Hunting the eagle killer: A cyanobacterial neurotoxin causes vacuolar myelinopathy

Breinlinger, Steffen; Phillips, Tabitha J.; Haram, Brigette N.; Mareš, Jan; Yerena, José A. Martínez; Hrouzek, Pavel; Sobotka, Roman; Henderson, W. Matthew; Schmieder, Peter; Williams, Susan M.; Lauderdale, James D.; Wilde, H. Dayton; Gerrin, Wesley L.; Kust, Andreja; Washington, John W.; Wagner, Christoph; Geier, Benedikt; Liebeke, Manuel; Enke, Heike; Niedermeyer, Timo H. J.; Wilde, Susan B.

doi:10.1126/science.aax9050

Cited by 116 publications

(103 citation statements)

References 83 publications

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“…An example of a recently discovered toxin with (yet) regionally limited occurrence is aetokthonotoxin, a polybrominated tryptophane derivative that is suspected to be the cause of the death of bald eagles and water birds in the United States [211]. Brominated metabolites are known primarily from marine cyanobacteria [212] while halogenated metabolites in freshwater cyanobacteria are generally chlorinated [213].…”

Section: Can We Expect New Cyanobacterial Toxins In the Future?mentioning

confidence: 99%

Cyanobacteria and Cyanotoxins in a Changing Environment: Concepts, Controversies, Challenges

Chorus

Fastner

Welker³

2021

Water

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Concern is widely being published that the occurrence of toxic cyanobacteria is increasing in consequence of climate change and eutrophication, substantially threatening human health. Here, we review evidence and pertinent publications to explore in which types of waterbodies climate change is likely to exacerbate cyanobacterial blooms; whether controlling blooms and toxin concentrations requires a balanced approach of reducing not only the concentrations of phosphorus (P) but also those of nitrogen (N); how trophic and climatic changes affect health risks caused by toxic cyanobacteria. We propose the following for further discussion: (i) Climate change is likely to promote blooms in some waterbodies—not in those with low concentrations of P or N stringently limiting biomass, and more so in shallow than in stratified waterbodies. Particularly in the latter, it can work both ways—rendering conditions for cyanobacterial proliferation more favourable or less favourable. (ii) While N emissions to the environment need to be reduced for a number of reasons, controlling blooms can definitely be successful by reducing only P, provided concentrations of P can be brought down to levels sufficiently low to stringently limit biomass. Not the N:P ratio, but the absolute concentration of the limiting nutrient determines the maximum possible biomass of phytoplankton and thus of cyanobacteria. The absolute concentrations of N or P show which of the two nutrients is currently limiting biomass. N can be the nutrient of choice to reduce if achieving sufficiently low concentrations has chances of success. (iii) Where trophic and climate change cause longer, stronger and more frequent blooms, they increase risks of exposure, and health risks depend on the amount by which concentrations exceed those of current WHO cyanotoxin guideline values for the respective exposure situation. Where trophic change reduces phytoplankton biomass in the epilimnion, thus increasing transparency, cyanobacterial species composition may shift to those that reside on benthic surfaces or in the metalimnion, changing risks of exposure. We conclude that studying how environmental changes affect the genotype composition of cyanobacterial populations is a relatively new and exciting research field, holding promises for understanding the biological function of the wide range of metabolites found in cyanobacteria, of which only a small fraction is toxic to humans. Overall, management needs case-by-case assessments focusing on the impacts of environmental change on the respective waterbody, rather than generalisations.

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Section: Can We Expect New Cyanobacterial Toxins In the Future?mentioning

confidence: 99%

Cyanobacteria and Cyanotoxins in a Changing Environment: Concepts, Controversies, Challenges

Chorus

Fastner

Welker³

2021

Water

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“…The disease was associated with exposure to Hydrilla , and epiphytic cyanobacteria present on the surface of this plant were considered as potential causative agents [ 73 ]. Feeding test animals extracts of certain collections of Hydrilla resulted in gross pathology consistent with AVM, and epiphytic cyanobacteria were also shown to be toxic to bird species such as coots that were fed these extracts [ 74 ]. Extensive research has now identified a brominated cyanobacterial toxin, aetokthonotoxin, which results in the production of vacuoles and lesions in the brains of birds fed this toxin, consistent with it being a cause of AVM [ 74 ].…”

Section: Toxins That Affect the Brain And Nervesmentioning

confidence: 99%

Cyanotoxins and the Nervous System

Metcalf

Tischbein

Cox

et al. 2021

Toxins

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Cyanobacteria are capable of producing a wide range of bioactive compounds with many considered to be toxins. Although there are a number of toxicological outcomes with respect to cyanobacterial exposure, this review aims to examine those which affect the central nervous system (CNS) or have neurotoxicological properties. Such exposures can be acute or chronic, and we detail issues concerning CNS entry, detection and remediation. Exposure can occur through a variety of media but, increasingly, exposure through air via inhalation may have greater significance and requires further investigation. Even though cyanobacterial toxins have traditionally been classified based on their primary mode of toxicity, increasing evidence suggests that some also possess neurotoxic properties and include known cyanotoxins and unknown compounds. Furthermore, chronic long-term exposure to these compounds is increasingly being identified as adversely affecting human health.

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“…Aetokthonotoxin (AETX) is a pentabrominated biindole alkaloid produced by the cyanobacterium Aetokthonos hydrillicola , which grows epiphytically on an invasive plant, Hydrilla verticillata , in freshwater lakes [1] . The toxin traverses the food chain from animals consuming the plant (and thus also the cyanobacterium) like waterfowl or snails and then on to raptors such as eagles (e. g. American bald eagle) and kites.…”

Section: Figurementioning

confidence: 99%

“…The toxin traverses the food chain from animals consuming the plant (and thus also the cyanobacterium) like waterfowl or snails and then on to raptors such as eagles (e. g. American bald eagle) and kites. While the mode‐of‐action of AETX is still unknown, it has been shown to elicit Vacuolar Myelinopathy in birds, which is characterized by a widespread vacuolization of the myelinated axons in the white matter of the brain and spinal cord of affected animals [1] . AETX has also been found to be highly toxic to the nematode C. elegans (LC 50 40 nM), [1] but susceptibility of mammals to this toxin has not been studied, yet.…”

Section: Figurementioning

confidence: 99%

Total Synthesis of Aetokthonotoxin, the Cyanobacterial Neurotoxin Causing Vacuolar Myelinopathy

Ricardo

Schwark

Llanes

et al. 2021

Chemistry A European J

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Aetokthonotoxin has recently been identified as the cyanobacterial neurotoxin causing Vacuolar Myelinopathy, a fatal neurologic disease, spreading through a trophic cascade and affecting birds of prey such as the bald eagle in the USA. Here, we describe the total synthesis of this specialized metabolite. The complex, highly brominated 1,2’‐biindole could be synthesized via a Somei‐type Michael reaction as key step. The optimised sequence yielded the natural product in five steps with an overall yield of 29 %.

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Hunting the eagle killer: A cyanobacterial neurotoxin causes vacuolar myelinopathy

Cited by 116 publications

References 83 publications

Cyanobacteria and Cyanotoxins in a Changing Environment: Concepts, Controversies, Challenges

Cyanobacteria and Cyanotoxins in a Changing Environment: Concepts, Controversies, Challenges

Cyanotoxins and the Nervous System

Total Synthesis of Aetokthonotoxin, the Cyanobacterial Neurotoxin Causing Vacuolar Myelinopathy

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