Molecular Phylogeny of the Parasitic Dinoflagellate Chytriodinium within the Gymnodinium Clade (Gymnodiniales,Dinophyceae)

The dinoflagellate genus Chytriodinium, an ectoparasite of copepod eggs, is reported for the first time in the North and South Atlantic Oceans. We provide the first large subunit rDNA (LSU rDNA) and Internal Transcribed Spacer 1 (ITS1) sequences, which were identical in both hemispheres for the Atlantic Chytriodinium sp. The first complete small subunit ribosomal DNA (SSU rDNA) of the Atlantic Chytriodinium sp. suggests that the specimens belong to an undescribed species. This is the first evidence of the split of the Gymnodinium clade: one for the parasitic forms of Chytriodiniaceae (Chytriodinium, Dissodinium), and other clade for the free‐living species.     

Phylogeny,Evidence for a Cryptic Plastid,and Distribution of Chytriodinium Parasites (Dinophyceae) Infecting Copepods

Spores of the dinoflagellate Chytriodinium are known to infest copepod eggs causing their lethality. Despite the potential to control the population of such an ecologically important host, knowledge about Chytriodinium parasites is limited: we know little about phylogeny, parasitism, abundance, or geographical distribution. We carried out genome sequence surveys on four manually isolated sporocytes from the same sporangium, which seemed to be attached to a copepod nauplius, to analyze the phylogenetic position of Chytriodinium based on SSU and concatenated SSU/LSU rRNA gene sequences, and also characterize two genes related to the plastidial heme pathway, hemL and hemY. The results suggest the presence of a cryptic plastid in Chytriodinium and a photosynthetic ancestral state of the parasitic Chytriodinium/Dissodinium clade. Finally, by mapping Tara Oceans V9 SSU amplicon data to the recovered SSU rRNA gene sequences from the sporocytes, we show that globally, Chytriodinium parasites are most abundant within the pico/nano‐ and mesoplankton of the surface ocean and almost absent within microplankton, a distribution indicating that they generally exist either as free‐living spores or host‐associated sporangia.     

Parasitic dinoflagellates and ellobiopsids (Ellobiopsidae) of the coastal waters of the sea of Japan

Five species of parasitic dinoflagellates of the genera Protoodinium, Paulsenella, Duboscquella, Syndinium, and Dissodinium and two species of ellobiopsids of the genus Ellobiopsis are described. Figures and distribution data are provided. All species, except for Dissodinium pseudolunula Swift ex Elbrachter et Drebes, are first records for the Russia Far-Eastern seas.     

Cyst‐motile stage relationship and molecular phylogeny of a new freshwater dinoflagellate Gymnodinium plasticum from Plastic Lake,Canada

The dinophyceaen genus Gymnodinium was established with the freshwater species G. fuscum as type. According to Thessen et al. (2012), there are 268 species, with the majority marine species. In recently published molecular phylogenies based on ribosomal DNA sequences, Gymnodinium is polyphyletic. Here, a new freshwater Gymnodinium species, G. plasticum, is described from Plastic Lake, Ontario, Canada. Two strains were established by incubating single cysts, and their morphology was examined with light microscopy and scanning electron microscopy. The cyst had a rounded epicyst and hypocyst with a wide cingulum and smooth surface. Vegetative cells were characterized by an elongated nucleus running vertically and a deep sulcal intrusion. The apical structure complex was horseshoe‐shaped and consisted of two pronounced ridges with a deep internal groove, encircling 80% of the apex. Small subunit ribosomal DNA (SSU rDNA), large subunit ribosomal DNA (LSU rDNA) and internal transcribed spacer (ITS) sequences were obtained from cultured strains. Molecular phylogeny based on concatenated SSU, LSU and ITS sequences supports the monophyly of the Gymnodiniales sensu stricto clade but our results suggest that many Gymnodinium species might need reclassification. Gymnodinium plasticum is closest to Dissodinium pseudolunula in our phylogeny but distant from the type species G. fuscum, as are the other gymnodiniacean taxa.     

