Description: The almost globally distributed, marine dinoflagellate genera Azadinium and Amphidoma (Amphidomataceae) produce a variety of lipophilic phycotoxins known as Azaspiracids (AZA). These toxins are accumulated mostly by filter-feeders like the blue mussel (Mytilus edulis) and may lead to the azaspiracid-shellfish-poisoning (AZP) syndrome in humans after consumption of contaminated seafood. With respect to the impacts on humans health, AZA-concentrations above the EU-regulatory limit (0.16 mg AZA Kg-1 mussel flesh) go along with closures of shellfish farms and are therefore a threat to the aquaculture industry, as well. Thus, there is a need for a rapid, sensitive and reliable detection and quantification of these microalgae and their toxigenic products. However, this is challenging, as the small-sized cells (12-16 µm) are hardly possible to be identified by traditional light microscopy. Even more challenging, only a few amphidomatacean species produce toxins, and toxigenic and non-toxigenic species can co-occur in the same area. In 2018, a seagoing expedition took place in the North Sea, the English Channel and Irish coastal waters, combining onboard light microscopy, quantitative real-time PCR (qPCR) and liquid-chromatography, coupled with tandem mass-spectrometry (LC-MS/MS), to search for the three azaspiracid-producing species known from the North Atlantic: Azadinium spinosum, Az. poporum and Amphidoma languida. Findings revealed that AZA-producers and respective toxins were widely distributed in the survey area, with high cell densities in the North Sea area and along the Irish coastline. Highlight was a bloom stage of Am. languida with 1.2 × 105 cells L-1, observed on a central North Sea station. Results of microscopy, molecular and chemical analyses matched well, which increased the confidence about species and toxin detection. This study supports again the recommendation to include toxigenic Amphidomataceans into regular monitoring programs and further demonstrated the advantage of real-time, multi-method approaches to investigate inconspicuous, harmful microalgae species in the field.

Description: Azaspiracids (AZA) are a group of lipophilic toxins, which are produced by a few species of the marine nanoplanktonic dinoflagellates Azadinium and Amphidoma (Amphidomataceae). A survey was conducted in 2018 to increase knowledge on the diversity and distribution of amphidomatacean species and their toxins in Irish and North Sea waters (North Atlantic). We here present a detailed morphological, phylogenetic, and toxinological characterization of 82 new strains representing the potential AZA producers Azadinium spinosum and Amphidoma languida. A total of ten new strains of Am. languida were obtained from the North Sea, and all conformed in terms of morphology and toxin profile (AZA-38 and-39) with previous records from the area. Within 72 strains assigned to Az. spinosum there were strains of two distinct ribotypes (A and B) which consistently differed in their toxin profile (dominated by AZA-1 and -2 in ribotype A, and by AZA-11 and -51 in ribotype B strains). Five strains conformed in morphology with Az. spinosum, but no AZA could be detected in these strains. Moreover, they revealed significant nucleotide differences compared to known Az. spinosum sequences and clustered apart from all other Az. spinosum strains within the phylogenetic tree, and therefore were provisionally designated as Az. cf. spinosum. These Az. cf. spinosum strains without detectable AZA were shown not to cause amplification in the species-specific qPCR assay developed to detect and quantify Az. spinosum. As shown here for the first time, AZA profiles differed between strains of Az. spinosum ribotype A in the presence/absence of AZA-1, AZA-2, and/or AZA-33, with the majority of strains having all three AZA congeners, and others having only AZA-1, AZA-1 and AZA-2, or AZA-1 and AZA-33. In contrast, no AZA profile variability was observed in ribotype B strains. Multiple AZA analyses of a period of up to 18 months showed that toxin profiles (including absence of AZA for Az. cf. spinosum strains) were consistent and stable over time. Total AZA cell quotas were highly variable both among and within strains, with quotas ranging from 0.1 to 63 fg AZA cell-1. Cell quota variability of single AZA compounds for Az. spinosum strains could be as high as 330-fold, but the underlying causes for the extraordinary large variability of AZA cell quota is poorly understood.

