The first evidence of paralytic shellfish toxins in the fresh water cyanobacterium Cylindrospermopsis raciborskii, isolated from Brazil.

The blooms of toxic cyanobacteria (blue-green algae) are causing problems in many countries. During a screening of toxic freshwater cyanobacteria in Brazil, three strains isolated from the State of Sao Paulo were found toxic by the mouse bioassay. They all were identified as Cylindrospermopsis raciborskii by a close morphological examination. Extracts of cultured cells caused acute death to mice when injected intraperitoneally after developing neurotoxic symptoms which resembled to those caused by paralytic shellfish toxins. The analysis of the sample by HPLC-FLD postcolumn derivatization method for paralytic shellfish toxins resulted in the detection of several saxitoxin analogs. To avoid being misled by false peaks, the sample was reanalyzed after purification and also under the different postcolumn derivatizing conditions. Finally, the newly developed LC-MS method for paralytic shellfish toxins was applied to unambiguously identify the toxins. One isolate produced neosaxitoxin predominantly with saxitoxin as a minor component. The other two showed identical toxin profiles containing saxitoxin and gonyautoxins 2/3 isomers in the ratio of 1:9. This is the first evidence of paralytic shellfish toxins in this species and also the occurrence of the toxin producing cyanobacterium in South American countries.     

Paralytic shellfish poison (saxitoxin family) bioassays: automated endpoint determination and standardization of the in vitro tissue culture bioassay, and comparison with the standard mouse bioassay.

Mouse neuroblastoma cells swell and eventually lyse upon exposure to veratridine, which, when added together with ouabain, enhances sodium ion influx. In the presence of saxitoxin (STX), which blocks sodium channels, the action of the other two compounds is inhibited and the cells remain morphologically normal. A tissue culture bioassay using mouse neuroblastoma cells, developed by Kogure and colleagues, takes advantage of these principles; in this bioassay, the fraction of the cells protected from the actions of ouabain and veratridine is in direct proportion to the concentration of STX and its analogues. We have modified this bioassay, improving its convenience and speed by eliminating the need to count individual cells to determine the saxitoxin equivalents, and instead have employed a microplate reader for automated determinations of absorbances of crystal violet from stained neuroblastoma cells. When these changes and other minor technical modifications were tested in the tissue culture bioassay systematically, we found the lower detection limit to be around 10 ng STX equivalents (eq) per ml of extract ( = 2.0 micrograms STX eq/100 g shellfish tissue). Our version of the tissue culture bioassay was compared with the standard mouse bioassay using 10 acid extracts of dinoflagellates (Alexandrium excavata and A. fundyense) and 47 AOAC extracts of shellfish tissues. The tissue culture bioassay provided results virtually identical to those obtained with the mouse bioassay (r > 0.96), and moreover, was considerably more sensitive. The results gained from high performance liquid chromatographic (HPLC) analysis of 12 of the same extracts were less consistent when compared with the results from both bioassay methods. The automated tissue culture (neuroblastoma cell) bioassay may be a valid alternative to live animal testing for paralytic shellfish poisoning.     

Adopting alternatives for the regulatory monitoring of shellfish for paralytic shellfish poisoning in Canada: Interface between federal regulators, science and ethics

To ensure the safety of Canada’s shellfish, the Canadian Shellfish Sanitation Program (CSSP) relies on the mouse bioassay to detect toxins known to cause paralytic shellfish poisoning (PSP). This assay uses a large number of mice and requires death as an endpoint. Canadian research has led to the development of a pre-column High Performance Liquid Chromatography (HPLC) method that is more sensitive and more reliable than the mouse bioassay. However, it is not being used by Canadian regulators despite its acceptance by the AOAC and adoption by the United Kingdom. An ethnography study of stakeholders in the CSSP was conducted to determine the opportunities and obstacles to adopting analytical testing methods.The results of the study indicate that the major obstacles are a lack of certified reference materials (CRMs) and the direction of resources towards the development of new instrument-based methods rather than towards the refinement of the existing pre-column HPLC method for regulatory use. To move away from the mouse bioassay, Canada should invest in: basic research to develop a complete set of CRMs for PSP toxins; method refinement to increase sample throughput; and exercises to gain international acceptance of the pre-column HPLC method.     

