21 results on '"Wakeman, Kevin C."'
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2. Taxonomic study of the polyphyletic Dudresnaya (Dumontiaceae, Florideophyceae) with descriptions of Dudresnaya ryukyuensis sp. nov. and two new genera, Himehibirhodia and Nudresdaya.
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Hoshino, Masakazu, Wakeman, Kevin C., Kato, Aki, Kitayama, Taiju, Sherwood, Alison R., Uwai, Shinya, and Kogame, Kazuhiro
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MOLECULAR phylogeny ,GIGARTINALES ,LIFE cycles (Biology) - Abstract
SUMMARY: The red algal genus Dudresnaya (Dumontiaceae, Gigartinales) has traditionally been a morphologically well‐defined taxon, but its molecular phylogeny has rarely been studied. To examine the phylogenetic relationships among Dudresnaya species, we generated new partial sequences of mitochondrial cox1, chloroplast rbcL and nuclear 28S rRNA genes from an undescribed Dudresnaya species from Okinawa Island, Japan, alongside five additional described species. Our phylogenetic analyses show that Dudresnaya is genetically diverse and polyphyletic. Based on molecular phylogeny and morphological data, we describe the Okinawan Dudresnaya as a new species, Dudresnaya ryukyuensis, and transferred Dudresnaya minima and Dudresnaya littleri, which were phylogenetically and morphologically distinct from the genuine Dudresnaya, to the new genera Himehibirhodia and Nudresdaya, respectively. Our phylogenetic analyses also showed that the Dumontiaceae is not a monophyletic group including the Gainiaceae and Rhizophyllidaceae (DGR complex). Considering that the DGR complex exhibits female reproductive structures and their post‐fertilization development that are similar to each other, the DGR complex appears to be recognized as the Dumontiaceae sensu lato. [ABSTRACT FROM AUTHOR]
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- 2024
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3. Coral geometry and why it matters.
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Kahng, Samuel E., Odle, Eric, and Wakeman, Kevin C.
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LIFE history theory ,CORAL reef restoration ,CORAL reefs & islands ,CORALS ,GEOMETRIC shapes ,BIOMASS production - Abstract
Clonal organisms like reef building corals exhibit a wide variety of colony morphologies and geometric shapes which can have many physiological and ecological implications. Colony geometry can dictate the relationship between dimensions of volume, surface area, and length, and their associated growth parameters. For calcifying organisms, there is the added dimension of two distinct components of growth, biomass production and calcification. For reef building coral, basic geometric shapes can be used to model the inherent mathematical relationships between various growth parameters and how colony geometry determines which relationships are size-dependent or size-independent. Coral linear extension rates have traditionally been assumed to be size-independent. However, even with a constant calcification rate, extension rates can vary as a function of colony size by virtue of its geometry. Whether the ratio between mass and surface area remains constant or changes with colony size is the determining factor. For some geometric shapes, the coupling of biomass production (proportional to surface area productivity) and calcification (proportional to volume) can cause one aspect of growth to geometrically constrain the other. The nature of this relationship contributes to a species' life history strategy and has important ecological implications. At one extreme, thin diameter branching corals can maximize growth in surface area and resource acquisition potential, but this geometry requires high biomass production to cover the fast growth in surface area. At the other extreme, growth in large, hemispheroidal corals can be constrained by calcification. These corals grow surface area relatively slowly, thereby retaining a surplus capacity for biomass production which can be allocated towards other anabolic processes. For hemispheroidal corals, the rate of surface area growth rapidly decreases as colony size increases. This ontogenetic relationship underlies the success of microfragmentation used to accelerate restoration of coral cover. However, ontogenetic changes in surface area productivity only applies to certain coral geometries where surface area to volume ratios decrease with colony size. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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4. Biodiversity of symbiotic microalgae associated with meiofaunal marine acoels in Southern Japan.
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Siratee Riewluang and Wakeman, Kevin C.
