Identification and characterization of a "biomarker of toxicity" from the proteome of the paralytic shellfish toxin-producing dinoflagellate Alexandrium tamarense (Dinophyceae)

The objective of this study was to identify and characterize a "biomarker of toxicity" from the proteome of Alexandrium tamarense, a paralytic shellfish toxin (PST)-producing dinoflagellate. A combination of 2-DE and MS approaches was employed to identify proteins of interest in the vegetative cells of several strains of A. tamarense with different toxin compositions and from different geographical locations. The electrophoretic analysis of the total water-soluble proteins from these toxic strains by 2-DE showed that several abundant proteins, namely AT-T1, AT-T2 and AT-T3, differing slightly in apparent Mr and pIs, were consistently present in all toxic strains of A. tamarense. Further analysis by MALDI-TOF MS and N-terminal amino acid sequencing revealed that they are isoforms of the same protein. Even more intriguing is that these proteins in A. tamarense have similar amino acid sequences and are closely related to a "biomarker of toxicity" previously reported in A. minutum. Unambiguous and highly species-specific identification was later achieved by comparing the PMFs of proteins in these two species. An initial attempt to characterize these proteins by generation of murine polyclonal antibodies against the AT-T1 protein was successful. Western blot analysis using the murine AT-T1-polycolonal antibodies identified all the toxic strains of A. tamarense and A. minutum, but not the nontoxic strain of A. tamarense. These results indicate that these protein characteristics for toxic strains are species-specific and that they are stable properties of the tested algae which are clearly distinguishable irrespective of geographical location and toxin composition. To our knowledge, this is the first study to demonstrate the use of polyclonal antibodies against marker proteins purified from 2-DE gels to distinguish different strains and species of the PST-producing dinoflagellate Alexandrium. It provides the basis for the production of monoclonal antibody probes against the "biomarkers of toxicity" for those dinoflagellates whose genome is incompletely characterized. Potentially, immunoassays could be developed to detect the presence of toxic algae in routine monitoring programs as well as to predict bloom development and movement.     

Characterization of nontoxic and toxin-producing strains of Alexandrium minutum (Dinophyceae) in Irish coastal waters

A comparative analysis of the morphology, toxin composition, and ribosomal DNA (rDNA) sequences was performed on a suite of clonal cultures of the potentially toxic dinoflagellate Alexandrium minutum Halim. These were established from resting cysts or vegetative cells isolated from sediment and water samples taken from the south and west coasts of Ireland. Results revealed that strains were indistinguishable, both morphologically and through the sequencing of the D1-D2 domain of the large subunit and the ITS1-5.8S-ITS2 regions of the rDNA. High-performance liquid chromatography fluorescence detection analysis, however, showed that only strains derived from retentive inlets on the southern Irish coast synthesized paralytic shellfish poisoning (PSP) toxins (GTX2 and GTX3), whereas all strains of A. minutum isolated from the west coast were nontoxic. Toxin analysis of net hauls, taken when A. minutum vegetative cells were in the water column, revealed no PSP toxins in samples from Killary Harbor (western coast), whereas GTX2 and GTX3 were detected in samples from Cork Harbor (southern coast). These results confirm the identity of A. minutum as the most probable causative organism for historical occurrences of contamination of shellfish with PSP toxins in Cork Harbor. Finally, random amplification of polymorphic DNA was carried out to determine the degree of polymorphism among strains. The analysis showed that all toxic strains from Cork Harbor clustered together and that a separate cluster grouped all nontoxic strains from the western coast.     

