Your search keyword '"Hehenberger E"' showing total 27 results

1. A kleptoplastidic dinoflagellate and the tipping point between transient and fully integrated plastid endosymbiosis.

Author

Hehenberger E, Gast RJ, and Keeling PJ

Subjects

Electron Transport, Gene Expression Profiling, Gene Expression Regulation, Plant, Models, Biological, Dinoflagellida physiology, Gene Transfer, Horizontal, Mutagenesis, Insertional, Plastids genetics, Symbiosis

Abstract

Plastid endosymbiosis has been a major force in the evolution of eukaryotic cellular complexity, but how endosymbionts are integrated is still poorly understood at a mechanistic level. Dinoflagellates, an ecologically important protist lineage, represent a unique model to study this process because dinoflagellate plastids have repeatedly been reduced, lost, and replaced by new plastids, leading to a spectrum of ages and integration levels. Here we describe deep-transcriptomic analyses of the Antarctic Ross Sea dinoflagellate (RSD), which harbors long-term but temporary kleptoplasts stolen from haptophyte prey, and is closely related to dinoflagellates with fully integrated plastids derived from different haptophytes. In some members of this lineage, called the Kareniaceae, their tertiary haptophyte plastids have crossed a tipping point to stable integration, but RSD has not, and may therefore reveal the order of events leading up to endosymbiotic integration. We show that RSD has retained its ancestral secondary plastid and has partitioned functions between this plastid and the kleptoplast. It has also obtained genes for kleptoplast-targeted proteins via horizontal gene transfer (HGT) that are not derived from the kleptoplast lineage. Importantly, many of these HGTs are also found in the related species with fully integrated plastids, which provides direct evidence that genetic integration preceded organelle fixation. Finally, we find that expression of kleptoplast-targeted genes is unaffected by environmental parameters, unlike prey-encoded homologs, suggesting that kleptoplast-targeted HGTs have adapted to posttranscriptional regulation mechanisms of the host., Competing Interests: The authors declare no conflict of interest.

Published

2019

2. Single cell genomics reveals plastid-lacking Picozoa are close relatives of red algae.

Author

Schön ME, Zlatogursky VV, Singh RP, Poirier C, Wilken S, Mathur V, Strassert JFH, Pinhassi J, Worden AZ, Keeling PJ, Ettema TJG, Wideman JG, and Burki F

Subjects

Biological Evolution, Eukaryota classification, Genetic Variation, Genome genetics, Genomics, Phylogeny, Rhodophyta classification, Single-Cell Analysis, Eukaryota genetics, Plastids genetics, Rhodophyta genetics

Abstract

The endosymbiotic origin of plastids from cyanobacteria gave eukaryotes photosynthetic capabilities and launched the diversification of countless forms of algae. These primary plastids are found in members of the eukaryotic supergroup Archaeplastida. All known archaeplastids still retain some form of primary plastids, which are widely assumed to have a single origin. Here, we use single-cell genomics from natural samples combined with phylogenomics to infer the evolutionary origin of the phylum Picozoa, a globally distributed but seemingly rare group of marine microbial heterotrophic eukaryotes. Strikingly, the analysis of 43 single-cell genomes shows that Picozoa belong to Archaeplastida, specifically related to red algae and the phagotrophic rhodelphids. These picozoan genomes support the hypothesis that Picozoa lack a plastid, and further reveal no evidence of an early cryptic endosymbiosis with cyanobacteria. These findings change our understanding of plastid evolution as they either represent the first complete plastid loss in a free-living taxon, or indicate that red algae and rhodelphids obtained their plastids independently of other archaeplastids., (© 2021. The Author(s).)

Published

2021

3. Evidence for the retention of two evolutionary distinct plastids in dinoflagellates with diatom endosymbionts.

Author

Hehenberger E, Imanian B, Burki F, and Keeling PJ

Subjects

Diatoms classification, Diatoms physiology, Dinoflagellida classification, Dinoflagellida physiology, Molecular Sequence Data, Phylogeny, Plastids physiology, Biological Evolution, Diatoms genetics, Dinoflagellida genetics, Plastids genetics, Symbiosis

Abstract

Dinoflagellates harboring diatom endosymbionts (termed "dinotoms") have undergone a process often referred to as "tertiary endosymbiosis"--the uptake of algae containing secondary plastids and integration of those plastids into the new host. In contrast to other tertiary plastids, and most secondary plastids, the endosymbiont of dinotoms is distinctly less reduced, retaining a number of cellular features, such as their nucleus and mitochondria and others, in addition to their plastid. This has resulted in redundancy between host and endosymbiont, at least between some mitochondrial and cytosolic metabolism, where this has been investigated. The question of plastidial redundancy is particularly interesting as the fate of the host dinoflagellate plastid is unclear. The host cytosol possesses an eyespot that has been postulated to be a remnant of the ancestral peridinin plastid, but this has not been tested, nor has its possible retention of plastid functions. To investigate this possibility, we searched for plastid-associated pathways and functions in transcriptomic data sets from three dinotom species. We show that the dinoflagellate host has indeed retained genes for plastid-associated pathways and that these genes encode targeting peptides similar to those of other dinoflagellate plastid-targeted proteins. Moreover, we also identified one gene encoding an essential component of the dinoflagellate plastid protein import machinery, altogether suggesting the presence of a functioning plastid import system in the host, and by extension a relict plastid. The presence of the same plastid-associated pathways in the endosymbiont also extends the known functional redundancy in dinotoms, further confirming the unusual state of plastid integration in this group of dinoflagellates., (© The Author(s) 2014. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2014

4. Encyclopedia of Family A DNA Polymerases Localized in Organelles: Evolutionary Contribution of Bacteria Including the Proto-Mitochondrion.