Life cycle ofSchizochytriodinium calani nov. gen. nov. spec., a dinoflagellate parasitizing copepod eggs

During the Polarstern-cruise ARK IV/2 June 1987, in the Fram Strait, dinophytes parasitizing copepod eggs were observed. In the laboratory on board, vegetative reproduction was documented and re-infection ofCalanus glacialis andC. hyperboreus eggs was experimentally established. During food uptake, a primary cyst produces successively several secondary cysts, all separating immediately after formation from the primary cyst. In every one of these free floating secondary cysts up to 256 dinospores are formed by palintomy. Re-infection only occurred after a “maturation time” of at least 2 days after formation of the dinospores. The life cycle is compared to that of other similar parasitic dinophyte genera:Apodinium Chatton,Chytriodinium Chatton,Dissodinium Klebs in Pascher andMyxodinium Cachon, Cachon & Bouquaheux. As the taxon under discussion does not fit in with any species or genus known so far, it is described asSchizochytriodinium calani nov. gen. nov. spec. Dedicated to Dr. Dr. h. c. P. Kornmann on the occasion of his 80th birthday. Mitglied der Taxonomischen Arbeitsgruppe an der BAH.     

Dissodinium pseudolunula (Dinophyta), a parasite on copepod eggs

Direct observation as well as culture experiments revealed Dissodinium pseudolunula as an ectoparasite on eggs of the marine planktonic copepod Temora longicornis. The vegetative life cycle, especially the parasitic phase, which involves phagocytosis, is reported for the first time. The species resembles D. pseudocalani, which is also parasitic upon copepod eggs. The taxonomic position and the survival of D. pseudolunula during the absence of the host in the winter is discussed.     

PARASITIC SPECIES OF THE GENUS BLASTODINIUM (BLASTODINIPHYCEAE) ARE PERIDINIOID DINOFLAGELLATES1

The taxonomic position of Blastodinium navicula Chatton and B. contortum Chatton, parasites of marine copepods, was investigated on the basis of morphological observations and molecular data. The life cycle of Blastodinium includes a parasitic stage, a trophont, and free‐swimming dinospores. The individual cells in the trophont, as well as the dinospores that they produced, were thecate. Dinospores of B. contortum and B. navicula had peridinioid plate tabulation formula, demonstrating an affiliation to the order Peridiniales Heackel (subdivision Dinokaryota Fensome et al.). This systematic position is in contrast to current classifications, in which the order Blastodiniales Chatton is thought to represent an early evolutionary branch of the dinokaryote lineage. Small‐subunit rRNA gene sequences were generated from six Blastodinium individuals isolated from three different host species. In phylogenetic analyses based on SSU rRNA genes, Blastodinium spp. branched with the typical dinoflagellates. Even though overall statistical support was low, the analyses suggested that Blastodinium spp. are late‐branching, dinokaryote dinoflagellates. Species currently included in Blastodiniales are all parasites, but they are morphologically and functionally diverse. Emerging molecular data also reveal high genetic diversity, and therefore, the taxonomy of the group requires reevaluation.     

First record of Grammatodinium (Dinophyceae) for the American Eastern Pacific coast: Morphological,molecular and ecological confirmation

Grammatodinium Li & Shin is a monospecific genus described from the Tongyeong Bay area in Korea. In the current study, we describe its presence in the American Eastern Pacific coast for the first time, particularly in Acapulco Bay, Mexico, using morphological, molecular and environmental data. Sequences generated in this study with SSU and LSU formed a monophyletic group with other sequences from GenBank belonging to Gr. tongyeonginum, the only species known for the genus; however, genetic distance values between this species and our specimens (8.5% SSU; 2.8% LSU) were equivalent or even greater than those reported in other genera of dinoflagellates. Our phylogeny clearly showed the relationship of Grammatodinium with the families Pyrocystaceae and Gonyaulacaceae. In our specimens, cells appeared individually and in colonies of up to 16 cells, which were observed mainly during the dry season, so they could be confused with Gymnodinium catenatum, a common dinoflagellate in Acapulco with which they can coexist and share their general appearance, but they are clearly differentiated by the presence of longitudinal furrows throughout the body and a yellowish-green coloration, both absent in Gymnodinium catenatum. Although our evidence strongly suggests the presence of a new species for the region, more detailed morphological examinations are needed to confirm this statement.     

