Michael A. Quilliam

AN OUTBREAK OF DOMOIC ACID POISONING ATTRIBUTED TO THE PENNATE DIATOM PSEUDONITZSCHIA AUSTRALIS1

A bloom of the pennate diatom Pseudonitzschia australis Frenguelli (= Nitzschia pseudoseriata Hasle) occurring in Monterey Bay, California, in early September 1991 coincided with an episode of mortality in brown pelicans (Pelicanus occidentalis) and Brandts cormorants (Phalacrocorax penicillatus). High levels of domoic acid (DA), the amnesic shellfish poisoning toxin, were recorded in the plankton samples. Furthermore, high levels of DA, as well as numerous remnants of P. australis frustules, were found in the stomach contents of affected birds and in the visceral contents of local anchovies, a principal food source of seabirds. This is the first confirmed report of DA poisoning since the original 1987 episode in Atlantic Canada caused by Nitzschia pungens Grunow forma multiseries Hasle. It suggests another species of planktonic pennate diatom is capable of producing DA and that herbivorous finfish can act as vectors for this toxin.

TRACE·DETERMINATION OF DOMOIC ACID IN SEAWATER AND PHYTOPLANKTON BY HIGH­ PERFORMANCE LIQUID CHROMATOGRAPHY OF THE FLUORENYLMETHOXYCARBONYL (FMOC) DERIVATIVE*

A method is presented for the trace determination of domoic acid, a neurotoxic amino acid responsible for cases of Amnesic Shellfish Poisoning resulting from the consumption of contaminated shellfish. The method involves pre-column derivatization with 9-fluorenylmethylchloroformate to form the FMOC derivative followed by reversed-phase HPLC with fluorescence detection. The detection limit for domoic acid in seawater and aqueous extracts is 15pg/mL (50pM) using gradient elution, a 20/lL injection volume, and a 2.1mm I.D. microbore column. Use of dihydrokainic acid as an internal standard improved quantitation. The method was applied to the detection of domoic acid in seawater, in phytoplankton cultures (Nitzschia pungens forma multiseries), and in natural mixed phytoplankton assemblages in estuarine waters.

HIGH-PERFORMANCE LIQUID CHROMATOGRAPHY OF DOMOIC ACID, A MARINE NEUROTOXIN, WITH APPLICATION TO SHELLFISH AND PLANKTON*

Abstract A recent outbreak of poisoning resulting from the consumption of cultured blue mussels (Mytilus edulis L.) from a localized area in Eastern Canada has been attributed to the presence of domoic acid (1), a relatively rare neurotoxic amino acid, previously found only in some algae of the family Rhodomelaceae. Studies on aqueous extracts of shellfish tissue indicated that the toxin and several of its isomers could be separated (and isolated in sufficient amounts for subsequent structural identification) by reversed-phase high-performance liquid chromatography (HPLC) with ultraviolet (UV) diode array detection (DAD). Aqueous acetonitrile containing 0.1% v/v trifluoroacetic acid was used as mobile phase. As the retention time and characteristic UV absorption spectrum of 1 (λmax = 242 nm) permit unequivocal identification, the HPLC-DAD procedure was refined with a microbore column to provide a rapid (5 min), sensitive (0.3 ng detection limit) and reproducible assay method for the determination of 1 in ...

Detection of new 7-O-acyl derivatives of diarrhetic shellfish poisoning toxins by liquid chromatography-mass spectrometry☆

A novel method for the detection of acylated diarrhetic shellfish poisoning toxins is reported. Direct determination of these compounds is possible using high performance liquid chromatography coupled with ion-spray mass spectrometry. An extract, purified from the digestive glands of toxic mussels (Mytilus edulis) contaminated with okadaic acid, dinophysistoxin-1, and a recently reported analog, dinophysistoxin-2, was also shown to contain small amounts of dinophysistoxin-3, a mixture of 7-O-acyl ester derivatives of dinophysistoxin-1. In addition, acyl ester derivatives of okadaic acid and dinophysistoxin-2 were also detected by direct LC-MS analysis and confirmed by analysis of their hydrolysis products. This is the first report of the detection of other naturally occurring 7-O-acyl esters similar to dinophysistoxin-3.

