in feed samples was found, with significantly higher concentrations in case herds, as well as the presence of DON and DON-Glca in sow plasma. Additional research is needed to identify risk factors, including within-herd factors, associated with neonatal tail necrosis in piglets.

Mycotoxins and other fungal metabolites in grain dust from Norwegian grain elevators and compound feed mills

Employees at grain elevators and compound feed mills are exposed to large amounts of grain dust during work, frequently leading to airway symptoms and asthma. Although the exposure to grain dust, microorganisms, β-1→3-glucans and endotoxins has been extensively studied, the focus on the mycotoxin content of grain dust has previously been limited to one or few mycotoxins. Our objective was therefore to screen settled grain dust from grain elevators and compound feed mills for fungal metabolites by LC/MS-MS and explore differences between work places, seasons and climatic zones. Seventy fungal metabolites and two bacterial metabolites were detected. Trichothecenes, depsipeptides, ergot alkaloids, and other metabolites from Fusarium, Claviceps, Alternaria, Penicillium, Aspergillus, and other fungi were represented. The prevalence of individual metabolites was highly variable, and the concentration of each metabolite varied considerably between samples. The prevalence and concentration of most metabolites were higher in grain elevators compared to compound feed mills. Differences between seasons and climatic zones were inconclusive. All samples contained multiple mycotoxins, indicating a highly complex pattern of possible inhalational exposure. A mean exposure of 20 ng/m3 of fungal metabolites was estimated, whereas a worst case scenario estimated as much as 10 ?g/m3. Although many of these compounds may be linked to toxicological and immunological effects through experimental or epidemiological studies, it still remains to be determined whether the detected concentrations implicate adverse health outcomes when inhaled.

Mechanisms of Mycotoxin-induced Dermal Toxicity and Tumorigenesis Through Oxidative Stress-related Pathways

Among the many mycotoxins, T-2 toxin, citrinin (CTN), patulin (PAT), aflatoxin B1 (AFB1) and ochratoxin A (OTA) are known to have the potential to induce dermal toxicity and/or tumorigenesis in rodent models. T-2 toxin, CTN, PAT and OTA induce apoptosis in mouse or rat skin. PAT, AFB1 and OTA have tumor initiating properties, and OTA is also a tumor promoter in mouse skin. This paper reviews the molecular mechanisms of dermal toxicity and tumorigenesis induced in rodent models by these mycotoxins especially from the viewpoint of oxidative stress-mediated pathways.

Tools for investigating workplace-related risks from mycotoxin exposure

There is growing recognition and interest in the role of mycotoxins as health hazards in the workplace. Examples will illustrate what we know about certain mycotoxins in some occupational settings and what we need to know to make further progress in assessing their impact on human health. A range of mycotoxins has been detected in different workplaces, e.g. in agricultural and food processing facilities, greenhouses, and the waste management sector. Their occurrence, mainly in dust from different raw materials or processed products, is indicative of a potential health hazard. However, assessing risks for workplace-related mycotoxin exposures remains a challenging task for several reasons, including uncertainties with regard to the transfer from contaminated material into air (inhalable mycotoxin concentrations) and/or the toxin fraction absorbed upon dermal contact or after respiratory intake. Human biomonitoring studies can considerably reduce these uncertainties, and serve to assess workplace-related exposures (in addition to dietary mycotoxin intake). These studies require not only sensitive methods for analysis of mycotoxins and/or their metabolites in blood or urine (biomarkers of exposure) in a cohort of workers, but also data on the levels/range of these biomarkers in non-occupationally exposed persons to account for exposures resulting from oral intake of mycotoxin-contaminated food (dietary 'background'). Biomonitoring methods were first developed for aflatoxin B1, then for ochratoxin A, and more recently for deoxynivalenol and for fumonisin B. But, there are no such methods for many other important mycotoxins. So far, only a small number of biomonitoring studies have addressed the question whether occupational mycotoxin exposures (by inhalation) add significantly to those from dietary exposure to mycotoxins, as observed in the general population. Therefore, a risk assessment is hampered by major uncertainties regarding the true impact of occupational mycotoxin exposures. Human biomonitoring (with biomarkers of exposure and/or effect) is considered a valuable instrument, and should be developed further for mycotoxins of relevance in the workplace.

Species-specific fungal DNA in airborne dust as surrogate for occupational mycotoxin exposure?

