Prorocentrum lima (Dinophyceae) in northeastern USA coastal waters: II: Toxin load in the epibiota and in shellfish

The seasonal variation in diarrhetic shellfish poisoning (DSP)-type toxins was followed in the epibiotic community and in shellfish between 41° and 44°N in coastal waters of the northwest Atlantic during a 2-year period. Low levels of okadaic-acid equivalents were detected at all stations in the <90 μm fraction of the collected epibiota as measured by the protein phosphatase inhibition assay, but only 3.5% of the samples had values greater than 100 ng (g dry weight of epibiota)⁻¹. No seasonal pattern could be detected due to differences in intensity, duration and timing of toxin content in the epibiota between the 2 years and between stations. Nevertheless, the concentration of DSP-type toxins in the epibiota correlated weakly but significantly with the abundance of Prorocentrum lima, when data from all stations were considered. A very limited toxin uptake by shellfish was measured at only one station in October and November 2001 and in June and July 2002 at times of maximum cell concentration of P. lima in the epibiota. Toxin levels in shellfish remained well below regulatory limits that would have required quarantine or bans on harvesting. Results from our 2-year survey suggest that, at this time, the threat of DSP events appears minimal. However, the presence of a known toxin producer and its demonstrated ingestion by shellfish would argue for further studies to better understand conditions leading to DSP outbreaks generated by an epiphytic dinoflagellate.     

Epiphytic abundance and toxicity of Prorocentrum lima populations in the Fleet Lagoon, UK

Planktonic Dinophysis spp. and epiphytic Prorocentrum lima (Ehrenberg) Dodge are known dinoflagellate producers of okadaic acid (OA) and dinophysistoxins (DTX), causative phycotoxins of diarrhetic shellfish poisoning (DSP). Underestimation of toxic dinoflagellates associated with a toxic event may be due to the lack of sampling of species with epiphytic and epibenthic strategies, such as P. lima. As Dinophysis spp. is not found in the Fleet Lagoon, Dorset, but previous DSP events have closed the Crassostrea gigas oyster farm, P. lima is the most likely causative organism. A field assay for separating microalgal epiphytes and concentrating wild cells on to filters was successfully applied to sub-samples of a variety of macroalgae and macrophytes (seagrass) collected from the Fleet during summer 2002. P. lima was present in increasing cell densities on most substratum species, over the sampling period, from 10² to 10³ cells g⁻¹ fresh weight (FW) plant biomass. LC–MS analysis detected OA and DTX-1 in extracts of wild P. lima cells, in ratios characteristic of P. lima strains previously isolated from the Fleet. No toxins, however, were detected in oyster flesh.     

Seasonality of Dinophysis spp. and Prorocentrum lima in Black Sea phytoplankton and associated shellfish toxicity

Plankton surveys, between 2001 and 2005 along the Russian Caucasian Black Sea Coast, revealed Dinophysis rotundata, D. caudata and Prorocentrum lima as the most ubiquitous of the known dinoflagellates associated with diarrhetic shellfish poisoning (DSP). Dinophysis spp. were first observed during the spring phytoplankton succession and persist throughout the late summer phytoplankton peak. The highest total concentration, 3000 cells/L, of D. rotundata and D. caudata was observed in April 2001. Unlike Dinophysis, P. lima was rarely observed in plankton samples but closely followed storm events with maximum cell counts of P. lima occurred in July 2002.The presence of Dinophysis in mussel (Mytilus galloprovincialis) hepatopancreas correlated with concentration with Dinophysis observed in the plankton samples. Conversely, P. lima could be found in most hepatopancreas samples collected during the May to October period. Therefore, planktonic concentration of P. lima does not reflect its availability for and consumption by shellfish.Samples of mussel hepatopancreas, from August 2002, with a corresponding Dinophysis concentration of 250 cells/L and no observable P. lima, were found to contain 0.03 ng OAE/g. This sample analyses by LC-MS/MS displayed okadaic acid (OA) and related congeners (DTX1) along with the pectinotoxins (PTX2 and PTX2sa). Highest observed levels of P. lima-induced DSP-toxicity in hepatopancreas was 0.41 g OA-equivalents/g corresponded to the highest observed planktonic cell counts of P. lima, 300 cell/L in August 2001. Cultures isolated from this sample were found to produce OA, DTX1 and their related diol esters.These data reveal a threat, represented by DSP-toxic species, at Black Sea coasts, and provide grounds for the introduction of phycotoxin control measures in the region.     

