Azaspiracid accumulation, detoxification and biotransformation in blue mussels (Mytilus edulis) experimentally fed Azadinium spinosum

Jauffrais, Thierry; Marcaillou, Christiane; Herrenknecht, Christine; Truquet, Philippe; Sechet, Véronique; Nicolau, Élodie; Tillmann, Urban; Heß, Philipp

doi:10.1016/j.toxicon.2012.04.351

Cited by 59 publications

(70 citation statements)

References 49 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A second set of samples from 2006 from South-West Ireland (significant year in terms of a major azaspiracid event) were also analysed via molecular methods, and again as in the Killary data set, there was a presence of A. spinosum corresponding with rapid increases in azaspiracid intoxification in mussels in the same locality. This has also been observed in earlier laboratory feeding experiments 21,41 where toxin levels rose rapidly in test shellfish in There remain many questions regarding the spatial and temporal distribution of Azadinium.…”

Section: Temporal and Spatial Distributionsupporting

confidence: 71%

“…This indicates that there is an active biotransformation of the toxins in the digestive system of the mussels. These observations were subsequently confirmed, and AZA-17 and AZA19 were highlighted as two major metabolites of AZA1 and -2, respectively, over a week of contamination using A. spinosum at different cell concentrations 41 . These bioconversions pose a public health problem as AZA17 and -19 are currently not regulated (see Twiner et al, this book).…”

Section: Direct Transfer To Musselsmentioning

confidence: 60%

See 1 more Smart Citation

Gambierol: Synthetic Aspects

Fuwa¹

2014

Seafood and Freshwater Toxins

View full text Add to dashboard Cite

Section: Temporal and Spatial Distributionsupporting

confidence: 71%

Section: Direct Transfer To Musselsmentioning

confidence: 60%

Gambierol: Synthetic Aspects

Fuwa¹

2014

Seafood and Freshwater Toxins

View full text Add to dashboard Cite

“…It is noteworthy that new AZA-43 and AZA-3, which is a shellfish metabolite of AZA-1 (Jauffrais et al, 2012), are not only isobaric (i.e., possess the same molecular mass), but also have very close retention times (Fig. 8) implying the risk of misidentification.…”

Section: Toxinsmentioning

confidence: 99%

“…), blue mussel (Mytilus galloprovincialis), clams (Ruditapes decusssatus), Venerupis senegalensis, and razor clams (Solen marginatus), but AZA levels in Portugal were rather low (1.6-6.1 mg kg in the digestive gland of blue mussels (Taleb et al, 2006). Noteworthy, toxins are highly concentrated in the digestive gland but not as much in other shellfish tissue (Hess et al, 2005;Jauffrais et al, 2012) and thus, such values cannot directly be compared with the EU regulatory limit. In summer 2006, low levels of AZA (up to 6 mg kg À1 edible tissue) were reported from the same area about 180 km south of Casablanca (Elgarch et al, 2008).…”

mentioning

confidence: 99%

Amphidoma languida (Amphidomatacea, Dinophyceae) with a novel azaspiracid toxin profile identified as the cause of molluscan contamination at the Atlantic coast of southern Spain

Tillmann

Jaén²,

Fernandez³

et al. 2017

Harmful Algae

Self Cite

View full text Add to dashboard Cite

A B S T R A C TAzaspiracids (AZA) are a group of food poisoning phycotoxins that are known to accumulate in shellfish. They are produced by some species of the planktonic dinophycean taxon Amphidomataceae. Azaspiracids have been first discovered in Ireland but are now reported in shellfish from numerous global sites thus showing a wide distribution. In shellfish samples collected in 2009 near Huelva (Spain), AZA was also found along the Andalusian Atlantic coast for the first time. Analysis using LC-MS/MS revealed the presence of two different AZA analogues in different bivalve shellfish species (Chamelea gallina, Cerastoderma edule, Donax trunculus, and Solen vagina). In a number of samples, AZA levels exceeded the EU regulatory level of 160 mg AZA-1 eq. kg À1 (reaching maximum levels of >500 mg AZA-1 eq. kg À1 in Chamelea gallina and >250 mg AZA-1 eq. kg À1 in Donax trunculus) causing closures of some local shellfish production areas. One dinophyte strain established from the local plankton during the AZA contamination period and determined as Amphidoma languida was in fact toxigenic, and its AZA profile disclosed it as the causative species: it contained AZA-2 as the main compound and the new compound AZA-43 initially detected in the shellfish. AZA-43 had the same mass as AZA-3, but produced different collision induced dissociation (CID) spectra. High resolution mass spectrometric measurements indicated that there is an unsaturation in the H, I ring system of AZA-43 distinguishing it from the classical AZA such as AZA-1, -2, and -3. Furthermore, the Spanish strain was different from the previously reported AZA profile of the species that consist of AZA-38 and AZ-39. In molecular phylogenetics, the Andalusian strain formed a monophyletic group together with other strains of Am. languida, but ITS sequences data revealed surprisingly high intragenomic variability. The first Andalusian case of AZA contamination of shellfish above the EU regulatory limit reported here clearly revealed the risk of azaspiracid poisoning (AZP) for this area and also for the Atlantic coast of Iberia and North Africa. The present study underlines the need for continuous monitoring of AZA and the organisms producing such toxins.

show abstract

“…Contaminated shellfish can take many months, especially in winter, to depurate the HAB biotoxins. Depuration times can be highly variable and are likely related to food availability among other things, such as the metabolic rate of the bivalves (Marcaillou et al, 2010;Jauffrais et al, 2012). A HAB warning system will give farmers the opportunity to extract product before long closures occur.…”

Section: Hab Warningmentioning

confidence: 99%

Ocean modelling for aquaculture and fisheries in Irish waters

et al. 2016

View full text Add to dashboard Cite

Abstract. The Marine Institute, Ireland, runs a suite of operational regional and coastal ocean models. Recent developments include several tailored products that focus on the key needs of the Irish aquaculture sector. In this article, an overview of the products and services derived from the models are presented. The authors give an overview of a shellfish model developed in-house and that was designed to predict the growth, the physiological interactions with the ecosystem, and the level of coliform contamination of the blue mussel. As such, this model is applicable in studies on the carrying capacity of embayments, assessment of the impacts of pollution on aquaculture grounds, and the determination of shellfish water classes. Further services include the assimilation of the model-predicted shelf water movement into a new harmful algal bloom alert system used to inform end users of potential toxic shellfish events and high biomass blooms that include fish-killing species. Models are also used to identify potential sites for offshore aquaculture, to inform studies of potential cross-contamination in farms from the dispersal of planktonic sea lice larvae and other pathogens that can infect finfish, and to provide modelled products that underpin the assessment and advisory services on the sustainable exploitation of the resources of marine fisheries. This paper demonstrates that ocean models can provide an invaluable contribution to the sustainable blue growth of aquaculture and fisheries.

show abstract

Azaspiracid accumulation, detoxification and biotransformation in blue mussels (Mytilus edulis) experimentally fed Azadinium spinosum

Cited by 59 publications

References 49 publications

Gambierol: Synthetic Aspects

Gambierol: Synthetic Aspects

Amphidoma languida (Amphidomatacea, Dinophyceae) with a novel azaspiracid toxin profile identified as the cause of molluscan contamination at the Atlantic coast of southern Spain

Ocean modelling for aquaculture and fisheries in Irish waters

Contact Info

Product

Resources

About