Author

Harada, Ryo, Hirakawa, Yoshihisa, Yabuki, Akinori, Kim, Eunsoo, Yazaki, Euki, Kamikawa, Ryoma, Nakano, Kentaro, Eliáš, Marek, and Inagaki, Yuji

Subjects

DNA polymerases, ORGANELLES, ENCYCLOPEDIAS & dictionaries, MITOCHONDRIAL DNA, EUKARYOTIC cells, CULTURAL pluralism, ELECTRONIC encyclopedias

Abstract

DNA polymerases synthesize DNA from deoxyribonucleotides in a semiconservative manner and serve as the core of DNA replication and repair machinery. In eukaryotic cells, there are 2 genome-containing organelles, mitochondria, and plastids, which were derived from an alphaproteobacterium and a cyanobacterium, respectively. Except for rare cases of genome-lacking mitochondria and plastids, both organelles must be served by nucleus-encoded DNA polymerases that localize and work in them to maintain their genomes. The evolution of organellar DNA polymerases has yet to be fully understood because of 2 unsettled issues. First, the diversity of organellar DNA polymerases has not been elucidated in the full spectrum of eukaryotes. Second, it is unclear when the DNA polymerases that were used originally in the endosymbiotic bacteria giving rise to mitochondria and plastids were discarded, as the organellar DNA polymerases known to date show no phylogenetic affinity to those of the extant alphaproteobacteria or cyanobacteria. In this study, we identified from diverse eukaryotes 134 family A DNA polymerase sequences, which were classified into 10 novel types, and explored their evolutionary origins. The subcellular localizations of selected DNA polymerases were further examined experimentally. The results presented here suggest that the diversity of organellar DNA polymerases has been shaped by multiple transfers of the PolI gene from phylogenetically broad bacteria, and their occurrence in eukaryotes was additionally impacted by secondary plastid endosymbioses. Finally, we propose that the last eukaryotic common ancestor may have possessed 2 mitochondrial DNA polymerases, POP, and a candidate of the direct descendant of the proto-mitochondrial DNA polymerase I, rdxPolA, identified in this study. [ABSTRACT FROM AUTHOR]

Published

2024

5. Multiple parallel origins of parasitic Marine Alveolates.

Author

Holt, Corey C., Hehenberger, Elisabeth, Tikhonenkov, Denis V., Jacko-Reynolds, Victoria K. L., Okamoto, Noriko, Cooney, Elizabeth C., Irwin, Nicholas A. T., and Keeling, Patrick J.

Subjects

BIOLOGICAL evolution, RIBOSOMAL RNA, APICOMPLEXA, MARINE ecology, DINOFLAGELLATES, PLASTIDS, PROTISTA, MARINE microbiology, PARASITISM

Abstract

Microbial eukaryotes are important components of marine ecosystems, and the Marine Alveolates (MALVs) are consistently both abundant and diverse in global environmental sequencing surveys. MALVs are dinoflagellates that are thought to be parasites of other protists and animals, but the lack of data beyond ribosomal RNA gene sequences from all but a few described species means much of their biology and evolution remain unknown. Using single-cell transcriptomes from several MALVs and their free-living relatives, we show that MALVs evolved independently from two distinct, free-living ancestors and that their parasitism evolved in parallel. Phylogenomics shows one subgroup (MALV-II and -IV, or Syndiniales) is related to a novel lineage of free-living, eukaryovorous predators, the eleftherids, while the other (MALV-I, or Ichthyodinida) is related to the free-living predator Oxyrrhis and retains proteins targeted to a non-photosynthetic plastid. Reconstructing the evolution of photosynthesis, plastids, and parasitism in early-diverging dinoflagellates shows a number of parallels with the evolution of their apicomplexan sisters. In both groups, similar forms of parasitism evolved multiple times and photosynthesis was lost many times. By contrast, complete loss of the plastid organelle is infrequent and, when this does happen, leaves no residual genes. The Marine Alveolates (MALVs) include important parasites of other protists/animals. Here, using new data from MALV-I, the psammosids, and a new group called the eleftherids, the authors show MALVs, and therefore parasitism in early dinoflagellates, evolved from two distinct free-living ancestors. [ABSTRACT FROM AUTHOR]

Published

2023

6. Red macroalgae in the genomic era.

Author

Borg, Michael, Krueger‐Hadfield, Stacy A., Destombe, Christophe, Collén, Jonas, Lipinska, Agnieszka, and Coelho, Susana M.

Subjects

RED algae, MULTICELLULAR organisms, MARINE algae, ENDOSYMBIOSIS, CENTRIOLES, PLASTIDS

Abstract

Summary: Rhodophyta (or red algae) are a diverse and species‐rich group that forms one of three major lineages in the Archaeplastida, a eukaryotic supergroup whose plastids arose from a single primary endosymbiosis. Red algae are united by several features, such as relatively small intron‐poor genomes and a lack of cytoskeletal structures associated with motility like flagella and centrioles, as well as a highly efficient photosynthetic capacity. Multicellular red algae (or macroalgae) are one of the earliest diverging eukaryotic lineages to have evolved complex multicellularity, yet despite their ecological, evolutionary, and commercial importance, they have remained a largely understudied group of organisms. Considering the increasing availability of red algal genome sequences, we present a broad overview of fundamental aspects of red macroalgal biology and posit on how this is expected to accelerate research in many domains of red algal biology in the coming years. [ABSTRACT FROM AUTHOR]

Published

2023

7. Complex Plastids and the Evolution of the Marine Phytoplankton.

Author

Gruber, Ansgar and Medlin, Linda K.

