Names | |
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IUPAC name (5R,8S,11R,12S,15S,18S,19S,22R)-15-[3-(diaminomethylideneamino)propyl]-18-[(1E,3E,5S,6S)-6-Methoxy-3,5-dimethyl-7-phenylhepta-1,3-dienyl]-1,5,12,19-tetramethyl-2-methylidene-8-(2-methylpropyl)-3,6,9,13,16,20,25-heptaoxo-1,4,7,10,14,17,21-heptazacyclopentacosane-11,22-dicarboxylic acid | |
Other names 5-L-Arginine-microcystin LA | |
Identifiers | |
3D model (JSmol) | |
Abbreviations | MC-LR, MCYST-LR |
ChEBI | |
ChEMBL | |
ChemSpider | |
ECHA InfoCard | 100.150.186 |
EC Number |
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KEGG | |
PubChem CID | |
UNII | |
CompTox Dashboard (EPA) | |
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Properties | |
C49H74N10O12 | |
Molar mass | 995.189 g·mol−1 |
Appearance | White solid |
Density | 1.299 g/cm3 |
Solubility in ethanol | 1 mg/mL |
log P | -1.44 |
Pharmacology | |
Ingestion | |
Hazards | |
Occupational safety and health (OHS/OSH): | |
Main hazards | extremely toxic |
GHS labelling: | |
Danger | |
H300, H310, H315, H317, H319, H335 | |
Lethal dose or concentration (LD, LC): | |
LD50 (median dose) | 5 mg/kg |
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa). |
Microcystin-LR (MC-LR) is a toxin produced by cyanobacteria. It is the most toxic of the microcystins.
Microcystins are cyclic heptapeptides. The seven amino acids that are involved in the structure of a microcystin include the unique amino acids ADDA and D-β-methyl-isoaspartate (D-β-Me-isoAsp). Furthermore, microcystins contain two variable residues, which make the differentiation between variants of microcystins. These two variable functionalities are always standard proteinogenic amino acids - In microcystin-LR these are leucine and arginine.
More than 250 microcystins have been identified to date, [1] representing differences in the two variable residues and some modifications in the other amino acids. These modifications include demethylation of Masp and Mdha and methylesterification of D-Glu. Different microcystins have different toxicity profiles, with microcystin-LR found to be the most toxic. [2] [3]
Microcystins are small nonribosomal peptides. In Microcystis aeruginosa microcystin-LR is synthesized by proteins that encoded by a 55 kb microcystin-gene cluster (mcy) that contains 6 large (over 3 kb) genes that encode proteins with polyketide synthase activity, nonribosomal peptide synthase activity (mcyA-E and G) and 4 smaller genes (mcyF and H-J). These large proteins are made up of different protein domains, coined 'modules', that each have their own specific enzymatic function. [4] Although the enzyme systems involved in the biosynthesis of microcystins is not identical among all cyanobacteria, there are large similarities and most of the essential enzymes are conserved. [4] [5]
The biosynthesis of microcystin-LR in Microcystis aeruginosa begins with the coupling of phenylacetate to the mcyG enzyme. In a series of reactions, catalysed by different enzyme modules as well as different enzymes, microcystin-LR is formed. The entire biosynthesis pathway of microcystin-LR in Microcystis aeruginosa is illustrated in the figure.
The first steps of the synthesis involve the insertion of several carbon- and oxygen atoms between the acetyl- and phenylgroup. This part of the synthesis is catalyzed by enzyme domains that possess β-ketoacylsynthase, acyltransferase, C-methyltransferase and ketoacyl reductase activity. At the end of this stage, that is, after the first condensation of glutamate, the amino acid Adda is formed. [4] The second part of the synthesis involves the condensation of the amino acids of which the microcystin is composed. Thus, in the case of microcystin-LR the consecutive condensation of the amino acids glutamic acid, methyldehydroalanine, alanine, leucine, methylaspartic acid and arginine leads to the coupled product. A nucleophilic attack of the nitrogen in the Adda residue results in the release of the cyclic microcystin-LR. [4]
The different microcystins are all synthesized by the same[ clarification needed ] enzymes as microcystin-LR. [6]
Microcystin-LR inhibits protein phosphatase type 1 and type 2A (PP1 and PP2A) activities in the cytoplasm of liver cells. This leads to an increase in phosphorylation of proteins in liver cells. The interaction of microcystin-LR to the phosphatases includes the formation of a covalent bond between a methylene group of microcystin-LR and a cystine residue at the catalytic subunit of the phosphoprotein phosphatase (PPP) family of serine/threonine-specific phosphatases, like PP1 and PP2A. When microcystin-LR binds directly to the catalytic center of the PPP enzymes, they block the access of the substrate to the active site completely and inhibition of the enzyme takes place. In this way the protein phosphatase is inhibited and more phosphorylated proteins in the liver cells are left, which is responsible for the hepatotoxicity of microcystin-LR.