Paralytic shellfish poisoning toxin profile of mussels Perna perna from southern Atlantic coasts of Morocco

During the monitoring programme of harmful algal blooms established along the south Atlantic coast of Morocco, a bimonthly determination of harmful algae and phycotoxins analysis in Perna perna was carried out from May 2003 to December 2004. Results of mouse bioassay (in organs and whole flesh) showed a seasonal evolution of paralytic shellfish poisoning (PSP) toxin. The mussel's contamination was associated with the occurrence in water of Alexandrium minutum.The PSP toxin profile obtained with high-performance liquid chromatography (HPLC/FD) revealed the dominance of gonyautoxins GTX2 and GTX3 and a minority of GTX1, GTX4 and saxitoxin (STX). This profile explains that the toxicity was mainly associated with A. minutum.     

A feasibility study into the provision of Paralytic Shellfish Toxins laboratory reference materials by mass culture of Alexandrium and shellfish feeding experiments

As the official control laboratory for biotoxin testing in England, Wales and Scotland, Cefas employs two approaches for the detection of Paralytic Shellfish Poisons (PSP) in bivalve shellfish: a qualitative HPLC method for oysters, whole king scallops and cockles (with PSP bioassay confirmation of positive HPLC samples) with subsequent quantitation of positive samples by mouse bioassay and a quantitative HPLC method for mussels (no PSP bioassay confirmation required). To aid the validation of the quantitative HPLC method for native oysters, Pacific oysters, cockles and king scallops and ultimately remove the need for the PSP bioassay for these species, appropriate contaminated shellfish matrices were required. As it was not possible to obtain naturally contaminated material for these species, shellfish were contaminated in-house through feeding experiments with high concentrations of Alexandrium species. A number of feeding experiments with two Alexandrium strains were performed successfully. The contaminated shellfish materials generated contained a number of different profiles of PSP toxins.This work has demonstrated the feasibility of these methods for the production of laboratory reference materials in a variety of bivalve shellfish species. Based on this study laboratory reference material production via these methods is now undertaken routinely within Cefas. By running two concurrent feeding trials per year for each species, enough laboratory reference material is produced for approximately 1 year of the programme. This removes the necessity for natural contaminated material which is not always available for reference material production. Additionally, such materials enable both the comparative testing of different PSP methodologies and the ongoing generation of long-term precision data for the HPLC method.     

Detection of paralytic shellfish poisoning (PSP) toxins in shellfish tissue using MIST Alert, a new rapid test, in parallel with the regulatory AOAC mouse bioassay.

In parallel trials with the mouse bioassay, MIST Alert for Paralytic Shellfish Poisoning (PSP), a rapid diagnostic test for PSP, detected 100% of the toxic extracts in over 2100 regulatory samples. Toxic extracts contained at least 80 microg saxitoxin equivalents (STX equiv.) in 100 g of shellfish tissue, or more, as measured by the regulatory AOAC mouse bioassay. Only one potentially toxic sample, which contained 78 and 86 microg STX equiv./100 g shellfish tissue in two different mouse bioassays, was recorded as negative in one replicate of MIST Alert. All other toxic extracts among more than 2100 regulatory shellfish tissue samples were detected by MIST Alert for PSP. The MIST Alert for PSP also detected the majority of extracts containing PSP toxin greater than 32 microg STX equiv./100 g, which is the mouse bioassay detection limit. The MIST Alert for PSP gave a false positive result compared to the mouse bioassay at an average rate of about 14% over all sites, although some differences were seen between sites. Further analysis by high performance liquid chromatography (HPLC) of the (false positive) extracts showed that many contained PSP toxicity in the range of 20-40 microg STX equiv./100 g, below the level detectable by the mouse bioassay. The MIST Alert for PSP gave false positive results from extracts containing less than 20 microg STX equiv./100 g shellfish tissue only about 6% of the time. The PSP family of toxin analogues can occur in any combination in naturally contaminated shellfish tissue and the antibody mixture in the MIST Alert tests detect each of the different PSP toxin analogues with different efficacy. It is therefore impossible to provide an exact detection limit for the MIST Alert that would be applicable for all possible toxin profiles. Through the experience of comparison testing with the regulatory mouse bioassay in many parts of the world, with over 2100 different samples, the MIST Alert for PSP has proven its ability to detect all types of profiles of the PSP toxin analogues. The detection limit for MIST Alert for PSP was about 40 microg STX equiv./100 g for the 'average' profile of PSP toxin analogues. Since the detection limit depends on the toxin profile in the individual extract, it will also vary depending on the profile of analogues most commonly found at each geographic location. This was observed in our study. Over all sites in the trials, approximately 5% of samples below 40 microg STX equiv./100 g were positive, and 5% of samples between 40-80 microg STX equiv./100 g were negative. This is a reflection of the different analogue profiles found in naturally contaminated extracts, even after acid hydrolysis using the AOAC extraction method.     