Identification of the dinoflagellate community during Cochlodinium polykrikoides (Dinophyceae) blooms using amplified rDNA melting curve analysis and real-time PCR probes

The dinoflagellate community present during blooms of the fish killing dinoflagellate Cochlodinium polykrikoides was characterized by DNA melting curve analysis and direct sequencing of the SSU rDNA amplified from environmental sample extracts. PCR amplification of genomic DNA from Gaedo water samples using dinoflagellate-specific SSU rDNA primers yielded 280 clones, which were screened by closed tube PCR-melting curve analysis targeting a region of the SSU rDNA, enabling high throughput analysis. Twenty-eight clones producing distinct melting curve patterns were sequenced, and their phylogenetic information revealed that C. polykrikoides co-occurred with morphologically similar species including Gymnodinium impudicum and Gymnodinium catenatum. Temporal variations of C. polykrikoides and G. impudicum abundances in South Sea were also examined by species-specific real-time TaqMan-based PCR probes developed in this study. C. polykrikoides- and G. impudicum-specific real-time PCR probes were designed targeting the internal transcribed spacer 2 ribosomal DNA region. The probe specificity was confirmed by testing against related dinoflagellates and verified by sequencing PCR products from environmental samples. The real-time PCR assays showed that C. polykrikoides cell densities peaked in August at 16,928 cells mL^?1, while G. impudicum was present at low abundances (below 25 cells mL^?1). Our amplified rDNA melting curve protocol provides a facile method for the characterization of the dinoflagellate community, and the real-time PCR assay could be an alternative method for rapid and sensitive enumeration of harmful dinoflagellates in the marine environment.     

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.     

Dissodinium pseudocalani sp. nov., ein parasitischer Dinoflagellat auf Copepodeneiern

Zusammenfassung 1.Dissodinium pseudocalani ist eine neue, auf den Eiern des CopepodenPseudocalanus elongatus ektoparasitisch lebende Peridinee. Die Art tritt im Plankton der Deutschen Bucht von Mitte April bis Anfang Juni auf.2. Anfänglich ist der blasenförmige Parasit mit einem stabilen Saug-Haftorgan in seiner Wirtszelle verankert. Nachdem der Inhalt des Eies aufgenommen ist, löst er sich als kugelförmige Primärzyste von einem Durchmesser zwischen 151–250 µ ab. Sie enthält einen gefärbten Nahrungsballen, der während der Vermehrungsteilungen zusammenschrumpft.3. Durch simultane Teilung entstehen in der Primärzyste 8, 16 oder 32 ovale Sekundärzysten, in denen sukzedan jeweils 16 oder 32 begeißelte Dinosporen gebildet werden. Die Dinosporen sind farblos und gehören demGymnodinium-Typ an. Die Infektion derPseudocalanus-Eier konnte nicht direkt beobachtet, sondern nur aus den verschiedenen im Plankton gefundenen Entwicklungsstadien erschlossen werden.

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Dissodinium pseudocalani sp. nov., a parasitic dinoflagellate on copepod eggs

In spring 1967 and 1968, a new marine dinoflagellate species,Dissodinium pseudocalani, was discovered off Helgoland in the German Bight. The species lives as ectoparasite on eggs of the copepodPseudocalanus elongatus. The vesicular parasitic stage adheres to the host by a suction organ. After the substrate of the egg is consumed, the parasite develops into a spherical primary cyst which produces 8, 16 or 32 oval secondary cysts by simultaneous cell divisions. Each secondary cyst forms 16 or 32 dinospores. The dinospores are colourless, flagellated and of theGymnodinium-type. During reproduction a large reddish or greenish coloured food source is resorbed by the protoplast and diminishes in size. In regard to its mode of reproduction,Dissodinium pseudocalani is related toD. lunula and the parasitic species ofChytriodinium.