Subjects

MARINE phytoplankton, PLASTIDS, EARTH (Planet), EUKARYOTIC cells, AEROBIC metabolism, EUKARYOTES

Abstract

Photosynthesis allows for the formation of biomass from inorganic carbon and therefore greatly enhances the amount of organic material on planet Earth. Especially, oxygenic photosynthesis removed a major bottleneck in the formation of biomass by utilising ubiquitous water (H2O) and CO2 molecules as raw materials for organic molecules. This, over billions of years, shaped the world into the form we know today, with an oxygen-containing atmosphere, largely oxygenated water bodies and landmasses consisting of sediment rocks. Oxygenic photosynthesis furthermore enabled the evolution of aerobic energy metabolism, and it would be very difficult to imagine animal (including human) life in the absence of molecular oxygen as an electron acceptor. Oxygenic photosynthesis first, and exclusively, evolved in cyanobacteria. However, eukaryotes also learned to photosynthesise, albeit with a trick, which is the integration of formerly free-living cyanobacteria into the eukaryotic cell. There, the former bacteria became endosymbionts, and from these endosymbionts, the photosynthetic organelles (termed plastids) evolved. In almost all major groups of eukaryotes, plastid-containing members are found. At the same time, plastid-related features also indicate that these plastids form a monophyletic group. This can be explained by the transfer of plastids between the eukaryotic super-groups, leading to plastids being found in groups that are otherwise non-photosynthetic. In this chapter, we discuss the evolutionary origin of plastids, with a special emphasis on the evolution of plankton algae, such as diatoms or dinoflagellates, who acquired their plastids from other photosynthetic eukaryotes. [ABSTRACT FROM AUTHOR]

Published

2023

8. Reconstruction of Plastid Proteomes of Apicomplexans and Close Relatives Reveals the Major Evolutionary Outcomes of Cryptic Plastids.

Author

Mathur, Varsha, Salomaki, Eric D, Wakeman, Kevin C, Na, Ina, Kwong, Waldan K, Kolisko, Martin, and Keeling, Patrick J

Subjects

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

9. Challenging the Importance of Plastid Genome Structure Conservation: New Insights From Euglenophytes.

Author

Maciszewski, Kacper, Fells, Alicja, and Karnkowska, Anna

Subjects

ORGANELLE formation, GENOMES, FRESHWATER algae, PLASTIDS, EUGLENOIDS, GREEN algae, ENDOSYMBIOSIS

Abstract

Plastids, similar to mitochondria, are organelles of endosymbiotic origin, which retained their vestigial genomes (ptDNA). Their unique architecture, commonly referred to as the quadripartite (four-part) structure, is considered to be strictly conserved; however, the bulk of our knowledge on their variability and evolutionary transformations comes from studies of the primary plastids of green algae and land plants. To broaden our perspective, we obtained seven new ptDNA sequences from freshwater species of photosynthetic euglenids—a group that obtained secondary plastids, known to have dynamically evolving genome structure, via endosymbiosis with a green alga. Our analyses have demonstrated that the evolutionary history of euglenid plastid genome structure is exceptionally convoluted, with a patchy distribution of inverted ribosomal operon (rDNA) repeats, as well as several independent acquisitions of tandemly repeated rDNA copies. Moreover, we have shown that inverted repeats in euglenid ptDNA do not share their genome-stabilizing property documented in chlorophytes. We hypothesize that the degeneration of the quadripartite structure of euglenid plastid genomes is connected to the group II intron expansion. These findings challenge the current global paradigms of plastid genome architecture evolution and underscore the often-underestimated divergence between the functionality of shared traits in primary and complex plastid organelles. [ABSTRACT FROM AUTHOR]

Published

2022

10. Enigmatic Stramenopile Sheds Light on Early Evolution in Ochrophyta Plastid Organellogenesis.

Author

Azuma, Tomonori, Pánek, Tomáš, Tice, Alexander K., Kayama, Motoki, Kobayashi, Mayumi, Miyashita, Hideaki, Suzaki, Toshinobu, Yabuki, Akinori, Brown, Matthew W., and Kamikawa, Ryoma

Subjects

GENETIC transformation, AMINOACYL-tRNA, PLASTIDS, SYNTHASES, ECOSYSTEMS, HETEROKONTOPHYTA, ALGAL growth

Abstract

Ochrophyta is an algal group belonging to the Stramenopiles and comprises diverse lineages of algae which contribute significantly to the oceanic ecosystems as primary producers. However, early evolution of the plastid organelle in Ochrophyta is not fully understood. In this study, we provide a well-supported tree of the Stramenopiles inferred by the large-scale phylogenomic analysis that unveils the eukaryvorous (nonphotosynthetic) protist Actinophrys sol (Actinophryidae) is closely related to Ochrophyta. We used genomic and transcriptomic data generated from A. sol to detect molecular traits of its plastid and we found no evidence of plastid genome and plastid-mediated biosynthesis, consistent with previous ultrastructural studies that did not identify any plastids in Actinophryidae. Moreover, our phylogenetic analyses of particular biosynthetic pathways provide no evidence of a current and past plastid in A. sol. However, we found more than a dozen organellar aminoacyl-tRNA synthases (aaRSs) that are of algal origin. Close relationships between aaRS from A. sol and their ochrophyte homologs document gene transfer of algal genes that happened before the divergence of Actinophryidae and Ochrophyta lineages. We further showed experimentally that organellar aaRSs of A. sol are targeted exclusively to mitochondria, although organellar aaRSs in Ochrophyta are dually targeted to mitochondria and plastids. Together, our findings suggested that the last common ancestor of Actinophryidae and Ochrophyta had not yet completed the establishment of host–plastid partnership as seen in the current Ochrophyta species, but acquired at least certain nuclear-encoded genes for the plastid functions. [ABSTRACT FROM AUTHOR]

Published

2022

11. Phylogenomic Insights into the Origin of Primary Plastids.

Author

Irisarri, Iker, Strassert, Jürgen F H, and Burki, Fabien

Subjects

PLASTIDS, ENDOSYMBIOSIS, DATA quality, DATA curation

Abstract

The origin of plastids was a major evolutionary event that paved the way for an astonishing diversification of photosynthetic eukaryotes. Plastids originated by endosymbiosis between a heterotrophic eukaryotic host and cyanobacteria, presumably in a common ancestor of the primary photosynthetic eukaryotes (Archaeplastida). A single origin of primary plastids is well supported by plastid evidence but not by nuclear phylogenomic analyses, which have consistently failed to recover the monophyly of Archaeplastida hosts. Importantly, plastid monophyly and nonmonophyletic hosts could be explained under scenarios of independent or serial eukaryote-to-eukaryote endosymbioses. Here, we assessed the strength of the signal for the monophyly of Archaeplastida hosts in four available phylogenomic data sets. The effect of phylogenetic methodology, data quality, alignment trimming strategy, gene and taxon sampling, and the presence of outlier genes were investigated. Our analyses revealed a lack of support for host monophyly in the shorter individual data sets. However, when analyzed together under rigorous data curation and complex mixture models, the combined nuclear data sets supported the monophyly of primary photosynthetic eukaryotes (Archaeplastida) and recovered a putative association with plastid-lacking Picozoa. This study represents an important step toward better understanding deep eukaryotic evolution and the origin of plastids. [Archaeplastida; Bayesian; chloroplast; maximum likelihood; mixture model; ortholog; outlier loci; paralog; protist.] [ABSTRACT FROM AUTHOR]