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MICROALGAE ,BIODIVERSITY ,DINOFLAGELLATES ,SYMBIODINIUM ,SPECIES ,DUNALIELLA - Abstract
Acoels in the family Convolutidae are commonly found with microalgal symbionts. Convolutids can host green algal Tetraselmis and dinoflagellates within the family Symbiodiniaceae and the genus Amphidinium. The diversity of these microalgae has not been well surveyed. In this study, we used PCR and culture techniques to demonstrate the biodiversity of Tetraselmis and dinoflagellates in symbiosis with meiofaunal acoels. Here, 66 acoels were collected from seven localities around Okinawa, Ishigaki, and Kochi, Japan. While convolutids were heavily represented in this sampling, some acoels formed a clade outside Convolutidae and are potentially a new family of acoels harboring symbiotic microalgae. From the acoels collected, a total of 32 Tetraselmis and 26 Symbiodiniaceae cultures were established. Molecular phylogenies were constructed from cultured material (and from total host DNA) using the 18S rRNA gene (Tetraselmis) and 28S rRNA gene (dinoflagellates). The majority of Tetraselmis sequences grouped within the T. astigmatica clade but strains closely related to T. convolutae, T. marina, and T. gracilis were also observed. This is the first report of Tetraselmis species, other than T. convolutae, naturally associating with acoels. For dinoflagellates, members of Cladocopium and Miliolidium were observed, but most Symbiodiniaceae sequences formed clusters within Symbiodinium, grouping with S. natans, or sister to S. tridacnidorum. Several new Symbiodinium sequences from this study may represent novel species. This is the first molecular record of Miliolidium and Symbiodinium from acoels. Microalgal strains from this study will provide a necessary framework for future taxonomic studies and research on symbiotic relationships between acoels and microalgae. [ABSTRACT FROM AUTHOR]
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- 2023
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5. Reconstruction of Plastid Proteomes of Apicomplexans and Close Relatives Reveals the Major Evolutionary Outcomes of Cryptic Plastids.
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Mathur, Varsha, Salomaki, Eric D, Wakeman, Kevin C, Na, Ina, Kwong, Waldan K, Kolisko, Martin, and Keeling, Patrick J
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PLASTIDS ,APICOMPLEXA ,RELATIVES ,ORGANELLES ,TRANSCRIPTOMES - Abstract
Apicomplexans and related lineages comprise many obligate symbionts of animals; some of which cause notorious diseases such as malaria. They evolved from photosynthetic ancestors and transitioned into a symbiotic lifestyle several times, giving rise to species with diverse non-photosynthetic plastids. Here, we sought to reconstruct the evolution of the cryptic plastids in the apicomplexans, chrompodellids, and squirmids (ACS clade) by generating five new single-cell transcriptomes from understudied gregarine lineages, constructing a robust phylogenomic tree incorporating all ACS clade sequencing datasets available, and using these to examine in detail, the evolutionary distribution of all 162 proteins recently shown to be in the apicoplast by spatial proteomics in Toxoplasma. This expanded homology-based reconstruction of plastid proteins found in the ACS clade confirms earlier work showing convergence in the overall metabolic pathways retained once photosynthesis is lost, but also reveals differences in the degrees of plastid reduction in specific lineages. We show that the loss of the plastid genome is common and unexpectedly find many lineage- and species-specific plastid proteins, suggesting the presence of evolutionary innovations and neofunctionalizations that may confer new functional and metabolic capabilities that are yet to be discovered in these enigmatic organelles. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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6. Phylogeny of Amphidinium (Dinophyceae) from Guam and Okinawa, with descriptions of A. pagoense sp. nov. and A. uduigamense sp. nov.
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Phua, Yong Heng, Husnik, Filip, Lemer, Sarah, and Wakeman, Kevin C.
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PHYLOGENY ,DINOFLAGELLATES ,CELL morphology ,CELL size ,ELECTRON microscopy ,MARINE toxins - Abstract
Marine benthic dinoflagellates within the genus Amphidinium were isolated from Guam and Okinawa. Isolated strains were identified to species-level using phylogenetic analyses of 28S rRNA and ITS-5.8S rRNA genes as well as microscopy. Of the six isolated strains, two were new species: A. pagoense sp. nov. and A. uduigamense sp. nov. Other isolates included strains of A. massartii and A. operculatum from Guam, and two strains of A. operculatum from Okinawa. Both new species were described using light and electron microscopy (SEM and TEM). The combination of characteristics that make A. pagoense sp. nov. unique includes a pair of centrally-located pyrenoids, variable cell shape, absence of scales and a long, curved ventral ridge. For A. uduigamense sp. nov., a combination of several morphological features distinguishes it from other species. These include a constriction near the anterior of the hypocone, two centrally located pyrenoids, a longitudinal flagellum inserted in the posterior one-third of the cell, cell size, cell division in the motile stage and the absence of scales. Toxicity was confirmed in these two novel species by testing methanol extracts in an Artemia bioassay. Previously unrecorded ITS rRNA gene sequences from A. operculatum were also sequenced from both locations. Species identified and newly described in this study expand the taxonomic knowledge of Amphidinium in the Pacific. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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7. Molecular phylogeny and ultrastructure of two novel parasitic dinoflagellates, Haplozoon gracile sp. nov. and H. pugnus sp. nov.