Possible health risks associated with occupational inhalation of mycotoxin-containing dust remain largely unknown, partly because methods for mycotoxin detection are not sensitive enough for the small dust masses obtained by personal sampling, which is needed for inhalable exposure measurements. Specific and sensitive PCR detection of fungi with mycotoxin-producing potential seem to be a good surrogate for occupational exposure measurements that include all fungal structures independent of morphology and cultivability. Results should, however, be interpreted with caution due to variable correlations with mycotoxin concentrations.

Toxigenic Fusarium spp. as determinants of trichothecene mycotoxins in settled grain dust

Trichothecenes are immunosuppressive mycotoxins produced mainly by Fusarium spp. and often are detected as natural contaminants of grain and other agricultural products. Exposure to trichothecenes through inhalation during grain work may represent possible health risks for grain farmers. We aimed, therefore, to investigate the level of Fusarium spp. and trichothecenes in settled grain dust collected during work on 92 Norwegian farms. Mycotoxins were determined by gas chromatography-mass spectrometry, whereas the Fusarium spp. were identified and quantified both by species-specific semiquantitative polymerase chain reaction (PCR) and by cultivation. All potential trichothecene-producing molds in the grain dust were quantified using a PCR assay specific for tri5, the gene coding for trichodiene synthase that catalyzes the first step in the trichothecene biosynthesis. We performed correlation analysis between mold-DNA and mycotoxins to assess whether the PCR-detected DNA could be used as indicators of the mycotoxins. The methodological problem of detecting small amounts of airborne mycotoxins during grain work may then be avoided. Whereas the trichothecene-producing Fusarium species in grain dust could not be identified or quantified to a sufficient extent by cultivation, all investigated Fusarium spp. could be specifically detected by PCR and quantified from the DNA agarose gel band intensities. Furthermore, we observed a strong correlation between the trichothecenes HT-2 toxin (HT-2) or T-2 toxin (T-2) and DNA specific for tri5 (r = 0.68 for HT-2 and r = 0.50 for T-2; p < 0.001), F. langsethiae (r = 0.77 for HT-2 and r = 0.59 for T-2; p < 0.001), or F. poae (r = 0.41 for HT-2 and r = 0.35 for T-2; p < 0.001). However, only a moderate correlation was observed between the trichothecene deoxynivalenol (DON) and the combination of its producers, F. culmorum and F. graminearum (r = 0.24, p = 0.02), and no significant correlation was observed between DON and tri5. PCR clearly improved the detection of toxigenic Fusaria as potential sources of health risks for farmers inhaling grain dust during work, but the use of Fusarium-DNA as indicators for trichothecenes should be used cautiously.

T-2 toxin-induced apoptosis in rat keratinocyte primary cultures

T-2 toxin, a kind of trichothecene mycotoxins produced by the genus Fusarium, induces apoptosis in basal keratinocytes when topically applied to the dorsal skin of rats. In the present study, direct effects of T-2 toxin on keratinocyte primary cultures obtained from newborn rats were examined after the third passage. Keratinocyte medium containing 0.25 microg/ml of T-2 toxin dissolved in dimethyl sulfoxide or solvent alone was added to 4-day cultures and incubated at 37 degrees C. At 0.5, 1, 3, 5, 7, and 9 h after treatment (h), feeder layer was separated from flasks, and cells were trypsinized. Cell viability was estimated by trypan blue exclusion method. In addition, RNA was obtained and RT-PCR was performed. Samples obtained from slide cultures at 3, 6, 9, and 12 h were fixed in 4% paraformaldehyde or 2.5% glutaraldehyde for morphological examination. After T-2 toxin application, cell viability decreased to 40% at 3 h. At 6 h, small-sized keratinocytes showed pyknosis or karyorrhexis, resulting in detachment from slides. The number of such cells increased until 12 h. These small-sized keratinocytes showed ultrastructural changes characteristic for apoptosis. At the same time, large squamous keratinocytes showed intracytoplasmic edema. The expression of apoptosis-related genes (c-fos and c-jun) and cytokines (TNF-alpha and IL-1beta) mRNAs markedly increased before the development of apoptosis. These findings indicate that c-fos and c-jun oncogenes and TNF-alpha and IL-1beta play an important role in the development of T-2 toxin-induced apoptosis in keratinocytes.

