Intracellular damage and death caused by protease inhibitors on Alexandrium catenella natural cysts and vegetative cells

Proteases from a Chilean clone of Alexandrium catenella were studied using gelatin–zymogram gel and protease fluorescent substrate to facilitate their visual identification in vitro and in vivo, respectively. Proteolytic activity bands were grouped arbitrarily according to their molecular weight as P1 (150 and 120 kDa), P2 (100 kDa), P3 (70 and 65 kDa), P4 (60, 55 and 50 kDa) and P5 (25 kDa). Protease inhibitors affect differentially P2 and P3 proteases. Only P2 activity increased in the presence of 1–10 phenanthroline (σPhe), pepstatin A (pepA), leupeptin (leup) and phenylmethanesulfonyl fluoride (PMSF), while P2 and P3 become inactivated with ρ-aminobenzamidine. The protease inhibitors lethal dose was determined by incubating cells with different concentration of the protease inhibitor and evaluating their effect on cell viability. Furthermore, cells treated for 4 h with one lethal dose of 1–10 phenanthroline and ρ-aminobenzamidine, caused serious damage to the intracellular vacuolar system and nuclear material. Live cysts also die when treated independently with these two protease inhibitors. Future work will be aimed at chemically designing species-specific inhibitors for their potential use in killing cysts transported within the sediment of ship ballast water before washing them off to the environment.     

AC29: the most abundant protein of Alexandrium catenella and its potential use in encystment/excystment studies

The objective of this research was to characterize specific protein(s) from Alexandrium catenella to evaluate its use as markers for specific physiological functions. To identify such protein(s) we concentrated our efforts on characterizing proteins with a high level of expression in vegetative cells of A. catenella. The electrophoretic analysis of a total protein cell extract showed the presence of a very abundant 29 kDa protein that we have named AC29. Analysis by 2D SDS-PAGE shows that the 29 kDa band contains one abundant protein (AC29) and various less abundant polypeptides, suggesting the presence of either different proteins with similar molecular weight or isoforms of AC29 protein. Ultracytolocalization using antibodies raised against gel purified AC29 indicates that this protein localizes within the chloroplast and that it is associated with thylakoid membranes, as well as with other membranes surrounding the chloroplast. Western blot analysis of cells grown under light starvation shows that the expression of the AC29 protein is down regulated. A similar analysis shows that this protein is not expressed in natural cysts or by isolated intracellular bacterium. The amino terminus of the AC29 protein that was recovered from 2D SDS-PAGE was sequenced. The sequence shows homology to the peridinin-chlorophyll a-protein from the marine organisms Alexandrium cohorticula, Amphidinium carterae and Symbiodinium. Based on these results, we suggest that the AC29 protein has the potential of being used as a marker for A. catenella encystment and excystment processes.     

Use of PCR and partial sequencing of the large-subunit rRNA gene to identify Alexandrium catenella (Dinophyceae) from the South of Chile

A fragment of the large-subunit ribosomal DNA gene (LSU rDNA) from Chilean Alexandrium catenella clones isolated from two different geographic regions (XI and XII) was amplified by PCR and the products cloned and sequenced. Based on the analysis of the PCR products it is possible to distinguish two strains of A. catenella, denominated strain type 1 (a single PCR product band) and strain type 2 (two PCR product bands). These two strains proliferate in both, the XI and XII regions. Only in the XI region, there is evidence that they bloom simultaneously. The LSU rDNA sequence analysis indicate that the Chilean A. catenella isolated clones are more related to the North American ribotype-Western subribotype.     

Application of real-time PCR assay for detection and quantification of Alexandrium tamarense and Alexandrium catenella cysts from marine sediments

The dinoflagellates Alexandrium tamarense (Lebor) Balech and Alexandrium catenella (Whedon and Kofoid) Balech (Dinophyceae) are believed to be the main species responsible for paralytic shellfish poisoning (PSP) all over the world. It is necessary to identify A. tamarense and A. catenella cysts and to monitor their distribution in sediment in order to minimize the damages caused by PSP to the economy and food quality because cysts are the seed population for blooms caused by motile vegetative cells. In this study, we developed an efficient DNA extraction method from the natural cysts present in marine sediments after they were size fractionated with a plankton net (mesh size of 20–150 μm). The 10–3000 cysts were added to the sediments collected from the Ariake Sea, and for which the primuline-staining method did not reveal any cysts. DNA was then extracted from each sample, and linear standard curves for A. tamarense and A. catenella cysts were obtained from the correlation between the Ct values by real-time PCR and the log of the initial densities of cysts. We monitored the A. tamarense and A. catenella cyst densities in the environmental samples. This assay was demonstrated to be a powerful tool for the identification, detection, and quantification of the cysts of the toxic dinoflagellates.     