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Yamamoto, Mana, Wakeman, Kevin C., Tomioka, Shinri, and Horiguchi, Takeo
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MOLECULAR phylogeny ,TRANSMISSION electron microscopy ,DINOFLAGELLATES ,CHLOROPLAST DNA - Abstract
This study describes two novel parasitic dinoflagellates: Haplozoon gracile sp. nov. isolated from a bamboo worm (Maldanidae), 'cf. Petaloclymene sp.' sensu Kobayashi et al. 2018; and, H. pugnus sp. nov. isolated from Nicomache sp. and Nicomache personata (Maldanidae). Trophonts (feeding stages) were observed with light, scanning, and transmission electron microscopy. Molecular phylogenetic analyses were performed based on 18S rDNA. COI sequences were obtained for host organisms. Trophonts of H. gracile were linear (single longitudinal row) and relatively slender with a mean length of 190 μm, and consisted of a long and narrow trophocyte, rectangular gonocytes (mean width = 10 μm), and slightly rounded sporocytes. Trophonts of H. pugnus were pectinate (1–8 rows of sporocytes in one plane), with a mean length of 179 μm, consisting of a bulbous trophocyte, rectangular gonocytes (mean width = 25 μm), and rounded sporocytes. The body of both species was covered with many depressions that overlaid the amphiesmal vesicles. TEM observations of trophocytes in H. gracile revealed a stylet with a central dense core and rich mitochondria subtending the amphiesma. Furthermore, amphiesmal vesicles appeared to contain thecal plates in both species. Phylogenetic analyses generally resolved a Haplozoon clade, and H. gracile and H. pugnus were clearly distinguished from other species for which molecular data are available. Based on the morphological and host comparisons with all described species and their molecular phylogeny, we conclude that these two isolates are new species of Haplozoon, H. gracile sp. nov. and H. pugnus sp. nov. [ABSTRACT FROM AUTHOR]
- Published
- 2020
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8. Validation of a universal set of primers to study animal‐associated microeukaryotic communities.
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del Campo, Javier, Pons, Maria J., Herranz, Maria, Wakeman, Kevin C., del Valle, Juana, Vermeij, Mark J. A., Leander, Brian S., and Keeling, Patrick J.
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RIBOSOMAL RNA ,DEEP-sea corals ,CTENOPHORA ,COMMUNITIES ,SPONGES (Invertebrates) ,CNIDARIA - Abstract
Summary: The application of metabarcoding to study animal‐associated microeukaryotes has been restricted because the universal barcode used to study microeukaryotic ecology and distribution in the environment, the Small Subunit of the Ribosomal RNA gene (18S rRNA), is also present in the host. As a result, when host‐associated microbial eukaryotes are analysed by metabarcoding, the reads tend to be dominated by host sequences. We have done an in silico validation against the SILVA 18S rRNA database of a non‐metazoan primer set (primers that are biased against the metazoan 18S rRNA) that recovers only 2.6% of all the metazoan sequences, while recovering most of the other eukaryotes (80.4%). Among metazoans, the non‐metazoan primers are predicted to amplify 74% of Porifera sequences, 4% of Ctenophora, and 15% of Cnidaria, while amplifying almost no sequences within Bilateria. In vivo, these non‐metazoan primers reduce significantly the animal signal from coral and human samples, and when compared against universal primers provide at worst a 2‐fold decrease in the number of metazoan reads and at best a 2800‐fold decrease. This easy, inexpensive, and near‐universal method for the study of animal‐associated microeukaryotes diversity will contribute to a better understanding of the microbiome. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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9. Dinoflagellate nucleus contains an extensive endomembrane network, the nuclear net.
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Gavelis, Gregory S., Herranz, Maria, Wakeman, Kevin C., Ripken, Christina, Mitarai, Satoshi, Gile, Gillian H., Keeling, Patrick J., and Leander, Brian S.
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- 2019
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10. Molecular phylogeny of the benthic dinoflagellate Cabra matta (Dinophyceae) from Okinawa, Japan.
