Trichothecene


Trichothecenes are a very large family of chemically related mycotoxins produced by various species of Fusarium, Myrothecium, Trichoderma, Trichothecium, Cephalosporium, Verticimonosporium, and Stachybotrys. Trichothecenes are a class of sesquiterpenes.
The most important structural features causing the biological activities of trichothecenes are the 12,13-epoxy ring, the presence of hydroxyl or acetyl groups at appropriate positions on the trichothecene nucleus, and the structure and position of the side-chain. They are produced on many different grains like wheat, oats or maize by various Fusarium species such as F. graminearum, F. sporotrichioides, F. poae and F. equiseti.
Some molds that produce trichothecene mycotoxins, such as Stachybotrys chartarum, can grow in damp indoor environments. It has been found that macrocyclic trichothecenes produced by S. chartarum can become airborne and thus contribute to health problems among building occupants.
A poisonous mushroom in Japan and China, Podostroma cornu-damae, contains six trichothecenes, including satratoxin H, roridin E, and verrucarin.

Classification

General classification

Trichothecenes are a group of over 150 chemically related mycotoxins. Each trichothecene displays a core structure consisting of a single six-membered ring containing a single oxygen atom, flanked by two carbon rings. This core ring structure contains an epoxide, or tricyclic ether, at the 12,13 carbon positions, as well as a double bond at the 9, 10 carbon positions. These two functional groups are primarily responsible for trichothecene ability to inhibit protein synthesis and incur general cytotoxic effects. Notably, this core structure is amphipathic, containing both polar and non polar parts. All trichothecenes are related through this common structure, but each trichothecene also has a unique substitution pattern of oxygen containing functional groups at possible sites on carbons 3,4,7,8, and 15. These functional groups govern the properties of an individual tricothecene and also serve as the basis for the most commonly used classification system for this family of toxins. This classification system breaks up the trichothecene family into four groups: Type A, B, C, and D.
Type A tricothecenes have hydroxyl, ester, or no functional group substitutions around the core ring structure. Common examples of these are Neosolaniol with a hydroxyl substitution at carbon 8, and T-2 toxin with an ester substitution at carbon 8.
Type B tricothecenes are classified by the presence of carbonyl functional groups substituted around the core ring structure. Common examples of these include nivalenol and trichotecin, which both have a ketone functional group at carbon 8.
Type C trichothecenes have an extra carbon 7, carbon 8 epoxide group. The common example of these is crotocin. which also has an ester functional group at carbon 4.
Type D trichothecenes have an additional ring between carbon 4 and carbon 15. These rings can have diverse additional functional groups. Common examples of these are roridin A and satratoxin H.
Although the distinct functional groups of these classification types give each trichothecene unique chemical properties, their classification type does not explicitly indicate their relative toxicity. While Type D trichothecenes are thought to be the most toxic, Types A and B have relatively mixed toxicity.

Alternative classifications

The classification system described above is the most commonly used to group molecules of the trichothecene family. However, a variety of alternative classification systems also exist for these complex molecules. Trichothecenes can also be generally described as simple or macrocyclic. Simple trichothecenes include Types A, B, and C, whereas macrocyclic tricothecenes include Type D and are characterized by the presence of a carbon 4 - carbon 15 bridge. Additionally, J. F. Grove proposed a classification of tricothecenes into three groups that was also based upon the functional substitution patterns of the ring skeleton. Group 1 tricothecenes only have functional groups substituted on the third, fully saturated carbon ring. Group 2 tricothecenes contain additional functional groups on the core ring containing the 9, 10 carbon double bond. Finally, Group 3 trichothecenes contain a ketone functional group at carbon 8; this is the same criteria for Type B trichothecenes.
Advances in the field of evolutionary genetics have also led to the proposal of trichothecene classification systems based on the pathway of their biosynthesis. Genes responsible for the biosynthesis of a mycotoxin are typically located in clusters; in Fusariumi these are known as TRI genes. TRI genes are each responsible for producing an enzyme that carries out a specific step in the biosynthesis of trichothecenes. Mutations in these genes can lead to the production of variant trichothecenes and therefore these moleules could be grouped on the basis of shared biosynthesis steps. For example, a shared step in the biosynthesis of trichothecenes is controlled by the gene TRI4. This enzyme product controls the addition of either three or four oxygens to trichodiene to form either isotrichodiol or isotrichotriol respectively. A variety of trichothecenes can then be synthesized from either of these intermediates and they could therefore be classified as either t-type if synthesized from isotrichotriol or d-type if synthesized from isotrichodiol.