Description: Azaspiracids (AZA) are a group of lipophilic toxins, which are produced by a few species of the marine nanoplanktonic dinoflagellate genera Azadinium and Amphidoma (Amphidomataceae). Amphidomataceae were found to be globally distributed in coastal waters and new areas of occurrence are regularly discovered. The AZA toxins accumulate mainly in shellfish and - when consumed by humans - can lead to the so-called azaspiracid shellfish poisoning syndrome (AZP). Given this serious threat to seafood production and to deepen knowledge about the distribution and risk potential of AZA-producing algae, an appropriate detection method enabling a fast identification and quantification for these toxigenic species is needed. Traditional light microscopy is time-consuming, requires expertise and is getting rather difficult when it comes to the detection, identification and quantification of small-sized plankton. To overcome this challenges, quantitative real-time PCR (qPCR) assays are increasingly used as a molecular additive. Basically, when amplifying the extracted DNA and using DNA standards, the amplification threshold (CT) gives information about the number of target species in the sample. For two AZA-producing species, Azadinium spinosum and Azadinium poporum, quantitative PCR assays have already been developed and successfully applied in the field. Another AZA-producing species, Amphidoma languida, was discovered in 2012 in Irish coastal waters and discovered as a new species within the group of Amphidomataceae - in close relationship with Azadinium spp. All available strains from Ireland, Iceland, Norway, Denmark and Spain produce azaspiracids. Moreover, Am. languida from the Atlantic coast of southern Spain was responsible for AZA amounts in shellfish above the EU regulatory limit, emphasizing the need for further investigations. We thus developed a quantitative TaqMan PCR assay, amplifying 60bp of the D2 region (located on the LSU/28S) of the ribosomal DNA (rDNA) to detect toxic Am. languida. To confirm assay specificity in vitro, cross-reactivity tests with DNA of a variety of related organisms were performed. This included 12 different Am. languida strains as positive controls, Amphidoma parvula, 10 Azadinium species (each including different strains), as well as 10 further related dinoflagellate species (Alexandrium spp., Gymnodinium spp., Heterocapsa spp., Karlodinium sp., Prorocentrum spp. & Scripsiella sp.). The developed probe and primer set successfully detected only A. languida strains. Currently, we perform tests of the newly-designed assay on spiked field samples to test and optimize the quantification ability of the assay. With this assay, we provide a tool for the rapid and distinctive quantification of the toxic dinoflagellate Amphidoma languida to be used in monitoring programs and bio-geographic studies.

Description: Planktonic dinophyte species of the familiy Amphidomataceae attract attention as producers of azaspiracids, lipophilic phycotoxins that accumulate in shellfish and cause human health problem for shellfish consumers. About 30 species are describe, which are small and difficult to differentiate with routine light microscopy. These group of species is thus an obvious case where molecular methods for detection and quantification are needed. An overview is given on the state of the art and current use of qPCR assays for Amphidomataceae (Dinophyceae). New challanges related to quantification and assay specificity due to the continuously increasing diversity of species and strains are highlighted and discussed.

Description: Representatives of the marine dinophyte family Amphidomataceae produce lipophilic phycotoxins called azaspiracids (AZA) which may cause azaspiracid shellfish poisoning (AZP) in humans after consumption of contaminated seafood. Three of the four known toxigenic species are observed frequently in the eastern North Atlantic. In 2018, a research survey was performed to strengthen knowledge on the distribution and abundance of toxigenic Amphidomataceae and their respective toxins in Irish coastal waters and in the North Sea. Species-specific quantification of the three toxigenic species (Azadinium spinosum, Azadinium poporum and Amphidoma languida) was based on recently developed qPCR assays, whose performance was successfully validated and tested with specificity tests and spike experiments. The multi-method approach of on-board live microscopy, qPCR assays and chemical AZA-analysis revealed the presence of Amphidomataceae in the North Atlantic including the three targeted toxigenic species and their respective AZA analogues (AZA-1, -2, -33, -38, -39). Azadinium spinosum was detected at the majority of Irish stations with a peak density of 8.3 x 104 cells L-1 and AZA (AZA-1, -2, -33) abundances up to 1,274 pg L-1. Amphidoma languida was also present at most Irish stations but appeared in highest abundance in a bloom at a central North Sea station with a density of 1.2 x 105 cells L-1 and an AZA (AZA-38, -39) abundances of 618 pg L-1. Azadinium poporum was detected sporadically at the Irish south coast and North Sea and was rather low in abundance during this study. The results confirmed the wide distribution and frequent occurrence of the target species in the North Atlantic area and revealed, for the first time, bloom abundances of toxigenic Amphidomataceae in this area. This emphasizes the importance of future studies and monitoring of amphidomatacean species and their respective AZA analogues in the North Atlantic.