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Yamaguchi, Aika, Wakeman, Kevin C., Hoppenrath, Mona, Horiguchi, Takeo, and Kawai, Hiroshi
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DINOFLAGELLATES ,MORPHOLOGY ,TAXONOMY ,MOLECULAR phylogeny ,CELL populations - Abstract
Cabra is a genus of marine heterotrophic thecate dinoflagellates with a peculiar cell shape and thecal plate tabulation. Previous studies suggested it was related to the benthic genus Roscoffia based on morphological features. A previous molecular phylogenetic study using 18S rDNA showed that Roscoffia capitata and members of the family Podolampadaceae formed a well-supported monophyletic group; however, the classification of Cabra remains uncertain. In this study, the first molecular phylogenetic analysis based on 18S rDNA sequence for the genus was performed using specimens of Cabra matta collected in Okinawa, Japan. Molecular phylogeny showed that C. matta formed a clade with R. capitata and the planktonic oceanic members of Podolampadaceae including Podolampas spp. and Blepharocysta sp. This result supported previous studies that inferred the close affinity between Cabra, podolampadaceans and R. capitata based on a very narrow and long 1′ plate, and the diminutive 2′ and 3′ plates, the larger precingular plates, smaller apical plates, the presence of three cingular plates, the hypothecal plate pattern of five postcingular plates and one antapical plate. In contrast, there are clear morphological differences between the planktonic podolampadaceans and the benthic genera Roscoffia and Cabra: the planktonic members have a cryptic cingulum and lack an apparent sulcus, while the benthic members have an apparent cingulum and sulcus. Molecular phylogeny in the present study did not resolve the evolutionary branching order for Cabra, Roscoffia, Podolampas and Blepharocysta. [ABSTRACT FROM AUTHOR]
- Published
- 2018
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11. Morphology and molecular phylogeny of the marine gregarine parasite Selenidium oshoroense n. sp. (Gregarina, Apicomplexa) isolated from a Northwest Pacific Hydroides ezoensis Okuda 1934 (Serpulidae, Polychaeta).
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Wakeman, Kevin C. and Horiguchi, Takeo
- Abstract
In this study, we describe a novel marine gregarine parasite, Selenidium oshoroense n. sp., isolated from Hydroides ezoensis Okuda 1934 (Serpulidae, Polychaeta). Trophozoites (feeding stages) of S. oshoroense n. sp. were isolated from the gut of H. ezoensis collected from the intertidal shore near Oshoro, Hokkaido, Japan, and prepared for analysis with scanning and transmission electron microscopy (SEM and TEM), and molecular phylogenetic analysis using 18S rDNA. Trophozoites of S. oshoroense n. sp. were, on average, 120 μm long and 13 μm wide. Observation of the cells under SEM and TEM revealed 23 longitudinally running epicytic folds on the surface of the cells. Peduncles, multimembrane-bound whorls, and inclusions were also observed and were indicative of surface-mediated nutrition. Myzocytotic feeding at the apical end of the cell was also indicated in sections of host gut tissue that were viewed under TEM, suggesting that myzocytosis could be a shared feature among this clade of Selenidium from tube-forming polychaetes. Molecular phylogenetic analysis of the 18S rDNA grouped S. oshoroense n. sp. within a clade of Selenidium from tube-forming polychaetes, sister to S. serpulae. The two 18S rDNA sequences generated from separate isolates of S. oshoroense n. sp. had a similarity of 0.997, but were 0.965 and 0.966 similar to S. serpulae. S. oshoroense n. sp. was differentiated from, S. serpulae, based on the absence of transverse striations on the surface of the epicytic folds and difference in ecological niche (host). Morphological differences were supported in phylogenetic analysis which grouped S. oshoroense n. sp. isolates, to the exclusion of S. serpulae. [ABSTRACT FROM AUTHOR]
- Published
- 2018
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12. Molecular Phylogenetic Positions and Ultrastructure of Marine Gregarines (Apicomplexa) Cuspisella ishikariensis n. gen., n. sp. and Loxomorpha cf. harmothoe from Western Pacific scaleworms (Polynoidae).
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Iritani, Davis, Horiguchi, Takeo, and Wakeman, Kevin C.