Effect of the endoparasite Amoebophrya sp. on toxin content and composition in the paralytic shellfish poisoning dinoflagellate Alexandrium fundyense (Dinophyceae)

Members of the Amoebophrya ceratii complex are endoparasitic dinoflagellates that parasitize a number of their dinoflagellate relatives, including toxic and/or harmful algal bloom-forming species. Despite many studies on the occurrence, prevalence, biology and molecular phylogeny of Amoebophrya spp., little attention has been given to toxin dynamics of host population following parasitism. Using Amoebophrya sp. infecting the paralytic shellfish toxin (PSP)-producing dinoflagellate Alexandrium fundyense, we addressed the following questions: (1) does parasitism by Amoebophrya sp. alter toxin content and toxin profiles of the dinoflagellate A. fundyense over the infection cycle? and (2) do parasite dinospores produced at the end of the infection cycle retain host toxins and thus potentially act as a vector to convey PSP toxin through the marine microbial food-web? Toxin time-course experiments showed that the PSP toxin contents did not vary significantly over the infection cycle, but mean toxin content for infected cultures was significantly higher than that for uninfected cultures. Host toxins were not detected in the free-living, dinospore stage of the parasite. Therefore, our results indicate that Amoebophrya sp. does not function as a vector for transferring PSP toxins to higher trophic levels. Rather, Amoebophrya infections appear to play an important role in maintaining healthy ecosystems by transforming potent toxins-producing dinoflagellates into non-toxic dinospores, representing “edible food” for consumers of the marine microbial food-web during toxic algal bloom event.     

A novel approach to identifying PST tolerant copepods: An individual ingestion assay

Phenotypic tolerance of individual copepods to paralytic shellfish toxins (PSTs), as determined by fecundity, has recently been reported. In the present study, we tested whether similar phenotypic tolerance related to ingestion also exists. In short-term feeding assays, ingestion rates of individual females of the copepod Acartia hudsonica were measured on a sole diet of toxic Alexandrium fundyense as well as on a sole diet of nontoxic Alexandrium tamarense. When copepods fed on A. fundyense, the frequency distribution of ingestion rates was polymodal, consistent with the hypothesis of levels of phenotypic tolerance associated with toxin ingestion. Four distinct groups of ingestion rates on toxic algae were observed. Mean rates ranged from near zero to more than 100 cells copepod⁻¹ h⁻¹. In contrast, when the same individuals fed on the nontoxic A. tamarense diet, the polymodal distribution of ingestion rates was not apparent. Furthermore, group-specific mean ingestion rates, for two ingestion-defined groups, were always significantly greater on the toxic diet than they were on the nontoxic diet. These results support the hypothesis that discrete groups of grazer ingestion of toxic A. fundyense are related to PST tolerance.     

中国东海和南海有害赤潮高发区麻痹性贝毒素研究

用小白鼠生物检测法和高效液相色谱法对采自浙江舟山和广东深圳海域贝类的麻痹性贝毒素进行了调查和分析,结果表明,舟山海域近岸的贝类毒素检出率为14％,染毒的贝类毒素含量不高,低于小白鼠生物检测法的测定范围;深圳近岸贝类毒素检出率为30％以上,华贵栉孔扇贝是主要的染毒贝类,有1个样品毒素含量达5．1Mu·g-1,超出安全食用标准．从深圳大亚湾华贵栉孔扇贝检测出10种麻痹性贝毒素成分,消化腺的主要毒素成分为GTXl+2和GTX5,Cl+2和GTX2+3,而剔除消化腺后其余贝组织的主要成分为neoSTX和GTX5．贝毒素主要积累在扇贝的消化腺内,消化腺含有的毒素是贝肉组织的8倍．     

Environmental drivers of paralytic shellfish toxin producing Alexandrium catenella blooms in a fjord system of northern Southeast Alaska

Paralytic shellfish poisoning (PSP) is a persistent problem that threatens human health and the availability of shellfish resources in Alaska. Regular outbreaks of marine dinoflagellates in the genus Alexandrium produce paralytic shellfish toxins (PSTs) that make shellfish consumption unsafe, and impose economic hardships on Alaska’s shellfish industry. Phytoplankton and environmental monitoring spanning 2008–2016, and a pilot benthic cyst survey in 2016, were focused in the Juneau region of Southeast Alaska to investigate Alexandrium catenella distributions and conditions favorable to bloom development. Overwintering Alexandrium cysts were found in near-shore sediments throughout the study region. Alexandrium catenella cells were present in the water column across a range of sea surface temperatures (7–15 °C) and surface salinities (S = 4–30); however, an optimal temperature/salinity window (10–13 °C, 18–23) supported highest cell concentrations. Measurable levels of PSTs were associated with lower concentrations (100 cells L⁻¹) of A. catenella, indicating high cell densities may not be required for shellfish toxicity to occur. Several interacting local factors were identified to support A. catenella blooms: 1) sea surface temperatures ≥7 °C; 2) increasing air temperature; 3) low to moderate freshwater discharge; and 4) several consecutive days of dry and calm weather. In combination, these bloom favorable conditions coincide with toxic bloom events during May and June in northern Southeast Alaska. These findings highlight how integrated environmental and phytoplankton monitoring can be used to enhance early warning capacity of toxic bloom events, providing more informed guidance to shellfish harvesters and resource managers in Alaska.     