First report of Alexandrium taylori and Alexandrium peruvianum (Dinophyceae) in Malaysia waters

The occurrence of Alexandrium taylori and Alexandrium peruvianum is reported for the first time in Malaysia waters. The Malaysian A. taylori isolates were pyriform in shape with a transdiameter range of 36–40 μm and a cell length range of 33–37 μm. The first apical plate (1′) was pentagonal with two distinctive anterior margins. No direct connection between 1′ and the apical pore complex was observed. The posterior sulcal plate (S.p.) was large, elongated and oblique to the right with anterior projections. The ventral pore (vp) was relatively large and situated at a confluence point of 1′, the second apical (2′) and the fourth apical (4′) plates. Cells of A. peruvianum were slightly anteriorly and posteriorly compressed. S.p. had an irregular pentagonal shape, with the anterior margin divided into 2 portions. 1′ was boomerang-shaped with a large and truncated ventral pore in the middle right margin. The anterior right margin of 1′ was straight. The sixth precingular plate (6″) was wider than long. The anterior sulcal plate (S.a.) was triangular and lacked a left portion extension. In laboratory cultures, both A. taylori and A. peruvianum produced paralytic shellfish toxins, with GTX4 and GTX6 as the predominant toxin, respectively. This is the first report of PSP toxins production for both species as well as the occurrences in Malaysia waters.     

Comparative studies on morphology, ITS sequence and protein profile of Alexandrium tamarense and A. catenella isolated from the China Sea

The Alexandrium tamarense species complex is a closely related cosmopolitan toxigenic group of morphology-based species, including A. tamarense, A. catenella and A. fundyense. This study investigated the morphology, internal transcribed spacer (ITS) sequence and protein profile of A. tamarense and A. catenella grown in the same culture conditions using a combination of scanning electronic microscope (SEM), molecular and proteomic approaches. The results showed that all Alexandrium strains had the plate formula of Po, 4′, 6″, 6C, 8S, 5″′, 2″″. The ventral pore, a key conventional morphological feature to discriminate A. tamarense and A. catenella, was usually present in the first apical plate of ten A. tamarense strains, however, it was found to be absent in some cells of one Alexandrium strain, ATGX01. A. tamarense and A. catenella shared an identical ITS sequence with a minor variation at intraspecific level. Protein profiles of A. catenella DH01 and A. tamarense DH01, isolated from the same region of the East China Sea, showed no significant difference, the similarity of protein profiles of the two species reached 99% with a few proteins unique to one or the other. The present results suggest that the ventral pore is not a consistent morphological feature in the Alexandrium genus, and that A. tamarense and A. catenella are conspecific and should be redesignated to one species.     

Toxin profile of Alexandrium catenella from the Chilean coast as determined by liquid chromatography with fluorescence detection and liquid chromatography coupled with tandem mass spectrometry

The profile of tetrahydropurine neurotoxins associated with paralytic shellfish poisoning (PSP) was determined from a Chilean strain of the marine dinoflagellate Alexandrium catenella. The toxin composition was compared with that of toxic shellfish, presumably contaminated by natural blooms of A. catenella from the same region in southern Chile. Ion pair-liquid chromatography with post-column derivatization and fluorescence detection (LC-FD) was employed for relative quantitative analysis of the toxin components, whereas unambiguous identification of the toxins was confirmed by tandem mass spectrometry (LC–MS/MS). In the dinoflagellate strain from Chile, the N-sulfocarbamoyl derivatives (C1/C2, B1) and the carbamoyl gonyautoxins GTX1/GTX4 comprise >90% of the total PSP toxin content on a molar basis. This toxin composition is consistent with that determined for A. catenella populations from the Pacific coast in the northern hemisphere. The characteristic toxin profile is also reflected in the shellfish, but with evidence of epimerization and metabolic transformations of C1 and C2 to GTX2 and GTX3, respectively. This work represents the first unequivocal identification and confirmation of such PSP toxin components from the Chilean coast.     

