Your search keyword '"TANIFUJI G."' showing total 42 results

1. An evolutionary transition of chloroplast degradation in euglenoids: heterotrophic digestion to secondary plastid senescence

Author

KASHIYAMA Y., KAWAHARA J., MARUYAMA M., KAYAMA M., NAKAZAWA M., TANIFUJI G., YOKOYAMA A., ISHIKAWA T., TAMIAKI H., and SUZAKI T.

Published

2016

2. The draft genome of Kipferia bialata reveals that the gain of function contributes the massive reductive evolution in Metamonada

Author

TANIFUJI G., TAKABAYASHI S., KUME K., TAKAGI M.T., INAGAKI Y.I., and HASHIMOTO T.

Published

2016

3. Algal genomes reveal evolutionary mosaicism and the fate of nucleomorphs

Author

Curtis, B. A., Tanifuji, G., Maruyama, S., Gile, G. H., Hopkins, J. F., Eveleigh, R. J. M., Nakayama, T., Malik, S.-B., Onodera, N. T., Slamovits, C. H., Spencer, D. F., Lane, C. E., Gray, M. W., Archibald, J. M., Burki, F., Hirakawa, Y., Reyes-Prieto, A., Keeling, P. J., Fast, N. M., Green, B. R., Grisdale, C. J., Gruber, A., Kroth, P. G., Irimia, M., Arias, M. C., Ball, S. G., Kuo, A., Schmutz, J., Grimwood, J., Lindquist, E., Lucas, S., Salamov, A., Grigoriev, I. V., Rensing, S. A., Symeonidi, A., Elias, M., Herman, E. K., Klute, M. J., Dacks, J. B., Oborník, M., Kořený, L., Durnford, D. G., Neilson, J. A. D., Armbrust, E. V., Rocap, G., Aves, S. J., Liu, Y., Beiko, R. G., Coutinho, P., Henrissat, B., Hempel, F., Maier, U.G., Zauner, S., Häppner, M. P., Ishida, K.-I., Shirato, S., Suzuki, S., Kim, E., Richards, T. A., Mc Rose, D., Worden, Alexandra Z., Mock, T., Poole, A. M., Pritham, E. J., Roy, S. W., Schaack, S., Bell, C., Bharti, A. K., Crow, J. A., Kramer, R., Mc Fadden, G. I., Curtis, B. A., Tanifuji, G., Maruyama, S., Gile, G. H., Hopkins, J. F., Eveleigh, R. J. M., Nakayama, T., Malik, S.-B., Onodera, N. T., Slamovits, C. H., Spencer, D. F., Lane, C. E., Gray, M. W., Archibald, J. M., Burki, F., Hirakawa, Y., Reyes-Prieto, A., Keeling, P. J., Fast, N. M., Green, B. R., Grisdale, C. J., Gruber, A., Kroth, P. G., Irimia, M., Arias, M. C., Ball, S. G., Kuo, A., Schmutz, J., Grimwood, J., Lindquist, E., Lucas, S., Salamov, A., Grigoriev, I. V., Rensing, S. A., Symeonidi, A., Elias, M., Herman, E. K., Klute, M. J., Dacks, J. B., Oborník, M., Kořený, L., Durnford, D. G., Neilson, J. A. D., Armbrust, E. V., Rocap, G., Aves, S. J., Liu, Y., Beiko, R. G., Coutinho, P., Henrissat, B., Hempel, F., Maier, U.G., Zauner, S., Häppner, M. P., Ishida, K.-I., Shirato, S., Suzuki, S., Kim, E., Richards, T. A., Mc Rose, D., Worden, Alexandra Z., Mock, T., Poole, A. M., Pritham, E. J., Roy, S. W., Schaack, S., Bell, C., Bharti, A. K., Crow, J. A., Kramer, R., and Mc Fadden, G. I.

Abstract

Cryptophyte and chlorarachniophyte algae are transitional forms in the widespread secondary endosymbiotic acquisition of photosynthesis by engulfment of eukaryotic algae. Unlike most secondary plastid-bearing algae, miniaturized versions of the endosymbiont nuclei (nucleomorphs) persist in cryptophytes and chlorarachniophytes. To determine why, and to address other fundamental questions about eukaryote–eukaryote endosymbiosis, we sequenced the nuclear genomes of the cryptophyte Guillardia theta and the chlorarachniophyte Bigelowiella natans. Both genomes have <21, 000 protein genes and are intron rich, and B. natans exhibits unprecedented alternative splicing for a single-celled organism. Phylogenomic analyses and subcellular targeting predictions reveal extensive genetic and biochemical mosaicism, with both host- and endosymbiont-derived genes servicing the mitochondrion, the host cell cytosol, the plastid and the remnant endosymbiont cytosol of both algae. Mitochondrion-to-nucleus gene transfer still occurs in both organisms but plastid-to-nucleus and nucleomorph-to-nucleus transfers do not, which explains why a small residue of essential genes remains locked in each nucleomorph. © 2012 Macmillan Publishers Limited. All rights reserved.

Published

2012

4. Transcriptome data sets of free-living diplomonads, Trepomonas sp. and Hexamita sp.

Author

Kume K, Gen T, Abe K, Komatsuzaki H, Yazaki E, Tanifuji G, Kamikawa R, Inagaki Y, and Hashimoto T

Abstract

Most species belonging to the diplomonad genera, Trepomonas and Hexamita , are considered to have secondarily adapted to free-living lifestyles from the parasitic ancestor. Here, we report the annotated transcriptome data of Trepomonas sp. NIES-1444 and Hexamita sp. NIES-1440, the analysis of which will provide insights into the lifestyle transitions., Competing Interests: The authors declare no conflict of interest.