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GREGARINES ,MOLECULAR phylogeny ,PARASITES ,UNICELLULAR organisms ,APICOMPLEXA ,POLYNOIDAE ,ULTRASTRUCTURE (Biology) - Abstract
Abstract: Marine gregarines are unicellular parasites of invertebrates commonly found infecting the intestine and coelomic spaces of their hosts. Situated at the base of the apicomplexan tree, marine gregarines offer an opportunity to explore the earliest stages of apicomplexan evolution. Classification of marine gregarines is often based on the morphological traits of the conspicuous feeding stages (trophozoites) in combination with host affiliation and molecular phylogenetic data. Morphological characters of other life stages such as the spore are also used to inform taxonomy when such stages can be found. The reconstruction of gregarine evolutionary history is challenging, due to high levels of intraspecific variation of morphological characters combined with relatively few traits that are taxonomically unambiguous. The current study combined morphological data with a phylogenetic analysis of small subunit rDNA sequences to describe and establish a new genus and species (Cuspisella ishikariensis n. gen., n. sp.) of marine gregarine isolated from the intestine of a polynoid host (Lepidonotus helotypus) collected from Hokkaido, Japan. This new species possesses a set of unusual morphological traits including a spiked attachment apparatus and sits on a long branch on the molecular phylogeny. Furthermore, this study establishes a molecular phylogenetic position for Loxomorpha cf. harmothoe, a previously described marine gregarine, and reveals a new group of gregarines that infect polynoid hosts. [ABSTRACT FROM AUTHOR]
- Published
- 2018
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13. Molecular Phylogeny and Surface Morphology of <italic>Thiriotia hyperdolphinae</italic> n. sp. and <italic>Cephaloidophora oradareae</italic> n. sp. (Gregarinasina, Apicomplexa) Isolated from a Deep Sea <italic>Oradarea</italic> sp. (Amphipoda) in the West Pacific
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Wakeman, Kevin C., Yabuki, Akinori, Fujikura, Katsunori, Tomikawa, Ko, and Horiguchi, Takeo
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MOLECULAR phylogeny ,GREGARINES ,CRUSTACEA ,AMPHIPODA ,RECOMBINANT DNA - Abstract
Abstract: In an effort to broaden our understanding of the biodiversity and distribution of gregarines infecting crustaceans, this study describes two new species of gregarines,
Thiriotia hyperdolphinae n. sp. andCephaloidophora oradareae n. sp., parasitizing a deep sea amphipod (Oradarea sp.). Amphipods were collected using the ROV Hyper‐Dolphin at a depth of 855 m while on a cruise in Sagami Bay, Japan. Gregarine trophozoites and gamonts were isolated from the gut of the amphipod and studied with light and scanning electron microscopy, and phylogenetic analysis of 18S rDNA.Thiriotia hyperdolphinae n. sp. was distinguished from existing species based on morphology, phylogenetic position, as well as host niche and geographic locality.Cephaloidophora oradareae n. sp. distinguished itself from existingCephaloidophora , based on a difference in host (Oradarea sp.), geographic location, and to a certain extent morphology. We established this latter new species with the understanding that a more comprehensive examination of diversity at the molecular level is necessary withinCephaloidophora . Results from the 18S rDNA molecular phylogeny showed thatT. hyperdolphinae n. sp. was positioned within a clade consisting ofThiriotia spp., whileC. oradareae n. sp. grouped within the Cephaloidophoridae. Still, supplemental genetic information from gregarines infecting crustaceans will be needed to better understand relationships within this group of apicomplexans. [ABSTRACT FROM AUTHOR]- Published
- 2018
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14. Ultrastructure of the marine benthic dinoflagellate Plagiodinium belizeanum (Dinophyceae) from the southeast Pacific island of Okinawa, Japan.
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WAKEMAN, KEVIN C., HOPPENRATH, MONA, AIKA YAMAGUCHI, GAVELIS, GREG S., LEANDER, BRIAN S., and HISAYOSHI NOZAKI
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DINOFLAGELLATES ,ULTRASTRUCTURE (Biology) ,SCANNING electron microscopy ,TRANSMISSION electron microscopy ,NUCLEOTIDE sequencing ,RECOMBINANT DNA ,CLASSIFICATION of algae - Abstract
We isolated Plagiodinium belizeanum into clonal culture from the Pacific island of Okinawa (Japan) and characterized it using a combination of light microscopy, scanning electron microscopy, transmission electron microscopy and 18S/28S ribosomal (r) gene sequences. Although molecular phylogenetic analyses of 18S rDNA and 28S rDNA sequences were unable to resolve the phylogenetic position of P. belizeanum within dinoflagellates, the ultrastructural data provided some new traits for the species. For instance, double-membrane-bound vesicles, distinct from the mitochondria, were interpreted as autolysosomes containing electron-dense virus particles. The thecal plate pattern was Po 1' 0a 5''5(6)C 4S 5'p 1', which is slightly different from the original description in having an additional epithecal plate and four sulcal plates. The laterally flattened cells were 22-34 μm long, 11-13 μm deep, and 15-18 μm wide and contained a peridinin-type plastid with lobes radiating from a central pyrenoid that lacked starch sheaths and was traversed by stacks of thylakoids. This isolate represents the first record of the species in Japan, and the new ultrastructural and DNA sequence data were used to emend the species description. [ABSTRACT FROM AUTHOR]
- Published
- 2018
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15. Description of Ganymedes yurii sp. n. (Ganymedidae), a New Gregarine Species from the Antarctic Amphipod Gondogeneia sp. (Crustacea).