A fluorimetric microplate assay for detection and quantitation of toxins causing paralytic shellfish poisoning

Paralytic shellfish poisoning is one of the most severe forms of food poisoning. The toxins responsible for this type of poisoning are metabolic products of dinoflagellates, which block neuronal transmission by binding to the voltage-gated Na(+) channel. Accumulation of paralytic toxins in shellfish is an unpredictable phenomenon that necessitates the implementation of a widespread and thorough monitoring program for mollusk toxicity. All of these programs require periodical collection and analysis of a wide range of shellfish. Therefore, development of accurate analytical protocols for the rapid determination of toxicity levels would streamline this process. Our laboratory has developed a fluorimetric microplate bioassay that rapidly and specifically determines the presence of paralytic shellfish toxins in many seafood samples. This method is based on the pharmacological activity of toxins and involves several steps: (i) Incubation of excitable cells in 96 well microtiter plates with the fluorescent dye, bis-oxonol, the distribution of which across the membrane is potential-dependent. (ii) Cell depolarization with veratridine, a sodium channel-activating toxin. (iii) Dose-dependent inhibition of depolarization with saxitoxin or natural samples containing paralytic shellfish toxins. Measuring toxin-induced changes in membrane potential allowed for quantification and estimation of the toxic potency of the samples. This new approach offers significant advantages over classical methods and can be easily automated.     

Investigations into matrix components affecting the performance of the official bioassay reference method for quantitation of paralytic shellfish poisoning toxins in oysters

Significant differences previously observed in the determination of paralytic shellfish poisoning toxins (PSTs) in oysters using official method AOAC 2005.06 and 959.08 were investigated in detail with regard to possible matrix effects. Method AOAC 2005.06 gave results 2-3 times higher than the mouse bioassay method, 959.08, differences thought to be due to underestimation of PSTs by the mouse bioassay. In order to prove the cause of these large differences, work was conducted here to examine the presence and effects of matrix components on the performance of each of the two assays. A range of oyster, cockle and mussel samples were extracted using the AOAC 959.08 hydrochloric acid (HCl) extraction method and analysed for PSP by both MBA and LC-FLD. In addition, extracts were analysed by Inductively Coupled Plasma Mass Spectrometry (ICP-MS) for metals as well as being subjected to a range of nutritional testing methods. Whilst there was no evidence for effect of nutritional components on either assay, ICP-MS analysis revealed a relationship between samples exhibiting the largest differences in relative method performance, specifically those with the largest LC-FLD/MBA toxicity ratio, and samples containing the highest concentrations of zinc and manganese. In order to prove the potential effect of the metals on either the LC-FLD and/or MBA assays, HCl extracts of a range of shellfish were subjected to a number of matrix modifications. Firstly, a number of PSP-positive oyster samples were processed to reduce the concentrations of metals within the extracts, without significantly reducing the concentrations of PSTs. Secondly, a range of mussel and cockle extracts, plus a standard solution of saxitoxin di-hydrochloride were spiked at variable concentrations of zinc. All treated and non-treated extracts, plus a number of controls were subjected to ICP-MS, LC-FLD and MBA testing. Results proved the absence of any effect of metals on the performance of the LC-FLD, whilst showing a large suppressive effect of the metals on the MBA. As such, the results show the performance of the official MBA is potentially unsafe for application to the routine monitoring of PSP toxicity in oysters or in any other shellfish found to contain high concentrations of metal ions.     