Published

2023

5. A practical assembly guideline for genomes with various levels of heterozygosity.

Author

Mochizuki T, Sakamoto M, Tanizawa Y, Nakayama T, Tanifuji G, Kamikawa R, and Nakamura Y

Subjects

Sequence Analysis, DNA, Haplotypes, Heterozygote, Alleles, High-Throughput Nucleotide Sequencing

Abstract

Although current long-read sequencing technologies have a long-read length that facilitates assembly for genome reconstruction, they have high sequence errors. While various assemblers with different perspectives have been developed, no systematic evaluation of assemblers with long reads for diploid genomes with varying heterozygosity has been performed. Here, we evaluated a series of processes, including the estimation of genome characteristics such as genome size and heterozygosity, de novo assembly, polishing, and removal of allelic contigs, using six genomes with various heterozygosity levels. We evaluated five long-read-only assemblers (Canu, Flye, miniasm, NextDenovo and Redbean) and five hybrid assemblers that combine short and long reads (HASLR, MaSuRCA, Platanus-allee, SPAdes and WENGAN) and proposed a concrete guideline for the construction of haplotype representation according to the degree of heterozygosity, followed by polishing and purging haplotigs, using stable and high-performance assemblers: Redbean, Flye and MaSuRCA., (© The Author(s) 2023. Published by Oxford University Press.)

Published

2023

6. Horizontally Acquired Nitrate Reductase Realized Kleptoplastic Photoautotrophy of Rapaza viridis.

Author

Maruyama M, Kagamoto T, Matsumoto Y, Onuma R, Miyagishima SY, Tanifuji G, Nakazawa M, and Kashiyama Y

Subjects

Nitrate Reductase genetics, Nitrate Reductase metabolism, Phylogeny, Nitrogen metabolism, Nitrates metabolism, Ammonium Compounds

Abstract

While photoautotrophic organisms utilize inorganic nitrogen as the nitrogen source, heterotrophic organisms utilize organic nitrogen and thus do not generally have an inorganic nitrogen assimilation pathway. Here, we focused on the nitrogen metabolism of Rapaza viridis, a unicellular eukaryote exhibiting kleptoplasty. Although belonging to the lineage of essentially heterotrophic flagellates, R. viridis exploits the photosynthetic products of the kleptoplasts and was therefore suspected to potentially utilize inorganic nitrogen. From the transcriptome data of R. viridis, we identified gene RvNaRL, which had sequence similarity to genes encoding nitrate reductases in plants. Phylogenetic analysis revealed that RvNaRL was acquired by a horizontal gene transfer event. To verify the function of the protein product RvNaRL, we established RNAi-mediated knock-down and CRISPR-Cas9-mediated knock-out experiments for the first time in R. viridis and applied them to this gene. The RvNaRL knock-down and knock-out cells exhibited significant growth only when ammonium was supplied. However, in contrast to the wild-type cells, no substantial growth was observed when nitrate was supplied. Such arrested growth in the absence of ammonium was attributed to impaired amino acid synthesis due to the deficiency of nitrogen supply from the nitrate assimilation pathway; this in turn resulted in the accumulation of excess photosynthetic products in the form of cytosolic polysaccharide grains, as observed. These results indicate that RvNaRL is certainly involved in nitrate assimilation by R. viridis. Thus, we inferred that R. viridis achieved its advanced kleptoplasty for photoautotrophy, owing to the acquisition of nitrate assimilation via horizontal gene transfer., (© The Author(s) 2023. Published by Oxford University Press on behalf of Japanese Society of Plant Physiologists. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2023

7. Fascinating strategies of marine benthic organisms to cope with emerging pollutant: Titanium dioxide nanoparticles.

Author

Ishitani Y, Ciacci C, Ujiié Y, Tame A, Tiboni M, Tanifuji G, Inagaki Y, and Frontalini F

Subjects

Reactive Oxygen Species, Titanium toxicity, Environmental Pollutants, Nanoparticles toxicity, Metal Nanoparticles toxicity

Abstract

Titanium dioxide nanoparticles (NPs) have numerous applications, and their demands have increased as an alternative for banned sunscreen filters. However, the underlying mechanisms of their toxicity, remain largely unknown. Here, we investigate the mechanism of TiO 2 NP cytotoxicity and detoxification through time-course experiments (1, 6, and 24 h) based on cellular observations and single-cell transcriptome analyses in a marine benthic foraminifer strain, derived from a common unicellular eukaryotic organism worldwide. After exposure for 1 h, cells enhanced the production of reactive oxygen species (ROS) in acidic endosomes containing TiO 2 NPs as well as in mitochondria. In acidic endosomes, ROS were produced through the Fenton reaction on the surface of charged TiO 2 NPs. In mitochondria, ROS were associated with porphyrin synthesis that chelated metal ions. Glutathione peroxide and neutral lipids acted as a sink for free radicals, whereas lipid peroxides were excreted to prevent further radical chain reactions. By 24 h, aggregated TiO 2 NPs were encapsulated in organic compounds, possibly ceramide, and excreted as mucus, thereby preventing their further uptake. Thus, we reveal that foraminifers can tolerate the toxicity of TiO 2 NPs and even prevent their further phagocytosis and uptake by trapping TiO 2 NPs inside mucus. This previously unknown strategy could be applied in bioremediation to sequester NPs from the marine environment and can guide management of TiO 2 pollution., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2023

8. Gene loss, pseudogenization, and independent genome reduction in non-photosynthetic species of Cryptomonas (Cryptophyceae) revealed by comparative nucleomorph genomics.