链状亚历山大藻赤潮衰亡的生理调控

研究了链状亚历山大藻在对数生长期、衰亡期、高氮、低氮条件下,藻细胞中可溶性蛋白含量、超氧化物歧化酶(SOD)活性、丙二醛(MDA)、过氧化氢(H2O2)和还原型谷胱甘肽(GSH)含量、光合速率和呼吸速率、DNA降解、端粒酶活性的变化。结果表明:在衰亡期、高氮、低氮条件下链状亚历山大藻细胞中可溶性蛋白、GSH含量、光合速率和呼吸速率下降;SOD活性(低氮条件除外)、H2O2、MDA含量上升;端粒酶活性和DNA Ladder随着藻细胞生长而变化,并在衰亡时期,出现了明显的DNALadder。研究结果显示链状亚历山大藻衰亡过程的反应表现为:蛋白质合成受阻或降解,产生大量氧化中间产物(MDA,H2O2等),抗氧化系统被激活,GSH等非酶抗氧化物质被大量消耗,SOD等酶抗氧化物被激活;另外表现为光合速率和呼吸速率下降;同时活性氧自由基(Reactive Oxygen Species,ROS)的积累诱发了细胞凋亡,核酸内切酶被激活,选择性降解染色质DNA。推测低氮、高氮条件均可以加快藻细胞的衰亡的生理过程,链状亚历山大藻的赤潮衰亡是一种有序的死亡过程。     

Quantification methods for Alexandrium catenella, a toxic dinoflagellate: Comparison of competitive enzyme-linked immunosorbent assay and sandwich hybridization integrated with a nuclease protection assay

Alexandrium catenella (Whedon et Kofoid) Balech, a toxic dinoflagellate, is a bloom-forming planktonic species in cold water coastal regions. It produces strong paralytic shellfish poisoning (PSP) toxins which are transmitted via tainted shellfish. These toxins can affect humans, other mammals, fish and birds. In this study, polyclonal antiserum against A. catenella was produced, and a competitive enzyme-linked immunosorbent assay (cELISA) was developed to detect A. catenella. The antiserum against A. catenella showed good specificity, the linear detection range was relatively large, between 38 and 600,000 cells. In addition, specific probes were designed to target the small subunit ribosomal RNA (SSU rRNA) of A. catenella, and quantitative sandwich hybridization integrated with a nuclease protection assay (NPA-SH) was established in order to identify and quantify A. catenella. The NPA-SH assay did not show good specificity as well as cELISA, by which A. catenella and A. tamarense could not be distinguished. Samples in different cell growth phases were analyzed with cELISA and NPA-SH. The results showed that the cell concentration calculated by cELISA was very similar with microscopy, while that of NPA-SH was sometimes higher than that of microscopy, especially in log phase. Comparing the two methods, both assays allow rapid identification of A. catenella without time-consuming microscopy when multiple sites need to be considered in routine monitoring. Meanwhile, cELISA was more specific and accurate in detection of A. catenella than NPA-SH.     

Phylogenetic relationship of Alexandrium monilatum (Dinophyceae) to other Alexandrium species based on 18S ribosomal RNA gene sequences

The phylogenetic relationship of Alexandrium monilatum to other Alexandrium spp. was explored using 18S rDNA sequences. Maximum likelihood phylogenetic analysis of the combined rDNA sequences established that A. monilatum paired with Alexandrium taylori and that the pair was the first of the Alexandrium taxa to diverge, followed by Alexandrium margalefii. All three are members of the Alexandrium subgenus Gessnerium Halim nov. comb.     

Intercalibration of classical and molecular techniques for identification of Alexandrium fundyense (Dinophyceae) and estimation of cell densities

A workshop with the aim to compare classical and molecular techniques for phytoplankton enumeration took place at Kristineberg Marine Research Station, Sweden, in August 2005. Seventeen different techniques – nine classical microscopic-based and eight molecular methods – were compared. Alexandrium fundyense was the target organism in four experiments. Experiment 1 was designed to determine the range of cell densities over which the methods were applicable. Experiment 2 tested the species specificity of the methods by adding Alexandrium ostenfeldii, to samples containing A. fundyense. Experiments 3 and 4 tested the ability of the methods to detect the target organism within a natural phytoplankton community. Most of the methods could detect cells at the lowest concentration tested, 100 cells L⁻¹, but the variance was high for methods using small volumes, such as counting chambers and slides. In general, the precision and reproducibility of the investigated methods increased with increased target cell concentration. Particularly molecular methods were exceptions in that their relative standard deviation did not vary with target cell concentration. Only two of the microscopic methods and three of the molecular methods had a significant linear relationship between their cell count estimates and the A. fundyense concentration in experiment 2, where the objective was to discriminate that species from a morphologically similar and genetically closely related species. None of the investigated methods were affected by the addition of a natural plankton community background matrix in experiment 3. The results of this study are discussed in the context of previous intercomparisons and the difficulties in defining the absolute, true target cell concentration.     