High CO2 promotes the production of paralytic shellfish poisoning toxins by Alexandrium catenella from Southern California waters

In many dinoflagellates, cellular toxin levels have been demonstrated to increase when growth is limited by essential nutrients such as phosphorus. Despite the recognized importance of nutrient limitation to dinoflagellate toxicity, interactions with current and future global environmental change variables have been relatively unexplored. This is a critical question, as dissolution of anthropogenic CO₂ emissions into seawater is leading to progressively lower pH values, or ocean acidification. Sea surface temperatures are concurrently increasing, a trend that is also projected to continue in the future. We conditioned a clonal culture of paralytic shellfish poisoning toxin producing Alexandrium catenella (A-11c) isolated from coastal Southern California to factorial combinations of two temperatures, two pCO₂ levels, and two phosphate concentrations for a period of eight months. Interactions between these variables influenced growth and carbon fixation rates and although these treatments only elicited minor differences in toxin profile, total cellular toxicity was dramatically affected. Cells conditioned to high pCO₂ (levels projected for year 2075) and low phosphate at low temperature (15 °C) were the most toxic, while lower pCO₂, higher phosphate levels, and warmer temperature (19 °C) alleviated this toxicity to varying degrees. Overall increased pCO₂ generally led to enhanced potency. Our results suggest that future increased ocean acidification may exacerbate the toxic threat posed by this toxic dinoflagellate, especially when combined with nutrient limitation, but that future warmer temperatures could also offset some of this enhanced toxicity.     

Erratum to: Bacterial diversity in toxic<Emphasis Type="Italic"> Alexandrium tamarense</Emphasis> blooms off the Orkney Isles and the Firth of Forth

The genetic diversity of the bacterial community associated with Alexandrium tamarense blooms was studied in blooms of the toxic dinoflagellates in the waters around the Orkney Isles and the Firth of Forth (Scotland). For toxin and molecular analysis of the bacterial communities associated with the toxic bloom, water samples were taken in 1998 and 1999 from A. tamarense blooms. The bacterial community structure, as determined by DGGE (denaturing gradient gel electrophoresis) showed clear differences between all three investigated size fractions (dinoflagellate-associated bacteria, attached bacteria and free-living bacteria), with high diversity within each sample. DNA sequence analysis of the dominant and most frequent DGGE bands revealed the dominance of Proteobacteria, mainly of the Roseobacter clade, with similarities of 91–99%. Moreover, DGGE bands occurring at the same position in the gel throughout in most samples corroborate the presence of several specific Proteobacteria of the Roseobacter clade. Overall, 500 bacteria were isolated from the bloom and partly phylogenetically analysed. They were members of two prokaryotic phyla, the Proteobacteria and the Bacteroidetes, related to Proteobacteria of the and subdivisions (Alteromonas, Pseudoalteromonas and Colwellia). All bacteria were tested for the production of sodium channel blocking (SCB) toxins using mouse neuroblastoma assay. No production of SCB toxins was found and high performance liquid chromatography (HPLC) analysis confirmed these results. The content of total paralytic shellfish poisoning (PSP) toxin in the water samples, as measured within the toxic dinoflagellate blooms using HPLC, ranged from 53 to 2191 ng PSP l^–1 in 1998 and from 0 to 478 ng PSP l^–1 in 1999. Changes in PSP toxin content were not accompanied by changes of DGGE band patterns. We therefore presume that the bacterial groups identified in this study were not exclusively associated with toxic A. tamarense, but were generally associated with the phytoplankton.An erratum to this article can be found at Communicated by H.-D. Franke     