Author

Kim JI, Tanifuji G, Jeong M, Shin W, and Archibald JM

Subjects

Genomics, Photosynthesis, Phylogeny, Plastids genetics, Cryptophyta genetics, Genome

Abstract

Background: Cryptophytes are ecologically important algae of interest to evolutionary cell biologists because of the convoluted history of their plastids and nucleomorphs, which are derived from red algal secondary endosymbionts. To better understand the evolution of the cryptophyte nucleomorph, we sequenced nucleomorph genomes from two photosynthetic and two non-photosynthetic species in the genus Cryptomonas. We performed a comparative analysis of these four genomes and the previously published genome of the non-photosynthetic species Cryptomonas paramecium CCAP977/2a., Results: All five nucleomorph genomes are similar in terms of their general architecture, gene content, and gene order and, in the non-photosynthetic strains, loss of photosynthesis-related genes. Interestingly, in terms of size and coding capacity, the nucleomorph genome of the non-photosynthetic species Cryptomonas sp. CCAC1634B is much more similar to that of the photosynthetic C. curvata species than to the non-photosynthetic species C. paramecium., Conclusions: Our results reveal fine-scale nucleomorph genome variation between distantly related congeneric taxa containing photosynthetic and non-photosynthetic species, including recent pseudogene formation, and provide a first glimpse into the possible impacts of the loss of photosynthesis on nucleomorph genome coding capacity and structure in independently evolved colorless strains., (© 2022. The Author(s).)

Published

2022

9. Genome evolution of a nonparasitic secondary heterotroph, the diatom Nitzschia putrida .

Author

Kamikawa R, Mochizuki T, Sakamoto M, Tanizawa Y, Nakayama T, Onuma R, Cenci U, Moog D, Speak S, Sarkozi K, Toseland A, van Oosterhout C, Oyama K, Kato M, Kume K, Kayama M, Azuma T, Ishii KI, Miyashita H, Henrissat B, Lombard V, Win J, Kamoun S, Kashiyama Y, Mayama S, Miyagishima SY, Tanifuji G, Mock T, and Nakamura Y

Abstract

Secondary loss of photosynthesis is observed across almost all plastid-bearing branches of the eukaryotic tree of life. However, genome-based insights into the transition from a phototroph into a secondary heterotroph have so far only been revealed for parasitic species. Free-living organisms can yield unique insights into the evolutionary consequence of the loss of photosynthesis, as the parasitic lifestyle requires specific adaptations to host environments. Here, we report on the diploid genome of the free-living diatom Nitzschia putrida (35 Mbp), a nonphotosynthetic osmotroph whose photosynthetic relatives contribute ca. 40% of net oceanic primary production. Comparative analyses with photosynthetic diatoms and heterotrophic algae with parasitic lifestyle revealed that a combination of gene loss, the accumulation of genes involved in organic carbon degradation, a unique secretome, and the rapid divergence of conserved gene families involved in cell wall and extracellular metabolism appear to have facilitated the lifestyle of a free-living secondary heterotroph.

Published

2022

10. Signs of the plastid: Enzymes involved in plastid-localized metabolic pathways in a eugregarine species.

Author

Yazaki E, Miyata R, Chikami Y, Harada R, Kawakubo T, Tanifuji G, Nakayama T, Yahata K, Hashimoto T, and Inagaki Y

Subjects

Apicomplexa metabolism, Metabolic Networks and Pathways, Plastids metabolism

Abstract

Apicomplexa mainly comprises parasitic species and some of them, which infect and cause severe diseases to humans and livestock, have been extensively studied due to the clinical and industrial importance. Besides, apicomplexans are a popular subject of the studies focusing on the evolution initiated by a secondary loss of photosynthesis. By interpreting the position in the tree of eukaryotes and lifestyles of the phylogenetic relatives parsimoniously, the extant apicomplexans are predicted to be the descendants of a parasite bearing a non-photosynthetic (cryptic) plastid. The plastid-bearing characteristic for the ancestral apicomplexan is further strengthened by non-photosynthetic plastids found in the extant apicomplexans. The research on apicomplexan members infecting invertebrates is much less advanced than that on the pathogens to humans and livestock. Gregarines are apicomplexans that infect diverse invertebrates and recent studies based on transcriptome data revealed the presence of cryptic plastids in a subset of the species investigated. In this study, we isolated gregarine-like organisms (GLOs) from three arthropod species and conducted transcriptome analyses on the isolated cells. A transcriptome-based, multi-gene phylogenetic analysis clearly indicated that all of the three GLOs are eugregarines. Significantly, the transcriptome data from the GLO in a centipede appeared to contain the transcripts encoding enzymes involved in the non-mevalonate pathway for isopentenyl diphosphate biosynthesis and C5 pathway for heme biosynthesis. The enzymes involved in the two plastid-localized metabolic pathways circumstantially but strongly suggest that the particular GLO possesses a cryptic plastid. The evolution of cryptic plastids in eugregarines is revised by incorporating the new data obtained from the three GLOs in this study., (Copyright © 2021 Elsevier B.V. All rights reserved.)

Published

2021

11. Barthelonids represent a deep-branching metamonad clade with mitochondrion-related organelles predicted to generate no ATP.