Sulfated diesters of okadaic acid and DTX-1: Self-protective precursors of diarrhetic shellfish poisoning (DSP) toxins

Many toxic secondary metabolites used for defense are also toxic to the producing organism. One important way to circumvent toxicity is to store the toxin as an inactive precursor. Several sulfated diesters of the diarrhetic shellfish poisoning (DSP) toxin okadaic acid have been reported from cultures of various dinoflagellate species belonging to the genus Prorocentrum. It has been proposed that these sulfated diesters are a means of toxin storage within the dinoflagellate cell, and that a putative enzyme mediated two-step hydrolysis of sulfated diesters such as DTX-4 and DTX-5 initially leads to the formation of diol esters and ultimately to the release of free okadaic acid. However, only one diol ester and no sulfated diesters of DTX-1, a closely related DSP toxin, have been isolated leading some to speculate that this toxin is not stored as a sulfated diester and is processed by some other means. DSP components in organic extracts of two large scale Prorocentrum lima laboratory cultures have been investigated. In addition to the usual suite of okadaic acid esters, as well as the free acids okadaic acid and DTX-1, a group of corresponding diol- and sulfated diesters of both okadaic acid and DTX-1 have now been isolated and structurally characterized, confirming that both okadaic acid and DTX-1 are initially formed in the dinoflagellate cell as the non-toxic sulfated diesters.     

Toxins and other chemical constituents from Prorocentrum lima

The marine phytoplankton Prorocentrum lima is one of the toxic and harmful microalgae which can cause red tides. In chemical investigation on cultured strain P. lima PL11, seven compounds were isolated and identified by spectroscopic data, including three typical shellfish toxins okadaic acid (OA, 1), OA methyl ester (2), and prorocentrolide (3), three terpenoids (4–6), and one polyketide (7). Compounds 5 and 6 should be derived from carotenoid fucoxanthin. Compounds 4–7 were isolated from this genus of microalgae for the first time.     

Determination of diarrhetic shellfish toxins in various dinoflagellate species

Sixteen species of unialgal samples of dinoflagellate, either wild or cultured, were tested for production of diarrhetic shellfish toxins such as okadaic acid (OA), dinophysistoxin-1 (DTX1), and pectenotoxins (PTXs). Determination of micro-quantities of the toxins was facilitated by fluorometry and UV HPLC. Seven Dinophysis species were confirmed to produce either OA or DTX1, or both. Toxin content and composition varied regionally and seasonally. Intraspecies variation was also observed among cultured strains of Prorocentrum lima. PTX2 was the only toxin detected among PTX family, and D. fortii was the only species to contain this toxin. author for correspondence     

Enzymatic digestive activity and absorption efficiency in Tagelus dombeii upon Alexandrium catenella exposure