Can general anaesthesia be used for the Paralytic Shellfish Poison bioassay?

The current method for Paralytic Shellfish Poisoning (PSP) testing in shellfish is based on the mouse bioassay (MBA), which involves injecting shellfish extract into a conscious mouse, and then converting its time to death into PSP toxicity using Sommer's table. To improve animal welfare, the present study investigated the use of anaesthesia. A saxitoxin (STX) calibration study was conducted where known amounts of STX were injected into both unanaesthetised and anaesthetised mice. Death time was approximately doubled when mice were anaesthetised. Both unanaesthetised and anaesthetised animals showed a linear relationship between the inverse death time and log(STX). Based on these data, new calibration curves were developed. This study revealed that the current method employing Sommer's table underestimates toxicity by up to 50% for higher toxin levels. Subsequently, shellfish samples were tested on both unanaesthetised and anaesthetised mice. Using the new calibration curves, the numbers of samples exceeding the field closure limit were similar for unanaesthetised and anaesthetised mice, and were nearly two-fold higher than those obtained with the current method. The studies showed that the bioassay gives variable results for both unanaesthetised and anaesthetised animals. Anaesthesia forms a viable and more ethical alternative to the current bioassay, at least in the short term. A practical summary on how to conduct this method is given.     

Study of paralytic shellfish poisoning toxin profile in shellfish from the Mediterranean shore of Morocco

Since 1992, a monitoring program for bivalve molluscs contaminated by algal toxins was established at different stations along the Mediterranean Moroccan shores. The monitored stations were tested every 2 weeks. The presence of toxicity was determined using the mouse bioassay method. Toxin profile was carried out by HPLC/FD in selected contaminated tissues. According to the outcomes of this surveillance from 1994 to 1999, reliable information on toxicity of shellfish was obtained. They indicate that PSP is a recurrent toxicity in molluscs along the Mediterranean shore of Morocco. It has been noted a difference of PSP accumulation among individual shellfish. The cockle (Achanthocardia tuberculatum) presents toxicity throughout the year, while other specimens from the same area such as clam (Callista chione), warty venus (Venus gallina) and marine beans (Donax trunculus) accumulate it seasonally from January to April, after which they depurate the toxin. Moreover, the study of toxin profiles among individual shellfish was undertaken. It was found that shellfish presented a complex profile pointing to contamination by Gymnodinium catenatum.     

A rapid and sensitive assay for paralytic shellfish poison (PSP) toxins using mouse brain synaptoneurosomes.

A membrane potential assay using mouse brain synaptoneurosomes was evaluated for the determination of paralytic shellfish poison (PSP) toxin content of mussels and other bivalve species important to the shellfish industry. The assay relies on the ability of PSP toxins to block veratridine-induced depolarization of synaptoneurosomes. Changes in the membrane potential of synaptoneurosomes were monitored using the voltage-sensitive fluorescent probe rhodamine 6G. Standard saxitoxin was found to be a potent inhibitor of the membrane depolarizing effects of the sodium channel activator veratridine (I(50) ca. 4 nM). Likewise, shellfish extracts containing PSP toxins inhibited veratridine-induced depolarization. Neither saxitoxin or shellfish extracts had any discernible effect on the resting membrane potential of synaptoneurosomes. When synaptoneurosomal results for extracts of mussels (n=120) and other shellfish (n=29) were correlated with official mouse toxicity assay data there was very good agreement (r(2)=0.84 and 0.86, respectively), indicating that the in vitro assay has utility for a variety of commercially relevant shellfish species. Our investigation suggests that the mouse synaptoneurosome assay is of similar sensitivity to the official CD1 mouse toxicity assay. The synaptoneurosome fraction can be prepared quickly (approx. 40 min) and an individual assay takes less than 7 min. Since 20 such assays can be performed using material from a single CD1 mouse brain, there is considerable opportunity for reducing the number of animals required in conventional PSP monitoring while retaining the same animal system.     