Single-cell analysis of paralytic shellfish toxins in Alexandrium tamarense by HPLC with post-column fluorescent derivatization

We developed a methodology for analyzing the C-toxin (C2) content in single Alexandrium tamarense cells; this method was based on high performance liquid chromatography (HPLC). C2 is the main paralytic shellfish toxin (PST) detected in a clonal culture of A. tamarense, which is a common causative organism in cases of paralytic shellfish poisoning in Japan. This HPLC method employs post-column fluorescent derivatization (FL). Mobile phase, column size, flow rate, reagent concentrations, and lamp type for the fluorescent detector were all optimized for the detection of C2. With this improved methodology, we could measure 1 fmol of C2 with a signal to noise ratio (S/N) = 2. Clonal heterogeneity within the toxic strain, which was maintained for 13 years after re-isolation from the original clonal culture, ranged from <1 fmol to 700 fmol cell⁻¹. This report is the first to demonstrate definitively that PST content varies on a cell-by-cell basis in a clonal culture of a dinoflagellate that causes paralytic shellfish poisoning.     

Selective surface adhesion of the toxic microalga Alexandrium minutum induced by contact with substituted polystyrene derivatives.

On the basis of observations that biospecific random copolymers (RACS) could induce phenotypic changes on contact with selected eukaryotic or prokaryotic cell lines, polystyrene derivatives of known compositions and obtained by random substitutions of sodium sulfonate and of sulfamides of aspartic acid dimethyl ester, phenylalanine and leucine, were placed in contact with swimming dinophytes of the PSP toxin producing species Alexandrium minutum and of the non-toxic species Heterocapsa triquetra. A. minutum cells exhibited higher adhesion for the random copolymer made up of polystyrene (29%), polystyrene aspartic acid dimethyl ester sulfamide (47%) and polystyrene sodium sulfonate (24%), than for samples of this series with different compositions. In contrast to this, A. minutum adhesion remained very low throughout the phenylalanine and leucine copolymer series. These results indicate that the cell-substrate adhesion phenomenon is dependent upon the final composition of the copolymer, i.e. that it is composition-specific. Taxonomic specificity was then demonstrated by presenting the PSAspOMe copolymer series with cells of the non toxic species H. triquetra (Peridinialia) related to A. minutum (Gonyaulacacea), and by observing no specific association, i.e. no signal above background levels at any composition. Specific ligand-cell adhesion is evidenced for the first time between biospecific RACS and phytoplankton, which may inspire a new generation of structures to be used in aquaculture as protective nets over shellfish clusters, or as selective filtering devices to assist in shellfish depuration from toxic microalgae.     

In vitro transformation of PSP toxins by different shellfish tissues

Many in vivo shellfish feeding experiments have been carried out in order to investigate the fate of PSP toxins in the marine food chain. A focal point of these studies concerns the species- and tissue-specific differences in toxin metabolism. However, tissue specific effects are often overlapped by selective toxin retention as well as transfer between individual compartiments. In in vitro experiments presented here digestive tissue and adductor homogenates of 10 shellfish species (bivalvia: Mytilus edulis, Crassostrea gigas, Cardium edule, Arctica islandica, Ensis ensis, Modiolus modiolus, Mactra stultorum, Pecten maximus as well as two snails: Littorina littorea and Buccinum undatum) were incubated with an extract of the toxic strain Alexandrium fundyense CCMP 1719. After incubation, changes in the toxin pattern could be observed in all samples with significant differences occuring between both the species and tissues. The greatest metabolic activity was found in digestive tissue samples. Among the organisms, the species with a non-filtering lifestyle, L. littorea and B. undatum, showed the highest conversion rates. Interestingly, the high metabolic transformation rate of the PSP toxins was accompanied with a fast reduction (up to 73%) of toxicity in the homogenates.     