Published

2022

12. Retention of Prey Genetic Material by the Kleptoplastidic Ciliate Strombidium cf. basimorphum.

Author

Maselli, Maira, Anestis, Konstantinos, Klemm, Kerstin, Hansen, Per Juel, and John, Uwe

Subjects

CHLOROPLASTS, PLASTIDS, RIBOSOMES, CILIATA, PROTISTA, CHLOROPLAST DNA, STARVATION, PREDATION

Abstract

Many marine ciliate species retain functional chloroplasts from their photosynthetic prey. In some species, the functionality of the acquired plastids is connected to the simultaneous retention of prey nuclei. To date, this has never been documented in plastidic Strombidium species. The functionality of the sequestered chloroplasts in Strombidium species is thought to be independent from any nuclear control and only maintained via frequent replacement of chloroplasts from newly ingested prey. Chloroplasts sequestered from the cryptophyte prey Teleaulax amphioxeia have been shown to keep their functionality for several days in the ciliate Strombidium cf. basimorphum. To investigate the potential retention of prey genetic material in this ciliate, we applied a molecular marker specific for this cryptophyte prey. Here, we demonstrate that the genetic material from prey nuclei, nucleomorphs, and ribosomes is detectable inside the ciliate for at least 5 days after prey ingestion. Moreover, single-cell transcriptomics revealed the presence of transcripts of prey nuclear origin in the ciliate after 4 days of prey starvation. These new findings might lead to the reconsideration of the mechanisms regulating chloroplasts retention in Strombidium ciliates. The development and application of molecular tools appear promising to improve our understanding on chloroplasts retention in planktonic protists. [ABSTRACT FROM AUTHOR]

Published

2021

13. Plastid-associated galactolipid composition in eyespot-containing dinoflagellates: a review.

Author

Graeff, Jori E., Elkins, Lindsey C., and Leblond, Jeffrey D.

Subjects

DINOFLAGELLATES, GREEN algae, EUGLENOIDS, PLASTIDS, CYANOBACTERIA, DIATOMS, PHAEODACTYLUM tricornutum

Abstract

Relative to the large number of photosynthetic dinoflagellate species, only a select few possess proteinaceous, carotenoid-rich eyespots which have been demonstrated in other algae to act in phototactic responses. The proteins comprising the different categories of dinoflagellate eyespots are positioned in or near the peridinin-containing photosynthetic plastid membranes which are composed primarily of two galactolipids, mono- and digalactosyldiacylglycerol (MGDG and DGDG). Within eyespot-containing dinoflagellates, this arrangement occurs mostly in those with secondary plastids, although some dinoflagellates with tertiary plastids of diatom origin are known to possess eyespots. We here provide an examination of the MGDG and DGDG composition of eyespot-containing dinoflagellates with secondary, peridinin-containing plastids and tertiary plastids of diatom origin to address the fundamental question of whether eyespots and their component proteins and carotenoids are associated with alterations in galactolipid composition when compared to eyespot-lacking photosynthetic dinoflagellates. This is an important question because the dinoflagellate eyespot-plastid membrane system can be considered a more complicated and evolved state of plastid development. Included in this examination are data on the previously unexamined peridinin- and type A eyespot-containing dinoflagellate Margalefidinium polykrikoides, and the type D eyespot-containing, aberrant plastid "dinotom" Durinskia baltica. In addition, we have reviewed the galactolipid composition of algae from the Chlorophyceae, Cryptophyceae, and Euglenophyceae as a comparison to determine if algal classes apart from the Dinophyceae contain altered galactolipids in association with eyespots. We conclude that the presence of an eyespot in dinoflagellates and other algae is not associated with noticeable changes in galactolipid composition. [ABSTRACT FROM AUTHOR]

Published

2021

14. Single-Cell Transcriptomics of Abedinium Reveals a New Early-Branching Dinoflagellate Lineage.

Author

Cooney, Elizabeth C, Okamoto, Noriko, Cho, Anna, Hehenberger, Elisabeth, Richards, Thomas A, Santoro, Alyson E, Worden, Alexandra Z, Leander, Brian S, and Keeling, Patrick J

Subjects

NUCLEOPROTEINS, GENE clusters, RNA editing, PLASTIDS, PLANT mitochondria, TERRITORIAL waters, RIBOSOMAL RNA

Abstract

Dinoflagellates possess many cellular characteristics with unresolved evolutionary histories. These include nuclei with greatly expanded genomes and chromatin packaged using histone-like proteins and dinoflagellate-viral nucleoproteins instead of histones, highly reduced mitochondrial genomes with extensive RNA editing, a mix of photosynthetic and cryptic secondary plastids, and tertiary plastids. Resolving the evolutionary origin of these traits requires understanding their ancestral states and early intermediates. Several early-branching dinoflagellate lineages are good candidates for such reconstruction, however these cells tend to be delicate and environmentally sparse, complicating such analyses. Here, we employ transcriptome sequencing from manually isolated and microscopically documented cells to resolve the placement of two cells of one such genus, Abedinium , collected by remotely operated vehicle in deep waters off the coast of Monterey Bay, CA. One cell corresponds to the only described species, Abedinium dasypus , whereas the second cell is distinct and formally described as Abedinium folium , sp. nov. Abedinium has classically been assigned to the early-branching dinoflagellate subgroup Noctilucales, which is weakly supported by phylogenetic analyses of small subunit ribosomal RNA, the single characterized gene from any member of the order. However, an analysis based on 221 proteins from the transcriptome places Abedinium as a distinct lineage, separate from and basal to Noctilucales and the rest of the core dinoflagellates. The transcriptome also contains evidence of a cryptic plastid functioning in the biosynthesis of isoprenoids, iron–sulfur clusters, and heme, a mitochondrial genome with all three expected protein-coding genes (cob , cox1 , and cox3), and the presence of some but not all dinoflagellate-specific chromatin packaging proteins. [ABSTRACT FROM AUTHOR]