A rapid detection method for paralytic shellfish poisoning toxins by cell bioassay.

We report here a rapid detection method for paralytic shellfish poisoning (PSP) toxins using a cultured neuroblastoma cell line, modified from the bioassay system previously established by Manger et al. [Manger, R.L., Leja, L.S., Lee, S.Y., Hungerford, J.M., Kirkpatrick, M.A., Yasumoto, T., Wekell, M.M., 2003. Detection of paralytic shellfish poison by rapid cell bioassay: antagonism of voltage-gated sodium channel active toxins in vitro. J. AOAC Int. 86 (3), 540-543]. In the present study, we made two major modifications to the previous method. The first is the use of maitotoxin, a marine toxin of ciguatera fish poisoning, which enables the incubation period to be reduced to 6 h when applied to the microplate 15 min prior to the end of the incubation. The second is the use of WST-8, a dehydrogenase detecting water-soluble tetrazolium salt for determining the target cell viability, which permits the omission of a washing step and simplifies the counting process. In addition, we attempted to reduce the required materials as much as possible. Thus, our modified method should be useful for screening the PSP-toxins from shellfish.     

Microtitre plate assay for paralytic shellfish toxins using saxiphilin: gauging the effects of shellfish extract matrices, salts and pH upon assay performance.

Saxiphilin is a hydrophilic protein with a high affinity and specificity for paralytic shellfish toxins (PSTs) found in the circulatory fluid of many invertebrates and ectothermic vertebrates. Saxiphilin has been found to be closely related to the iron binding transferrins, a group of proteins that range in molecular weight between 70 and 90 kDa. One saxiphilin isoform, that from the centipede Ethmostigmus rubripes, has been used to develop a microtitre plate assay for PSTs which relies upon detection of bound tritiated saxitoxin (STX). In this study, this assay was challenged with differing conditions of salt concentration and identity, pH and addition of non-toxic extracts of commercial shellfish prepared following the Association of Official Analytical Chemists endorsed procedure, elements the assay would encounter if used for PST monitoring and may compromise assay performance. The assay tolerated up to 15% of the total reaction, volume being shellfish extract before assay signal started to diminish. The presence of these extract matrices had little effect upon assay accuracy and precision when measuring STX, as a typical PST. Also, the detection of STX in the presence of shellfish matrices could be confidently reproduced on different days by different experimenters. The elements present in the shellfish extracts were measured by inductively coupled plasma spectroscopy, with the most common cationic elements being Na followed by K, Mg and Ca. Only trace amounts of other cationic elements were also present. From these results, the effects upon the assay by the four most common salts of these elements, NaCl, KCl, CaCl(2) and MgCl(2) were measured. Both NaCl and KCl did not impair assay performance at concentrations as high as 550 mM. It should be noted, however, that greater than 80 mM of either of these salts must be present in the assay for it to achieve the maximal signal. Adding CaCl(2) and MgCl(2) to the assay had dramatic effects upon performance. In the case of CaCl(2), the NaCl that was present in standard assay conditions enhanced its negative impact upon the assay. With MgCl(2), NaCl counteracted its inhibitory effect to some extent. After taking into account sample dilutions of shellfish extracts however, the potential for an interfering effect by Ca or Mg is minimal. A pH of 5.4 or less is necessary for there to be any significant impact upon the assay, with the assay signal being stable up to an alkaline pH as high as 9. Using the conditions herein, this assay can be used to reliably detect 1.3 microg STXeq/100 g shellfish tissue if it were to be used for monitoring for PST contaminated shellfish. These results demonstrate that this assay is a highly robust diagnostic tool for the measurement of PSTs in shellfish extracts.     