Apoptosis in mouse fetuses from dams exposed to T-2 toxin at different days of gestation

T-2 toxin (2 mg/kg b.w.) was orally inoculated to pregnant mice at gestational day (GD) 8.5, 9.5, 10.5, 11.5, 12.5, 13.5, 14.5, 15.5 and GD 16.5, respectively, and the fetuses were examined 24 hours later. The number and region of pyknotic or karyorrhectic cells varied according to inoculation date. In the GD 13.5-subgroup, a moderate to high number of pyknotic or karyorrhectic neuronal cells were observed in the central nervous system, peri-ventricular zone to subventricular zone, and pyknosis or karyorrhexis were also observed in a small number of chondroblasts and chondrocytes. In the GD 16.5-subgroup, a moderate to high number of pyknotic or karyorrhectic cells were observed in the thymus and renal subcapsular parenchyma. The nuclei of these pyknotic or karyorrhectic cells were strongly stained by the terminal deoxy nucleotidyl transferase (TdT)-mediated dUTP-digoxigenin nick end labeling method widely used for the in situ detection of apoptotic nuclei. In addition, a few fetuses from dams which were given T-2 toxin at GD 13.5 or GD 14.5 and killed at GD 17.5 showed skeletal abnormalities such as wavy ribs and short scapula. From the present findings and the well known fact that T-2 toxin readily crosses the rat placenta, it seems that T-2 toxin-induced apoptosis in the developing mouse fetuses might be a direct effect of T-2 toxin on fetuses.

T-2 toxin-induced apoptosis in intestinal crypt epithelial cells of mice

The characteristics of T-2 toxin-induced cell damage in the intestinal crypt epithelia was investigated in mice. Following T-2 toxin-inoculation (0, 2.5, 5 and 10 mg/kg b.w.), dead cells showing pyknosis were sporadically observed in the crypt epithelia, and the nuclei of these cells were strongly stained by the modified TUNEL method which detects fragmented DNA in situ. Electron microscopically, the dead cells were characterized by shrinkage of the cell body and condensation of nuclear chromatin frequently along the nuclear membrane, and such nuclei were sometimes fragmented into small pieces. These morphological characteristics are well consistent with those of apoptosis. The mitotic index in the crypt epithelia drastically decreased at 6 hours after T-2 toxin-inoculation (6 HAI), but thereafter it recovered to almost the same value with that in control mice at 48 HAI. On the other hand, the apoptotic index in the crypt epithelia increased with the lapse of time. Clear mouse strain- and sex-differences were detected in the apoptotic index but not in the mitotic index. This is the first report that T-2 toxin caused apoptotic cell death in the intestinal crypt epithelial cells.

T-2 toxin-induced apoptosis in lymphoid organs of mice

Lymphoid organs of male and female mice of 4 strains (ICR: CD-1, BALB/c, C57BL/6 and DBA/2) were histologically and biochemically examined at 24 hours after oral inoculation of T-2 toxin (0, 2.5, 5 and 10 mg/kg b.w.). Light microscopically, dose-dependent decrease in number of lymphocytes was observed in the thymic cortex and splenic follicles. The nuclei of lymphocytes showed pyknosis or karyorrhexis, and they were positively stained by the modified TUNEL method which detects fragmented DNA in situ. Electron microscopic characteristics of damaged lymphocytes were shrinkage of the cell body, nuclear chromatin condensation and fragmentation. Agarose gel electrophoresis of DNA extracted from the thymus showed DNA fragmentation into nucleosome units, i.e. ladder formation. The above-mentioned findings clearly showed that T-2 toxin could induce apoptotic cell death in the lymphoid organs of mice. These changes were more prominent in female BALB/c and C57BL/6 mice.

Process of the development of T-2 toxin-induced apoptosis in the lymphoid organs of mice

Female ICR:CD-1 mice orally treated with 10 mg/kg b.w. of T-2 toxin were killed at 1, 3, 6, 9, 12, 24 and 48 hr after treatment (HAT) and subjected to examination of the process of the development of T-2 toxin-induced apoptosis in the thymus and spleen. The early ultrastructural changes in lymphocytes characterized by shrinkage of the cell body and condensation of nuclear chromatin were detected at 3HAT in the thymus. The number of apoptotic lymphocytes observed by the in situ detection method for fragmented DNA increased drastically from 9 to 24 HAT in the thymus while it began to increase at 12 HAT in the spleen. The DNA ladder was first detected by agarose gel electrophoresis at 9 HAT and became clearer at 12 and 24 HAT in the thymus but was not clearly detected in the spleen throughout the observation period. Thus T-2 toxin-induced apoptosis developed earlier and was apparently severer in the thymus than in the spleen. Apoptotic was first detected by electron microscopy, then by the in situ detection method for fragmented DNA, and finally by DNA agarose gel electrophoresis.