An autecological study of the potentially toxic dinoflagellate Alexandrium affine isolated from Vietnamese waters

The potentially toxic dinoflagellate species Alexandrium affine isolated from Ha Long Bay (Tonkin Gulf), Vietnam was cultured and maintained for morphological, physiological and toxicological studies. Classical morphological examinations including plate pattern were in good agreement with the international nomenclature of the species. The fine structure of A. affine, including morphology of its developmental stages during vegetative and sexual reproduction was found to be typical of other species in the genus. Two general trends in growth of A. Affine from Vietnamese waters were apparent: (1) growth rates were low at low salinities (10 and 15 psu) in all experimental temperatures (21–27 °C); (2) growth rates were high at salinities 25, 30, and 35 psu in all temperatures. There were no significant differences in growth rates at different salinities at low temperature (21 °C), and the most significant difference in growth rate was between high temperature–high salinity and high temperature–low salinity. The optimum temperature and salinity for growth were 24 °C and 30 psu. Maximum division rates per day (0.5–0.7) were at salinities 30 and 35 psu and at temperatures 24 and 27 °C. But the best conditions for division rate were 21 and 24 °C at salinities 30 and 35 psu. Toxicity analyses indicated A. affine to be both toxic and non-toxic at certain times. In the former case, toxicity was very low, 2.28 fmol  per cell; the toxicity component of A. affine was compared with that of A. leei and the mussel Perna viridis including neoSTX, STX, and GTX₁–GTX₄.     

Alexandrium ostenfeldii growth and spirolide production in batch culture and photobioreactor

Growth and spirolide production of the toxic dinoflagellate Alexandrium ostenfeldii (Danish strain CCMP1773) were studied in batch culture and a photobioreactor (continuous cultures). First, batch cultures were grown in 450 mL flasks without aeration and under varying conditions of temperature (16 and 22 °C) and culture medium (L1, f/2 and L1 with addition of soil extract). Second, cultures were grown at 16 °C in 8 L aerated flat-bottomed vessels using L1 with soil extract as culture medium. Finally, continuous cultures in a photobioreactor were conducted at 18 °C in L1 with soil extract; pH was maintained at 8.5 and continuous stirring was applied.This study showed that A. ostenfeldii growth was significantly affected by temperature. At the end of the exponential phase, maximum cell concentration and cell diameter were significantly higher at 16 °C than at 22 °C. In batch culture, maximum spirolide quota per cell (approx. 5 pg SPX 13-desMeC eq cell⁻¹) was detected during lag phase for all conditions used. Spirolide quota per cell was negatively and significantly correlated to cell concentration according to the following equation: y = 4013.9x^−0.858. Temperature and culture medium affected the spirolide profile which was characterized by the dominance of 13,19-didesMeC (29–46%), followed by SPX-D (21–28%), 13-desMeC (21–23%), and 13-desMeD (17–21%).Stable growth of A. ostenfeldii was maintained in a photobioreactor over two months, with maximum cell concentration of 7 × 10⁴ cells mL⁻¹. As in batch culture, maximum spirolide cell quota was found in lag phase and then decreased significantly throughout the exponential phase. Spirolide cell quota was negatively and significantly correlated to cell concentration according to the equation: y = 12,858x^−0.8986. In photobioreactor, spirolide profile was characterized by higher proportion of 13,19-didesMeC (60–87%) and lower proportions of SPX-D (3–12%) and 13-desMeD (1.6–10%) as compared to batch culture.     

