Tag: dinoflagellates

Colponemids Represent Multiple Ancient Alveolate Lineages.

Curr Biol. 2013 Dec 3;

Authors: Janouškovec J, Tikhonenkov DV, Mikhailov KV, Simdyanov TG, Aleoshin VV, Mylnikov AP, Keeling PJ

Abstract
The alveolates comprise three well-studied protist lineages of significant environmental, medical, and economical importance: apicomplexans (e.g., Plasmodium), dinoflagellates (e.g., Symbiodinium), and ciliates (e.g., Tetrahymena). These major lineages have evolved distinct and unusual characteristics, the origins of which have proved to be difficult evolutionary puzzles. Mitochondrial genomes are a prime example: all three groups depart from canonical form and content, but in different ways. Reconstructing such ancient transitions is difficult without deep-branching lineages that retain ancestral characteristics. Here we describe two such lineages and how they illuminate the ancestral state of alveolate mitochondrial genomes. We established five clonal cultures of colponemids, predatory alveolates without cultured representatives and molecular data. Colponemids represent at least two independent lineages at the phylum level in multilocus phylogenetic analysis; one sister to apicomplexans and dinoflagellates, and the other at a deeper position. A genome survey from one strain showed that ancestral state of the mitochondrial genomes in the three major alveolate lineages consisted of an unusual linear chromosome with telomeres and a substantially larger gene set than known alveolates. Colponemid sequences also identified several environmental lineages as colponemids, altogether suggesting an untapped potential for understanding the origin and evolution of apicomplexans, dinoflagellates, and ciliates.

PMID: 24316202 [PubMed – as supplied by publisher]

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Horizontal Gene Transfer is a Significant Driver of Gene Innovation in Dinoflagellates.
Genome Biol Evol. 2013 Nov 19;
Authors: Wisecaver JH, Brosnahan ML, Hackett JD
Abstract
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The case of horizontal gene transfer from bacteria to the peculiar dinoflagellate plastid genome.

Mob Genet Elements. 2013 Jul 1;3(4):e25845

Authors: Mackiewicz P, Bodył A, Moszczyński K

Abstract
Organelle genomes lose their genes by transfer to host nuclear genomes, but only occasionally are enriched by foreign genes from other sources. In contrast to mitochondria, plastid genomes are especially resistant to such horizontal gene transfer (HGT), and thus every gene acquired in this way is notable. An exceptional case of HGT was recently recognized in the peculiar peridinin plastid genome of dinoflagellates, which is organized in plasmid-like minicircles. Genomic and phylogenetic analyses of Ceratium horridum and Pyrocystis lunula minicircles revealed four genes and one unannotated open reading frame that probably were gained from bacteria belonging to the Bacteroidetes. Such bacteria seem to be a good source of genes because close endosymbiotic associations between them and dinoflagellates have been observed. The HGT-acquired genes are involved in plastid functions characteristic of other photosynthetic eukaryotes, and their arrangement resembles bacterial operons. These studies indicate that the peridinin plastid genome, usually regarded as having resulted from reduction and fragmentation of a typical plastid genome derived from red algae, may have a chimeric origin that includes bacterial contributions. Potential contamination of the Ceratium and Pyrocystis plastid genomes by bacterial sequences and the controversial localization of their minicircles in the nucleus are also discussed.

PMID: 24195014 [PubMed – as supplied by publisher]

A journey into the wild of the cnidarian model system Aiptasia and its symbionts.