We analyzed absorption efficiency (AE) and digestive enzyme activity (amylase, cellulase complex, and laminarinase) of the infaunal bivalve Tagelus dombeii originating from two geographic sites, Corral-Valdivia and Melinka-Aysén, which have different long-term paralytic shellfish poisoning (PSP) exposure rates. We report the effects of past feeding history (origin) on T. dombeii exposed to a mixed diet containing the toxic dinoflagellate Alexandrium catenella and another dinoflagellate-free control diet over a 12-day period in the laboratory. Absorption efficiency values of T. dombeii individuals that experienced PSP exposure in their habitat (Melinka-Aysén) remained unchanged during exposure to toxic food in the laboratory. In contrast, T. dombeii from a non-PSP exposure field site (Corral-Valdivia) showed a significant reduction in AE with toxic exposure time. This study established that the amylase and cellulase complexes were the most important enzymes in the digestive glands of Tagelus from both sites. The temporal evolution of enzymatic activity under toxic diet was fitted to exponential (amylase and cellulase) and to a logarithmic (laminarinase) models. In all fits, we found significant effect of origin in the model parameters. At the beginning of the experiment, higher enzymatic activity was observed for clams from Corral-Valdivia. The amylase activity decreased with time exposure for individuals from Corral and increased for individuals from Melinka. Cellulase activity did not vary over time for clams from Corral, but increased for individuals from Melinka and laminarinase activity decreased over time for individuals from Corral and remained unchanged over time for Melinka. A feeding history of exposure to the dinoflagellate A. catenella was reflected in the digestive responses of both T. dombeii populations.     

Responses of Pyrodinium bahamense var. compressum and associated cultivable bacteria to antibiotic treatment

Pyrodinium bahamense var. compressum is a toxic dinoflagellate that produces paralytic shellfish poisoning toxins. It is responsible for the chronic toxicity of shellfish in many coastal areas of the Philippines and other South East Asian countries. For the purpose of using antibiotic treatment to possibly generate axenic cultures and understand their growth requirements, the antibiotic tolerances of two local P. bahamense var. compressum isolates and their associated bacteria were determined. The antibacterial compounds ampicillin, chloramphenicol, ciprofloxacin, kanamycin, neomycin, penicillin G, and streptomycin were tested, as well as two antifungals, amphotericin B, and nystatin. All except chloramphenicol, amphotericin B, and nystatin were generally well-tolerated. An antibiotic mixture composed of ciprofloxacin, kanamycin, neomycin, and streptomycin completely inhibited the cultivable bacteria associated with P. bahamense var. compressum MZRVA, although epifluorescence microscopy revealed that residual bacteria were still present. From long-term tests with this antibiotic mix, it was observed that survival of isolate MZRVA post-antibiotic treatment appeared to be associated with re-growth of heterotrophic bacteria and that excess vitamins could potentially enhance dinoflagellate survival. These results suggest that the associated heterotrophic bacterial populations help support the growth of P. bahamense var. compressum MZRVA in culture and possibly in nature. This is the first report on the growth responses of P. bahamense var. compressum and associated cultivable bacteria to a variety of single and combinations of antibiotics.     

Parallel Analyses of Alexandrium catenella Cell Concentrations and Shellfish Toxicity in the Puget Sound

