Rapid Downward Transport of the Neurotoxin Domoic Acid in Coastal Waters

Toxic phytoplankton blooms threaten coastlines worldwide by diminishing beach quality and adversely affecting marine ecosystems and human health1,2 . The common diatom genus Pseudo-nitzschia consists of several species known to produce the neurotoxin domoic acid3 . Recent studies suggest that algal blooms dominated by Pseudo-nitzschia are increasing in frequency and duration owing to changes in coastal nutrient regimes1,4,5 . However, few studies have examined the persistence or long-term biogeochemical cycling of domoic acid in marine waters6–8 . Here, we measure the concentration of domoic acid in surface waters and sediment traps—up to 800 m in depth—off the coast of Southern California. We show that peaks in Pseudo-nitzschia abundance and domoic acid concentrations in surface waters coincide with peaks in diatom and toxin abundance at depth, suggesting rapid downward transport of the toxin. In some cases, the sinking particles contain over five times the United States federal limit of domoic acid. Detection of domoic acid in bottom sediments indicates that the toxin may persist long after the Pseudo-nitzschia blooms. Our results indicate that vertical fluxes of domoic acid are a substantial source of the toxin to deep-ocean food webs, and could explain high levels of domoic acid previously observed in benthic organisms9,10

Morphological adaptation of a planktonic diatom to growth in Antarctic sea ice.

Chaetoceros dichaeta Ehrenberg is one of the most important planktonic diatom species in the Southern Ocean, making a significant contribution to the total biomass in the region. Our observations on both field and culture material have revealed the existence of a specialized form of C. dichaeta adapted to living in sea ice. This sea ice form differs from the planktonic form by the shape and orientation of the setae and the aperture length between sibling cells. Thus, the diameter of the chain is equivalent to the apical axes of the cells and is accompanied by a two order of magnitude decrease in minimal space requirement. Here, we report for the first time on the extraordinary overwintering strategy of a planktonic diatom in sea ice facilitated by its rapid morphological adaptation to changing environmental conditions. This morphological plasticity enables it to thrive in the confined space of the sea ice brine matrix and retain its numerical dominance in recurrent growing seasons and has likely evolved to optimally exploit the dynamic ecosystem of the seasonally ice-covered seas of the Southern Ocean

Key Questions and Recent Research Advances on Harmful Algal Blooms in Stratified Systems

22 pages, 5 figuresThe GEOHAB Core Research Project (CRP) on HABs in Stratified Systems was a crosscutting project focused on the relevance of physical structure to fundamental life processes of harmful microorganisms such as growth (together with nutrient and light availability), reproduction, life cycle, and ecological interactions. Advances in this area have heavily depended on the development of innovative instruments to observe and adequately sample these environments, as well as on improvements in numerical modelling techniques (GEOHAB 2011, 2013; Berdalet et al. 2014). [...]Peer reviewe