Differentiation of lesions caused by mycotoxin T-2 from autolytic morphologic change in CD-1 mice

Experiments with topically applied T-2 trichothecene mycotoxin were undertaken to determine whether lesions caused by this toxin could be differentiated from autolysis. Two pathologists, who had previously seen lesions caused by T-2 toxin, graded lesions without knowledge of treatment group and stated whether the animal had received the toxin or not. Both pathologists differentiated T-2 toxin-treated mice up to 6 h post-mortem. Failure to distinguish between treated and control mice resulted in false-negative diagnoses only. It was concluded that the diagnosis of trichothecene mycotoxicosis would probably be missed more than 6 h post-mortem.

Penetration of [3H]T-2 mycotoxin through abraded and intact skin and methods to decontaminate [3H]T-2 mycotoxin from abrasions

Penetration of 50 muCi of [3H]T-2 mycotoxin through abraded and intact skin was studied in anesthetized rats sacrificed at 5, 15, 30, 45, 60 and 90 min post-exposure. The greatest penetration was through abraded skin (49 +/- 7%) at 90 min post-exposure, whereas penetration through intact skin (2 +/- 3%) was substantially less (P less than 0.0015). Methods to decontaminate [3H]T-2 mycotoxin from abraded skin over time were studied. Treatment of [3H]T-2 contaminated abrasions by applying Trau + Medic dressing, applying Charcoal Cloth-Anti-bacterial Field Dressing (Charcoal Dressing), or swabbing with povidone-iodine 30 min post-exposure removed 17-32% of the applied [3H]T-2. Immediate blotting with immediate removal of the dressings absorbed 103 +/- 4% (Trau + Medic) and 87 +/- 4% (Charcoal Dressing) of the applied [3H]T-2, while immediate blotting and leaving the dressing in place for 30 min removed 91 +/- 5% (Trau + Medic) and 76 +/- 3% (Charcoal Dressing). It appears that immediate blotting with either dressing followed by immediate removal before application of a clean dressing is an effective method for decontaminating [3H]T-2 from abrasions.

Assessment of efficacy of activated charcoal for treatment of acute T-2 toxin poisoning

"Superactive" charcoal was assessed for efficacy in decreasing the lethality of both oral and parenteral exposure to T-2 toxin, a fungal metabolite which can cause death or illness upon ingestion. In vitro binding studies, analyzed using the Langmuir adsorption isotherm, showed that activated charcoal had a maximal binding capacity of 0.48 mg toxin/mg charcoal and a dissociation constant of 0.078 mg charcoal/l. In vivo, orally administered, activated charcoal was assessed for treatment of acute oral or parenteral exposure to T-2 toxin in mice. Following oral toxin administration (5 mg/kg), untreated mice showed only 6% survival after 72 hr. Charcoal treatment (7 g/kg,po) either immediately or 1 hr after toxin exposure resulted in significant improvement in survival with values of 100% and 75%, respectively. Following parenteral toxin exposure (2.8 mg/kg, sc), untreated and charcoal-treated (7 g/kg, po) mice showed 50% and 90% survival, respectively, after 72 hr. LD50 value for T-2 toxin, determined at 96 hr after intoxication, increased significantly from 2 mg/kg for untreated controls to 4.5 mg/kg for activated charcoal treatment.

Effects of T-2 mycotoxin on gastrointestinal tissues: a review of in vivo and in vitro models

T-2 mycotoxin, a trichothecene, is the principal toxic component of Fusarium sp. Agricultural products and food are frequently contaminated with this toxin. Various animal models have been used to determine its metabolic fate, rate of excretion, and distribution. A modulation effect on cell-mediated immunity and alterations in gastrointestinal propulsion have been demonstrated. The toxin has been shown to produce some similar pathologic alterations in various animal species studied. The consistent alteration appears to mainly affect mitotic cells of the gastrointestinal tract and the lymphoid system. A host of bioassay systems are now being used as alternative methods to the use of animals for testing of the mycotoxin. These tests may accurately assess and define the role of the subject-toxin interactions following consumption of T-2 mycotoxin contaminated food sources. T-2 mycotoxin, as observed above with in vivo and in vitro models, promotes a chemically-induced change in structure and function of affected gastrointestinal cells from a transient and reversible aberration in a single enzymatic reaction to cell death. Regardless of the end point measured, the toxic response brought about in cells appears to involve the interactions of virtually all subcellular processes--membrane transport and permeability, chemical metabolism, DNA function, and energy production/expenditure--as cells attempt to maintain their functional integrity while disposing of the toxicant. The variation in the quality of the toxic response with dose suggests that more cellular processes are perturbed as the chemical dose is increased.