Published

2020

15. Five Non-motile Dinotom Dinoflagellates of the Genus Dinothrix.

Author

Yamada, Norico, Sakai, Hiroto, Onuma, Ryo, Kroth, Peter G., and Horiguchi, Takeo

Subjects

RIBOSOMAL DNA, DINOFLAGELLATES, MOTILITY of bacteria, CELL division, PLANTS, GYMNODINIUM, PLASTIDS

Abstract

Dinothrix paradoxa and Gymnodinium quadrilobatum are benthic dinoflagellates possessing diatom-derived tertiary plastids, so-called dinotoms. Due to the lack of available genetic information, their phylogenetic relationship remains unknown. In this study, sequencing of 18S ribosomal DNA (rDNA) and the rbc L gene from temporary cultures isolated from natural samples revealed that they are close relatives of another dinotom, Galeidinium rugatum. The morphologies of these three dinotoms differ significantly from each other; however, they share a distinctive life cycle, in which the non-motile cells without flagella are their dominant phase. Cell division occurs in this non-motile phase, while swimming cells only appear for several hours after being released from each daughter cell. Furthermore, we succeeded in isolating and establishing two novel dinotom strains, HG180 and HG204, which show a similar life cycle and are phylogenetically closely related to the aforementioned three species. The non-motile cells of strain HG180 are characterized by the possession of a hemispheroidal cell covered with numerous nodes, while those of the strain HG204 form aggregations consisting of spherical smooth-surface cells. Based on the similarity in life cycles and phylogenetic closeness, we conclude that all five species should belong to a single genus, Dinothrix , the oldest genus within this clade. We transferred Ga. rugatum and Gy. quadrilobatum to Dinothrix , and described strains HG180 and HG204 as Dinothrix phymatodea sp. nov. and Dinothrix pseudoparadoxa sp. nov. [ABSTRACT FROM AUTHOR]

Published

2020

16. Genomic Insights into Plastid Evolution.

Author

Sibbald, Shannon J and Archibald, John M

Subjects

CELLULAR evolution, COMPARATIVE genomics, PLASTIDS, CHLOROPLAST DNA, TREE branches, CHLOROPLASTS, CYANOBACTERIAL toxins

Abstract

The origin of plastids (chloroplasts) by endosymbiosis stands as one of the most important events in the history of eukaryotic life. The genetic, biochemical, and cell biological integration of a cyanobacterial endosymbiont into a heterotrophic host eukaryote approximately a billion years ago paved the way for the evolution of diverse algal groups in a wide range of aquatic and, eventually, terrestrial environments. Plastids have on multiple occasions also moved horizontally from eukaryote to eukaryote by secondary and tertiary endosymbiotic events. The overall picture of extant photosynthetic diversity can best be described as "patchy": Plastid-bearing lineages are spread far and wide across the eukaryotic tree of life, nested within heterotrophic groups. The algae do not constitute a monophyletic entity, and understanding how, and how often, plastids have moved from branch to branch on the eukaryotic tree remains one of the most fundamental unsolved problems in the field of cell evolution. In this review, we provide an overview of recent advances in our understanding of the origin and spread of plastids from the perspective of comparative genomics. Recent years have seen significant improvements in genomic sampling from photosynthetic and nonphotosynthetic lineages, both of which have added important pieces to the puzzle of plastid evolution. Comparative genomics has also allowed us to better understand how endosymbionts become organelles. [ABSTRACT FROM AUTHOR]

Published

2020

17. Fates of Evolutionarily Distinct, Plastid‐type Glyceraldehyde 3‐phosphate Dehydrogenase Genes in Kareniacean Dinoflagellates.

Author

Kamikawa, Ryoma, Yazaki, Euki, Tahara, Michiru, Sakura, Takaya, Matsuo, Eriko, Nagamune, Kisaburo, Hashimoto, Tetsuo, and Inagaki, Yuji

Subjects

GLYCERALDEHYDEPHOSPHATE dehydrogenase, OXIDOREDUCTASES, GENETIC transformation, ENDOSYMBIOSIS, PLASTIDS

Abstract

Abstract: The ancestral kareniacean dinoflagellate has undergone tertiary endosymbiosis, in which the original plastid is replaced by a haptophyte endosymbiont. During this plastid replacement, the endosymbiont genes were most likely flowed into the host dinoflagellate genome (endosymbiotic gene transfer or EGT). Such EGT may have generated the redundancy of functionally homologous genes in the host genome—one has resided in the host genome prior to the haptophyte endosymbiosis, while the other transferred from the endosymbiont genome. However, it remains to be well understood how evolutionarily distinct but functionally homologous genes were dealt in the dinoflagellate genomes bearing haptophyte‐derived plastids. To model the gene evolution after EGT in plastid replacement, we here compared the characteristics of the two evolutionally distinct genes encoding plastid‐type glyceraldehyde 3‐phosphate dehydrogenase (GAPDH) in Karenia brevis and K. mikimotoi bearing haptophyte‐derived tertiary plastids: “gapC1h” acquired from the haptophyte endosymbiont and “gapC1p” inherited from the ancestral dinoflagellate. Our experiments consistently and clearly demonstrated that, in the two species examined, the principal plastid‐type GAPDH is encoded by gapC1h rather than gapC1p. We here propose an evolutionary scheme resolving the EGT‐derived redundancy of genes involved in plastid function and maintenance in the nuclear genomes of dinoflagellates that have undergone plastid replacements. Although K. brevis and K. mikimotoi are closely related to each other, the statuses of the two evolutionarily distinct gapC1 genes in the two Karenia species correspond to different steps in the proposed scheme. [ABSTRACT FROM AUTHOR]