The active site of catalytic PPP enzymes represents three surface grooves: the hydrophobic groove, the acidic groove and the C-terminal groove, which are Y-shaped with the active site at the bifurcation point. The Adda side-chain of microcystin-LR is accommodated to the hydrophobic groove, the carboxylic D-Glu site makes hydrogen bonds to metal-bound water molecules and the carboxyl group of the Masp site makes hydrogen bonds to conserved arginine and tyrosine residues in the PPP enzyme. Finally the methylene group at the Mdha site of microcystin-LR binds covalently to a S-atom of a cysteine residue, and the leucine residue packs closely to another conserved tyrosine residue. [2]
Microcystin-LR is toxic for both humans and animals. There are epidemiological results from studies that have shown symptoms of poisoning attributed to the presence of cyanotoxins in drinking water. The effects are divided in short-term and long-term effects.
There are no verifiable reports of human deaths known to have been specifically caused by microcystin-LR, although there are reports of health effects after exposure and there have been deaths attributed to microcystins in general. [7] One of the most outstanding reports was an outbreak in Caruaru, Brazil, in 1996. 116 patients experienced multiple effects: visual disturbance, nausea, vomiting and muscle weakness. One hundred developed acute liver failure and 52 suffered from symptoms of what is now called "Caruaru Syndrome." [8] The syndrome was caused by dialysis therapy with water that had not been properly treated. [9]
There are few short-term effects caused by exposure to microcystin-LR. Microcystins are primarily hepatotoxic compounds; therefore, noticeable toxic effects are not immediate. Most of the toxicity studies have been done with mice that received intra-peritoneal injections. The most common effect is liver damage, [10] Two of the most commonly seen symptoms are gastroenteritis and cholestatic liver disease.
In an experiment with mice, the animals died within a few hours after injection of a lethal dose of micocystin-LR. Liver damage could be noticed in 20 minutes. Within a few hours, liver cells died. [11]
Acute microcystin-LR intoxication may result in long-term injury, while chronic low-level exposure may cause adverse health effects. From animal studies, it is proven that there will be chronic liver injury from oral exposure to microcystin-LR. It might even be carcinogenic. Cancers have been found during animal studies. Microcystin-LR itself does not cause cancer, but it may stimulate the growth of cancer cells.
Microcystin-LR had effects on all animals, not only the domestic animals from swimming in a river of drinking water with cyanobacteria blooms. Symptoms in domestic animal poisoning include diarrhea, vomiting, weakness, recumbency and are fatal in most cases [12] [13]
Mircocystin-LR is toxic for all animals, including the animals consumed by humans. Fishes and birds are also at risk for microcystin-LR poisoning.
Cyanobacteria prefer to live in water bodies such as lake, ponds, reservoirs, and slow-moving streams. When the water is warm there are enough nutrients available for the bacteria to survive. Most cyanobacteria produce toxins, of which microcystin is only one group. When a cyanobacterium dies, its cell wall degrades while the toxins are released in the water. Microcystins are extremely stable in water and withstand chemical breakdown such as hydrolysis or oxidation. The half-life of this toxin is 3 weeks at pH 1 and 40 °C. At typical conditions in the environment, however, the half-life is 10 weeks. [10] Microcystin-LR water contamination is resistant to boiling and microwave treatments. [14]
After release in the water, microcystins are actively absorbed by fish and birds from intoxicated water and thus enter the food chain. Humans are also exposed to microcystins by performing activities in intoxicated water. [15]
Microcystin-LR is rapidly excreted from the blood plasma. Plasma half-lives for the α- and β-stages, corresponding to distribution and elimination, are respectively 0.8 and 6.9 minutes. [16] [17] The total clearance of the compound from the plasma is about 0.9 mL/min. The excretion of the compound takes primarily place via the feces and urine. After 6 days approximately 24% of the intake is excreted from the body, of which about 9% is excreted via the feces and 14.5% via the urine. [17]
Microcystin-LR is mostly concentrated in the liver. Other tissues get exposed at much lower levels. [17]
Data about the metabolism of microcystin-LR in humans is very scarce. Data about metabolism and disposition of the toxin in mice and rats is more widely available. In these animals microcystin-LR is rapidly concentrated in the liver. [18] Intoxication of mice with microcystin-LR led to a decrease in the levels of cytochrome P450 and cytochrome b5 and an increase in cytochrome P420, to which CYP450 is converted. Together with the fact that mice with an induced higher concentration CYP450 are less affected by the toxin, this suggest that CYP450 plays an important role in the detoxification of the compound.
