This Article Appeared in a Journal Published by Elsevier. the Attached

This Article Appeared in a Journal Published by Elsevier. the Attached

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Authors requiring further information regarding Elsevier’s archiving and manuscript policies are encouraged to visit: http://www.elsevier.com/copyright Author's personal copy Protist, Vol. 163, 306–323, March 2012 http://www.elsevier.de/protis Published online date 3 November 2011 ORIGINAL PAPER Morphology, Ultrastructure and Life Cycle of Vitrella brassicaformis n. sp., n. gen., a Novel Chromerid from the Great Barrier Reef a,b,c,1 a,d b,c a Miroslav Oborník , David Modry´ , Martin Lukesˇ , Eva Cernotíková-Stˇ ríbrnᡠ, b a b,c a Jaromír Cihlárˇ , Martina Tesarovᡠ, Eva Kotabová , Marie Vancová , b,c a,b,1 Ondrejˇ Prásilˇ , and Julius Lukesˇ a ˇ Biology Centre, Institute of Parasitology, Czech Academy of Sciences, Ceské Budejovice,ˇ Czech Republic b ˇ University of South Bohemia, Faculty of Science, Ceské Budejovice,ˇ Czech Republic c Institute of Microbiology, Czech Academy of Sciences, Treboˇ n,ˇ Czech Republic d Institute of Pathology and Parasitology, University of Veterinary and Pharmaceutical Sciences, Brno, Czech Republic Submitted March 16, 2011; Accepted September 15, 2011 Monitoring Editor: Barry S. C. Leadbeater Chromerida are photoautotrophic alveolates so far only isolated from corals in Australia. It has been shown that these secondary plastid-containing algae are closely related to apicomplexan parasites and share various morphological and molecular characters with both Apicomplexa and Dinophyta. So far, the only known representative of the phylum was Chromera velia. Here we provide a formal description of another chromerid, Vitrella brassicaformis gen. et sp. nov., complemented with a detailed study on its ultrastructure, allowing insight into its life cycle. The novel alga differs significantly from the related chromerid C. velia in life cycle, morphology as well as the plastid genome. Analysis of photosynthetic pigments on the other hand demonstrate that both chromerids lack chlorophyll c, the hallmark of phototrophic chromalveolates. Based on the relatively high divergence between C. velia and V. brassicaformis, we propose their classification into distinct families Chromeraceae and Vitrellaceae. Moreover, we predict a hidden and unexplored diversity of the chromerid algae. © 2011 Elsevier GmbH. All rights reserved. Key words: Apicomplexa; Chromera; morphology; ultrastructure; life cycle; phylogeny; coral. Introduction et al. 1997; McFadden et al. 1996). The pres- ence of a remnant plastid in these cells reflects The evolutionary origin of apicomplexan para- their photosynthetic ancestry. The discovery of a sites has been obscure for a long time. A first coral-associated secondary plastid-containing alga insight into their evolution came with the discovery Chromera velia represented another key break- of a non-photosynthetic plastid within apicom- through in supporting this notion (Archibald 2009; plexans now known as the apicoplast (Köhler Keeling 2008; Moore et al. 2008; Okamoto and McFadden 2008). The apicomplexan relationship 1 of this novel alga has been demonstrated by Corresponding authors; fax +420 385310388 multiple lines of evidence including: i) molecu- e-mail [email protected] (M. Oborník), [email protected] (J. Lukes).ˇ lar phylogeny of numerous plastid and nuclear © 2011 Elsevier GmbH. All rights reserved. doi:10.1016/j.protis.2011.09.001 Author's personal copy Vitrella brassicaformis, a Novel Chromerid from the Great Barrier Reef 307 genes (Janouskovecˇ et al. 2010; Moore et al. C. velia was isolated from a stony coral Plesi- 2008; Oborník et al. 2009; Okamoto and McFadden astrea versipora in Sydney harbor (Moore et al. 2008); ii) structure of the plastid super operon 2008). However, another putative algal symbiont (Janouskovecˇ et al. 2010); iii) presence of typical was isolated from the Australian stony coral Lep- morphological and ultrastructural characters such tastrea purpurea at One Tree Island, Great Barrier as cortical alveoli, a micropore, four membranes Reef by R. A. Andersen and R. B. Moore and was surrounding the plastid (Moore et al. 2008) and deposited in the CCMP collection under the iden- a pseudoconoid (Oborník et al. 2011). Moreover, tifier CCMP3155. Hence, together with C. velia, the use of a non-canonical genetic code for tryp- this putative chromerid alga has been subject tophan in the plastid, a character shared with a to extensive molecular studies, which confirmed parasitic group within the phylum Apicomplexa, the that