Grazing on a toxic Alexandrium catenella bloom by the lobster krill Munida gregaria (Decapoda: Galatheoidea: Munididae)

Specimens of Munida gregaria were collected within and in the vicinity of a bloom of the toxic dinoflagellate Alexandrium catenella in Queen Charlotte Sound, New Zealand. The crustacean contained paralytic shellfish toxin (PST) with an analogue profile dominated by N-sulfocarbamoyl analogues (C1,2 and GTX5) and carbamate gonyautoxins (GTX1,4), similar to that of the dinoflagellate. A feeding experiment showed that M. gregaria is capable of actively grazing on A. catenella and it may play a role in controlling population growth of the dinoflagellate. This is the first account of the accumulation of PST by M. gregaria. When it is periodically abundant, M. gregaria is an important food item for fish, birds and other marine fauna and they are a vector by which PST may be transferred to higher trophic levels.     

Determination of paralytic shellfish poisoning (PSP) toxins in UK shellfish

A study was conducted to aid the interpretation of data generated by parallel testing of the qualitative Jellett Rapid Test (JRT) and the mouse bioassay (MBA) for detection of paralytic shellfish poisoning (PSP) toxins within the UK statutory shellfish biotoxin monitoring programme. A selection of stored sample extracts subjected to testing by MBA and/or JRT were further analysed by liquid chromatography with fluorescence detection (LC–FLD) to provide additional information on the concentrations of PSP toxins and toxin profiles.Results, from this study, demonstrate the potential of the JRT to effectively screen out PSP toxin negative shellfish samples and samples containing low concentrations of toxins from UK monitoring programmes. Additionally, data generated using LC–FLD highlights the potential of introducing alternative analytical techniques to completely replace the requirement for the MBA.     

Paralytic shellfish toxin profiles of different geographic populations of Gymnodinium catenatum (Dinophyceae) in Korean coastal waters

Paralytic shellfish poisoning toxin profiles of dinoflagellate cultures of Gymnodinium catenatum Graham from the Yellow and South Seas in Korea were investigated by high performance liquid chromatography fluorometric detection. Strains from the Yellow Sea had predominantly carbamate toxins, while strains from Sujeongri and Chindong in the South Sea contained the N‐sulfocarbamoyl toxins, Cl,2, as major components including the presence of GTX5 and dcSTX in some strains. Toxin profiles from St. Deukryang Bay strains (South Sea) showed both characteristics of those in the South Sea and those in the Yellow Sea. Thirty strains could be divided into three groups based on cluster analysis of toxin compositions. Group I (Yellow Sea strains) was distinguished from Group II (Sujeongri and Chindong strains) by the absence of GTX5 and dcSTX. Group III comprised Deukryang Bay strains. In conclusion, the Yellow Sea and the South Sea were found to have different dinoflagellate populations with different toxin compositions.     

Paralytic shellfish toxins or spirolides? The role of environmental and genetic factors in toxin production of the Alexandrium ostenfeldii complex

Dinoflagellates of the Alexandrium ostenfeldii complex (A. ostenfeldii, A. peruvianum) are capable of producing different types of neurotoxins: paralytic shellfish toxins (PSTs), spirolides and gymnodimines, depending on the strain and its geographic origin. While Atlantic and Mediterranean strains have been reported to produce spirolides, strains originating from the brackish Baltic Sea produce PSTs. Some North Sea, USA and New Zealand strains contain both toxins. Causes for such intraspecific variability in toxin production are unknown. We investigated whether salinity affects toxin production and growth rate of 5 A. ostenfeldii/peruvianum strains with brackish water (Baltic Sea) or oceanic (NE Atlantic) origin. The strains were grown until stationary phase at 7 salinities (6–35), and their growth and toxin production was monitored. Presence of saxitoxin (STX) genes (sxtA1 and sxtA4 motifs) in each strain was also analyzed. Salinity significantly affected both growth rate and toxicity of the individual strains but did not change their major toxin profile. The two Baltic Sea strains exhibited growth at salinities 6–25 and consistently produced gonyautoxin (GTX) 2, GTX3 and STX. The two North Sea strains grew at salinities 20–35 and produced mainly 20-methyl spirolide G (20mG), whereas the strain originating from the northern coast of Ireland was able to grow at salinities 15–35, only producing 13-desmethyl spirolide C (13dmC). The effects of salinity on total cellular toxin concentration and distribution of toxin analogs were strain-specific. Both saxitoxin gene motifs were present in the Baltic Sea strains, whereas the 2 North Sea strains lacked sxtA4, and the Irish strain lacked both motifs. Thus sxtA4 only seems to be specific for PST producing strains. The results show that toxin profiles of A. ostenfeldii/peruvianum strains are predetermined and the production of either spirolides or PSTs cannot be induced by salinity changes. However, changes in salinity may lead to changed growth rates, total cellular toxin concentrations as well as relative distribution of the different PST and spirolide analogs, thus affecting the actual toxicity of A. ostenfeldii/peruvianum populations.     