Reduction of anguidine toxicity in rats by atropine and methylatropine

Lethality of anguidine (diacetoxyscirpenol) in rats and mice appears to be the result of primary or secondary cardiovascular collapse and to be related to severe tissue destruction in the gut and elsewhere. Experiments were performed in rats to examine the effect on anguidine lethality of treatment with several agents that alter gut function or toxic effects of other chemicals in the gut. Administration of atropine sulfate or methylatropine nitrate by sc injection to rats immediately following administration of an LD50 of anguidine and again 4 hr later gave modest but significant protection against anguidine lethality. The drugs were effective over a range of doses between 2.5 and 20 mg/kg, without a clear dose response, and probably were effective at doses lower than 2.5 mg/kg. S-Adenosylmethionine, 25 mg/kg, given to rats at the time of administration of an LD50 of anguidine and again 4 hr later gave some evidence of protection also. Semiquantitative evaluation of pathologic changes in the small intestine, a target of anguidine, indicated partial protection by atropine sulfate against anguidine toxicity at that site. Atropine-treated rats showed less severe damage, earlier resolution of damage, or both.

Toxicology of novel macrocyclic trichothecenes, baccharinoid B4, myrotoxin B, and roritoxin B

Baccharinoid B4, Myrotoxin B and Roritoxin B, some recently identified macrocyclic trichothecenes, were tested in Swiss mice with respect to their toxicity after oral and topical application. For oral dosing, the mycotoxins were dissolved in propylene glycol, and doses from 0 to 8.0 mg/kg body weight (BW) were employed. For topical application, toxins were dissolved in DMSO. A dose of 40 mg/kg BW was applied, except for Roritoxin B, where a dose of 10 mg/kg BW was also utilized. Animals were observed until death, or until 14 days after application and histopathological examinations were performed. It was found that Baccharinoid B4 was only moderately toxic, but this macrocyclic trichothecene appeared to exert its toxicity particularly on the intestine. Myrotoxin B was found to be quite toxic, and Roritoxin B was determined to be the most potent and toxic macrocyclic trichothecene of the three investigated. Oral administration of Roritoxin B resulted in death of 70-90% of mice at doses up to 1.0 mg/kg BW, and topical application of 10 or 40 mg/kg BW caused 100% death within 18 hours after application.

Comparison of penetration and metabolism of [3H]diacetoxyscirpenol, [3H]verrucarin A and [3H]T-2 toxin in skin

The purpose of this research was to determine the rate of cutaneous penetration and metabolism of [3H]diacetoxyscirpenol (DAS) and [3H]verrucarin A (VCA) and compare these values to previously determined values for [3H]T-2 toxin (T-2), to compare the cutaneous penetration and metabolism of DAS in human and guinea-pig skin, and to compare the effects of dose and of two vehicles, methanol and dimethylsulphoxide (DMSO), on penetration rates. DAS or VCA was applied to the epidermal surface of excised skin, and the receptor fluid bathing the dermal surface was sampled periodically for 48 hr. Whether the applied dose (581 ng/cm2) was dissolved in methanol or DMSO, the rate of penetration through human skin was lower for VCA than for DAS or T-2, the rates for the two latter compounds being similar at this dose. Metabolism of DAS occurred during penetration through excised human skin and did not occur in the receptor fluid as a result of enzymes leaching out of the skin. VCA appeared to be metabolized by human skin, but this conclusion is tentative because of the relative instability of this compound. DAS penetrated significantly (P less than 0.05) faster through excised guinea-pig skin than through human skin. Metabolism of DAS was greater in human skin than in guinea-pig skin. When compared with methanol, DMSO increased the penetration of DAS and VCA by factors of between 7 and 52. At the low dose (79 ng/cm2) DAS penetrated human and guinea-pig skin significantly (P less than 0.05) faster than T-2 using either vehicle.