Studies in the use of magnetic microspheres for immunoaffinity extraction of paralytic shellfish poisoning toxins from shellfish

Paralytic shellfish poisoning (PSP) is a potentially fatal human health condition caused by the consumption of shellfish containing high levels of PSP toxins. Toxin extraction from shellfish and from algal cultures for use as standards and analysis by alternative analytical monitoring methods to the mouse bioassay is extensive and laborious. This study investigated whether a selected MAb antibody could be coupled to a novel form of magnetic microsphere (hollow glass magnetic microspheres, brand name Ferrospheres-N) and whether these coated microspheres could be utilized in the extraction of low concentrations of the PSP toxin, STX, from potential extraction buffers and spiked mussel extracts. The feasibility of utilizing a mass of 25 mg of Ferrospheres-N, as a simple extraction procedure for STX from spiked sodium acetate buffer, spiked PBS buffer and spiked mussel extracts was determined. The effects of a range of toxin concentrations (20-300 ng/mL), incubation times and temperature on the capability of the immuno-capture of the STX from the spiked mussel extracts were investigated. Finally, the coated microspheres were tested to determine their efficiency at extracting PSP toxins from naturally contaminated mussel samples. Toxin recovery after each experiment was determined by HPLC analysis. This study on using a highly novel immunoaffinity based extraction procedure, using STX as a model, has indicated that it could be a convenient alternative to conventional extraction procedures used in toxin purification prior to sample analysis.     

Bacterial degradation of paralytic shellfish toxins.

Bacteria isolated from the digestive tracts of blue mussels (Mytilus edulis) contaminated with paralytic shellfish toxins (PSTs) were screened for the ability to reduce the toxicity of a PST mixture in vitro. Bacteria were isolated on marine agar and grown in marine broth supplemented with a mussel extract and an algal extract containing PSTs (saxitoxin, neosaxitoxin, gonyautoxins 2 and 3, decarbamoyl-gonyautoxins 2 and 3 and C1/C2 toxins). Toxin levels were measured before and after 5d of incubation, using high performance liquid chromatography (HPLC) and reduction of overall toxicity verified by mouse bioassays. Of the 73 bacterial cultures screened, seven isolates were designated "competent" PST degraders, individually reducing the overall toxicity of the PSTs by at least 90% within 3d. Most isolates degraded 100% of the saxitoxin and neosaxitoxin within 1-3d. In all cases, the overall kinetics of degradation of the toxicities was first order, as were the individual degradation kinetics of most of the individual toxins. This is the first report of nearly complete elimination of PSTs through bacterial action and may perhaps result in the development of a practical means to eliminate or reduce the risk of PSP intoxication associated with shellfish consumption.     

Purification and characterization of paralytic shellfish toxin transforming enzyme from Mactra chinensis.

A carbamoylase, which catalyzes hydrolysis of the carbamoyl (or N-sulfocarbamoyl) moiety of paralytic shellfish toxins, was purified from the digestive glands of the Japanese clam Mactra chinensis. Using five steps of column chromatography, 290 microg of Carbamoylase I showing homogeneity on SDS-PAGE was obtained. Carbamoylase I was revealed to be a glycoprotein, having estimated molecular weight of 190 kDa. Observation of single band equivalent to 94 kDa on SDS-PAGE under reducing conditions suggested it to be a homodimer. The optimal temperature and pH were 20 degrees C and 7.0. Carbamoylase I did not require a divalent cation and its activity was inhibited by the serine proteinase inhibitors, benzenesulfonyl fluoride and 4-(2-aminoethyl)-benzenesulfonyl fluoride. Carbamoylase I hydrolyzed both carbamate and N-sulfocarbamate toxins. The presence or absence of a hydroxyl moiety at the N-1 position of the substrate toxins did not significantly alter the reaction rate, but the stereochemistry of sulfate esters at C-11 greatly affected it. The K(m) was 3.02 microM for saxitoxin as a substrate. Nineteen amino acids of the N-terminal sequence were identified by the Edman method. MALDI-TOF-MS/MS spectra of (18)O-labeled tryptic peptides indicated the possible internal amino acid sequences of five peptides.     