Alexandrium catenella is widespread in western North America and produces a suite of potent neurotoxins that cause paralytic shellfish poisoning (PSP) in humans and have deleterious impacts on public health and economic resources. There are seasonal PSP-related closures of recreational and commercial shellfisheries in the Puget Sound, but the factors that influence cell distribution, abundance, and relationship to paralytic shellfish toxins (PSTs) in this system are poorly described. Here, a quantitative PCR assay was used to detect A. catenella cells in parallel with state shellfish toxicity testing during the 2006 bloom season at 41 sites from April through October. Over 500,000 A. catenella cells liter⁻¹ were detected at several stations, with two main pulses of cells driving cell distribution, one in June and the other in August. PSTs over the closure limit of 80 μg of PST 100 per g of shellfish tissue were detected at 26 of the 41 sites. Comparison of cell numbers and PST data shows that shellfish toxicity is preceded by an increase in A. catenella cells in 71% of cases. However, cells were also observed in the absence of PSTs in shellfish, highlighting the complex relationship between A. catenella and the resulting shellfish toxicity. These data provide important information on the dynamics of A. catenella cells in the Puget Sound and are a first step toward assessing the utility of plankton monitoring to augment shellfish toxicity testing in this system.Various species of the dinoflagellate genus Alexandrium, including members of the species complex comprising Alexandrium catenella, Alexandrium fundyense, and Alexandrium tamarense, produce saxitoxins and a number of related derivatives (1). Shellfish that ingest toxic Alexandrium cells accumulate these potent neurotoxins, which can then lead to paralytic shellfish poisoning (PSP) in human consumers of shellfish. As such, paralytic shellfish toxins (PSTs) pose a serious threat to both public health and economically important fisheries (16). Within the Alexandrium genus, A. catenella is widespread in the northwestern part of North America, including the Puget Sound, and is responsible for seasonal harmful algal blooms (HABs) in this region (17). In the Puget Sound, recreational shellfish harvesters collect nearly 2 million pounds of clams and oysters annually, and Washington is also a leading producer of farmed bivalve shellfish in the United States, generating an estimated $77 million in sales a year and supporting thousands of jobs (13).PSTs are not a new problem in the Pacific Northwest; events have been documented as far back as the late 18th century (17). Currently, the Sentinel Monitoring Program of the Washington State Department of Health (WADOH) is in place to provide systematic early warning of harmful levels of PSTs, with caged mussels sampled at as many as 70 sites throughout all basins of Puget Sound at roughly 2-week intervals. Analysis of this long-term shellfish monitoring data indicates that maximum PST levels and PST-related closures have increased over the past 20 years, reaching >10,000 μg of PST per 100 g of shellfish tissue in multiple years and resulting in significant negative impacts on shellfisheries in the region (17).To date, monitoring efforts in the Puget Sound have focused on measuring the level of PSTs present in shellfish tissue. Existing programs do not typically monitor for phytoplankton species composition or abundance. Information on A. catenella distribution and seasonal dynamics is limited for this region, despite its potential value for monitoring and understanding toxic A. catenella blooms and their impacts. Toward this end, we used a previously developed high-throughput quantitative PCR (qPCR) method (5, 6) to detect and enumerate A. catenella cells. We couple this specific and sensitive detection method for A. catenella with PST monitoring efforts to examine changes in A. catenella populations and accompanying shellfish toxicity in the Puget Sound. The data, collected from April through October, span nearly all of the 2006 A. catenella bloom season in the region. These results provide important information on the abundance and dynamics (e.g., possible source populations) of A. catenella cells during a bloom season and on their relationship to PSTs in shellfish. This effort represents a first step toward assessing the utility of plankton monitoring to augment shellfish toxicity testing in this region.     

Morphology and phylogeny of Prorocentrum caipirignum sp. nov. (Dinophyceae), a new tropical toxic benthic dinoflagellate

A new species of toxic benthic dinoflagellate is described based on laboratory cultures isolated from two locations from Brazil, Rio de Janeiro and Bahia. The morphology was studied with SEM and LM. Cells are elliptical in right thecal view and flat. They are 37–44 μm long and 29–36 μm wide. The right thecal plate has a V shaped indentation where six platelets can be identified. The thecal surface of both thecal plates is smooth and has round or kidney shaped and uniformly distributed pores except in the central area of the cell, and a line of marginal pores. Some cells present an elongated depression on the central area of the apical part of the right thecal plate. Prorocentrum caipirignum is similar to Prorocentrum lima in its morphology, but can be differentiated by the general cell shape, being elliptical while P. lima is ovoid. In the phylogenetic trees based on ITS and LSU rDNA sequences, the P. caipirignum clade appears close to the clades of P. lima and Prorocentrum hoffmannianum. The Brazilian strains of P. caipirignum formed a clade with strains from Cuba, Hainan Island and Malaysia and it is therefore likely that this new species has a broad tropical distribution. Prorocentrum caipirignum is a toxic species that produces okadaic acid and the fast acting toxin prorocentrolide.     