In phase 2 of the biotransformation the compound is conjugated with several different endogenous substances. Microcystin-LR is known to be excreted as glutathione conjugate, cysteine conjugate and an oxidized ADDA diene conjugate. The glutathione and cysteine conjugate with the Mda-moiety. The oxidized ADDA is conjugated at the conjugated bond. [19]
Toxic effects cyanotoxins are very diverse and include neurotoxicity, hepatotoxicity and cytotoxicity with chemical burns. Microcystins are generally associated with hepatotoxicity. The toxic effect of microcystins is due to their inhibition of protein phosphatases. [20]
Many studies took place with intraperitoneal administration. Because of the differences in lipophilicity and polarity between the different microcystins, it cannot be presumed that the i.p. LD50 will predict toxicity after oral administration. [10]
Microcystins are hepatotoxins. After acute exposure, severe liver damage is noticeable by a disruption of liver cell structure. The liver weight will increase due to intrahepatic hemorrhage, haemodynamic shock, heart failure and death. [10]
After nasal administration of microcystin-LR, the epithelium of nasal mucosa of both the olfactory and respiratory zones were suffering from necrosis. Even liver lesions were noticed after oral administration. The LD50 for nasal administration is equal to the intraperitoneal administration.
For the assessment of possible chronic human health effects, studies involving repeated oral administration of pure microcystins at various dose levels are most desirable. In a mice study, pure mirocystin-LR was administered orally at doses 0, 40, 200 or 1000 μg/kg bodyweight. At the highest dose, almost all mice showed liver changes and chronic inflammation and a few other symptoms. In female mice only changes in transaminases were observed at the highest dose. [10]
Mice showed neoplastic liver nodules after 100 oral administrations at 20 μg/kg bodyweight. The nodules observed were up to 5mm in diameter. However, no mice showed liver nodules after 100 administrations of 80 μg/kg.
The IARC committee concluded that microcystin-LR is possibly carcinogenic to humans. So, microcystin-LR itself is not a carcinogen, but it stimulates tumor growth. Mice treated with the carcinogenic compound dimethylbenzathracene showed an increased number and weight of skin tumors. [7]
There is very little known about acute toxicity for humans, but there have been animal studies, showing the following results.
Method of administration [21] | Toxicity | Species | Value |
---|---|---|---|
Oral | LD50 | Mouse | 5 mg/kg |
Inhalation, 10h | LC50 | Mouse | 18 mg/kg |
Intraperitoneal | LD50 | Rat | 0.05 mg/kg |
Intraperitoneal | LD50 | Mouse | 0.0325 mg/kg |
Intravenous | LD50 | Mouse | 0.06 mg/kg |
When microcystins are injected intravenously or intraperitoneally, they localize in the liver. This appears to be the result of uptake by hepatocytes. The WHO report states that microcystins are lethal to mice when they are exposed intraperitoneally to 25 to 150 μg/kg body weight. [10] Perhaps due to poor absorption after exposure, orally administered microscytins are less toxic, as a lethal dose in mice is about 5 to 10 μg/kg body weight. Hepatotoxicity in the form of hepatic necrosis occurs within 60 minutes after an intraveneous dose. [20] Blooms of Microcystis aeruginosa did not cause increased tumor rates in groups of mice treated for up to one year. It is shown that mice given 20 μg/kg body weight 4 times a week during a period of 28 weeks developed neoplasms of the liver. [20] There results are, however, ambiguous. By the oral route, microcystin-LR displays acute toxicity in rodents. It is apparent that a significant amount of the oral dose passes the intestinal barrier.
Microcystins do not appear to show developmental toxicity.