     

Morphology,ultrastructure, and molecular phylogeny of Wangodinium sinense gen. et sp. nov. (Gymnodiniales,Dinophyceae) and revisiting of Gymnodinium dorsalisulcum and Gymnodinium impudicum

The genus Gymnodinium includes many morphologically similar species, but molecular phylogenies show that it is polyphyletic. Eight strains of Gymnodinium impudicum, Gymnodinium dorsalisulcum and a novel Gymnodinium‐like species from Chinese and Malaysian waters and the Mediterranean Sea were established. All of these strains were examined with light microscopy, scanning electron microscopy and transmission electron microscopy. SSU, LSU and internal transcribed spacers rDNA sequences were obtained. A new genus, Wangodinium, was erected to incorporate strains with a loop‐shaped apical structure complex (ASC) comprising two rows of amphiesmal vesicles, here referred to as a new type of ASC. The chloroplasts of Wangodinium sinense are enveloped by two membranes. Pigment analysis shows that peridinin is the main accessory pigment in W. sinense. Wangodinium differs from other genera mainly in its unique ASC, and additionally differs from Gymnodinium in the absence of nuclear chambers, and from Lepidodinium in the absence of Chl b and nuclear chambers. New morphological information was provided for G. dorsalisulcum and G. impudicum, e.g., a short sulcal intrusion in G. dorsalisulcum; nuclear chambers in G. impudicum and G. dorsalisulcum; and a chloroplast enveloped by two membranes in G. impudicum. Molecular phylogeny was inferred using maximum likelihood and Bayesian inference with independent SSU and LSU rDNA sequences. Our results support the classification of Wangodinium within the Gymnodiniales sensu stricto clade and it is close to Lepidodinium. Our results also support the close relationship among G. dorsalisulcum, G. impudicum, and Barrufeta. Further research is needed to assign these Gymnodinium species to Barrufeta or to erect new genera.     

Yihiella yeosuensis gen. et sp. nov. (suessiaceae,dinophyceae), a novel dinoflagellate isolated from the coastal waters of Korea

A small (7–11 μm long) dinoflagellate with thin amphiesmal plates was isolated into culture from a water sample collected in coastal waters of Yeosu, southern Korea, and examined by LM, SEM, and TEM, and molecular analyses. The hemispheric episome was smaller than the hyposome. The nucleus was oval and situated from the central to the episomal region of the cell. A large yellowish‐brown chloroplast was located at the end of the hyposome, and some small chloroplasts extended into the periphery of the episome. The dinoflagellate had a single elongated apical vesicle (EAV) and a type E eyespot, which are key characteristics of the family Suessiaceae. Unlike other genera in this family, it had two long furrow lines, one on the episome and the other on the hyposome, and encircling the dorsal, and lateral sides of the cell body. The pyrenoid lacked starch sheaths, but tubular invaginations into the pyrenoid matrix from the cytoplasm were observed. In the TEM, the dinoflagellate was observed to have cable‐like structures (CLSs) near the eyespot but so far not observed in other dinoflagellates. The SSU rDNA sequences examined were 1.2%–5.1% different from those of other genera in the family Suessiaceae, whereas the LSU (D1‐D3) rDNA sequences of this dinoflagellate were 15.1%–31.5% different. The dinoflagellate lacked a 51‐bp fragment in domain D2 of the LSU rDNA, but it had an ~100‐bp fragment in domain D2. This feature has been found previously only in the genera Leiocephalium and Polarella, two other genera of the Suessiaceae. The molecular phylogeny and sequence divergence based on SSU, and LSU rDNA indicate that the Korean dinoflagellate holds a taxonomically distinctive position and we consider it to be a new species in a new genus in the family Suessiaceae, named Yihiella yeosuensis gen. et sp. nov.     

Phylogenetic analysis of a free-living strain of Symbiodinium isolated from Jiaozhou Bay, P.R. China

This paper reported the isolation and the phylogenetic analysis of a free-living Gymnodinium-like dinoflagellates (G. sp. (15)) from the sea water collected at Jiaozhou bay, Qingdao, Shandong Province, P.R. China. Phylogenetic reconstruction analysis with Neighbor-Joining (NJ) method using sequences of variable regions (V1+V2+V3) of the small subunit (SSU) rDNA indicated that G. sp. (15) was a Symbiodinium sp., which was closely related to a symbiont of anemones, S. californium, and the free-living strain, Gymnodinium varians. These three strains formed a new clade (which had been designated as clade F) with 100% bootstrap support. Sequence comparison showed that sequences of the internal transcribed spacer (ITS) of these three strains were highly homologous, suggesting that they might belong to one species.     