Species-specific and cross-reactive antigens of Entamoeba

Specific and cross-reactive antigens were defined in four species of Entamoeba: invadens, moshkovskii, Laredo and histolytica strains HM1, HM3, HM38 and HK9. Among these species extensive common reactivities were observed by immunoblot. Eight E. histolytica antigenic markers were revealed after blocking common specificities with antigens of other Entamoeba species. A monoclonal antibody (mAb) defined two protein markers of E. histolytica, M, 29 and 25 kDa. The four strains of E. histolytica, which varied in virulence as determined by the development of liver abscesses in hamsters, showed the same antigenic patterns with the mAb and with polyclonal antibodies.     

Phylogenetic relationship of Alexandrium tamiyavanichii (Dinophyceae) to other Alexandrium species based on ribosomal RNA gene sequences

The phylogenetic relationship of the thecate PSP-toxin producing dinoflagellate Alexandrium tamiyavanichii Balech to other species of Alexandrium was studied based on nucleotide sequences of the ITS1, ITS2, 5.8S, 18S and 28S subunits of the ribosomal RNA gene. These are the first such sequences available for A. tamiyavanichii, which is one of the producers of paralytic shellfish poisoning toxins in tropical waters. Based on the nucleotide sequences of the 28S, 18S and 5.8S subunits of the rRNA gene, A. tamiyavanichii grouped together with A. tamarense, A. catenella and A. fundyense. More interestingly, A. tamiyavanichii was most closely affiliated to A. tamarense isolates from Thailand. This result reaffirmed conclusions from previous studies that, for the A. tamarense/fundyense/catenella species complex, geographical origin rather than morphology seems to determine genetic relatedness. Results of this study also suggest that A. tamiyavanichii most probably belongs to the same species complex. Ribosomal RNA gene sequences do not separate the PSP toxin producing from the non-producing species of Alexandrium.     

Toxic Alexandrium minutum (Dinophyceae) from Vietnam with new gonyautoxin analogue

Clonal cultures of Alexandrium species collected from a shrimp pond on the northern coast of Vietnam were established and morphologically identified as Alexandrium minutum. Nucleotide sequences of domains 1 and 2 of the large subunit ribosomal (LSU) rRNA gene showed high sequence similarity to A. minutum isolates from Malaysia. Paralytic shellfish toxin profile of the clones was characterized by the dominance of GTX4, GTX1, and NEO. GTX3, GTX2, and dcSTX were also present in trace amount. Toxin content varied among the strains and growth stages, ranged from 3.0 to 12.5 fmol cell⁻¹. In addition to these known toxin components, a new gonyautoxin derivative was detected by HPLC, eluting between GTX4 and GTX1. The peak of this compound disappeared under non-oxidizing HPLC condition but unchanged either after treated with 0.05 M ammonium phosphate/10% mercaptoethanol or 0.1N HCl hydrolysis. LCMS ion scanning showed a parental ion of [M + H]⁺ at m/z 396, [M − SO₃]⁺ at m/z 316, and [M − SO₄]⁺ at m/z 298. Based on these results, the derivative was identified as deoxy-GTX4-12ol, and this represents the first report of this toxin analogue.     

Probable origin and toxin profile of Alexandrium tamarense (Lebour) Balech from southern Brazil

The distribution of the toxic dinoflagellate Alexandrium tamarense Lebour has apparently expanded within the southern hemisphere during the last 2 decades. Toxic blooms of A. tamarense were recorded in Argentinean coastal waters since 1980; however, the first documented bloom in southern Brazil was in 1996. In this study, 13 strains of A. tamarense from southern Brazil were isolated and kept in culture. Phylogenetic analysis using RFLP and DNA sequences of the D1–D2 region of large subunit ribosomal DNA (rDNA) clearly indicates that Brazilian strains are most closely related to other South American strains. The strains from South America are placed firmly within a phylogenetic clade which contains strains from North America, northern Europe and northern Asia, previously called the North American clade. Possible dispersal hypotheses are discussed. The cultures were also analyzed for saxitoxin and its derivatives by high performance liquid chromatography (HPLC). The main saxitoxin groups found were the low toxicity N-sulfocarbamoyl group, C1, 2 (30–84%), followed by the high potency carbamate toxins, gonyautoxins 1, 4 (6.6–55%), gonyautoxins 2, 3 (0.3–29%), neosaxitoxin (1.4–24%) and saxitoxin (0–4.4%). The toxin composition is similar to that of other strains from South America, supporting a close relationship between A. tamarense from southern Brazil and other areas of South America. Toxicity values were variable (7.07–65.92 pg STX cell⁻¹), with the higher range falling among the most toxic values recorded for cultures of A. tamarense, indicating the significant risk for shellfish contamination and human intoxication during blooms of this species along the southern Brazilian coast.     

