Description: From the German Bight along Jutland to the western Skagerrak, we found representatives of almost all groups of phycotoxins known to occur in North Sea plankton. Identification was by liquid chromatography coupled to tandem mass spectrometry (LC-MS/MS) in plankton size fractions, with domoic acid and 20-me G the most abundant toxins. The dominance of 20-me G in the spirolide (SPX) composition of plankton from the Jutland current system matched very well with that of an isolate of the dinoflagellate Alexandrium ostenfeldii. The SPXs of the A. ostenfeldii strain S6_P12_E11, previously isolated from the western North Sea along the Scottish coast, comprised 100% 20-me G, suggesting toxin homogeneity among North Sea populations of this species. We detected highest amounts of azaspiracid-1 in the 3–20-mm size fraction at offshore stations, where the Jutland coastal current converges with the westward North Sea flow off Skagerrak. Azadinium spinosum was subsequently identified by clonal isolation from crude cultures established from these stations. Except for lipophilic toxins usually produced by the dinoflagellate Dinophysis spp., dinophysistoxin-1 (DTX-1) and DTX-2, we detected no other phycotoxins in plankton from the southern German Bight. The spatial distribution of the phycotoxins in the eastern North Sea was apparently related to the hydrographical conditions, identified from salinity and coloured dissolved organic matter profiles. The biogeographical distribution of phycotoxins indicates a strong association with the northward advection by the Jutland current and the mixing of German Bight and North water masses along the northwest Danish coast towards the Skagerrak.

Description: Molecular probes were developed for the dinoflagellate genus Azadinium to discriminate among three taxa difficult to differentiate by light microscopy. This genus contains azaspiracid toxin-producing Azadinium spinosum, but also non-toxigenic species. Quantitative polymerase chain reaction (qPCR) and fluorescence in situ hybridization (FISH) assays were applied to cultured isolates and Azadiniumspiked field plankton. Molecular methods were highly specific and sensitive in the unambiguous detection of Azadinium, and thus are valuable for routine plankton, biogeographic and phylogenetic investigations.

Description: Naturally occurring neurotoxins belonging to two structurally distinct groups of guanidinium alkaloids known collectively as saxitoxins (STXs) and tetrodotoxins (TTXs) share a high affinity and ion flux blockage capacity for voltage-gated sodium ion channels (NaV). Both toxin groups are produced by marine microorganisms and widely distributed among vector species in the oceans, but are also found in terrestrial species. The STXs are often referred to as paralytic shellfish toxins (PSTs) based on their accumulation in shellfish and the symptoms in humans after consumption of toxic seafood. Biosynthesis of STXs is confirmed in four genera of marine dinoflagellates and among about a dozen species of primarily freshwater and brackish water strains of filamentous cyanobacteria. The origin of the STX biosynthetic genes in dinoflagellates remains controversial and may represent multiple horizontal gene transfer (HGT) events from progenitor bacteria and/or cyanobacteria. The recent identification of the biosynthetic genes for STX analogs in both cyanobacteria and dinoflagellates has yielded insights into mechanisms of toxin heterogeneity among species and the evolutionary origins of the respective elements of the toxin gene cluster. The biogenic origins of TTXs and tetrodotoxicity remain even more enigmatic. The TTXs occur primarily in marine pufferfish species, and hence tetrodotoxicity is frequently described as pufferfish poisoning (PFP) after the toxin syndrome in human consumers of such toxic fish. In marine environments, TTXs also appear in invertebrate species, particularly of benthic feeders on suspended particulates and carnivorous vector species. Symbiotic colonizing bacteria or free-living bacteria sequestered via feeding from the water column or sediments are most often invoked as proximal sources of TTXs in marine macrofauna, but endogenous biosynthesis independent of bacteria cannot be excluded. The TTX biosynthetic pathway has not been completely elucidated, and the biosynthetic genes are unknown.