The WHO states microcystin-LR has no mutagenic effect. However, the induction of DNA strand-breaks in lymphocytes has been observed in mice after single oral administration. The effect is time- and dose-dependent. There is no change in the expression of selected genes involved in the cellular response to DNA damage after a 4-hour exposure. After 24 hours, the DNA damage-responsive genes were upregulated, which indicates that microcystin-LR is an indirect genotoxic agent. [22] In China, the highest incidence of liver cancer occurs in areas with abundant cyanobacteria in the surface waters. Tumor development is associated with low-concentration exposure over a long period of time. [20]
In vitro studies showed that microcystin-LR is a potent inhibitor of protein phosphatase 1 (PP-1) and PP2A, but has no effect on protein kinase C or cyclic AMP-dependent kinase. Mutagenicity does not appear to occur for purified toxins derived from Microcystis , although the toxins were clastogenic for human lymphocytes. [20]
A metalloprotease enzyme isolated from bacteria at Lake Rotorua, among other locations, is called microcystinase. This particular enzyme turns microcystins into products with a 160-fold decrease in toxicity. [23]
The Chinese general Zhu-Ge Liang was the first to observe cyanobacteria poisoning about 1000 years ago. He reported the death of troops who drank green coloured water from a river in southern China.[ citation needed ] The first published report of an incidence of cyanobacteria poisoning dates from the poisoning of an Australian lake in 1878. [24] Also, in China and Brasil, people died after drinking water from a lake. All these incidents have been attributed to cyanobacteria and the toxic compound microcystin-LR. That is the reason why the World Health Organization (WHO) issued a guideline for microcystins in drinking water. The WHO guideline for microcystins in drinking water, based on microcystin-LR, is 1 μg/L. [16] With the high levels of Eutrophication in South Africa, typical exposures can be as high as 10 μg/L. [25] [26] [27] [28]
An oligopeptide, is a peptide consisting of two to twenty amino acids, including dipeptides, tripeptides, tetrapeptides, and other polypeptides. Some of the major classes of naturally occurring oligopeptides include aeruginosins, cyanopeptolins, microcystins, microviridins, microginins, anabaenopeptins, and cyclamides. Microcystins are best studied because of their potential toxicity impact in drinking water. A review of some oligopeptides found that the largest class are the cyanopeptolins (40.1%), followed by microcystins (13.4%).
Hepatotoxicity implies chemical-driven liver damage. Drug-induced liver injury (DILI) is a cause of acute and chronic liver disease caused specifically by medications and the most common reason for a drug to be withdrawn from the market after approval.
Microcystins—or cyanoginosins—are a class of toxins produced by certain freshwater cyanobacteria, commonly known as blue-green algae. Over 250 different microcystins have been discovered so far, of which microcystin-LR is the most common. Chemically they are cyclic heptapeptides produced through nonribosomal peptide synthases.
Cyanotoxins are toxins produced by cyanobacteria. Cyanobacteria are found almost everywhere, but particularly in lakes and in the ocean where, under high concentration of phosphorus conditions, they reproduce exponentially to form blooms. Blooming cyanobacteria can produce cyanotoxins in such concentrations that they can poison and even kill animals and humans. Cyanotoxins can also accumulate in other animals such as fish and shellfish, and cause poisonings such as shellfish poisoning.
Abrin is an extremely toxic toxalbumin found in the seeds of the rosary pea, Abrus precatorius. It has a median lethal dose of 0.7 micrograms per kilogram of body mass when given to mice intravenously. The median toxic dose for humans ranges from 10 to 1000 micrograms per kilogram when ingested and is 3.3 micrograms per kilogram when inhaled.
Amatoxin is the collective name of a subgroup of at least nine related toxic compounds found in three genera of poisonous mushrooms and one species of the genus Pholiotina. Amatoxins are very potent, as little as half a mushroom cap can cause severe liver injury if swallowed.
Anatoxin-a, also known as Very Fast Death Factor (VFDF), is a secondary, bicyclic amine alkaloid and cyanotoxin with acute neurotoxicity. It was first discovered in the early 1960s in Canada, and was isolated in 1972. The toxin is produced by multiple genera of cyanobacteria and has been reported in North America, South America, Central America, Europe, Africa, Asia, and Oceania. Symptoms of anatoxin-a toxicity include loss of coordination, muscular fasciculations, convulsions and death by respiratory paralysis. Its mode of action is through the nicotinic acetylcholine receptor (nAchR) where it mimics the binding of the receptor's natural ligand, acetylcholine. As such, anatoxin-a has been used for medicinal purposes to investigate diseases characterized by low acetylcholine levels. Due to its high toxicity and potential presence in drinking water, anatoxin-a poses a threat to animals, including humans. While methods for detection and water treatment exist, scientists have called for more research to improve reliability and efficacy. Anatoxin-a is not to be confused with guanitoxin, another potent cyanotoxin that has a similar mechanism of action to that of anatoxin-a and is produced by many of the same cyanobacteria genera, but is structurally unrelated.