Published

2018

18. Did some red alga‐derived plastids evolve via kleptoplastidy? A hypothesis.

Author

Bodył, Andrzej

Subjects

RED algae, ENDOSYMBIOSIS, ORGANELLES, PLASTIDS, CHIMERIC proteins

Abstract

ABSTRACT: The evolution of plastids has a complex and still unresolved history. These organelles originated from a cyanobacterium via primary endosymbiosis, resulting in three eukaryotic lineages: glaucophytes, red algae, and green plants. The red and green algal plastids then spread via eukaryote–eukaryote endosymbioses, known as secondary and tertiary symbioses, to numerous heterotrophic protist lineages. The number of these horizontal plastid transfers, especially in the case of red alga‐derived plastids, remains controversial. Some authors argue that the number of plastid origins should be minimal due to perceived difficulties in the transformation of a eukaryotic algal endosymbiont into a multimembrane plastid, but increasingly the available data contradict this argument. I suggest that obstacles in solving this dilemma result from the acceptance of a single evolutionary scenario for the endosymbiont‐to‐plastid transformation formulated by Cavalier‐Smith & Lee (1985). Herein I discuss data that challenge this evolutionary scenario. Moreover, I propose a new model for the origin of multimembrane plastids belonging to the red lineage and apply it to the dinoflagellate peridinin plastid. The new model has several general and practical implications, such as the requirement for a new definition of cell organelles and in the construction of chimeric organisms. [ABSTRACT FROM AUTHOR]

Published

2018

19. Kingdom Chromista and its eight phyla: a new synthesis emphasising periplastid protein targeting, cytoskeletal and periplastid evolution, and ancient divergences.

Author

Cavalier-Smith, Thomas

Subjects

EUKARYOTES, CHLOROPLAST membranes, PLASTIDS, CYTOSKELETAL proteins, CELLULAR evolution

Abstract

In 1981 I established kingdom Chromista, distinguished from Plantae because of its more complex chloroplast-associated membrane topology and rigid tubular multipartite ciliary hairs. Plantae originated by converting a cyanobacterium to chloroplasts with Toc/Tic translocons; most evolved cell walls early, thereby losing phagotrophy. Chromists originated by enslaving a phagocytosed red alga, surrounding plastids by two extra membranes, placing them within the endomembrane system, necessitating novel protein import machineries. Early chromists retained phagotrophy, remaining naked and repeatedly reverted to heterotrophy by losing chloroplasts. Therefore, Chromista include secondary phagoheterotrophs (notably ciliates, many dinoflagellates, Opalozoa, Rhizaria, heliozoans) or walled osmotrophs (Pseudofungi, Labyrinthulea), formerly considered protozoa or fungi respectively, plus endoparasites (e.g. Sporozoa) and all chromophyte algae (other dinoflagellates, chromeroids, ochrophytes, haptophytes, cryptophytes). I discuss their origin, evolutionary diversification, and reasons for making chromists one kingdom despite highly divergent cytoskeletons and trophic modes, including improved explanations for periplastid/chloroplast protein targeting, derlin evolution, and ciliary/cytoskeletal diversification. I conjecture that transit-peptide-receptor-mediated 'endocytosis' from periplastid membranes generates periplastid vesicles that fuse with the arguably derlin-translocon-containing periplastid reticulum (putative red algal trans-Golgi network homologue; present in all chromophytes except dinoflagellates). I explain chromist origin from ancestral corticates and neokaryotes, reappraising tertiary symbiogenesis; a chromist cytoskeletal synapomorphy, a bypassing microtubule band dextral to both centrioles, favoured multiple axopodial origins. I revise chromist higher classification by transferring rhizarian subphylum Endomyxa from Cercozoa to Retaria; establishing retarian subphylum Ectoreta for Foraminifera plus Radiozoa, apicomonad subclasses, new dinozoan classes Myzodinea (grouping Colpovora gen. n., Psammosa), Endodinea, Sulcodinea, and subclass Karlodinia; and ranking heterokont Gyrista as phylum not superphylum. [ABSTRACT FROM AUTHOR]

Published

2018

20. Evolution of UhpC-type hexose-phosphate transporters in dinoflagellates.

Author

Hirakawa, Yoshihisa, Nakayama, Takuro, Keilert, Nadine, and Ishida, Ken‐ichiro

Subjects

DINOFLAGELLATES, ALGAL evolution, HEXOSE phosphates, PLASTIDS, ENDOSYMBIOSIS

Abstract

SUMMARY Primary plastids of the group Archaeplastida are descendants of a single cyanobacterial endosymbiont, while many other algal groups have obtained complex plastids, the so-called secondary plastids, via several parallel endosymbiotic uptakes of primary plastid-bearing algae. Integration of the endosymbiont into its host during primary and secondary endosymbiosis necessitated the establishment of transport mechanisms for metabolites, inorganic ions, and proteins across plastid envelope membranes. As a potential protein for exporting photosynthates out of primary plastids, homologs of bacterial UhpC-type hexose-phosphate transporters were found in algal members of the Archaeplastida. It has been proposed that plastidic UhpC-type transporters have been acquired in the common ancestor of Archaeplastida by the lateral gene transfer from a bacterial lineage closely related to Chlamydiae. However, it remains unknown whether secondary plastid-bearing organisms possess UhpC-type transporters. In the present study, we investigated homologous genes of UhpC in diverse algae using available genome and transcriptome data. Our homology survey and phylogenetic analyses revealed that only dinoflagellates possess UhpC-type transporters derived from an archaeplastidal lineage, whereas many other secondary plastid-bearing organisms lack them. It is possible that UhpC-type transporters are not essential in many secondary plastids because of the existence of other families of sugar phosphate transporters. [ABSTRACT FROM AUTHOR]

Published

2017

21. Major transitions in dinoflagellate evolution unveiled by phylotranscriptomics.

Author

Janouškovec, Jan, Waller, Ross F., Fensome, Robert A., Rohwer, Forest L., Dinh, Donna, Imanian, Behzad, Saldarriaga, Juan F., Leander, Brian S., Burki, Fabien, Gavelis, Gregory S., Bachvaroff, Tsvetan R., Gornik, Sebastian G., Bright, Kelley J., Strom, Suzanne L., and Delwiche, Charles F.