CCMP3155 is also closely related to the Coccidia, provides convincing additional support for Apicomplexa, although it probably forms a novel this relationship (Janouskovecˇ et al. 2010; Moore lineage evolutionarily independent of C. velia. Plas- et al. 2008; Oborník et al. 2009). In contrast to tid genomes of both taxa, as well as a number dinoflagellates, which contain condensed chromo- of their nuclear protein-coding genes, have been somes during the entire cell cycle (Rizzo 2003), analyzed (Janouskovecˇ et al. 2010). Although both C. velia possesses a typical eukaryotic nucleus algae are classified as chromerids based on the (Oborník et al. 2011), a feature further supported by previously mentioned common metabolic features, the presence of genes encoding highly conserved photosynthetic ability and molecular phylogeny, eukaryotic histones H2A and H2B in the genome they substantially differ in their morphology (this of this alga (Oborník et al. 2009). In addition, the study), and certain other molecular characters also plastid of C. velia displays a unique pigment com- show significant mutual divergence (see Table 1 position, since chlorophyll c, the hallmark of most for details). Their plastid genomes are particularly chromalveolate plastids, is missing. Moreover, in revealing in this respect: while the highly diver- addition to chlorophyll a, C. velia also contains vio- gent plastid genes of C. velia are placed within laxanthin and a novel isoform of isofucoxanthin as an unusual genome, which even appears to be major light harvesting pigments (Moore et al. 2008). linear and lacks the inverted repeats of rRNA C. velia uses fast de-epoxidation of violaxanthin units, CCMP3155 possesses a highly conserved for highly efficient non-photochemical fluorescence and compact circular plastid genome, in which quenching (Kotabová et al. 2011). Although the the conserved genes display one of the highest absence of chlorophyll c has also been noted in GC contents (47.7%) so far described for plastid Eustigmatophyceae (Sukenik 1992), no phyloge- genes (Janouskovecˇ et al. 2010). Also in contrast netic relationship between eustigmatophytes and to C. velia, CCMP3155 uses exclusively the canon- chromerids has so far been shown, suggesting that ical code for all tryptophans in its plastid-encoded chlorophyll c might have been lost twice during genes (Janouskovecˇ et al. 2010), and has devel- the course of evolution. The phototrophic alveo- oped a different life cycle. late C. velia also uses a novel mechanism for Here we formally describe CCMP3155 as Vitrella iron uptake, which differs from the classical reduc- brassicaformis gen. et sp. nov., and investigate its tive and siderophore-mediated iron uptake systems morphology, ultrastructure and photosynthetic pig- present in yeasts and terrestrial plants (Sutak et al. ments. We classify C. velia and V. brassicaformis in 2011). It also contains plant-like galactolipids (Botté separate families, Chromeraceae and Vitrellaceae. et al. 2011). In addition to the non-motile coccoid stage, which under cultivation conditions represents the domi- Results nant stage of C. velia (Moore et al. 2008; Oborník et al. 2011), motile biflagellate plastid-bearing Light Microscopy Observations cells were also observed (Oborník et al. 2011; Weatherby et al. 2011). Morphologically, these The dominant stages under the cultivation con- flagellates resemble colpodellids, aquatic apicom- ditions were single coccoid non-motile vegetative plexan predators with a pseudoconoid (Leander cells of various sizes containing abundant quanti- and Keeling 2003). Although the vegetative life ties of green pigment and storage granules. The cycle of C. velia in culture has been reconstructed size variation of cultured cells is considerable (Oborník et al. 2011), we can only speculate at (Figs 1-4). While a thick multilayered cell wall is present about the function of these flagellate cells characteristic of stationary phase (Figs 9-10), the in natural conditions. cell wall of the younger stages is relatively thin 308 M. Oborník et al. in plastid for plastid celled present surrounded code cycle the flagellum projections sporangia no yes no in cell chromosomes fragmented shorter trichocysts entire to have on no finger-like dinoflagellates tryptophan yes no no non-canonical far. in yes no no condensed during found 3 so are yes yes not homologous dinoflagellates genome be plastids c heterodynamic flagella to yes yes no conspicuous pyrenoid of plastid found 2 a Peridinin tertiary seems 5 in not yes yes pseudoconoid chromerosome

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