Mol Ecol. 2013 Sep;22(17):4366-8

Authors: Voolstra CR

Abstract
The existence of coral reef ecosystems relies critically on the mutualistic relationship between calcifying cnidarians and photosynthetic, dinoflagellate endosymbionts in the genus Symbiodinium. Reef-corals have declined globally due to anthropogenic stressors, for example, rising sea-surface temperatures and pollution that often disrupt these symbiotic relationships (known as coral bleaching), exacerbating mass mortality and the spread of disease. This threatens one of the most biodiverse marine ecosystems providing habitats to millions of species and supporting an estimated 500 million people globally (Hoegh-Guldberg et al. 2007). Our understanding of cnidarian–dinoflagellate symbioses has improved notably with the recent application of genomic and transcriptomic tools (e.g. Voolstra et al. 2009; Bayer et al. 2012; Davy et al. 2012), but a model system that allows for easy manipulation in a laboratory environment is needed to decipher underlying cellular mechanisms important to the functioning of these symbioses. To this end, the sea anemone Aiptasia, otherwise known as a ‘pest’ to aquarium hobbyists, is emerging as such a model system (Schoenberg & Trench 1980; Sunagawa et al. 2009; Lehnert et al. 2012). Aiptasia is easy to grow in culture and, in contrast to its stony relatives, can be maintained aposymbiotically (i.e. dinoflagellate free) with regular feeding. However, we lack basic information on the natural distribution and genetic diversity of these anemones and their endosymbiotic dinoflagellates. These data are essential for placing the significance of this model system into an ecological context. In this issue of Molecular Ecology, Thornhill et al. (2013) are the first to present genetic evidence on the global distribution, diversity and population structure of Aiptasia and its associated Symbiodinium spp. By integrating analyses of the host and symbiont, this research concludes that the current Aitpasia taxonomy probably needs revision and that two distinct Aiptasia lineages are prevalent that have probably been spread through human activity. One lineage engages in a specific symbiosis with Symbiodinium minutum throughout the tropics, whereas a second, local Aiptasia sp. population in Florida appears more flexible in partnering with more than one symbiont. The existence of symbiont-specific and symbiont-flexible Aiptasia lineages can greatly complement laboratory-based experiments looking into mechanisms of symbiont selectivity. In a broader context, the study by Thornhill et al. (2013) should inspire more studies to target the natural environment of model systems in a global context targeting all participating member species when establishing ecological and genetic baselines.

PMID: 24137737 [PubMed – in process]

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Comparative Genomic Analysis of Multi-Subunit Tethering Complexes Demonstrates an Ancient Pan-Eukaryotic Complement and Sculpting in Apicomplexa.
PLoS One. 2013;8(9):e76278
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Genomics Study of the Exposure Effect of Gymnodinium catenatum, a Paralyzing Toxin Producer, on Crassostrea gigas’ Defense System and Detoxification Genes.

PLoS One. 2013;8(9):e72323

Authors: García-Lagunas N, Romero-Geraldo R, Hernández-Saavedra NY

Abstract
BACKGROUND: Crassostrea gigas accumulates paralytic shellfish toxins (PST) associated with red tide species as Gymnodinium catenatum. Previous studies demonstrated bivalves show variable feeding responses to toxic algae at physiological level; recently, only one study has reported biochemical changes in the transcript level of the genes involved in C. gigas stress response.
PRINCIPAL FINDINGS: We found that 24 h feeding on toxic dinoflagellate cells (acute exposure) induced a significant decrease in clearance rate and expression level changes of the genes involved in antioxidant defense (copper/zinc superoxide dismutase, Cu/Zn-SOD), cell detoxification (glutathione S-transferase, GST and cytochrome P450, CPY450), intermediate immune response activation (lipopolysaccharide and beta glucan binding protein, LGBP), and stress responses (glutamine synthetase, GS) in Pacific oysters compared to the effects with the non-toxic microalga Isochrysis galbana. A sub-chronic exposure feeding on toxic dinoflagellate cells for seven and fourteen days (30×10(3) cells mL(-1)) showed higher gene expression levels. A significant increase was observed in Cu/Zn-SOD, GST, and LGBP at day 7 and a major increase in GS and CPY450 at day 14. We also observed that oysters fed only with G. catenatum (3×10(3) cells mL(-1)) produced a significant increase on the transcription level than in a mixed diet (3×10(3) cells mL(-1) of G. catenatum+0.75×10(6) cells mL(-1) I. galbana) in all the analyzed genes.
CONCLUSIONS: Our results provide gene expression data of PST producer dinoflagellate G. catenatum toxic effects on C. gigas, a commercially important bivalve. Over expressed genes indicate the activation of a potent protective mechanism, whose response depends on both cell concentration and exposure time against these toxic microalgae. Given the importance of dinoflagellate blooms in coastal environments, these results provide a more comprehensive overview of how oysters respond to stress generated by toxic dinoflagellate exposure.

PMID: 24039751 [PubMed – in process]