Algae or Protozoa: Phylogenetic Position of Euglenophytes and Dinoflagellates as Inferred from Mitochondrial Sequences (original) (raw)
Related papers
Journal of Phycology, 2005
Despite their evolutionary and ecological importance, dinoflagellate phylogeny remains poorly resolved. Here we explored the utility of mitochondrial cytochrome b (cob) in inferring a dinoflagellate tree and focused on resolving the relationship between fucoxanthin-and peridinin-containing taxa. Trees were inferred using cob and small subunit rDNA alone or in combination as concatenated data and including members of the six major dinoflagellate orders. Many regions of the cob DNA or protein and rDNA trees were congruent with support for the monophyly of Symbiodinium spp. Freudenthal and of the Prorocentrales and the early divergence of Crypthecodinium cohnii Seligo in Grasse. However, these markers provided differing support for the monophyly of Pfiesteria spp. Steidinger et Burkholder (only supported strongly by rDNA) and of the fucoxanthin dinoflagellates with Akashiwo sp. (Hirasaka) Hansen et Moestrup (Gymnodiniales, only supported strongly by the cob data). The approximately unbiased (AU) test was used to assess these results using 13-and 11-taxon (excluding apicomplexans) backbone maximum likelihood trees inferred from the combined cob+rDNA data. The AU test suggested that our data were insufficient to resolve the phylogenetic position of Symbiodinium spp. and that the ancestral position of C. cohnii might have resulted from long-branch attraction to the apicomplexan outgroup. We found significant support, however, for the association of fucoxanthin dinoflagellates with Akashiwo sp. The monophyly and relatively derived position of the Gymnodiniales in our cob DNA and protein trees and in the cob+rDNA tree is consistent with the tertiary endosymbiotic origin of the plastid in fucoxanthin dinoflagellates.
PLoS ONE, 2012
Background: Mitochondria or mitochondrion-derived organelles are found in all eukaryotes with the exception of secondary or tertiary plastid endosymbionts. In these highly reduced systems, the mitochondrion has been lost in all cases except the diatom endosymbionts found in a small group of dinoflagellates, called 'dinotoms', the only cells with two evolutionarily distinct mitochondria. To investigate the persistence of this redundancy and its consequences on the content and structure of the endosymbiont and host mitochondrial genomes, we report the sequences of these genomes from two dinotoms.
Despite their evolutionary and ecological importance, dinoflagellate phylogeny remains poorly resolved. Here we explored the utility of mitochondrial cytochrome b (cob) in inferring a dinoflagellate tree and focused on resolving the relationship between fucoxanthin-and peridinin-containing taxa. Trees were inferred using cob and small subunit rDNA alone or in combination as concatenated data and including members of the six major dinoflagellate orders. Many regions of the cob DNA or protein and rDNA trees were congruent with support for the monophyly of Symbiodinium spp. Freudenthal and of the Prorocentrales and the early divergence of Crypthecodinium cohnii Seligo in Grasse. However, these markers provided differing support for the monophyly of Pfiesteria spp. Steidinger et Burkholder (only supported strongly by rDNA) and of the fucoxanthin dinoflagellates with Akashiwo sp. (Hirasaka) Hansen et Moestrup (Gymnodiniales, only supported strongly by the cob data). The approximately unbiased (AU) test was used to assess these results using 13-and 11-taxon (excluding apicomplexans) backbone maximum likelihood trees inferred from the combined cob þ rDNA data. The AU test suggested that our data were insufficient to resolve the phylogenetic position of Symbiodinium spp. and that the ancestral position of C. cohnii might have resulted from long-branch attraction to the apicomplexan outgroup. We found significant support, however, for the association of fucoxanthin dinoflagellates with Akashiwo sp. The monophyly and relatively derived position of the Gymnodiniales in our cob DNA and protein trees and in the cob þ rDNA tree is consistent with the tertiary endosymbiotic origin of the plastid in fucoxanthin dinoflagellates.