Discovery of new analogs of the marine biotoxin azaspiracid in blue mussels (Mytilus edulis) by ultra-performance liquid chromatography/tandem mass spectrometry.

Azaspiracids (AZAs) are a group of lipophilic marine biotoxins that were first discovered in blue mussels harvested in 1995 in Killary Harbour on the west coast of Ireland. At least eight people fell ill after the consumption of contaminated mussels and developed symptoms of nausea, stomach cramps, vomiting and severe diarrhoea. Until now, eleven different analogs of these toxins have been described, with a twelfth one theoretically postulated. This paper describes the detection and identification of twenty new analogs of azaspiracid, including dihydroxy-AZAs and carboxy-AZAs, using state-of-the-art techniques including ultra-performance liquid chromatography (UPLC) and tandem mass spectrometry (MS/MS). Blue mussels (Mytilus edulis) from a toxic event of the northwest coast of Ireland in 2005 were extracted and analysed using LC/MS. The mass spectra obtained from different instruments enabled identification of previously unknown analogs of azaspiracid with additional hydroxyl and carboxyl substituents. Mass fragmentation patterns of the dihydroxy-AZAs indicated the positions of these substituents to be at the C3 and C23 position. The previously theoretically postulated AZA12 was also observed in this study. Product ion spectra showed the presence of a unique fragment ion at m/z 408 for all C23-hydroxylated analogs. This fragmentation competes with the fragmentation leading to m/z 362, a fragment ion that has shown to be present in all AZAs. The novel analogs have not been seen in plankton or water samples and are believed to be metabolites of AZAs formed in mussels. All the new AZA analogs were present at low concentrations in the shellfish and it is probably safe to assume that they do not pose a risk for the shellfish consumer.

Spirolide composition of micro-extracted pooled cells isolated from natural plankton assemblages and from cultures of the dinoflagellate Alexandrium ostenfeldii

A novel micro-extraction technique was applied to the extraction of biologically active macrocyclic imines known as spirolides from pooled individual cells isolated from spirolide-rich plankton material. For comparison, this method was also applied to pooled individual cells isolated from a unialgal culture of the marine dinoflagellate Alexandrium ostenfeldii (Paulsen) Balech & Tangen, a species known to produce spirolides. Both athecate cells and motile forms of gonyaulacoid dinoflagellates derived from size-fractionated plankton material from Nova Scotia, Canada were sorted and pooled by the glass micropipette isolation technique and by flow cytometry. The development of a highly sensitive analytical method for spirolides (detection limit 2 ng ml(-1) for spirolide B) using liquid chromatography-mass spectrometry (LC-MS) and application to micro-extracted samples allowed the accurate determination of spirolide composition in as few as 50 cells. Total spirolide concentrations (fmol cell(-1)) calculated from pooled micropipette isolated cells were very consistent with those based upon bulk- or micro-extractions of A. ostenfeldii cells from unialgal batch cultures in exponential growth phase. The results of the pooled cell selection from field material from two sites in Nova Scotia confirmed the association of spirolides with vegetative cells of A. ostenfeldii and related athecate forms. Combining these techniques represents a highly sensitive method for the analysis of marine toxins within complex plankton matrices, even when the toxigenic species is in low abundance, by enrichment of the target organism.

Characterization of flame-generated C10 to C160 polycyclic aromatic hydrocarbons by atmospheric-pressure chemical ionization mass spectrometry with liquid introduction via heated nebulizer interface