Iceberg Scour and Shell Damage in the Antarctic Bivalve Laternula elliptica

We document differences in shell damage and shell thickness in a bivalve mollusc (Laternula elliptica) from seven sites around Antarctica with differing exposures to ice movement. These range from 60% of the sea bed impacted by ice per year (Hangar Cove, Antarctic Peninsula) to those protected by virtually permanent sea ice cover (McMurdo Sound). Patterns of shell damage consistent with blunt force trauma were observed in populations where ice scour frequently occurs; damage repair frequencies and the thickness of shells correlated positively with the frequency of iceberg scour at the different sites with the highest repair rates and thicker shells at Hangar Cove (74.2% of animals damaged) compared to the other less impacted sites (less than 10% at McMurdo Sound). Genetic analysis of population structure using Amplified Fragment Length Polymorphisms (AFLPs) revealed no genetic differences between the two sites showing the greatest difference in shell morphology and repair rates. Taken together, our results suggest that L. elliptica exhibits considerable phenotypic plasticity in response to geographic variation in physical disturbance.     

Genetic isolation and evolutionary history of oases populations of the Baja California killifish,Fundulus lima

The Baja California killifish, Fundulus lima, is found in six desert oases of the southern Baja California Peninsula, Mexico. The recent introduction of exotic fishes, particularly redbelly tilapia, have impacted the ecology of Fundulus lima such that it is now endangered. Plans of relocating F. lima to bodies of freshwater that are free of exotics have been proposed, however little is know about the genetic identity of the current populations. In this study, we examined the mitochondrial control region of F. lima samples from 4 oases, and in addition, compared these samples to their sister species, the California killifish F.␣parvipinnis. Using a combination of phylogenetic and coalescent approaches, we were able to determine that the two subspecies of the California killifish, F. p.␣brevis, and F. p. parvipinnis, and F. lima form an unresolved trichotomy that diverged between 200,000 years and 400,000 years ago. The one F. lima individual that we were able to collect in the southernmost oasis grouped with the southern subspecies of the California killifish, F. parvipinnis brevis. In contrast, we found that the 3 northern oases grouped together in a “Fundulus lima” clade. Each oasis is genetically distinct, yet there is no evidence of a␣marked genetic bottleneck in any populations (Haplotype diversity between 0.5 and 0.8). Future relocation plans will therefore need to be done cautiously to preserve the genetic identity of the original populations.     

A survey of epiphytic dinoflagellates from the coastal waters of the island of Hawai‘i

Three hundred and sixty-nine macroalgal and non-algal samples were collected from six coastal sites around the island of Hawai‘i on a biweekly basis over a 1-year period to ascertain (1) the presence of potentially toxigenic benthic dinoflagellates, and (2) substrate and environmental preferences of the dinoflagellates. Twenty-six genera/species of dinoflagellates were encountered including the (potentially) toxigenic species Amphidinium sp., Coolia monotis, Gambierdiscus sp., Ostreopsis ovata, Prorocentrum concavum, Prorocentrum hoffmannianum, Prorocentrum lima, and Prorocentrum mexicanum. Twenty of the species are being reported for the first time as present in Hawaiian coastal waters. There was some evidence of macroalgal host preference (e.g., C. monotis on Tolypiocladia glomerulata), although host morphology preferences was greater (e.g., Gambierdiscus sp., and P. lima on filamentous turfs; O. sp. 1 on sheet-like macroblades). While some dinoflagellate groups were significantly correlated with nutrient concentrations (e.g., total dinoflagellates with nitrate + nitrite and phosphate concentrations), others were not (e.g., Gambierdiscus sp., Prorocentrum emarginatum, P. lima, and Sinophysis microcephalus). The presence of several potentially toxigenic dinoflagellate species in Hawai‘i merits future study on possible impacts of these dinoflagellates on coastal food webs and human health.     