Subjects

DINOFLAGELLATES, MARINE ecology, MOLECULAR biology, EUKARYOTE phylogeny, BIOLUMINESCENCE, INSECTS

Abstract

Dinoflagellates are key species in marine environments, but they remain poorly understood in part because of their large, complex genomes, unique molecular biology, and unresolved in-group relationships. We created a taxonomically representative dataset of dinoflagellate transcriptomes and used this to infer a strongly supported phylogeny to map major morphological and molecular transitions in dinoflagellate evolution. Our results show an earlybranching position of Noctiluca, monophyly of thecate (plate-bearing) dinoflagellates, and paraphyly of athecate ones. This represents unambiguous phylogenetic evidence for a single origin of the group’s cellulosic theca, which we show coincided with a radiation of cellulases implicated in cell division. By integrating dinoflagellate molecular, fossil, and biogeochemical evidence, we propose a revised model for the evolution of thecal tabulations and suggest that the late acquisition of dinosterol in the group is inconsistent with dinoflagellates being the source of this biomarker in pre-Mesozoic strata. Three distantly related, fundamentally nonphotosynthetic dinoflagellates, Noctiluca, Oxyrrhis, and Dinophysis, contain cryptic plastidial metabolisms and lack alternative cytosolic pathways, suggesting that all free-living dinoflagellates are metabolically dependent on plastids. This finding led us to propose general mechanisms of dependency on plastid organelles in eukaryotes that have lost photosynthesis; it also suggests that the evolutionary origin of bioluminescence in nonphotosynthetic dinoflagellates may be linked to plastidic tetrapyrrole biosynthesis. Finally, we use our phylogenetic framework to show that dinoflagellate nuclei have recruited DNA-binding proteins in three distinct evolutionary waves, which included two independent acquisitions of bacterial histone-like proteins. [ABSTRACT FROM AUTHOR]

Published

2017

22. Evolution of the Tetrapyrrole Biosynthetic Pathway in Secondary Algae: Conservation, Redundancy and Replacement.

Author

Cihlář, Jaromír, Füssy, Zoltán, Horák, Aleš, and Oborník, Miroslav

Subjects

TETRAPYRROLES, BIOSYNTHESIS, ALGAL evolution, PHOTOSYNTHESIS, OXIDATIVE phosphorylation, ALGAE

Abstract

Tetrapyrroles such as chlorophyll and heme are indispensable for life because they are involved in energy fixation and consumption, i.e. photosynthesis and oxidative phosphorylation. In eukaryotes, the tetrapyrrole biosynthetic pathway is shaped by past endosymbioses. We investigated the origins and predicted locations of the enzymes of the heme pathway in the chlorarachniophyte Bigelowiella natans, the cryptophyte Guillardia theta, the “green” dinoflagellate Lepidodinium chlorophorum, and three dinoflagellates with diatom endosymbionts (“dinotoms”): Durinskia baltica, Glenodinium foliaceum and Kryptoperidinium foliaceum. Bigelowiella natans appears to contain two separate heme pathways analogous to those found in Euglena gracilis; one is predicted to be mitochondrial-cytosolic, while the second is predicted to be plastid-located. In the remaining algae, only plastid-type tetrapyrrole synthesis is present, with a single remnant of the mitochondrial-cytosolic pathway, a ferrochelatase of G. theta putatively located in the mitochondrion. The green dinoflagellate contains a single pathway composed of mostly rhodophyte-origin enzymes, and the dinotoms hold two heme pathways of apparently plastidal origin. We suggest that heme pathway enzymes in B. natans and L. chlorophorum share a predominantly rhodophytic origin. This implies the ancient presence of a rhodophyte-derived plastid in the chlorarachniophyte alga, analogous to the green dinoflagellate, or an exceptionally massive horizontal gene transfer. [ABSTRACT FROM AUTHOR]

Published

2016

23. Complex Ancestries of Isoprenoid Synthesis in Dinoflagellates.

Author

Bentlage, Bastian, Rogers, Travis S., Bachvaroff, Tsvetan R., and Delwiche, Charles F.

Subjects

ISOPENTENOID synthesis, DINOFLAGELLATES, PLASTIDS, MEVALONATE kinase, PRYMNESIOPHYCEAE

Abstract

Isoprenoid metabolism occupies a central position in the anabolic metabolism of all living cells. In plastid-bearing organisms, two pathways may be present for de novo isoprenoid synthesis, the cytosolic mevalonate pathway ( MVA) and nuclear-encoded, plastid-targeted nonmevalonate pathway ( DOXP). Using transcriptomic data we find that dinoflagellates apparently make exclusive use of the DOXP pathway. Using phylogenetic analyses of all DOXP genes we inferred the evolutionary origins of DOXP genes in dinoflagellates. Plastid replacements led to a DOXP pathway of multiple evolutionary origins. Dinoflagellates commonly referred to as dinotoms due to their relatively recent acquisition of a diatom plastid, express two completely redundant DOXP pathways. Dinoflagellates with a tertiary plastid of haptophyte origin , by contrast, express a hybrid pathway of dual evolutionary origin. Here, changes in the targeting motif of signal/transit peptide likely allow for targeting the new plastid by the proteins of core isoprenoid metabolism proteins. Parasitic dinoflagellates of the Amoebophyra species complex appear to have lost the DOXP pathway, suggesting that they may rely on their host for sterol synthesis. [ABSTRACT FROM AUTHOR]

Published

2016

24. Single-cell transcriptomics using spliced leader PCR: Evidence for multiple losses of photosynthesis in polykrikoid dinoflagellates.