Description: Species of the planktonic dinoflagellates Azadinium and Amphidoma are small, inconspicuous and difficult, if not impossible to be identified and differentiated by light microscopy. Within this group, there are some species that produce the marine biotoxin azaspiracid (AZA) while others are non-toxigenic, therefore a requirement exists for precise species identification. A quantitative polymerase chain reaction (qPCR) assay for molecular detection and quantification of one of the toxigenic species, Amphidoma languida, was designed and extensively tested. The assay was highly specific and sensitive to detect and quantify down to 10 target gene copies (corresponding to ca. 0.05 cells) per reaction. DNA cell quota and copy number cell−1 were constant for four different Am. languida strains, and for one strain they were shown to be stable at various time points throughout the growth cycle. Recovery of known cell numbers of Am. languida spiked into natural samples was 95–103%, and the assay was successfully tested on field samples collected from Irish coastal waters. This new qPCR assay is a valuable tool for routine monitoring for the prevention of AZA-shellfish-poisoning caused by the consumption of contaminated shellfish and is a supportive tool for studies on the biogeography of this AZA-producing species.

Description: Shellfish contamination with azaspiracids (AZA), which are lipophilic marine biotoxins produced by marine dinoflagellates, is a major and recurrent problem for the Irish shellfish industry. AZA are produced by certain species of Amphidomataceae, but the species diversity of this group of microalgae in Irish waters is poorly known. Here we present a morphological and molecular characterization of multiple new strains of non-toxigenic Azadinium isolated on an oceanographic survey in 2018. A lack of AZA production for all strains presented here was demonstrated by LC-MS/ MS analysis. One strain of Azadinium caudatum var. margalefii (first strain for the area) confirmed nontoxigenicity of Atlantic populations of this species. One strain designated as Azadinium cf. zhuanum was similar to Az. zhuanum described from China but differed from the type strain in nucleus position, by the dominant number of apical plates, and by significant differences in rRNA gene sequences. Finally, two new non-toxigenic Azadinium species are described from the North East Atlantic: Azadinium galwayense sp. nov. and Azadinium perfusorium sp. nov. Azadinium galwayense differed from other Azadinium by a characteristic combination regarding presence and location of the ventral pore (vp; on the right side of the pore plate), of a pyrenoid (located in the episome), and by a pentagonal shape of the median anterior intercalary plate 2a, and lack of contact between plates 1´´ and 1a. Azadinium perfusorium shared the same vp position as Az. galwayense and differed by a characteristic combination of a pyrenoid located in the hyposome, a tetragonal shape of plate 2a, and a relatively large size of the two lateral anterior intercalary plates. Molecular phylogeny confirmed the distinctiveness of these two new species and their placement in Azadinium. The present findings significantly increased knowledge on the diversity of Azadinium species in the North East Atlantic.

Description: The IOC-ICES-PICES Harmful Algal Event Database (HAEDAT) was used to describe the diversity and spatiotemporal distribution of harmful algal events along the Atlantic margin of Europe from 1987 - 2018. The majority of events recorded are caused by Diarrhetic Shellfish Toxins (DSTs). These events are recorded annually over a wide geographic area from southern Spain to northern Scotland and Iceland, and are responsible for annual closures of many shellfish harvesting areas. The dominant causative dinoflagellates, members of the morphospecies ‘Dinophysis acuminata complex’ and D. acuta, are common in the waters of the majority of countries affected. There are regional differences in the causative species associated with PST events; the coasts of Spain and Portugal with the dinoflagellates Alexandrium minutum and Gymnodinium catenatum, north west France/south west England/south Ireland with A. minutum, and Scotland/Faroe Islands/Iceland with A. catenella. This can influence the duration and spatial scale of PST events as well as the toxicity of shellfish. The diatom Pseudo-nitzschia australis is the most widespread Domoic Acid (DA) producer, with records coming from Spain, Portugal, France, Ireland and the UK. Amnesic Shellfish Toxins (ASTs) have caused prolonged closures for the scallop fishing industry due to the slow depuration rate of DA. Amendments to EU shellfish hygiene regulations introduced between 2002 and 2005 facilitated end-product testing and sale of adductor muscle. This reduced the impact of ASTs on the scallop fishing industry and thus the number of recorded HAEDAT events. Azaspiracids (AZAs) are the most recent toxin group responsible for events to be characterised in the ICES area. Events associated with AZAs have a discrete distribution with the majority recorded along the west coast of Ireland. Ciguatera Poisoning (CP) has been an emerging issue in the Canary Islands and Madeira since 2004. The majority of aquaculture and wild fish mortality events are associated with blooms of the dinoflagellate Karenia mikimotoi and raphidophyte Heterosigma akashiwo. Such fish killing events occur infrequently yet can cause significant mortalities. Interannual variability was observed in the annual number of HAEDAT areas with events associated with individual shellfish toxin groups. HABs represent a continued risk for the aquaculture industry along the Atlantic margin of Europe and along the Atlantic margin of Europe and should be accounted for when considering expansion of the industry or operational shifts to offshore areas.