Cylindrospermopsin is a cyanotoxin produced by a variety of freshwater cyanobacteria. CYN is a polycyclic uracil derivative containing guanidino and sulfate groups. It is also zwitterionic, making it highly water soluble. CYN is toxic to liver and kidney tissue and is thought to inhibit protein synthesis and to covalently modify DNA and/or RNA. It is not known whether cylindrospermopsin is a carcinogen, but it appears to have no tumour initiating activity in mice.
Nodularins are potent toxins produced by the cyanobacterium Nodularia spumigena, among others. This aquatic, photosynthetic cyanobacterium forms visible colonies that present as algal blooms in brackish water bodies throughout the world. The late summer blooms of Nodularia spumigena are among the largest cyanobacterial mass occurrences in the world. Cyanobacteria are composed of many toxic substances, most notably of microcystins and nodularins: the two are not easily differentiated. A significant homology of structure and function exists between the two, and microcystins have been studied in greater detail. Because of this, facts from microcystins are often extended to nodularins.
Senecionine is a toxic pyrrolizidine alkaloid isolated from various botanical sources. It takes its name from the Senecio genus and is produced by many different plants in that genus, including Jacobaea vulgaris. It has also been isolated from several other plants, including Brachyglottis repanda, Emilia, Erechtites hieraciifolius, Petasites, Syneilesis, Crotalaria, Caltha leptosepala, and Castilleja.
Cyclamides are a class of oligopeptides produced by cyanobacteria algae strains such as Microcystis aeruginosa. Some of them can be toxic.
Microcystis is a genus of freshwater cyanobacteria that includes the harmful algal bloom-forming Microcystis aeruginosa. Many members of a Microcystis community can produce neurotoxins and hepatotoxins, such as microcystin and cyanopeptolin. Communities are often a mix of toxin-producing and nonproducing isolates.
Microcystis aeruginosa is a species of freshwater cyanobacteria that can form harmful algal blooms of economic and ecological importance. They are the most common toxic cyanobacterial bloom in eutrophic fresh water. Cyanobacteria produce neurotoxins and peptide hepatotoxins, such as microcystin and cyanopeptolin. Microcystis aeruginosa produces numerous congeners of microcystin, with microcystin-LR being the most common. Microcystis blooms have been reported in at least 108 countries, with the production of microcystin noted in at least 79.
ADDA is a non-proteinogenic amino acid found in toxins made by cyanobacteria. Toxins which include this amino acid include microcystins and nodularins.
Cyanopeptolins (CPs) are a class of oligopeptides produced by Microcystis and Planktothrix algae strains, and can be neurotoxic. The production of cyanopeptolins occurs through nonribosomal peptides synthases (NRPS).
4-Ipomeanol (4-IPO) is a pulmonary pre-toxin isolated from sweet potatoes infected with the fungus Fusarium solani. One of the 4-IPO metabolites is toxic to the lungs, liver and kidney in humans and animals. This metabolite can covalently bind to proteins, thereby interfering with normal cell processes.
Crotoxin (CTX) is the main toxic compound in the snake venom of the South American rattlesnake, Crotalus durissus terrificus. Crotoxin is a heterodimeric beta-neurotoxin, composed of an acidic, non-toxic and non-enzymatic subunit (CA), and a basic, weakly toxic, phospholipase A2 protein (CB). This neurotoxin causes paralysis by both pre- and postsynaptic blocking of acetylcholine signalling.
Penicillin Roquefort toxin is a mycotoxin produced by the fungus Penicillium roqueforti. In 1973, PR toxin was first partially characterized by isolating moldy corn on which the fungi had grown. Although its lethal dose was determined shortly after the isolation of the chemical, details of its toxic effects were not fully clarified until 1982 in a study with mice, rats, anesthetized cats and preparations of isolated rat auricles.
GiTx1 (β/κ-theraphotoxin-Gi1a) is a peptide toxin present in the venom of Grammostola iheringi. It reduces both inward and outward currents by blocking voltage-gated sodium and potassium channels, respectively.