Paralytic shellfish toxin profiles and toxin variability of the genus Alexandrium (Dinophyceae) isolated from the Southeast China Sea.

Paralytic shellfish toxin (PST) profiles of 16 Alexandrium isolates from the Southeast China Sea were analyzed by high-pressure liquid chromatography. Toxin content and composition of three A. tamarense isolates, ATDH01, ATGX02 and ATMJ02, were also investigated at different growth phases and under various culture conditions. Our results showed that six strains of A. affine were non-toxic, while 10 strains of A. tamarense and A. catenella were toxic. These toxic isolates grown in the same culture conditions consistently produced an unusually high proportion of the N-sulfocarbamoyl toxin C1/2 (around 60-80% of total toxins) and medium amounts of gonyautoxin GTX5 (around 15-30% of total) with only trace quantities (<5% of total) of other saxitoxin derivatives (i.e. GTX1, GTX3, GTX4 and neoSTX). The toxin composition of three A. tamarense isolates did not vary with the growth phases, although higher toxin contents (Qt, fmolcell(-1)) were found in the exponential phase. Variations in temperature, salinity and nutrient levels affected toxin content of three A. tamarense isolates but they did not have pronounced effects on the toxin composition (mole %). These results indicate that toxin composition remained relatively constant under various culture conditions, suggesting that toxin composition could be used as a stable biomarker for the Alexandrium species in this region. However, comparison of toxin profiles between isolates from different localities require special caution since isolates even from the same region can have distinct toxin profiles.     

Development of a Method for Detecting Alexandrium pacificum Based on the Quantification of sxtA4 by Chip-Based Digital PCR

Alexandrium pacificum, which produces the paralytic shellfish toxin (PST) saxitoxin (STX), is one of the causative species of paralytic shellfish poisoning outbreaks in coastal areas of Korea. In this study, we developed a chip-based digital PCR (dPCR) method for A. pacificum detection and tested it for monitoring in Jinhae-Masan Bay. Using the sequence of an A. pacificum strain isolated in 2017, species-specific primers targeting sxtA4 (a STX biosynthesis-related gene) were designed and used in a dPCR, detecting 2.0 ± 0.24 gene copies per cell of A. pacificum. Cell abundance in field samples, estimated by a chip-based dPCR, was compared with the PST content, and measured using a mouse bioassay. A comparison with shellfish PST concentrations indicated that cell concentrations above 500 cells L⁻¹, as measured using the dPCR assay, may cause shellfish PST concentrations to exceed the allowed limits for PSTs. Concordance rates between dPCR and PST results were 62.5% overall in 2018–2021, reaching a maximum of 91.7% in 2018–2019. The sensitivity of the dPCR assay was higher than that of microscopy and sxtA4-based qPCRs. Absolute quantification by chip-based dPCRs targeting sxtA4 in A. pacificum exhibits potential as a complementary approach to mouse bioassay PST monitoring for the prevention of toxic blooms.     

Paralytic shellfish poisons produced by the freshwater cyanobacterium Aphanizomenon flos-aquae NH-5

A single filament clonal isolate of Aphanizomenon flos-aquae was made from a water bloom sample taken at a small pond near Durham, New Hampshire, in 1980. When batch cultured the strain was toxic to mice and had an i.p. LD50 of about 5.0 mg/kg. Using an extraction procedure originally designed for paralytic shellfish poisons and other neurotoxins of freshwater cyanobacteria, a purification method was developed. The procedure involved acidified water/ethanol extraction of the cells followed by ultrafiltration, gel filtration, use of C18 cartridges to remove pigments, ion-exchange and high performance liquid chromatography using u.v. detection at 220 or 240 nm. Thin-layer chromatography and high performance liquid chromatography results indicate that Aphanizomenon flos-aquae NH-5 may produce paralytic shellfish poisons, mainly neo-saxitoxin and saxitoxin. Three labile toxins were also detected which were not similar to any of the known paralytic shellfish poisons.