Author

Yazaki E, Kume K, Shiratori T, Eglit Y, Tanifuji G, Harada R, Simpson AGB, Ishida KI, Hashimoto T, and Inagaki Y

Subjects

Anaerobiosis, Eukaryota metabolism, Mitochondria metabolism, Organelles metabolism, Biological Evolution, Eukaryota physiology, Phylogeny

Abstract

We here report the phylogenetic position of barthelonids, small anaerobic flagellates previously examined using light microscopy alone. Barthelona spp. were isolated from geographically distinct regions and we established five laboratory strains. Transcriptomic data generated from one Barthelona strain (PAP020) were used for large-scale, multi-gene phylogenetic (phylogenomic) analyses. Our analyses robustly placed strain PAP020 at the base of the Fornicata clade, indicating that barthelonids represent a deep-branching metamonad clade. Considering the anaerobic/microaerophilic nature of barthelonids and preliminary electron microscopy observations on strain PAP020, we suspected that barthelonids possess functionally and structurally reduced mitochondria (i.e. mitochondrion-related organelles or MROs). The metabolic pathways localized in the MRO of strain PAP020 were predicted based on its transcriptomic data and compared with those in the MROs of fornicates. We here propose that strain PAP020 is incapable of generating ATP in the MRO, as no mitochondrial/MRO enzymes involved in substrate-level phosphorylation were detected. Instead, we detected a putative cytosolic ATP-generating enzyme (acetyl-CoA synthetase), suggesting that strain PAP020 depends on ATP generated in the cytosol. We propose two separate losses of substrate-level phosphorylation from the MRO in the clade containing barthelonids and (other) fornicates.

Published

2020

12. Putative genome features of relic green alga-derived nuclei in dinoflagellates and future perspectives as model organisms.

Author

Nakayama T, Takahashi K, Kamikawa R, Iwataki M, Inagaki Y, and Tanifuji G

Abstract

Nucleomorphs, relic endosymbiont nuclei, have been studied as a model to elucidate the evolutionary process of integrating a eukaryotic endosymbiont into a host cell organelle. Recently, we reported two new dinoflagellates possessing nucleomorphs, and proposed them as new models in this research field based on the following findings: genome integration processes are incomplete, and the origins of the endosymbiont lineages were pinpointed. Here, we focused on the nucleomorph genome features in the two green dinoflagellates and compared them with those of the known nucleomorph genomes of cryptophytes and chlorarachniophytes. All nucleomorph genomes showed similar trends suggesting convergent evolution. However, the number of nucleomorph genes that are unrelated to housekeeping machineries in the two green dinoflagellates are greater than the numbers in cryptophytes and chlorarachniophytes, providing additional evidence that their genome reduction has not progressed much compared with those of cryptophytes and chlorarachniophytes. Finally, potential future work is discussed., Competing Interests: No potential conflict of interest was reported by the authors., (© 2020 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group.)

Published

2020

13. Inventory and Evolution of Mitochondrion-localized Family A DNA Polymerases in Euglenozoa.

Author

Harada R, Hirakawa Y, Yabuki A, Kashiyama Y, Maruyama M, Onuma R, Soukal P, Miyagishima S, Hampl V, Tanifuji G, and Inagaki Y

Abstract

The order Trypanosomatida has been well studied due to its pathogenicity and the unique biology of the mitochondrion. In Trypanosoma brucei , four DNA polymerases, namely PolIA, PolIB, PolIC, and PolID, related to bacterial DNA polymerase I (PolI), were shown to be localized in mitochondria experimentally. These mitochondrion-localized DNA polymerases are phylogenetically distinct from other family A DNA polymerases, such as bacterial PolI, DNA polymerase gamma (Polγ) in human and yeasts, "plant and protist organellar DNA polymerase (POP)" in diverse eukaryotes. However, the diversity of mitochondrion-localized DNA polymerases in Euglenozoa other than Trypanosomatida is poorly understood. In this study, we discovered putative mitochondrion-localized DNA polymerases in broad members of three major classes of Euglenozoa-Kinetoplastea, Diplonemea, and Euglenida-to explore the origin and evolution of trypanosomatid PolIA-D. We unveiled distinct inventories of mitochondrion-localized DNA polymerases in the three classes: (1) PolIA is ubiquitous across the three euglenozoan classes, (2) PolIB, C, and D are restricted in kinetoplastids, (3) new types of mitochondrion-localized DNA polymerases were identified in a prokinetoplastid and diplonemids, and (4) evolutionarily distinct types of POP were found in euglenids. We finally propose scenarios to explain the inventories of mitochondrion-localized DNA polymerases in Kinetoplastea, Diplonemea, and Euglenida.

Published

2020

14. Dinoflagellates with relic endosymbiont nuclei as models for elucidating organellogenesis.

Author

Sarai C, Tanifuji G, Nakayama T, Kamikawa R, Takahashi K, Yazaki E, Matsuo E, Miyashita H, Ishida KI, Iwataki M, and Inagaki Y

Subjects

Cell Nucleus genetics, Cell Nucleus physiology, Cercozoa classification, Cercozoa genetics, Chlorophyta classification, Chlorophyta physiology, Chlorophyta ultrastructure, Cryptophyta classification, Cryptophyta genetics, Dinoflagellida classification, Dinoflagellida genetics, Models, Biological, Phylogeny, Plastids genetics, Cercozoa ultrastructure, Cryptophyta ultrastructure, Dinoflagellida ultrastructure, Evolution, Molecular, Genome, Plastid, Plastids physiology, Symbiosis

Abstract

Nucleomorphs are relic endosymbiont nuclei so far found only in two algal groups, cryptophytes and chlorarachniophytes, which have been studied to model the evolutionary process of integrating an endosymbiont alga into a host-governed plastid (organellogenesis). However, past studies suggest that DNA transfer from the endosymbiont to host nuclei had already ceased in both cryptophytes and chlorarachniophytes, implying that the organellogenesis at the genetic level has been completed in the two systems. Moreover, we have yet to pinpoint the closest free-living relative of the endosymbiotic alga engulfed by the ancestral chlorarachniophyte or cryptophyte, making it difficult to infer how organellogenesis altered the endosymbiont genome. To counter the above issues, we need novel nucleomorph-bearing algae, in which endosymbiont-to-host DNA transfer is on-going and for which endosymbiont/plastid origins can be inferred at a fine taxonomic scale. Here, we report two previously undescribed dinoflagellates, strains MGD and TGD, with green algal endosymbionts enclosing plastids as well as relic nuclei (nucleomorphs). We provide evidence for the presence of DNA in the two nucleomorphs and the transfer of endosymbiont genes to the host (dinoflagellate) genomes. Furthermore, DNA transfer between the host and endosymbiont nuclei was found to be in progress in both the MGD and TGD systems. Phylogenetic analyses successfully resolved the origins of the endosymbionts at the genus level. With the combined evidence, we conclude that the host-endosymbiont integration in MGD/TGD is less advanced than that in cryptophytes/chrorarachniophytes, and propose the two dinoflagellates as models for elucidating organellogenesis., Competing Interests: The authors declare no competing interest.