Author

Gavelis, Gregory S., White III, Richard A., Suttle, Curtis A., Keeling, Patrick J., and Leander, Brian S.

Subjects

POLYMERASE chain reaction, DINOFLAGELLATES, PHOTOSYNTHESIS, PLASTIDS, PRYMNESIOPHYCEAE, GENE amplification

Abstract

Background: Most microbial eukaryotes are uncultivated and thus poorly suited to standard genomic techniques. This is the case for Polykrikos lebouriae, a dinoflagellate with ultrastructurally aberrant plastids. It has been suggested that these plastids stem from a novel symbiosis with either a diatom or haptophyte, but this hypothesis has been difficult to test as P. lebouriae dwells in marine sand rife with potential genetic contaminants. Results: We applied spliced-leader targeted PCR (SLPCR) to obtain dinoflagellate-specific transcriptomes on single-cell isolates of P. lebouriae from marine sediments. Polykrikos lebouriae expressed nuclear-encoded photosynthetic genes that were characteristic of the peridinin-plastids of dinoflagellates, rather than those from a diatom of haptophyte. We confirmed these findings at the genomic level using multiple displacement amplification (MDA) to obtain a partial plastome of P. lebouriae. Conclusion: From these data, we infer that P. lebouriae has retained the peridinin plastids ancestral for dinoflagellates as a whole, while its closest relatives have lost photosynthesis multiple times independently. We discuss these losses with reference to mixotrophy in polykrikoid dinoflagellates. Our findings demonstrate new levels of variation associated with the peridinin plastids of dinoflagellates and the usefulness of SLPCR approaches on single cell isolates. Unlike other transcriptomic methods, SLPCR has taxonomic specificity, and can in principle be adapted to different splice-leader bearing groups. [ABSTRACT FROM AUTHOR]

Published

2015

25. Integration of plastids with their hosts: Lessons learned from dinoflagellates.

Author

Dorrell, Richard G. and Howe, Christopher J.

Subjects

PLASTIDS, DINOFLAGELLATES, GENOMICS, CELL nuclei, CHLOROPLAST DNA

Abstract

After their endosymbiotic acquisition, plastids become intimately connected with the biology of their host. For example, genes essential for plastid function may be relocated from the genomes of plastids to the host nucleus, and pathways may evolve within the host to support the plastid. In this review, we consider the different degrees of integration observed in dinoflagellates and their associated plastids, which have been acquired through multiple different endosymbiotic events. Most dinoflagellate species possess plastids that contain the pigment peridinin and show extreme reduction and integration with the host biology. In some species, these plastids have been replaced through serial endosymbiosis with plastids derived from a different phylogenetic derivation, of which some have become intimately connected with the biology of the host whereas others have not. We discuss in particular the evolution of the fucoxanthin-containing dinoflagellates, which have adapted pathways retained from the ancestral peridinin plastid symbiosis for transcript processing in their current, serially acquired plastids. Finally, we consider why such a diversity of different degrees of integration between host and plastid is observed in different dinoflagellates and how dinoflagellates may thus inform our broader understanding of plastid evolution and function. [ABSTRACT FROM AUTHOR]

Published

2015

26. There Is Treasure Everywhere: Reductive Plastid Evolution in Apicomplexa in Light of Their Close Relatives.

Author

Salomaki, Eric D. and Kolisko, Martin

Subjects

PLASMODIUM falciparum, APICOMPLEXA, INTRACELLULAR pathogens, PLASTIDS, FATTY acids

Abstract

The phylum Apicomplexa (Alveolates) comprises a group of host-associated protists, predominately intracellular parasites, including devastating parasites like Plasmodium falciparum, the causative agent of malaria. One of the more fascinating characteristics of Apicomplexa is their highly reduced (and occasionally lost) remnant plastid, termed the apicoplast. Four core metabolic pathways are retained in the apicoplast: heme synthesis, iron–sulfur cluster synthesis, isoprenoid synthesis, and fatty acid synthesis. It has been suggested that one or more of these pathways are essential for plastid and plastid genome retention. The past decade has witnessed the discovery of several apicomplexan relatives, and next-generation sequencing efforts are revealing that they retain variable plastid metabolic capacities. These data are providing clues about the core genes and pathways of reduced plastids, while at the same time further confounding our view on the evolutionary history of the apicoplast. Here, we examine the evolutionary history of the apicoplast, explore plastid metabolism in Apicomplexa and their close relatives, and propose that the differences among reduced plastids result from a game of endosymbiotic roulette. Continued exploration of the Apicomplexa and their relatives is sure to provide new insights into the evolution of the apicoplast and apicomplexans as a whole. [ABSTRACT FROM AUTHOR]

Published

2019

27. Plastid Genome Evolution

Author

Shu-Miaw Chaw, Robert K. Jansen, Shu-Miaw Chaw, and Robert K. Jansen

Subjects

Plastids

Abstract

Plastid Genome Evolution, Volume 85 provides a summary of recent research on plastid genome variation and evolution across photosynthetic organisms. It covers topics ranging from the causes and consequences of genomic changes, to the phylogenetic utility of plastomes for resolving relationships across the photosynthetic tree of life. This newly released volume presents thorough, up-to-date information on coevolution between the plastid and nuclear genomes, with chapters on plastid autonomy vs. nuclear control over plastid function, establishment and genetic integration of plastids, plastid genomes in alveolate protists, plastid genomes of glaucophytes, the evolution of the plastid genome in chlorophyte and streptophyte green algae, and more. - Provides comprehensive coverage of plastid genome variation by leading researchers in the field - Presents a broad range of taxonomic groups, ranging from single and multicellular algae, to the major clades of land plants - Includes thorough, up-to-date information on coevolution between the plastid and nuclear genomes

Published

2018