Growth rates and elemental composition of Alexandrium monilatum, a red-tide dinoflagellate

The combined effects of temperature and salinity on growth of Alexandrium monilatum were studied in laboratory cultures. This toxic, red-tide dinoflagellate grew faster with higher temperatures, up to a maximum of approximately 1 division per day at 31 °C. Salinities above 15 psu had a lesser effect on growth rate, as might be expected for an estuarine species. Growth rates of cultures exposed to natural light and temperature fluctuations were comparable to laboratory cultures. The minimum N cell quota suggested that high N flux would be required to support bloom development. A literature survey of documented A. monilatum blooms indicated that within US waters, blooms occur in July–September in nearshore or estuarine regions of the Gulf of Mexico and the Florida Atlantic coast. Temperature and salinity measured during blooms correspond to the optimal growth conditions of the laboratory cultures. Nevertheless, the occurrence of A. monilatum blooms is sporadic compared to the occurrence of seemingly optimal growth conditions. Laboratory growth experiments predict when blooms of this species are unlikely due to low growth rates, but so far cannot predict individual blooms.     

Rapid detection of natural cells of Alexandrium tamarense and A. catenella (Dinophyceae) by fluorescence in situ hybridization

The marine toxic dinoflagellates Alexandrium tamarense (Lebor) Balech and A. catenella (Whedon and Kofoid) Taylor that cause paralytic shellfish poisoning (PSP) are identified on the basis of morphological features in routine monitoring. Rapid and simple identification is, however, often difficult because of the morphological similarity. Fluorescent in situ hybridization (FISH) using ribosomal RNA (rRNA)-targeted probes has been studied as a method of easily identifying and enumerating species responsible for harmful algal blooms (HABs). Its application to monitoring natural populations of HAB species, however, is limited. Here, we applied the FISH method to identify and enumerate cells of A. tamarense and A. catenella in natural plankton assemblages collected from Japanese coastal waters. A. tamarense-specific (Atm1) and A. catenella-specific (Act1) probes were established based on the D2 region of the large-subunit ribosomal RNA gene (28S rDNA). With these two probes, natural cells of A. tamarense or A. catenella in field samples could easily be identified when the following three conditions were met. First, cells should be concentrated by filtration, not centrifugation, in order to avoid the loss of cells. Second, autofluorescence should be minimized; acetone was an effective decolorization reagent. Third, samples should be stored at −20 or −80 °C for long-term preservation. The results indicate that FISH is a useful tool for the rapid identification of toxic Alexandrium spp. and can facilitate the analysis of numerous natural samples.     

A comparative study on recurrent blooms of Alexandrium minutum in two Mediterranean coastal areas

Alexandrium minutum is a toxic dinoflagellate widespread along the Mediterranean coasts. This species is frequently detected year-round at low concentrations within the Mediterranean basin. However, it only proliferates recurrently in some localities. Two affected areas are the Catalan and Sicilian coasts. In order to identify the factors determining the A. minutum blooms in the Mediterranean Sea, we compare the bloom conditions in two harbours: Arenys de Mar (Catalan coast, Spain) and Syracuse (Sicily, Italy), during 2002–2003. Arenys de Mar harbour is a fishing and leisure harbour and receives an input of freshwater rich in nutrients. Likewise, the Syracuse harbour – located on the Ionian coast of Sicily – is subject to freshwater inputs. Some points of this site are used for productive activities such as shellfish farming. A. minutum from the two areas studied were morphologically and genetically identical. In both sites, recurrent blooms take place from winter to spring. Surface water temperatures and salinities during A. minutum bloom events were 12–14.5 °C and 32–38, and 16–24 °C and 32–37.7 for Arenys and Syracuse, respectively. During the blooms, the spatial distribution of A. minutum in the two harbours, the physicochemical characteristics and the phytoplankton community were studied. Similarities in composition of the phytoplankton community were evidenced, with a clear dominance of dinoflagellates over the other taxa. In Arenys, the second dominant species was Prorocentrum micans followed by Scrippsiella spp. and Dinophysis sacculus. The same species were found in Syracuse although P. triestinum, and alternatively Lingulodinium polyedrum, reached cell densities much higher than the other dinoflagellates giving marked water discolourations.