Effects of different levels of N- and P-deficiency on cell yield,okadaic acid,DTX-1, protein and carbohydrate dynamics in the benthic dinoflagellate Prorocentrum lima

Prorocentrum lima (Ehrenberg) Dodge is a cosmopolitan epiphytic dinoflagellate that produces biotoxins which are causative of diarrhetic shellfish poisoning (DPS). Here we report on effects of several nitrogen (N) and phosphorous (P) limited conditions on cell yield, okadaic acid (OA) and dinophysistoxin-1 (DTX-1) contents synoptically with cell carbohydrate, exopolysaccharide (EPS) and cell protein concentrations in a P. lima strain isolated from the Sacca di Goro lagoon (Northern Adriatic Sea). Batch culture experiments were set to assess changes induced by four nitrogen-limited levels (1/3-N, 1/10-N, 1/20-N, and 1/50-N) and four phosphorus-limited levels (1/3-P, 1/10-P, 1/20-P, and 1/50-P) with respect to control nutrient conditions (f/2 medium; NO₃⁻ and PO₄³⁻ concentrations: 883 and 36.3 μM, respectively; N/P ratio: 24). Low nutrients availability determined lower cell yields starting from 1/10-N and 1/3-P levels and the pattern observed was dependent on nutrient dynamics, as shown by N and P analyses performed in culture media during growth. Final cell yield decreased significantly up to 4.7- and 5.6-fold under 1/50-N and 1/50-P-limited levels with respect to control values, while cell volume increased with respect to control (up to 30% and 35% for N- and P-experiment, respectively). On overall, OA concentration ranged from 6.69 to 15.80 pg cell⁻¹, while DTX-1 ranged from 0.12 and 0.39 pg cell⁻¹ resulting in unusual high OA/DTX-1 ratios. The study indicates that protein, carbohydrate, EPS, and toxin concentrations displayed remarkable different patterns under the two kinds of nutrient deficiencies. The main differences can be summarised as: (i) significant decrease of cell protein concentration (up to 2-fold) under N-limitation, conversely no significant changes in protein concentration under P-limitation; (ii) significant increase of cell carbohydrate (up to 2.8-fold and 3.4-fold for N- and P-limitation, respectively) and cell OA amount (up to 1.9-fold and 2.3-fold, N- and P-limitation, respectively) under both N- and P-limitations, however different level-deficiency dependent patterns were displayed under the two nutrient conditions; (iii) significant increase of EPS concentration (up to 6.50-fold) under P-limitation, conversely no significant changes in EPS concentration under N-limitation. Data presented here indicate that P. lima adopts different eco-physiological strategies to face N-limitation or P-limitation. This study provides the first evidence for an increase in EPS production by benthic dinoflagellates under P-limited conditions; the ecological significance of this increase is discussed.     

THE PAS/ACCUMULATION BODIES IN PROROCENTRUM LIMA AND PROROCENTRUM MACULOSUM (DINOPHYCEAE) ARE DINOFLAGELLATE LYSOSOMES1

Numerous spherical bodies containing electron-dense material, fibrous material, and membranous material are present in the cytoplasm of two dinoflagellate species, Prorocentrum lima (Ehr.) Dodge and Prorocentrum maculosum Faust. Similar bodies have been observed in other dinoflagellates and have been termed accumulation bodies or PAS bodies. In both Prorocentrum species, these bodies autofluoresce under blue light excitation and increase in size with cell culture age. They possess acid phosphatase activity, react positively with the periodic acid/Schiff reagent, and stain with acridine orange. All these properties are characteristic of eukaryotic lysosomes; thus, we propose that dinoflagellate accumulation bodies and PAS bodies are identical organelles and are, in fact, dinoflagellate lysosomes.     