Published

2020

15. Comparative Plastid Genomics of Cryptomonas Species Reveals Fine-Scale Genomic Responses to Loss of Photosynthesis.

Author

Tanifuji G, Kamikawa R, Moore CE, Mills T, Onodera NT, Kashiyama Y, Archibald JM, Inagaki Y, and Hashimoto T

Subjects

Genome, Plastid genetics, Genomics methods, Photosynthesis genetics, Photosynthesis physiology, Phylogeny, Cryptophyta genetics, Plastids genetics

Abstract

Loss of photosynthesis is a recurring theme in eukaryotic evolution. In organisms that have lost the ability to photosynthesize, nonphotosynthetic plastids are retained because they play essential roles in processes other than photosynthesis. The unicellular algal genus Cryptomonas contains both photosynthetic and nonphotosynthetic members, the latter having lost the ability to photosynthesize on at least three separate occasions. To elucidate the evolutionary processes underlying the loss of photosynthesis, we sequenced the plastid genomes of two nonphotosynthetic strains, Cryptomonas sp. CCAC1634B and SAG977-2f, as well as the genome of the phototroph Cryptomonas curvata CCAP979/52. These three genome sequences were compared with the previously sequenced plastid genome of the nonphotosynthetic species Cryptomonas paramecium CCAP977/2a as well as photosynthetic members of the Cryptomonadales, including C. curvata FBCC300012D. Intraspecies comparison between the two C. curvata strains showed that although their genome structures are stable, the substitution rates of their genes are relatively high. Although most photosynthesis-related genes, such as the psa and psb gene families, were found to have disappeared from the nonphotosynthetic strains, at least ten pseudogenes are retained in SAG977-2f. Although gene order is roughly shared among the plastid genomes of photosynthetic Cryptomonadales, genome rearrangements are seen more frequently in the smaller genomes of the nonphotosynthetic strains. Intriguingly, the light-independent protochlorophyllide reductase comprising chlB, L, and N is retained in nonphotosynthetic SAG977-2f and CCAC1634B. On the other hand, whereas CCAP977/2a retains ribulose-1,5-bisphosphate carboxylase/oxygenase-related genes, including rbcL, rbcS, and cbbX, the plastid genomes of the other two nonphotosynthetic strains have lost the ribulose-1,5-bisphosphate carboxylase/oxygenase protein-coding genes., (© The Author(s) 2020. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2020

16. Single-cell genomics unveiled a cryptic cyanobacterial lineage with a worldwide distribution hidden by a dinoflagellate host.

Author

Nakayama T, Nomura M, Takano Y, Tanifuji G, Shiba K, Inaba K, Inagaki Y, and Kawata M

Subjects

Base Sequence, Cyanobacteria isolation & purification, DNA Barcoding, Taxonomic, Genome, Bacterial, Likelihood Functions, Metagenomics, Symbiosis genetics, Cyanobacteria genetics, Dinoflagellida microbiology, Genomics methods, Geography, Phylogeny, Single-Cell Analysis methods

Abstract

Cyanobacteria are one of the most important contributors to oceanic primary production and survive in a wide range of marine habitats. Much effort has been made to understand their ecological features, diversity, and evolution, based mainly on data from free-living cyanobacterial species. In addition, symbiosis has emerged as an important lifestyle of oceanic microbes and increasing knowledge of cyanobacteria in symbiotic relationships with unicellular eukaryotes suggests their significance in understanding the global oceanic ecosystem. However, detailed characteristics of these cyanobacteria remain poorly described. To gain better insight into marine cyanobacteria in symbiosis, we sequenced the genome of cyanobacteria collected from a cell of a pelagic dinoflagellate that is known to host cyanobacterial symbionts within a specialized chamber. Phylogenetic analyses using the genome sequence revealed that the cyanobacterium represents an underdescribed lineage within an extensively studied, ecologically important group of marine cyanobacteria. Metagenomic analyses demonstrated that this cyanobacterial lineage is globally distributed and strictly coexists with its host dinoflagellates, suggesting that the intimate symbiotic association allowed the cyanobacteria to escape from previous metagenomic studies. Furthermore, a comparative analysis of the protein repertoire with related species indicated that the lineage has independently undergone reductive genome evolution to a similar extent as Prochlorococcus , which has the most reduced genomes among free-living cyanobacteria. Discovery of this cyanobacterial lineage, hidden by its symbiotic lifestyle, provides crucial insights into the diversity, ecology, and evolution of marine cyanobacteria and suggests the existence of other undiscovered cryptic cyanobacterial lineages., Competing Interests: The authors declare no conflict of interest.

Published

2019

17. Taming chlorophylls by early eukaryotes underpinned algal interactions and the diversification of the eukaryotes on the oxygenated Earth.