Complex mixtures of polycyclic aromatic hydrocarbons (PAHs) generated from fuel-rich combustion of ethylene-naphthalene mixtures in a jet-stirred-plug-flow reactor were chemically characterized by combined mass spectrometric techniques to yield product composition data that cover the molecular mass region from simple PAHs (naphthalene, 128 u) to large molecules comparable in molecular size (1792 u) to nanoparticles of soot. Two techniques based on atmospheric-pressure chemical ionization mass spectrometry (APCI-MS) were investigated: (1) APCI-MS combined with high-performance liquid chromatography through a heated nebulizer interface was found suitable for PAHs up to C36 (448 u). (2) For the characterization of larger PAHs beyond C36, direct liquid introduction (DLI) of sample into an atmospheric-pressure chemical ionization mass spectrometer through a heated nebulizer gave protonated molecular ions for PAHs over the m/z 400–2000 range. Although unequivocal elemental composition information is unattainable from the unit-resolution DLI/APCI-MS data, by starting with structural data from identified C16 to C32 PAHs, and applying PAH molecular growth principles, it was possible to generate PAH molecular maps from the DLI/APCI-MS data from which values for the elemental composition could be derived for all major peaks.

Neural Injury Biomarkers of Novel Shellfish Toxins, Spirolides: A Pilot Study Using Immunochemical and Transcriptional Analysis

In 1991, routine biotoxin monitoring of bivalve molluscs at aquaculture sites along the eastern shore of Nova Scotia, Canada revealed a group of novel seafood toxins called spirolides, whose origin was the dinoflagellate Alexandrium ostenfeldii. Result from this preliminary study in rodents demonstrates a highly toxic lethal response in rats and mice after intraperitoneal injections of lipophilic extracts. To elucidate the modes of action and toxicologic pathology, brain and internal organs were examined by histology and various biomarkers of neural injury were monitored by immunohistochemistry (IH) and/or transcriptional analysis. The histological and transcriptional data showed that the effects of spirolides are species dependent for mice and rats. Histopathology showed that in the mouse brain, the hippocampus and brain stem appeared to be the major target regions but no histological changes were observed in the rat. Transcriptional analysis in the mouse brain showed no alterations in the biomarkers whereas in the rat brain there were major changes in the markers of neuronal injury. These biomarkers included the early injury markers HSP-72, c-jun and c-fos which are essential for converting stimuli into intracellular changes within neurons. The potential effects of spirolides were also evaluated with respect to different subtypes of the acetylcholine receptors (AChRs) since earlier reports showed these as putative targets. Both the muscarinic and nicotinic AChRs were found to be upregulated. Hence, transcriptional and immunohistochemical analysis does provide insight to the molecular mechanisms of this novel group of shellfish toxins. No histological changes were observed in other tissues.

The role of chromatography in the hunt for red tide toxins.

An overview is given of the different approaches that have been used to identify toxins responsible for seafood poisoning incidents, to investigate the origins of toxins, and to monitor seafood on a routine basis. It is shown that advancements in our knowledge of toxins and our ability to protect the public have often followed key developments in separation and analysis technologies. Specific examples of research in this field are presented to illustrate the significant role that chromatographic methods play. The presentation will be given in an order that reflects the typical sequence of investigations that follow a new toxin episode.

CONFIRMATION OF DOMOIC ACID PRODUCTION BY PSEUDO‐NITZSCHIA AUSTRALIS (BACILLARIOPHYCEAE) ISOLATED FROM IRISH WATERS1

A nonaxenic isolate of the potentially toxic diatom Pseudo‐nitzschia australis (Frenguelli) from Irish waters was tested in two separate batch culture experiments. When grown under a low irradiance (∼12 μmol photons·m−2·s− 1 ; 16:8‐h light:dark cycle) for up to 40 days, the culture produced only trace amounts of the neurotoxin domoic acid (DA) during late stationary phase. Growth at a higher irradiance (∼115 μmol photons·m−2·s− 1 ; 12:12‐h light:dark cycle) resulted in DA production starting during late exponential phase and reaching a maximum concentration of 26 pg DA·cell− 1 during late stationary phase. Liquid chromatography coupled to mass spectrometry was used to confirm the identity of DA in the culture. Irradiance and photoperiod could be important factors that contribute directly or indirectly to the control of DA production in P. australis. This is the first record of a DA‐producing diatom in Irish waters, and results indicate P. australis may have been the source of DA that has recently contaminated shellfisheries in this area.