The parasitic dinoflagellates of marine crustaceans

Parasitic dinoflagellates have recently emerged as significant disease agents of commercially important crustaceans. For example, epizootics of Hematodinium have seriously affected certain crab and lobster fisheries. The parasitic dinoflagellates of crustaceans are, however, relatively unknown. Marine crustaceans are parasitized by two orders of dinoflagellates: the Blastodinida and the Syndinida. Crustaceans are also parasitized by the Paradinida and the Ellobiopsidae, taxa that have close historical ties and possible taxonomic affinities with the dinoflagellates. The taxonomy and life history patterns of the different parasitic species are largely dictated by their host-parasite relationships. For example, sporulation in the blastodinids occurs internally but is completed externally with the expulsion of spores via the anus of the host. The egg-parasitic chytriodinids sporulate externally after destroying their host egg. The tissue-dwelling syndinids have plasmodia that sporulate internally and generally kill their hosts upon the expulsion of the dinospores. Unfortunately, complete life cycles have not been elucidated for any of the parasitic forms, hence characteristics of the life cycles must be applied cautiously to the systematics of the taxa. For example, gamogony and the presence of resting cysts are only known from a few species; they probably occur in most species. Further work on the life cycles of the parasitic dinoflagellates of crustaceans should concentrate on establishing the life cycles of representative species from each order or family. Parasitic dinoflagellates infect copepods, amphipods, mysids, euphausiids, and decapods. Their pathogenicity varies with their invasiveness in the host. The gut-dwelling blastodinids are relatively benign, while the chytriodinids kill their host egg. Members of the pervasive Syndinida and Paradinida are overtly pathogenic and insidiously ramify throughout the hemal sinuses and organs of their hosts. Members of the Ellobiopsidae vary from the commensal Ellobiocystis to the overtly parasitic Thalassomyces. Host castration and feminization are common pathologic results of infection by these parasites. The severity of the castration is dependent upon the invasiveness of the parasitic species and the duration of the infection, while the degree of feminization is related to the stage at which the host acquires the infection. Most of the parasitic dinoflagellates occur in epizootics in their host populations. Recent epizootics of Hematodinium spp. have had severe effects on crustacean fisheries in Alaska, Virginia, and Scotland, and may potentially result in changes to the benthic communities of the hosts. The epizootics are often associated with host-parasite systems that occur in regions with unique hydrological features, such as fjords or poorly draining estuaries with shallow sills. These regions are ideal for the application of a “landscape” ecology approach that could lead to a better understanding of the epizootiology of parasitic dinoflagellates and other marine pathogens.     

Nuclear 28S rDNA phylogeny supports the basal placement of Noctiluca scintillans (Dinophyceae; Noctilucales) in dinoflagellates

Noctiluca scintillans (Macartney) Kofoid et Swezy, 1921 is an unarmoured heterotrophic dinoflagellate with a global distribution, and has been considered as one of the ancestral taxa among dinoflagellates. Recently, 18S rDNA, actin, α-, β-tubulin, and Hsp90-based phylogenies have shown the basal position of the noctilucids. However, the relationships of dinoflagellates in the basal lineages are still controversial. Although the nuclear rDNA (e.g. 18S, ITS-5.8S, and 28S) contains much genetic information, DNA sequences of N. scintillans rDNA molecules were insufficiently characterized as yet. Here the author sequenced a long-range nuclear rDNA, spanning from the 18S to the D5 region of the 28S rDNA, of N. scintillans. The present N. scintillans had a nearly identical genotype (>99.0% similarity) compared to other Noctiluca sequences from different geographic origins. Nucleotide divergence in the partial 28S rDNA was significantly high (p<0.05) as compared to the 18S rDNA, demonstrating that the information from 28S rDNA is more variable. The 28S rDNA phylogeny of 17 selected dinoflagellates, two perkinsids, and two apicomplexans as outgroups showed that N. scintillans and Oxyrrhis marina formed a clade that diverged separately from core dinoflagellates.     