Description: The marine dinoflagellate Alexandrium Halim represents perhaps the most significant and intensively studied genus with respect to species diversity, life history strategies, toxigenicity, biogeographical distribution, and global magnitude and consequences harmful algal blooms (HABs). The socioeconomic impacts, environmental and human health risks, and mitigation strategies for toxigenic Alexandrium blooms have also been explored in recent years. Human adaptive actions based on future scenarios of bloom dynamics and shifts in biogeographical distribution under climate-change parameters remain under development and not yet implemented on a regional scale. In the CoCliME (Co-development of climate services for adaptation to changing marine ecosystems) project these issues were addressed with respect to past, current and anticipated future status of key HAB genera and expected benefits of enhanced monitoring. Data on the distribution and frequency of Alexandrium blooms related to paralytic shellfish toxin (PST) events from key CoCliME Case Study areas, comprising the North Sea and adjacent Kattegat-Skagerrak, Norwegian Sea, and Baltic Sea, and eastern North Atlantic marginal seas, were evaluated in a contemporary and historical context over the past several decades. The first evidence of possible biogeographical expansion of Alexandrium taxa into eastern Arctic gateways was provided from DNA barcoding signatures. Various key climate change indicators, such as salinity, temperature, and water-column stratification, relevant to Alexandrium bloom initiation and development were identified. The possible influence of changing variables on bloom dynamics, magnitude, frequency and spatial and temporal distribution were interpreted in the context of regional ocean climate models. These climate change impact indicators may play key roles in selecting for the occurrence and diversity of Alexandrium species within the broader microeukaryote communities. For example, shifts to higher temperature and lower salinity regimes predicted for the southern North Sea indicate the potential for increased Alexandrium blooms, currently absent from this area. Ecological and socioeconomic impacts of Alexandrium blooms and effects on fisheries and aquaculture resources and coastal ecosystem function are evaluated, and, where feasible, effective adaptation strategies are proposed herein as emerging climate services.

Description: The diatom Pseudo-nitzschia H. Peragallo is perhaps the most intensively researched genus of marine pennate diatoms, with respect to species diversity, life history strategies, toxigenicity, and biogeographical distribution. The global magnitude and consequences of harmful algal blooms (HABs) of Pseudo-nitzschia are particularly significant because of the high socioeconomic impacts and environmental and human health risks associated with the production of the neurotoxin domoic acid (DA) among populations of many (although not all) species. This has led to enhanced monitoring and mitigation strategies for toxigenic Pseudo-nitzschia blooms and their toxins in recent years. Nevertheless, human adaptive actions based on future scenarios of bloom dynamics and proposed shifts in biogeographical distribution under climate-change regimes have not been implemented on a regional scale. In the CoCliME (Co-development of climate services for adaptation to changing marine ecosystems) program these issues were addressed with respect to past, current and anticipated future status of key HAB genera such as Pseudo-nitzschia and expected benefits of enhanced monitoring. Data on the distribution and frequency of Pseudo-nitzschia blooms in relation to DA occurrence and associated amnesic shellfish toxin (AST) events were evaluated in a contemporary and historical context over the past several decades from key northern CoCliME Case Study areas. The regional studies comprised the greater North Sea and adjacent Kattegat-Skagerrak and Norwegian Sea, eastern North Atlantic marginal seas and Arctic gateways, and the Baltic Sea. The first evidence of possible biogeographical expansion of Pseudo-nitzschia taxa into frontier eastern Arctic gateways was provided from DNA barcoding signatures. Key climate change indicators, such as salinity, temperature, and water-column stratification were identified as drivers of upwelling and advection related to the distribution of regional Pseudo-nitzschia blooms. The possible influence of changing variables on bloom dynamics, magnitude, frequency and spatial and temporal distribution were interpreted in the context of regional ocean climate models. These climate change indicators may play key roles in selecting for the occurrence and diversity of Pseudo-nitzschia species within the broader microeukaryote communities. Shifts to higher temperature and lower salinity regimes predicted for the southern North Sea indicate the potential for high-magnitude Pseudo-nitzschia blooms, currently absent from this area. Ecological and socioeconomic impacts of Pseudo-nitzschia blooms are evaluated with reference to effects on fisheries and mariculture resources and coastal ecosystem function. Where feasible, effective adaptation strategies are proposed herein as emerging climate services for the northern CoCLiME region.