Toxin composition variations in cultures of Alexandrium species isolated from the coastal waters of southern China

The composition of the paralytic shellfish toxins (PSTs) of five Alexandrium tamarense strains isolated from the coastal waters of southern China and one Alexandrium minutum strain from Taiwan Island were investigated. A. tamarense CI01 and A. tamarense Dapeng predominantly produced C2 toxin (over 90%) with trace amounts of C1 toxin (C1), gonyautoxin-2 (GTX2) and GTX3; two strains of A. tamarense HK9301 maintained in different locations produced C1-4 toxins and GTX1, 4, 5 and 6; no PSTs were found in A. tamarense NEW, while A. minutum TW produced only GTX1-4. The toxin compositions of cultured A. tamarense strains did not vary as much during different growth phases as did the toxin composition of A. minutum TW. The toxin compositions of A. tamarense HK9301-1 did not change significantly under different salinity, light intensity, and nitrate and phosphate levels in the culture medium, although the toxin productivity varied expectably. Another strain HK9301-2 maintained in a different location produced much less toxins with a considerably different toxin composition. Under similar culture maintenance conditions for 3 years, the toxin profiles of A. tamarense HK9301-1 did not change as much as did A. tamarense CI01. Our results indicate that toxin compositions of the dinoflagellate strains are strain-specific and are subject to influence by nutritional and environmental conditions but not as much by the growth phase. Use of toxin composition in identifying a toxigenic strain requires special caution.     

Modelling paralytic shellfish toxins (PSTs) transfer and accumulation in populations of two planktonic grazers

A model was developed in this paper in order to study and compare the paralytic shellfish toxin (PST) transfer and accumulation of two different potential PST vectors in the planktonic community, the heterotrophic dinoflagellate in its red form Noctiluca scintillans and the copepod Acartia clausi. Different factors that influence the toxin transfer such as toxin synthesis, grazing on toxic and non-toxic food and population size of PST producers and vectors were considered in the model. Moreover, a laboratory experiment was conducted in order to calculate the detoxification rates of Noctiluca fed on Alexandrium catenella. According to the model results, the two grazers showed a significant difference mainly in the timing of the PST accumulation. Noctiluca exhibited a rapid response to the grazing of Alexandrium with high initial toxin accumulation, followed by a reduction to zero concentration of toxins in a period of almost two days. In contrast, Acartia showed a considerable delay in comparison to Noctiluca to accumulate the same amount of toxin in the population. This delay is linked to the slower reproduction rates that characterize the copepod. The range of the initial values used for the sensitivity analysis of the model is representative of the coastal environment of a Galician ria (embayment located at the NW of Iberian Peninsula), where the two grazers and Alexandrium may co-exist. The model for Acartia showed less sensitivity to these key parameters probably due to the time delay in accumulation of significant amount of toxins. Both grazers showed a rapid (50 h) reduction of ingested toxin, suggesting inefficiency to transfer toxins through predation in the food web.     