Sinophysis and Pseudophalacroma are distantly related to typical Dinophysoid dinoflagellates (Dinophysales, Dinophyceae)

Dinophysoid dinoflagellates are usually considered a large monophyletic group. Large subunit and small subunit (SSU) rDNA phylogenies suggest a basal position for Amphisoleniaceae (Amphisolenia,Triposolenia) with respect to two sister groups, one containing most Phalacroma species plus Oxyphysis and the other Dinophysis,Ornithocercus, Dinophysoid dinoflagellates are usually considered a large monophyletic group. Large subunit and small subunit (SSU) rDNA phylogenies suggest a basal position for Amphisoleniaceae (Amphisolenia,Triposolenia) with respect to two sister groups, one containing most Phalacroma species plus Oxyphysis and the other Dinophysis,Ornithocercus, Histioneis,Citharistes and some Phalacroma species. We provide here new SSU rDNA sequences of Pseudophalacroma (pelagic) and Sinophysis (the only benthic dinophysoid genus). Molecular phylogenies support that they are very divergent with respect to the main clade of Dinophysales. Additional molecular markers of these two key genera are needed to elucidate the evolutionary relations among the dinophysoid dinoflagellates. Histioneis,Citharistes and some Phalacroma species. We provide here new SSU rDNA sequences of Pseudophalacroma (pelagic) and Sinophysis (the only benthic dinophysoid genus). Molecular phylogenies support that they are very divergent with respect to the main clade of Dinophysales. Additional molecular markers of these two key genera are needed to elucidate the evolutionary relations among the dinophysoid dinoflagellates.     

Redescription and molecular characterization of two Trichodina species (Ciliophora,Peritrichia, Mobilida) from freshwater fish in China

During an investigation of parasitic ciliates in northern China, two Trichodina species, T. acuta Lom, 1970 and T. nigra Lom, 1960, were isolated from the freshwater fish Cyprinus carpio Linnaeus, 1758. The morphology of each species was investigated based on dry silver nitrate-stained specimens. In addition, the molecular phylogeny of each was analyzed based on small subunit ribosomal DNA (SSU rDNA) sequence data. Trichodina acuta can be distinguished from its congeners by the undefined periphery of the central circle, the distinct gap between the rays and the central circle, and the distinctly sickle-shaped blades. Trichodina nigra is a cosmopolitan ciliate and is characterized by its densely linked denticles, broad, rounded spatula-shaped blades, robust central parts, and well developed rays. Phylogenetic analyses revealed that T. acuta and T. nigra nest within different clades, supporting the assertion that the GC content of SSU rDNA sequences could reflect evolutionary relationships among Trichodina species.     

The crustacean parasites <Emphasis Type="Italic">Ellobiopsis</Emphasis> Caullery, 1910 and <Emphasis Type="Italic">Thalassomyces</Emphasis> Niezabitowski, 1913 form a monophyletic divergent clade within the Alveolata

The Ellobiopsidae are enigmatic parasites of crustaceans that have been grouped together exclusively on the basis of morphological similarities. Ultrastructural studies have revealed their affiliation within the alveolates, which was confirmed by the phylogenetic analysis of the ribosomal RNA gene (SSU rDNA) sequences of two species of Thalassomyces Niezabitowski, 1913. However, their precise systematic position within this group remains unresolved, since they could not be definitively allied with any particular alveolate group. To better determine the systematic position of ellobiopsids by molecular phylogeny, we sequenced the SSU rDNA from the type-species of the Ellobiopsidae, Ellobiopsis chattoni Caullery, 1910. We found E. chattoni infecting various copepod hosts, Acartia clausi Giesbrecht, Centropages typicus Kröyer and Clausocalanus sp., in the Bay of Marseille, NW Mediterranean Sea, which allowed us to study several stages of the parasite development. A single unicellular multinucleate specimen provided two different sequences of the SSU rDNA gene, indicating the existence of polymorphism at this locus within single individuals. Ellobiopsis Caullery, 1910 and Thalassomyces formed a very divergent and well-supported clade in phylogenetic analyses. This clade appears to be more closely related to the dinoflagellates (including the Syndiniales/Marine Alveolate Group II and the Dinokaryota) and Marine Alveolate Group I than to the other alveolates (Ciliophora, Perkinsozoa and Apicomplexa).