- Author
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Diakin, Andrei, Wakeman, Kevin C., and Valigurová, Andrea
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APICOMPLEXA ,AMPHIPODA ,MOLECULAR phylogeny ,CRUSTACEA - Abstract
A novel species of aseptate eugregarine, Ganymedes yurii sp. n., is described using microscopic and molecular approaches. It inhabits the intestine of Gondogeneia sp., a benthic amphipod found along the shore of James Ross Island, Weddell Sea, Antarctica. The prevalence of the infection was very low and only a few caudo-frontal syzygies were found. Morphologically, the new species is close to a previously described amphipod gregarine, Ganymedes themistos, albeit with several dissimilarities in the structure of the contact zone between syzygy partners, as well as other characteristics. Phylogenetic analysis of the 18S rDNA from G. yurii supported a close relationship between these species. These two species were grouped with other gregarines isolated from crustaceans hosts (Cephaloidophoroidea); however, statistical support throughout the clade of Cephaloidophoroidea gregarines was minimal using the available dataset. [ABSTRACT FROM AUTHOR]
- Published
- 2017
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16. Molecular Phylogeny of the Marine Planktonic Dinoflagellate Oxytoxum and Corythodinium (Peridiniales, Dinophyceae).
- Author
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GÓMEZ, Fernando, WAKEMAN, Kevin C., YAMAGUCHI, Aika, and NOZAKI, Hisayoshi
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MOLECULAR phylogeny ,DINOFLAGELLATES ,PHYTOFLAGELLATES ,SPECIES ,BIOLOGICAL classification - Abstract
The dinoflagellate genera Oxytoxum and Corythodinium that account for more than fifty species are widespread in warm oceans. These genera have been considered synonyms and thecal plate designations varied among authors. Several planktonic and sand-dwelling genera have been placed within the Oxytoxaceae. We obtained the first molecular data based on small subunit (SSU) rRNA gene sequences of Oxytoxum and Corythodinium, including the type species (O. scolopax and C. tessellatum) and C. frenguellii and C. cristatum. The three species of Corythodinium branched together a strong support [bootstrap (BP) of 98%]. This formed a sister clade with moderate support (BP 75%) with O. scolopax that supported the generic split. Oxytoxaceae should exclusively remain for Oxytoxum and Corythodinium, as an independent group, unrelated to any other known dinoflagellate. Oxytoxum was characterized by spindle-shaped cells with an anterior narrow epitheca, an apical spine and little cingular displacement. Corythodinium exhibits relatively broad cell shapes, with wider epitheca and greater cingular displacement, and an obovate or pentangular anterior sulcal plate that noticeably indented the epitheca. This suggested the need of new combinations for species that were described as Oxytoxum and possessed the characteristics of Corythodinium. [ABSTRACT FROM AUTHOR]
- Published
- 2016
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17. Molecular Phylogeny and Ultrastructure of Caliculium glossobalani n. gen. et sp. (Apicomplexa) from a Pacific Glossobalanus minutus (Hemichordata) Confounds the Relationships Between Marine and Terrestrial Gregarines.
- Author
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Wakeman, Kevin C., Reimer, James D., Jenke‐Kodama, Holger, and Leander, Brian S.