Author

Kashiyama Y, Yokoyama A, Shiratori T, Hess S, Not F, Bachy C, Gutierrez-Rodriguez A, Kawahara J, Suzaki T, Nakazawa M, Ishikawa T, Maruyama M, Wang M, Chen M, Gong Y, Seto K, Kagami M, Hamamoto Y, Honda D, Umetani T, Shihongi A, Kayama M, Matsuda T, Taira J, Yabuki A, Tsuchiya M, Hirakawa Y, Kawaguchi A, Nomura M, Nakamura A, Namba N, Matsumoto M, Tanaka T, Yoshino T, Higuchi R, Yamamoto A, Maruyama T, Yamaguchi A, Uzuka A, Miyagishima S, Tanifuji G, Kawachi M, Kinoshita Y, and Tamiaki H

Subjects

Chloroplasts metabolism, Ecosystem, Eukaryota classification, Eukaryota genetics, Microalgae classification, Microalgae genetics, Microalgae metabolism, Photosynthesis, Phylogeny, Symbiosis, Chlorophyll metabolism, Eukaryota metabolism, Oxygen metabolism

Abstract

Extant eukaryote ecology is primarily sustained by oxygenic photosynthesis, in which chlorophylls play essential roles. The exceptional photosensitivity of chlorophylls allows them to harvest solar energy for photosynthesis, but on the other hand, they also generate cytotoxic reactive oxygen species. A risk of such phototoxicity of the chlorophyll must become particularly prominent upon dynamic cellular interactions that potentially disrupt the mechanisms that are designed to quench photoexcited chlorophylls in the phototrophic cells. Extensive examination of a wide variety of phagotrophic, parasitic, and phototrophic microeukaryotes demonstrates that a catabolic process that converts chlorophylls into nonphotosensitive 13 2 ,17 3 -cyclopheophorbide enols (CPEs) is phylogenetically ubiquitous among extant eukaryotes. The accumulation of CPEs is identified in phagotrophic algivores belonging to virtually all major eukaryotic assemblages with the exception of Archaeplastida, in which no algivorous species have been reported. In addition, accumulation of CPEs is revealed to be common among phototrophic microeukaryotes (i.e., microalgae) along with dismantling of their secondary chloroplasts. Thus, we infer that CPE-accumulating chlorophyll catabolism (CACC) primarily evolved among algivorous microeukaryotes to detoxify chlorophylls in an early stage of their evolution. Subsequently, it also underpinned photosynthetic endosymbiosis by securing close interactions with photosynthetic machinery containing abundant chlorophylls, which led to the acquisition of secondary chloroplasts. Our results strongly suggest that CACC, which allowed the consumption of oxygenic primary producers, ultimately permitted the successful radiation of the eukaryotes throughout and after the late Proterozoic global oxygenation.

Published

2019

18. The draft genome of Kipferlia bialata reveals reductive genome evolution in fornicate parasites.

Author

Tanifuji G, Takabayashi S, Kume K, Takagi M, Nakayama T, Kamikawa R, Inagaki Y, and Hashimoto T

Subjects

Eukaryota genetics, Evolution, Molecular, Genome

Abstract

The fornicata (fornicates) is a eukaryotic group known to consist of free-living and parasitic organisms. Genome datasets of two model fornicate parasites Giardia intestinalis and Spironucleus salmonicida are well annotated, so far. The nuclear genomes of G. intestinalis assemblages and S. salmonicida are small in terms of the genome size and simple in genome structure. However, an ancestral genomic structure and gene contents, from which genomes of the fornicate parasites have evolved, remains to be clarified. In order to understand genome evolution in fornicates, here, we present the draft genome sequence of a free-living fornicate, Kipferlia bialata, the divergence of which is earlier than those of the fornicate parasites, and compare it to the genomes of G. intestinalis and S. salmonicida. Our data show that the number of protein genes and introns in K. bialata genome are the most abundant in the genomes of three fornicates, reflecting an ancestral state of fornicate genome evolution. Evasion mechanisms of host immunity found in G. intestinalis and S. salmonicida are absent in the K. bialata genome, suggesting that the two parasites acquired the complex membrane surface proteins on the line leading to the common ancestor of G. intestinalis and S. salmonicida after the divergence from K. bialata. Furthermore, the mitochondrion related organelles (MROs) of K. bialata possess more complex suites of metabolic pathways than those in Giardia and in Spironucleus. In sum, our results unveil the process of reductive evolution which shaped the current genomes in two model fornicate parasites G. intestinalis and S. salmonicida.

Published

2018

19. Microbial Eukaryotes that Lack Sterols.

Author

Takishita K, Chikaraishi Y, Tanifuji G, Ohkouchi N, Hashimoto T, Fujikura K, and Roger AJ

Subjects

Cell Membrane chemistry, Eukaryota chemistry, Eukaryota physiology, Sterols analysis, Triterpenes analysis

Abstract

It is widely held that sterols are key cyclic triterpenoid lipids in eukaryotic cell membranes and are synthesized through oxygen-dependent multienzyme pathways. However, there are known exceptions-ciliated protozoans, such as Tetrahymena, along with diverse low-oxygen-adapted eukaryotes produce, instead of sterols, the cyclic triterpenoid lipid tetrahymanol that does not require molecular oxygen for its biosynthesis. Here, we report that a number of anaerobic microbial eukaryotes (protists) utilize neither sterols nor tetrahymanol in their membranes. The lack of detectable sterol-like compounds in their membranes may provide an opportunity to reconsider the physiological function of sterols and sterol-like lipids in eukaryotes., (© 2017 The Author(s) Journal of Eukaryotic Microbiology © 2017 International Society of Protistologists.)