SPECIES BOUNDARIES IN THE TOXIC DINOFLAGELLATE PROROCENTRUM LIMA (DINOPHYCEAE,PROROCENTRALES), BASED ON MORPHOLOGICAL AND PHYLOGENETIC CHARACTERS1

Wild and cultured specimens of Prorocentrum lima (Ehrenb.) F. Stein from 26 widely different areas in 13 countries were examined in order to determine consistent characters for delimiting species boundaries in this taxon. The morphological characters valve shape, valve size, valve ornamentation, number and shape of valve pores, number and shape of marginal pores, and periflagellar platelets were observed using LM and SEM, and two molecular genetic regions were sequenced. We identified stable morphological characters that were consistent among wild specimens and all cultures, which were valve shape, valve ornamentation, and number and arrangement of periflagellar platelets. All cultures of P. lima identified by these characters formed a monophyletic group in phylogenetic analyses based on the two genes, which, however, included the species Prorocentrum arenarium. P. arenarium was determined to be within the range of morphological variation of P. lima, and therefore we synonymize the two taxa. Within this monophyletic group, P. lima was divided into several subclades in the all phylogenetic analyses. There were no morphological characters specifically related to any one subclade. The subclades appeared to correlate broadly to sample collection regions, suggesting that geographically separated populations may have become genetically distinct within this epi‐benthic species. We have emended species boundaries in P. lima.     

Occurrence of epibenthic dinoflagellates in relation to biotic substrates and to environmental factors in Southern Mediterranean (Bizerte Bay and Lagoon,Tunisia): An emphasis on the harmful Ostreopsis spp., Prorocentrum lima and Coolia monotis

Harmful events associated with epibenthic dinoflagellates, have been reported more frequently over the last decades. Occurrence of potentially toxic benthic dinoflagellates, on the leaves of two magnoliophytes (Cymodocea nodosa and Zostera noltei) and thalli of the macroalgae (Ulva rigida), was monitored over one year (From May 2015 to April 2016) in the Bizerte Bay and Lagoon (North of Tunisia, Southern Mediterranean Sea). The investigated lagoon is known to be highly anthropized. This is the first report on the seasonal distribution of epibenthic dinoflagellates hosted by natural substrates, from two contrasted, adjacent coastal Mediterranean ecosystems. The environmental factors promoting the development of the harmful epibenthic dinoflagellates Ostreopsis spp., Prorocentrum lima and Coolia monotis were investigated. The highest cell densities were reached by Ostreopsis spp. (1.9 × 10³ cells g⁻¹ FW, in October 2015), P. lima (1.6 × 10³ cells g⁻¹ FW, in June 2015) and C. monotis (1.1 × 10³ cells g⁻¹ FW, in May 2015). C. nodosa and Z. noltei were the most favorable host macrophytes for C. monotis (in station L2) and Ostreopsis spp. (in station L3), respectively. Positive correlations were recorded between Ostreopsis spp. and temperature. Densities of the epibenthic dinoflagellates varied according to the collection site, and a great disparity was observed between the Bay and the Lagoon. Maximum concentrations were recorded on C. nodosa leaves from the Bizerte Bay, while low epiphytic cell abundances were associated with macrophytes sampled from the Bizerte Lagoon. The observed differences in dinoflagellate abundances between the two ecosystems (Bay-Lagoon) seemed not related to the nutrients, but rather to the poor environmental conditions in the lagoon.     

Development of microsatellite markers in the toxic dinoflagellate Alexandrium minutum (Dinophyceae)

Outbreaks of paralytic shellfish poisoning caused by the toxic dinoflagellate Alexandrium minutum (Dinophyceae) are a worldwide concern from both the economic and human health points of view. For population genetic studies of A. minutum distribution and dispersal, highly polymorphic genetic markers are of great value. We isolated 12 polymorphic microsatellites from this cosmopolitan, toxic dinoflagellate species. These loci provide one class of highly variable genetic markers, as the number of alleles ranged from four to 12, and the estimate of gene diversity was from 0.560 to 0.862 across the 12 microsatellites; these loci have the potential to reveal genetic structure and gene flow among A. minutum populations.