The toxigenic marine dinoflagellate Alexandrium tamarense as the probable cause of mortality of caged salmon in Nova Scotia

The toxins associated with paralytic shellfish poisoning (PSP) are potent neurotoxins produced by natural populations of the marine dinoflagellate Alexandrium tamarense. In early June 2000, a massive bloom (>7×10⁵ cells l⁻¹) of this dinoflagellate coincided with an unusually high mortality of farmed salmon in sea cages in southeastern Nova Scotia. Conditions in the water column in the harbour were characterised by the establishment of a sharp pycnocline after salinity stratification due to abundant freshwater runoff. In situ fluorescence revealed a high sub-surface (2–4 m depth) chlorophyll peak related to the plankton bloom. The intense bloom was virtually monospecific and toxicity was clearly related to the concentration of Alexandrium cells in plankton size fractions. Cultured clonal isolates of A. tamarense from the aquaculture sites were very toxic on a per cell basis and yielded a diversity of PSP toxin profiles, some of which were similar to those from plankton concentrates from the natural bloom population. The toxin profile of plankton concentrates from the 21–56 μm size fraction was complex, dominated by the N-sulfocarbamoyl derivative C2, with levels of other PSP toxins GTX4, NEO, GTX5 (=B1), GTX3, GTX1, STX, C1, and GTX2, in decreasing order of relative abundance. Although no PSP toxin was found systemically in the fish tissues (liver, digestive tract) from this salmon kill event, the detection of Alexandrium cells and low levels of PSP toxins in salmon gills provide evidence that the enhanced mortalities were caused by direct exposure to toxic Alexandrium cells and/or to soluble toxins released during the bloom.     

Assessment of sodium channel mutations in Makah tribal members of the U.S. Pacific Northwest as a potential mechanism of resistance to paralytic shellfish poisoning

The Makah Tribe of Neah Bay, Washington, has historically relied on the subsistence harvest of coastal seafood, including shellfish, which remains an important cultural and ceremonial resource. Tribal legend describes visitors from other tribes that died from eating shellfish collected on Makah lands. These deaths were believed to be caused by paralytic shellfish poisoning, a human illness caused by ingestion of shellfish contaminated with saxitoxins, which are produced by toxin-producing marine dinoflagellates on which the shellfish feed. These paralytic shellfish toxins include saxitoxin, a potent Na⁺ channel antagonist that binds to the pore region of voltage gated Na⁺ channels. Amino acid mutations in the Na⁺ channel pore have been demonstrated to confer resistance to saxitoxin in softshell clam populations exposed to paralytic shellfish toxins present in their environment. Because of the notion of resistance to paralytic shellfish toxins, the study aimed to determine if a resistance strategy was possible in humans with historical exposure to toxins in shellfish. We collected, extracted and purified DNA from buccal swabs of 83 volunteer Makah tribal members and sequenced the skeletal muscle Na⁺ channel (Nav1.4) at nine loci to characterize potential mutations in the relevant saxitoxin binding regions. No mutations of these specific regions were identified after comparison to a reference sequence. This study suggests that any resistance of Makah tribal members to saxitoxin, if present, is not a function of Nav1.4 modification, but may be due to mutations in neuronal or cardiac sodium channels, or some other mechanism unrelated to sodium channel function.     

Tn5 MUTAGENESIS OF PSEUDOMONAS STUTZERI SF/PS, A BACTERIUM ASSOCIATED WITH ALEXANDRIUM LUSITANICUM (DINOPHYCEAE) AND PARALYTIC SHELLFISH POISONING

It is becoming increasingly clear that bacteria can play an important role in the toxin and population dynamics of harmful algal bloom (HAB) events. In this paper, we document protocols and strategies that can be used to identify bacterial genes involved in either the production of toxic compounds and/or the establishment and maintenance of relationships between bacteria and algae. The protocols we tested involved transposon mutagenesis and complementation with broad-host-range plasmids. We tested six bacterial strains thought to be involved, either directly or indirectly, in the production of toxins associated with paralytic shellfish poisoning (PSP). Five strains were resistant to transformation under the growth conditions used. However, a single strain, Pseudomonas stutzeri SF/PS, was readily transformed when grown under appropriate conditions. This bacterium has been shown to accumulate PSP toxins and to increase toxin production when added to axenic cultures of a toxic dinoflagellate, Alexandrium lusitanicum . We conclude that a transposon mutagenesis strategy can be used to identify genes involved in HAB events.