Published

2017

20. Genome sequencing reveals metabolic and cellular interdependence in an amoeba-kinetoplastid symbiosis.

Author

Tanifuji G, Cenci U, Moog D, Dean S, Nakayama T, David V, Fiala I, Curtis BA, Sibbald SJ, Onodera NT, Colp M, Flegontov P, Johnson-MacKinnon J, McPhee M, Inagaki Y, Hashimoto T, Kelly S, Gull K, Lukeš J, and Archibald JM

Subjects

Amoebozoa genetics, Genome, Protozoan, Kinetoplastida genetics, Sequence Analysis, DNA, Amoebozoa growth & development, Amoebozoa metabolism, Kinetoplastida growth & development, Kinetoplastida metabolism, Symbiosis

Abstract

Endosymbiotic relationships between eukaryotic and prokaryotic cells are common in nature. Endosymbioses between two eukaryotes are also known; cyanobacterium-derived plastids have spread horizontally when one eukaryote assimilated another. A unique instance of a non-photosynthetic, eukaryotic endosymbiont involves members of the genus Paramoeba, amoebozoans that infect marine animals such as farmed fish and sea urchins. Paramoeba species harbor endosymbionts belonging to the Kinetoplastea, a diverse group of flagellate protists including some that cause devastating diseases. To elucidate the nature of this eukaryote-eukaryote association, we sequenced the genomes and transcriptomes of Paramoeba pemaquidensis and its endosymbiont Perkinsela sp. The endosymbiont nuclear genome is ~9.5 Mbp in size, the smallest of a kinetoplastid thus far discovered. Genomic analyses show that Perkinsela sp. has lost the ability to make a flagellum but retains hallmark features of kinetoplastid biology, including polycistronic transcription, trans-splicing, and a glycosome-like organelle. Mosaic biochemical pathways suggest extensive 'cross-talk' between the two organisms, and electron microscopy shows that the endosymbiont ingests amoeba cytoplasm, a novel form of endosymbiont-host communication. Our data reveal the cell biological and biochemical basis of the obligate relationship between Perkinsela sp. and its amoeba host, and provide a foundation for understanding pathogenicity determinants in economically important Paramoeba.

Published

2017

21. Global Kinetoplastea phylogeny inferred from a large-scale multigene alignment including parasitic species for better understanding transitions from a free-living to a parasitic lifestyle.

Author

Yazaki E, Ishikawa SA, Kume K, Kumagai A, Kamaishi T, Tanifuji G, Hashimoto T, and Inagaki Y

Subjects

DNA, Kinetoplast genetics, Sequence Alignment, Trypanosomatina genetics, Virulence genetics, Evolution, Molecular, Genes, Protozoan, Phylogeny, Trypanosomatina pathogenicity

Abstract

All members of the order Trypanosomatida known to date are parasites that are most likely descendants of a free-living ancestor. Trypanosomatids are an excellent model to assess the transition from a free-living to a parasitic lifestyle, because a large amount of experimental data has been accumulated for well-studied members that are harmful to humans and livestock (Trypanosoma spp. and Leishmania spp.). However, recent advances in our understanding of the diversity of trypanosomatids and their close relatives (i.e., members of the class Kinetoplastea) have suggested that the change in lifestyle took place multiple times independently from that which gave rise to the extant trypanosomatid parasites. In the current study, transcriptomic data of two parasitic kinetoplastids belonging to orders other than Trypanosomatida, namely Azumiobodo hoyamushi (Neobodonida) and Trypanoplasma borreli (Parabodonida), were generated. We re-examined the transition from a free-living to a parasitic lifestyle in the evolution of kinetoplastids by combining (i) the relationship among the five orders in Kinetoplastea and (ii) that among free-living and parasitic species within the individual orders. The former relationship was inferred from a large-scale multigene alignment including the newly generated data from Azumiobodo and Trypanoplasma, as well as the data from another parasitic kinetoplastid, Perkinsela sp., deposited in GenBank; and the latter was inferred from a taxon-rich small subunit ribosomal DNA alignment. Finally, we discuss the potential value of parasitic kinetoplastids identified in Parabodonida and Neobodonida for studying the evolutionary process that turned a free-living species into a parasite.

Published

2017

22. A Non-photosynthetic Diatom Reveals Early Steps of Reductive Evolution in Plastids.

Author

Kamikawa R, Moog D, Zauner S, Tanifuji G, Ishida KI, Miyashita H, Mayama S, Hashimoto T, Maier UG, Archibald JM, and Inagaki Y

Subjects

Amino Acids biosynthesis, Biological Evolution, Cytosol metabolism, Evolution, Molecular, Gene Expression Profiling methods, Photosynthesis genetics, Phylogeny, Plants genetics, Diatoms metabolism, Plastids genetics, Plastids metabolism

Abstract

Nonphotosynthetic plastids retain important biological functions and are indispensable for cell viability. However, the detailed processes underlying the loss of plastidal functions other than photosynthesis remain to be fully understood. In this study, we used transcriptomics, subcellular localization, and phylogenetic analyses to characterize the biochemical complexity of the nonphotosynthetic plastids of the apochlorotic diatom Nitzschia sp. NIES-3581. We found that these plastids have lost isopentenyl pyrophosphate biosynthesis and ribulose-1,5-bisphosphate carboxylase/oxygenase-based carbon fixation but have retained various proteins for other metabolic pathways, including amino acid biosynthesis, and a portion of the Calvin-Benson cycle comprised only of glycolysis/gluconeogenesis and the reductive pentose phosphate pathway (rPPP). While most genes for plastid proteins involved in these reactions appear to be phylogenetically related to plastid-targeted proteins found in photosynthetic relatives, we also identified a gene that most likely originated from a cytosolic protein gene. Based on organellar metabolic reconstructions of Nitzschia sp. NIES-3581 and the presence/absence of plastid sugar phosphate transporters, we propose that plastid proteins for glycolysis, gluconeogenesis, and rPPP are retained even after the loss of photosynthesis because they feed indispensable substrates to the amino acid biosynthesis pathways of the plastid. Given the correlated retention of the enzymes for plastid glycolysis, gluconeogenesis, and rPPP and those for plastid amino acid biosynthesis pathways in distantly related nonphotosynthetic plastids and cyanobacteria, we suggest that this substrate-level link with plastid amino acid biosynthesis is a key constraint against loss of the plastid glycolysis/gluconeogenesis and rPPP proteins in multiple independent lineages of nonphotosynthetic algae/plants., (© The Author 2017. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2017

23. Mitochondrial Genome of Palpitomonas bilix: Derived Genome Structure and Ancestral System for Cytochrome c Maturation.