Mechanism of action

The toxicity of tricothecenes is primarily the result of their widely cited action as protein synthesis inhibitors. This inhibition occurs at ribosomes during all three stages of protein synthesis: initiation, elongation, and termination. During intitiation, trichothecenes can either inhibit the association of the two ribosomal subunits, or inhibit the function of the mature ribosome by preventing the association of the first tRNA with the start codon. Inhibition at elongation most likely occurs due to trichothecenes preventing the function peptidyl transferase, the enzyme which catalyzes the formation of new peptide bonds on the 60s ribosomal subunit. Inhibition during termination can also be the result of peptidyl transferase inhibition or the ability of trichothecenes to prevent the hydrolysis required at this final step. It is interesting to note that the substitution pattern of the ring core of trichothecenes influences the toxin's action as either an inhibitor of initiation or as an inhibitor of elongation/termination. Trichothecenes also have the ability to affect general cellular enzyme function due to the tendency of active site thiol groups to attack the 12,13 carbon epoxide ring. These inhibitory effects are seen most dramatically in actively proliferating cells such as in the gastrointestinal tract or the bone marrow.
Protein synthesis occurs in both the cytoplasm of the cell as well as in the luminal space of mitochondria, the cytoplasmic organelle responsible for producing the cell's energy. This is done through an enzymatic pathway that generates highly oxidized molecules called reactive oxygen species, for example hydrogen peroxide. Reactive oxygen species can react with and cause damage to many critical parts of the cell including membranes, proteins, and DNA. Trichothecene inhibition of protein synthesis in the mitochondria allows reactive oxygen species to build up in the cell which inevitably leads to oxidative stress and induction of the programmed cell death pathway, apoptosis.
The induction of apoptosis in cells with high levels of reactive oxygen species is due to a variety of cell signaling pathways. The first is the p53 pathway which is shown to be upregulated by the T-2 toxin. p53 is a protein responsible for controlling the cell cycle, but an increase in the activity of this protein also leads to increased activation of BAX proteins in the cell. These BAX proteins are primarily responsible for increasing the permeability of the mitochondrial membrane and leading to the release of cytochrome c and reactive oxygen species. Release of cytochrome c from the mitochondria induces apoptosis by initiating the assembly of caspases, or proteins responsible for degrading the cell from within. Additionally, trichothecenes such as T-2, have also been shown to increase the c-Jun N-Terminal Kinase signaling pathway in cells. Here, c-Jun N-Terminal Kinase is able to increase to phosphorylation of its target, c-Jun, into its active form. Activated c-jun acts as a transcription factor in the cell nucleus for proteins important for facilitating the downstream apoptotic pathway.

