Review

. 2016 Sep;9(5):641-51.

doi: 10.1111/1751-7915.12383. Epub 2016 Jul 15.

Moving towards adaptive management of cyanotoxin-impaired water bodies

Hans W Paerl¹, Timothy G Otten², Alan R Joyner¹

Affiliations

¹ Institute of Marine Sciences, University of North Carolina at Chapel Hill, Morehead City, NC, USA.
² Bend Genetics, LLC, 87 Scripps Drive, Ste. 301, Sacramento, CA, USA.

PMID: 27418325
PMCID: PMC4993183
DOI: 10.1111/1751-7915.12383

Review

Moving towards adaptive management of cyanotoxin-impaired water bodies

Hans W Paerl et al. Microb Biotechnol. 2016 Sep.

. 2016 Sep;9(5):641-51.

doi: 10.1111/1751-7915.12383. Epub 2016 Jul 15.

Authors

Hans W Paerl¹, Timothy G Otten², Alan R Joyner¹

Affiliations

¹ Institute of Marine Sciences, University of North Carolina at Chapel Hill, Morehead City, NC, USA.
² Bend Genetics, LLC, 87 Scripps Drive, Ste. 301, Sacramento, CA, USA.

PMID: 27418325
PMCID: PMC4993183
DOI: 10.1111/1751-7915.12383

Abstract

The cyanobacteria are a phylum of bacteria that have played a key role in shaping the Earth's biosphere due to their pioneering ability to perform oxygenic photosynthesis. Throughout their history, cyanobacteria have experienced major biogeochemical changes accompanying Earth's geochemical evolution over the past 2.5+ billion years, including periods of extreme climatic change, hydrologic, nutrient and radiation stress. Today, they remain remarkably successful, exploiting human nutrient over-enrichment as nuisance "blooms." Cyanobacteria produce an array of unique metabolites, the functions and biotic ramifications of which are the subject of diverse ecophysiological studies. These metabolites are relevant from organismal and ecosystem function perspectives because some can be toxic and fatal to diverse biota, including zooplankton and fish consumers of algal biomass, and high-level consumers of aquatic food sources and drinking water, including humans. Given the long history of environmental extremes and selection pressures that cyanobacteria have experienced, it is likely that that these toxins serve ecophysiological functions aimed at optimizing growth and fitness during periods of environmental stress. Here, we explore the molecular and ecophysiological mechanisms underlying cyanotoxin production, with emphasis on key environmental conditions potentially controlling toxin production. Based on this information, we offer potential management strategies for reducing cyanotoxin potentials in natural waters; for cyanotoxins with no clear drivers yet elucidated, we highlight the data gaps and research questions that are still lacking. We focus on the four major classes of toxins (anatoxins, cylindrospermopsins, microcystins and saxitoxins) that have thus far been identified as relevant from environmental health perspectives, but caution there may be other harmful metabolites waiting to be elucidated.

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Figures

**Figure 1**
Putative environmental drivers of cyanotoxin production that are presently recognized and the interplay of environmental stimuli on growth of toxigenic cyanobacteria.

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Moving towards adaptive management of cyanotoxin-impaired water bodies

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Moving towards adaptive management of cyanotoxin-impaired water bodies

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