Changes in circulatory white blood cells of mice and rats due to acute trichothecene intoxication

In mice, administration of pure T-2 toxin caused a rapid decrease of lymphocyte counts, which was linear with respect to dose, whereas granulocyte counts showed a delayed decrease. The blood cell counts of both cell types attained normal values after 4-7 days. Similar results were obtained for crude A-, B- and macrocyclic type trichothecene. Intoxication of rats with T-2 toxin or crude A-type trichothecene caused changes in white blood cells, which differed quantitatively from those in the mouse: lymphocyte counts decreased less and a rapid transient increase of granulocytes was more obvious. Results of this study show that lymphocyte and granulocyte blood cell counts of small rodents respond sensitively to acute intoxication with various trichothecenes.

In vitro percutaneous penetration and metabolism of [3H]T-2 toxin: comparison of human, rabbit, guinea pig and rat

The purpose of this research was to determine which species of laboratory animal provided the best approximation of in vitro percutaneous penetration and metabolism of T-2 in humans. The [3H]T-2 which penetrated discs of skin after 48 hr (expressed as per cent of dose, 581 ng/cm2) was 1.0, 1.4, 2.8 and 9.7% for the human, rabbit, guinea pig and rat when the vehicle was methanol. The penetration was 29.2, 19.6, 51.9 and 52.6% for the human, rabbit, guinea pig and rat when the vehicle was DMSO. When 2 concentrations were compared, 79 ng/cm2 and 581 ng/cm2 (the vehicle was methanol), the higher dose caused a significant (P less than 0.05) increase in the per cent of dose which penetrated human and guinea pig skin. Metabolism was extensive in the human, rabbit, and rat, with the main metabolite being HT-2 toxin. Previous studies comparing human to monkey indicated penetration in these 2 species was different when methanol was the vehicle. This study indicates that the rabbit provides the best approximation of human skin, both in terms of penetration kinetics and metabolic activity.

Acute toxicity of T2 toxin in rats, mice, guinea pigs, and pigeons

The acute intravenous, intragastric, subcutaneous, intraperitoneal and intratracheal toxicity of T2 toxin has been studied in rats, mice, guinea-pigs, and pigeons. The acute LD50 values obtained varied between 1.0 and 14 mg X kg-1, there being little difference between the various routes in any given species. T2 caused vomiting in pigeons at doses of one fifth or less the LD50. In rats doses of 3.0 and 5.0 mg X kg-1 T2 produced lymphopenia, reticulocytosis, and in the highest dose groups normoblastaemia. Additionally, changes in plasma alkaline phosphatase and aspartate aminotransferase activities were seen. Histological changes were observed in lymphoid organs and were most severe in the thymus, lymph nodes, and Peyer's patches. The spleen was less severely affected. Gastrointestinal changes consisting of dead and dying lymphoid cells throughout the lamina propria were seen together with, in some cases, mucosal ulceration. The time course of the development and of the reversal of the changes was followed.

Cutaneous injury by topical T-2 toxin: involvement of microvessels and mast cells

Topical applications of various doses of T-2 toxin to rats led to delayed skin reactions. Following a dose-dependent latent period of 12-24 hr, there appeared vascular dilation, stasis, edema and mononuclear cell infiltration, with many degranulating mast cells. These signs were earliest and strongest in the subcutis. Epidermal necrosis occurred 1-2 days later and was probably caused secondarily by ischemia, due to microcirculatory failure. Ultrastructurally, endothelial cells of small vessels were the earliest sites of change. While intercellular junctions remained closed and pinocytosis decreased, the cytoplasm contained many ribosomes, vacuoles, and abnormal mitochondria. Another early effect of topical T-2 toxin was an increase in number and degranulation of mast cells, especially in the subcutis. The resemblance of the skin injury to that produced by irradiation is noted.

Toxigenic Potential of Some Fusarium Isolates from Southeast Asia

The isolation and characterization of 10 isolates of six Fusarium spp. from plant and soil samples collected in Southeast Asia is reported. The ability of these isolates to produce trichothecenes both in liquid cultures (CZ, GYEP, and MYRO) and on rice was assessed, and their toxigenic potential was examined by skin assay and gavage studies with culture filtrates. Although culture filtrates of all the isolates caused minor damage to test animals, only that of F. equiseti DAOM 189762 produced trichothecenes.