Symptomology

The trichothecene mycotoxins are toxic to humans, other mammals, birds, fish, a variety of invertebrates, plants, and eukaryotic cells. The specific toxicity varies depending on the particular toxin and animal species, however the route of administration plays a significantly higher role in determining lethality. The effects of poisoning will depend on the concentration of exposure, length of time and way the person is exposed. A highly concentrated solution or large amount of the gas is more likely to cause severe effects, including death. Upon consumption, the toxin inhibits ribosomal protein, DNA and RNA synthesis, mitochondrial functions cell division while simultaneously activating a cellular stress response named ribotoxic stress response
The trichothecene mycotoxins can be absorbed though topical, oral and inhalational routes and are highly toxic at the sub-cellular, cellular, and organic system level. Trichothecenes differ from most other potential weapon toxins since they can act through the skin, which is attributed to their amphipathic and lipophilic characteristics. The small amphipathic nature of trichothecenes allows them to easily cross cell membranes and interact with different organelles such as the mitochondria, endoplasmic reticulum. and chloroplast The lipophilic nature of trichothecenes allow them to be easily absorbed through skin pulmonary mucosa, and gut. Direct dermal application or oral ingestion of trichothecene causes rapid irritation to the skin or intestinal mucosa. As a dermal irritant and blistering agent, it is alleged to be 400 times more intoxicating than sulfur mustard.
The response in the body to the mycotoxin, alimentary toxic aleukia, occurs several days after consumption, in four stages. The first stage includes inflammation of the gastric and intestinal mucosa. The second stage is characterized by leukopenia, granulopenia, and progressive lymphocytosis. The third stage is characterized by the appearance of a red rash on the skin of the body, as well as hemorrhage of the skin and mucosa. If severe, aphonia and death by strangulation can occur. By the fourth stage, cells in the lymphoid organs and erythropoiesis in the bone marrow and spleen are depleted and immune response is down. Infection can be triggered by an injury as minor as a cut, scratch or abrasion.
The following symptoms are exhibited:
When it comes to animal and human food, type A trichothecenes are of special interest because they are more toxic than the other foodborne trichothecenes i.e. type B group. However, deoxynivalenol is of concern as it is the most prevalent trichothecene in Europe. The major effects of trichothecenes – related to their concentration in the commodity – are reduced feed uptake, vomiting and immuno-suppression.
A relatively few countries, primarily in the European Union, have recommended maximum limits for these mycotoxins in food and animal feed. However, trichothecenes are often tested for elsewhere, in order to prevent them from entering the food chain and to prevent losses in animal production.

History

Trichothecenes are believed to have been discovered in 1932 in Orenburg, Russia, during World War II, by the Soviet Union. Around 100,000 people began to suffer and die from alimentary toxic aleukia, a lethal disease with symptoms resembling radiation. It is believed that the Soviet civilians had become ill from ingesting contaminated bread, and inhaling mold through contaminated hay, dusts and ventilation systems. The culprit is believed to be the toxins Fusarium sporotrichioides and Fusarium poae which are high producers of T-2 toxin. Fusarium species are probably the most commonly cited and among the most abundant of the trichothecene-producing fungi.
Trichothecenes make an ideal biologic warfare agent, being lethal and inexpensive to produce in large quantities, stable as an aerosol for dispersion, and without effective vaccination/treatment. Evidence suggests that mycotoxins have already been utilized as biological warfare.
Since then trichothecenes have been reported throughout the world. They’ve had a significant economic impact on the world due to causes such as: loss of human and animal life, increased health care and veterinary care costs, reduced livestock production, disposal of contaminated foods and feeds, and investment in research and applications to reduce severity of the mycotoxin problem. These mycotoxins account for millions of dollars annually in losses, due to factors that are often beyond human control.

Food contamination

Hazardous concentrations of trichothecenes have been detected in corn, wheat, barley, oats, rice, rye, vegetables, and other crops. Diseases resulting from infection include seed rot, seedling blight, root rot, stalk rot, and ear rot. Trichothecenes are also common contaminants of poultry feeds and their adverse effects on poultry health and productivity have been studied extensively.
Several studies have shown that optimal conditions for fungal growth are not necessarily optimum for toxin production. Toxin production is greatest with high humidity and temperatures of 6-24°C. The fungal propagation and production is enhanced in tropical conditions with high temperatures and moisture levels; monsoons, flash floods and unseasoned rains during harvest. Trichothecenes have been detected in air samples suggesting that they can be aerosolized on spores or small particles
Natural occurrence of TCT has been reported in Asia, Africa, South America, Europe, and North America
There are no known direct antidotes to trichothecene exposure. Therefore, risk management in contaminated areas is primarily defined by the treatment of exposure symptoms as well as prevention of future exposure.