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MOLECULAR phylogeny ,ULTRASTRUCTURE (Biology) ,GREGARINES ,APICOMPLEXA ,MORPHOLOGY of protozoa ,TROPHOZOITES ,HEMICHORDATA - Abstract
Gregarines are a diverse group of apicomplexan parasites with a conspicuous extracellular feeding stage, called a 'trophozoite', that infects the intestines and other body cavities of invertebrate hosts. Although the morphology of trophozoites is very diverse in gregarines as a whole, high degrees of intraspecific variation combined with relatively low degrees of interspecific variation make the delimitation of different species based on trophozoite morphology observed with light microscopy difficult. The coupling of molecular phylogenetic data with comparative morphology has shed considerable light onto the boundaries and interrelationships of different gregarine species. In this study, we isolated a novel marine gregarine from the hepatic region of a Pacific representative of the hemichordate Glossobalanus minutus, and report the first ultrastructural and molecular data from any gregarine infecting this distinctive group of hosts. Molecular phylogenetic analyses of an SSU r DNA sequence derived from two single-cell isolates of this marine gregarine demonstrated a strong and unexpected affiliation with a clade of terrestrial gregarines (e.g. Gregarina). This molecular phylogenetic data combined with a comparison of the morphological features in previous reports of gregarines collected from Atlantic representatives of G. minutus justified the establishment of a new binomial for the new isolate, namely Caliculium glossobalani n. gen. et sp. The molecular phylogenetic analyses demonstrated a clade of terrestrial gregarines associated with a sequence acquired from a marine species, which suggest that different groups of terrestrial/freshwater gregarines evolved independently from marine ancestors. [ABSTRACT FROM AUTHOR]
- Published
- 2014
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18. Discovery of a Diverse Clade of Gregarine Apicomplexans (Apicomplexa: Eugregarinorida) from Pacific Eunicid and Onuphid Polychaetes, Including Descriptions of Paralecudina n. gen., Trichotokara japonica n. sp., and T. eunicae n. sp.
- Author
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Rueckert, Sonja, Wakeman, Kevin C., and Leander, Brian S.
- Subjects
GREGARINES ,TROPHOZOITES ,APICOMPLEXA - Abstract
Marine gregarines are poorly understood apicomplexan parasites with large trophozoites that inhabit the body cavities of marine invertebrates. Two novel species of gregarines were discovered in polychaete hosts collected in Canada and Japan. The trophozoites of Trichotokara japonica n. sp. were oval to rhomboidal shaped, and covered with longitudinal epicytic folds with a density of six to eight folds/micron. The nucleus was situated in the middle of the cell, and the mucron was elongated and covered with hair-like projections; antler-like projections also extended from the anterior tip of the mucron. The distinctively large trophozoites of Trichotokara eunicae n. sp. lacked an elongated mucron and had a tadpole-like cell shape consisting of a bulbous anterior region and a tapered tail-like posterior region. The cell surface was covered with longitudinal epicytic folds with a density of three to five folds/micron. Small subunit ( SSU) r DNA sequences of both species were very divergent and formed a strongly supported clade with the recently described species Trichotokara nothriae and an environmental sequence (). This phylogenetic context combined with the morphological features of T. eunicae n. sp. required us to amend the description for Trichotokara. The sister clade to the Trichotokara clade consisted of environmental sequences and Lecudina polymorpha, which also possesses densely packed epicyctic folds (3-5 folds/micron) and a prominently elongated mucron. This improved morphological and molecular phylogenetic context justified the establishment of Paralecudina (ex. Lecudina) polymorpha n. gen. et comb. [ABSTRACT FROM AUTHOR]
- Published
- 2013
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19. Molecular Phylogeny of Pacific Archigregarines (Apicomplexa), Including Descriptions of Veloxidium leptosynaptae n. gen., n. sp., from the Sea Cucumber Leptosynapta clarki (Echinodermata), and Two New Species of Selenidium.
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Wakeman, Kevin C. and Leander, Brian S.
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MOLECULAR phylogeny ,APICOMPLEXA ,ECHINODERMATA ,GREGARINES ,BIOLOGICAL evolution ,MARINE invertebrates ,LECUDINIDAE - Abstract
Although archigregarines are poorly understood intestinal parasites of marine invertebrates, they are critical for understanding the earliest stages in the evolution of the Apicomplexa. Previous studies suggest that archigregarines are a paraphyletic stem group from which other lineages of gregarines, and possibly all other groups of apicomplexans, evolved. However, substantiating this inference is difficult because molecular phylogenetic data from archigregarines, in particular, and other gregarines, in general, are severely limited. In an attempt to help fill gaps in our knowledge of archigregarine diversity and phylogeny, we set out to discover and characterize novel lineages of archigregarines with high-resolution light and scanning electron microscopy and analyses of small subunit ( SSU) rDNA sequences derived from single-cell ( SC) PCR techniques. Here, we describe two novel species of Selenidium, namely Selenidium idanthyrsae n. sp. and S. boccardiellae n. sp., and demonstrate the surface morphology and molecular phylogenetic position of the previously reported species S. cf. mesnili. We also describe a novel genus of archigregarine, Veloxidium leptosynaptae n. gen., n. sp., which branches with an environmental sequence and, together, forms the nearest sister lineage to a diverse clade of marine eugregarines (i.e. lecudinids and urosporids). This molecular phylogenetic result is consistent with the hypothesis that archigregarines are deeply paraphyletic within apicomplexans, and suggests that convergent evolution played an important role in shaping the diversity of eugregarine trophozoites. [ABSTRACT FROM AUTHOR]
- Published
- 2012
- Full Text
- View/download PDF
20. Molecular Phylogenetic Positions of Two New Marine Gregarines (Apicomplexa)—<italic>Paralecudina anankea</italic> n. sp. and <italic>Lecudina caspera</italic> n. sp.—from the Intestine of <italic>Lumbrineris inflata</italic> (Polychaeta) Show Patterns of Co‐evolution
- Author
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Iritani, Davis, Wakeman, Kevin C., and Leander, Brian S.