Research Article: Tertiary Endosymbiosis Driven Genome Evolution in Dinoflagellate Algae
2000
Running title: Dinoflagellate tertiary endosymbiosis Abbreviations: GAPDH, glyceraldehyde-3-phosphate dehydrogenase; PsaA, photosystem I P700 chlorophyll a apoprotein A1; PsaB, photosystem I P700 chlorophyll a apoprotein A2; PsbA, photosystem II reaction center protein D1; PsbC, photosystem II 44 KD apoprotein; PsbD, photosystem II D2 reaction center protein; PsbO, oxygen-evolving enhancer protein 1
PLoS ONE, 2011
The Dinophysis genus is an ecologically and evolutionarily important group of marine dinoflagellates, yet their molecular phylogenetic positions and ecological characteristics such as trophic modes remain poorly understood. Here, a population of Dinophysis miles var. indica was sampled from South China Sea in March 2010. Nuclear ribosomal RNA gene (rDNA) SSU, ITS1-5.8S-ITS2 and LSU, mitochondrial genes encoding cytochrome B (cob) and cytochrome C oxidase subunit I (cox1), and plastid rDNA SSU were PCR amplified and sequenced. Phylogenetic analyses based on cob, cox1, and the nuclear rRNA regions showed that D. miles was closely related to D. tripos and D. caudata while distinct from D. acuminata. Along with morphology the LSU and ITS1-5.8S-ITS2 molecular data confirmed that this population was D. miles var. indica. Furthermore, the result demonstrated that ITS1-5.8S-ITS2 fragment was the most effective region to distinguish D. miles from other Dinophysis species. Three distinct types of plastid rDNA sequences were detected, belonging to plastids of a cryptophyte, a haptophyte, and a cyanobacterium, respectively. This is the first documentation of three photosynthetic entities associated with a Dinophysis species. While the cyanobacterial sequence likely represented an ectosymbiont of the D. miles cells, the detection of the cryptophyte and haptophyte plastid sequences indicates that the natural assemblage of D. miles likely retain more than one type of plastids from its prey algae for temporary use in photosynthesis. The result, together with recent findings of plastid types in other Dinophysis species, suggests that more systematic research is required to understand the complex nutritional physiology of this genus of dinoflagellates.
A Comparative Analysis of Mitochondrial Genomes in Eustigmatophyte Algae
Genome Biology and Evolution, 2016
Eustigmatophyceae (Ochrophyta, Stramenopiles) is a small algal group with species of the genus Nannochloropsis being its best studied representatives. Nuclear and organellar genomes have been recently sequenced for several Nannochloropsis spp., but phylogenetically wider genomic studies are missing for eustigmatophytes. We sequenced mitochondrial genomes (mitogenomes) of three species representing most major eustigmatophyte lineages, Monodopsis sp. MarTras21, Vischeria sp. CAUP Q 202 and Trachydiscus minutus, and carried out their comparative analysis in the context of available data from Nannochloropsis and other stramenopiles, revealing a number of noticeable findings. First, mitogenomes of most eustigmatophytes are highly collinear and similar in the gene content, but extensive rearrangements and loss of three otherwise ubiquitous genes happened in the Vischeria lineage; this correlates with an accelerated evolution of mitochondrial gene sequences in this lineage. Second, eustigm...
