The Effects of Elevated CO2 on Paralytic Shellfish Poisoning Toxin
Van de Waal, D.B., Eberlein, T., John, U., Wohlrab, S. and Rost, B. 2014. Impact of elevated pCO2 on paralytic shellfish poisoning toxin content and composition in Alexandrium tamarense. Toxicon 78: 58-67.
Determined to make new inroads into this little-studied subject, Van de Wall et al. investigated the potential impacts of elevated pCO2 on paralytic shellfish-poisoning toxin (PST), in terms of both its "content and composition in two strains of Alexandrium tamarense (Alex5 and Alex2), which were isolated from the same population at the Scottish east coast of the North Sea (Alpermann et al., 2009; Tillmann et al., 2009)." This they did because "no study thus far," as they put it, had "investigated the impact of elevated pCO2 on toxin production and gene regulation in A. tamarense." And so it was that more specifically - but very briefly - they grew cultures of Alex5 and Alex2 in filtered natural seawater enriched with various metals and vitamins, after which "the culture medium was equilibrated with air containing a pCO2 of 180 µatm (~Last Glacial Maximum), 380 µatm (~present day), 800 µatm (~2100 scenario), and 1200 µatm (>2100 scenario)," while various sets of measurements were made.
The five researchers observed "only minor changes with respect to growth and elemental composition in response to elevated pCO2." But most importantly, they say "for both strains, the cellular PST content, and in particular the associated cellular toxicity, was lower in the high CO2 treatments." And they additionally found that "Alex5 showed a shift in its PST composition from a non-sulfated analogue towards less toxic sulfated analogues with increasing pCO2." Furthermore, they found "genes associated to secondary metabolite and amino acid metabolism in Alex5 were down-regulated in the high CO2 treatment," which they felt "may explain its lower PST content."
"All in all," as they conclude, Van de Waal et al. say their results indicate "elevated pCO2 will have minor consequences for growth and elemental composition, but may potentially reduce the cellular toxicity of A. tamarense," which would be good news for fish, marine mammals, seabirds and humans.
Alpermann, T.J., Beszteri, B., John, U., Tillmann, U. and Cembella, A.D. 2009. Implications of life-history transitions on the population genetic structure of the toxigenic marine dinoflagellate Alexandrium tamarense. Molecular Ecology 18: 2122-2133.
Anderson, D.M., Alpermann, T.J., Cembella, A.D., Collos, Y., Masseret, E. and Montresor, M. 2012. The globally distributed genus Alexandrium: multifaceted roles in marine ecosystems and impacts on human health. Harmful Algae 14: 10-35.
Fu, F.X., Place, A.R., Garcia, N.S. and Hutchins, D.A. 2010. CO2 and phosphate availability control the toxicity of the harmful bloom dinoflagellate Karlodinium veneficum. Aquatic Microbiology and Ecology 59: 55-65.
Graneli, E. and Turner, J.T. 2006. Ecology of Harmful Algae. Springer-Verlag, Berlin, Heidelberg, Germany.
Hallegraeff, G.M. 2010. Ocean climate change, phytoplankton community responses, and harmful algal blooms: a formidable predictive challenge. Journal of Phycology 46: 220-235.
Kremp,A., Godhe, A., Egardt, J., Dupont, S., Suikkanen, S., Casabianca, S. and Penna, A. 2012. Intraspecific variability in the response of bloom-forming marine microalgae to changed climate conditions. Ecology and Evolution 2: 1195-1202.
Tillmann, U., Alpermann, T.L., da Purificacao, R.C., Krock, B. and Cembella, A. 2009. Intra-population clonal variability in allelochemical potency of the toxigenic dinoflagellate Alexandrium tamarense. Harmful Algae 8: 759-769.