- Subjects
MOLECULAR phylogeny ,GREGARINES ,TROPHOZOITES ,SMALL subunit processomes ,RECOMBINANT DNA - Abstract
Abstract: Gregarine apicomplexans are unicellular parasites commonly found in the intestines and coeloms of invertebrate hosts. Traits associated with the conspicuous feeding stage of gregarines, known as the trophozoite, have been used in combination with molecular phylogenetic data for species delimitation and the reconstruction of evolutionary history. Trophozoite morphology alone is often inadequate for inferring phylogenetic relationships and delimiting species due to frequent cases of high intraspecific variation combined with relatively low interspecific variation. The current study combined morphological data with small subunit (SSU) rDNA sequences to describe and establish two novel marine gregarine species isolated from the intestine of a polychaete host
Lumbrineris inflata collected in British Columbia (Canada):Paralecudina anankea n. sp. andLecudina caspera n. sp. The sister species to the host isLumbrineris japonica , which can be found on the opposite side of the Pacific Ocean (Japan) and contains two different species of gregarine parasites:Paralecudina polymorpha andLecudina longissima . Molecular phylogenetic analyses placedP. anankea n. sp. as the sister species toP. polymorpha andL. caspera n. sp. as the sister species toL. longissima . This phylogenetic pattern demonstrates a co‐evolutionary history whereby speciation of the host (Lumbrineris ) corresponds with simultaneous speciation of the two different lineages of intestinal gregarines (Paralecudina andLecudina ). [ABSTRACT FROM AUTHOR]- Published
- 2018
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- View/download PDF
21. Molecular Phylogeny of Marine Gregarine Parasites (Apicomplexa) from Tube-forming Polychaetes (Sabellariidae, Cirratulidae and Serpulidae), Including Descriptions of Two New Species of Selenidium.
- Author
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Wakeman, Kevin C. and Leander, Brian S.
- Subjects
GREGARINES ,APICOMPLEXA ,TROPHOZOITES ,SERPULIDAE ,CIRRATULIDA ,PARASITES - Abstract
Selenidium is a genus of gregarine parasites that infect the intestines of marine invertebrates and have morphological, ecological, and motility traits inferred to reflect the early evolutionary history of apicomplexans. Because the overall diversity and phylogenetic position(s) of these species remain poorly understood, we performed a species discovery survey of Selenidium from tube-forming polychaetes. This survey uncovered five different morphotypes of trophozoites (feeding stages) living within the intestines of three different polychaete hosts. We acquired small subunit (SSU) rDNA sequences from single-cell (trophozoite) isolates, representing all five morphotypes that were also imaged with light and scanning electron microscopy. The combination of molecular, ecological, and morphological data provided evidence for four novel species of Selenidium, two of which were established in this study: Selenidium neosabellariae n. sp. and Selenidium sensimae n. sp. The trophozoites of these species differed from one another in the overall shape of the cell, the specific shape of the posterior end, the number and form of longitudinal striations, the presence/absence of transverse striations, and the position and shape of the nucleus. A fifth morphotype of Selenidium, isolated from the tube worm Dodecaceria concharum, was inferred to have been previously described as Selenidium cf. echinatum, based on general trophozoite morphology and host association. Phylogenetic analyses of the SSU rDNA sequences resulted in a robust clade of Selenidium species collected from tube-forming polychaetes, consisting of the two new species, the two additional morphotypes, S. cf. echinatum, and four previously described species ( Selenidium serpulae, Selenidium boccardiellae, Selenidium idanthyrsae, and Selenidium cf. mesnili). Genetic distances between the SSU rDNA sequences in this clade distinguished closely related and potential cryptic species of Selenidium that were otherwise very similar in trophozoite morphology. [ABSTRACT FROM AUTHOR]
- Published
- 2013
- Full Text
- View/download PDF
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