Treatment

Typical routes of exposure to trichothecene toxins include topical absorption, ingestion, and inhalation. Severity of symptoms depends on the dose and type of exposure, but treatment is primarily focused on supporting bodily systems damaged by the mycotoxin. The first step in most exposure cases is to remove potentially contaminated clothing and to flush the sites of exposure thoroughly with water. This prevents the victim from repeated exposure. Fluids and electrolytes can be given to victims with high levels of gastrointestinal damage to mitigate the effects of reduced tract absorption. Fresh air and assisted respiration can also be administered upon the development of mild respiratory distress. Increasingly severe symptoms can require the application of advanced medical assistance. The onset of leukopenia, or reduction of white blood cell count, can be treated with a plasma or platelet transfusion. Hypotension can be treated with the administration of norepinephrine or dopamine. Development of severe cardiopulmonary distress may require intubation and additional drug treatments to stabilize heart and lung activity.
Additionally, there are a variety of chemicals that can indirectly reduce the damaging effects of trichothecenes on cells and tissues. Activated charcoal solutions are frequently administered to ingestion cases as an adsorbent. Here, the charcoal acts as a porous substance for the toxin to bind, preventing its absorption through the gastrointestinal track and increasing its removal from the body through bowel excretion. Similar detoxifying adsorbents can also be added to animal feed upon contamination to reduce the bioavailability of the toxin upon consumption. Antioxidants are also useful in mitigating the damaging effects of trichothecenes in response to the increase of reactive oxygen species they produce in cells. Generally, a good diet rich in probiotics, vitamins and nutrients, proteins, and lipidis is thought to be effective in reducing the symptoms of trichothecene poisoning. For example, vitamin E was found to counteract the formation of lipid peroxides induced by T-2 toxin in chickens. Similarly, cosupplementation of modified glucomannas and selenium in the diets of chickens also consuming T-2 toxin, reduced the deleterious effects of toxin associated depletion of antioxidants in the liver. Despite not being a direct antidote, these antioxidants may be critical in reducing the severity of trichothecene exposures.

Prevention

Trichothecenes are mycotoxins produced by molds that frequently contaminate stores of grain products. This makes trichothecene contamination a significant public health problem, and many areas have strict limits on permitted trichothecene content. For example, in the European Union, only.025 ppm of T-2 toxin is permissible in bakery products intended for human consumption. The molds that can produce trichothecenes grow well in dark, temperate places with high moisture content. Therefore, one of the best ways to prevent trichothecene contamination in food products is to store the resources in the proper conditions to prevent the growth of molds. For example, it is generally advised to only store grains in areas with a moisture content of less than 15%. However, if an area has already been contaminated with trichothecene toxins, there are a variety of possible decontamination strategies to prevent further exposure. Treatment with 1% sodium hypochlorite in 0.1M sodium hydroxide for 4-5 hours has been shown to inhibit the biological activity of T-2 toxin. Incubation with aqueous ozone at approximately 25 ppm has also been shown to degrade a variety of trichothecenes through a mechanism involving oxidation of the 9, 10 carbon double bond. UV exposure has also been shown to be effective under the right conditions.
Outside of the strategies for physcial and chemical decontamination, advancing research in molecular genetics has also given rise to the potential of a biological decontamination approach. Many microbes, including bacteria, yeast, and fungi, have evolved enzymatic gene products which facilitate the specific and efficient degradation of trichothecene mycotoxins. Many of these enzymes specifically degrade the 12,13 carbon epoxide ring which is important for the toxicity of trichothecenes. For example, the Eubacteria strain BBSH 797 produces de-epoxidase enzymes which reduce the 12,13 carbon epoxide ring to a double bond group. These, along with other microbes expressing trichothecene detoxifying properties, can be used in feed stores to prevent to toxic effect of contaminated feed upon consumption. Furthermore, molecular cloning of the genes responsible for producing these detoxifying enzymes could be useful in producing strains of agricultural products that are resistant to trichothecene poisoning.

Epoxitrichothecenes

Epoxitrichothecenes are a variation of the above, and were once explored for military use in East Germany, and possibly the whole Soviet bloc. There is no feasible treatment once symptoms of epoxithichothecene poisoning set in, though the effects can subside without leaving any permanent damage.
The plans for use as a large-scale bioweapon were dropped, as the relevant epoxitrichothecenes degrade very quickly under UV light and heat, as well as chlorine exposure, making them useless for open attacks and the poisoning of water supplies.