Journal of Phycology, 1998
The three green algal mitochondrial genomes completely sequenced to date-those of Chlamydomonas reinhardtii Dangeard, Chlamydomonas eugametos Gerloff, and Prototheca wickerhamii Soneda & Tubaki-revealed very different mitochondrial genome organizations and sequence affiliations. The Chlamydomonas genomes resemble the ciliate/fungal/animal counterparts, and the Prototheca genome resembles land plant homologues. This review points out that all the green algal mitochondrial genomes examined to date resemble either the Chlamydomonas or the Prototheca mitochondrial genome; the Chlamydomonas-like mitochondrial genomes are small and have a reduced gene content (no ribosomal protein or 5S rRNA genes and only a few protein-coding and tRNA genes) and fragmented and scrambled rRNA coding regions, whereas the Prototheca-like mitochondrial genomes are larger and have a larger set of protein-coding genes (including ribosomal protein genes), more tRNA genes, and 5S rRNA and conventional continuous smallsubunit (SSU) and large-subunit (LSU) rRNA coding regions. It appears, therefore, that the differences previously observed between the mitochondrial genomes of C. reinhardtii and P. wickerhamii extend to the two green algal mitochondrial lineages to which they belong and are significant enough to raise questions about the causes and mechanisms responsible for such contrasting evolutionary strategies among green algae. This review suggests an integrative approach in explaining the occurrence of distinct evolutionary strategies and apparent phylogenetic affiliations among the known green algal mitochondrial lineages. The observed differences could be the result of distinct genetic potentials differentiated during the previous evolutionary history of the flagellate ancestors and/or of subsequent changes in habitat and life history of the more advanced green algal lineages.
THE PLANT CELL ONLINE, 1999
Green plants appear to comprise two sister lineages, Chlorophyta (classes Chlorophyceae, Ulvophyceae, Trebouxiophyceae, and Prasinophyceae) and Streptophyta (Charophyceae and Embryophyta, or land plants). To gain insight into the nature of the ancestral green plant mitochondrial genome, we have sequenced the mitochondrial DNAs (mtDNAs) of Nephroselmis olivacea and Pedinomonas minor . These two green algae are presumptive members of the Prasinophyceae. This class is thought to include descendants of the earliest diverging green algae. We find that Nephroselmis and Pedinomonas mtDNAs differ markedly in size, gene content, and gene organization. Of the green algal mtDNAs sequenced so far, that of Nephroselmis (45,223 bp) is the most ancestral (minimally diverged) and occupies the phylogenetically most basal position within the Chlorophyta. Its repertoire of 69 genes closely resembles that in the mtDNA of Prototheca wickerhamii , a later diverging trebouxiophycean green alga. Three of the Nephroselmis genes ( nad10 , rpl14 , and rnpB ) have not been identified in previously sequenced mtDNAs of green algae and land plants. In contrast, the 25,137-bp Pedinomonas mtDNA contains only 22 genes and retains few recognizably ancestral features. In several respects, including gene content and rate of sequence divergence, Pedinomonas mtDNA resembles the reduced mtDNAs of chlamydomonad algae, with which it is robustly affiliated in phylogenetic analyses. Our results confirm the existence of two radically different patterns of mitochondrial genome evolution within the green algae.
Tracing the Evolution of Streptophyte Algae and Their Mitochondrial Genome
Genome Biology and Evolution, 2013
Six monophyletic groups of charophycean green algae are recognized within the Streptophyta. Although incongruent with earlier studies based on genes from three cellular compartments, chloroplast and nuclear phylogenomic analyses have resolved identical relationships among these groups, placing the Zygnematales or the Zygnematales + Coleochaetales as sister to land plants. The present investigation aimed at determining whether this consensus view is supported by the mitochondrial genome and at gaining insight into mitochondrial DNA (mtDNA) evolution within and across streptophyte algal lineages and during the transition toward the first land plants. We present here the newly sequenced mtDNAs of representatives of the Klebsormidiales (Entransia fimbriata and Klebsormidium spec.) and Zygnematales (Closterium baillyanum and Roya obtusa) and compare them with their homologs in other charophycean lineages as well as in selected embryophyte and chlorophyte lineages. Our results indicate that important changes occurred at the levels of genome size, gene order, and intron content within the Zygnematales. Although the representatives of the Klebsormidiales display more similarity in genome size and intron content, gene order seems more fluid and gene losses more frequent than in other charophycean lineages. In contrast, the two members of the Charales display an extremely conservative pattern of mtDNA evolution. Collectively, our analyses of gene order and gene content and the phylogenies we inferred from 40 mtDNAencoded proteins failed to resolve the relationships among the Zygnematales, Coleochaetales, and Charales; however, they are consistent with previous phylogenomic studies in favoring that the morphologically complex Charales are not sister to land plants.