Author

Nishimura Y, Tanifuji G, Kamikawa R, Yabuki A, Hashimoto T, and Inagaki Y

Subjects

Archaea classification, DNA Copy Number Variations, Phylogeny, Archaea genetics, Archaeal Proteins genetics, Cytochromes c genetics, Evolution, Molecular, Genome, Archaeal, Genome, Mitochondrial

Abstract

We here reported the mitochondrial (mt) genome of one of the heterotrophic microeukaryotes related to cryptophytes, Palpitomonas bilix The P. bilix mt genome was found to be a linear molecule composed of "single copy region" (∼16 kb) and repeat regions (∼30 kb) arranged in an inverse manner at both ends of the genome. Linear mt genomes with large inverted repeats are known for three distantly related eukaryotes (including P. bilix), suggesting that this particular mt genome structure has emerged at least three times in the eukaryotic tree of life. The P. bilix mt genome contains 47 protein-coding genes including ccmA, ccmB, ccmC, and ccmF, which encode protein subunits involved in the system for cytochrome c maturation inherited from a bacterium (System I). We present data indicating that the phylogenetic relatives of P. bilix, namely, cryptophytes, goniomonads, and kathablepharids, utilize an alternative system for cytochrome c maturation, which has most likely emerged during the evolution of eukaryotes (System III). To explain the distribution of Systems I and III in P. bilix and its phylogenetic relatives, two scenarios are possible: (i) System I was replaced by System III on the branch leading to the common ancestor of cryptophytes, goniomonads, and kathablepharids, and (ii) the two systems co-existed in their common ancestor, and lost differentially among the four descendants., (© The Author 2016. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2016

24. Hyper-eccentric structural genes in the mitochondrial genome of the algal parasite Hemistasia phaeocysticola.

Author

Yabuki A, Tanifuji G, Kusaka C, Takishita K, and Fujikura K

Abstract

Diplonemid mitochondria are considered to have very eccentric structural genes. Coding regions of individual diplonemid mitochondrial genes are fragmented into small pieces and found on different circular DNAs. Short RNAs transcribed from each DNA molecule mature through a unique RNA maturation process involving assembly and three types of RNA editing (i.e., U insertion and A-to-I & C-to-U substitutions), although the molecular mechanism(s) of RNA maturation and the evolutionary history of these eccentric structural genes still remain to be understood. Since the gene fragmentation pattern is generally conserved among the diplonemid species studied to date, it was considered that their structural complexity has plateaued and further gene fragmentation could not occur. Here, we show the mitochondrial gene structure of Hemistasia phaeocysticola, which was recently identified as a member of a novel lineage in diplonemids, by comparison of the mitochondrial DNA sequences with cDNA sequences synthesized from mature mRNA. The genes of H. phaeocysticola are fragmented much more finely than those of other diplonemids studied to date. Furthermore, in addition to all known types of RNA editing, it is suggested that a novel processing step (i.e., secondary RNA insertion) is involved in the RNA maturation in the mitochondria of H. phaeocysticola Our findings demonstrate the tremendous plasticity of mitochondrial gene structures., (© The Author(s) 2016. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2016

25. Complex evolution of two types of cardiolipin synthase in the eukaryotic lineage stramenopiles.

Author

Noguchi F, Tanifuji G, Brown MW, Fujikura K, and Takishita K

Subjects

DNA, Complementary chemistry, DNA, Complementary metabolism, Membrane Proteins classification, Membrane Proteins genetics, Membrane Proteins metabolism, Mitochondria, Phylogeny, RNA isolation & purification, RNA metabolism, Sequence Analysis, DNA, Transferases (Other Substituted Phosphate Groups) classification, Transferases (Other Substituted Phosphate Groups) genetics, Transferases (Other Substituted Phosphate Groups) metabolism, Evolution, Molecular, Stramenopiles enzymology

Abstract

The phospholipid cardiolipin is indispensable for eukaryotes to activate mitochondria, and it was previously reported that two phylogenetically distinct types of enzyme synthesizing cardiolipin, one with two phospholipase D domains (CLS&#95;pld) and the other with a CDP-alcohol phosphatidyltransferase domain (CLS&#95;cap), are patchily and complementarily distributed at higher taxonomic (e.g., supergroup) levels of eukaryotes. Stramenopiles, one of the major eukaryotic clades, were considered to exclusively possess CLS&#95;cap. However, through our present surveys with genome or transcriptome data from a broad range of stramenopile taxa, species with both CLS&#95;cap and CLS&#95;pld and species with only CLS&#95;pld or CLS&#95;cap were discovered among this group. Because these homologues of CLS&#95;cap and CLS&#95;pld retrieved from stramenopiles were likely inherited from the last eukaryotic common ancestor, it is reasonable to assume that a common ancestor of all stramenopiles harbored both CLS&#95;cap and CLS&#95;pld. Furthermore, based on the robust organismal phylogeny of stramenopiles unveiled with large-scale phylogenetic analyses, the earliest diverging lineage of stramenopiles (including bicosoecids, placidids, etc.) was found to comprise species with both CLS&#95;cap and CLS&#95;pld along with species with only either CLS&#95;cap or CLS&#95;pld. These findings suggest that a common ancestor of the most basal stramenopile lineage retained these two vertically inherited enzymes and that differential losses of either CLS&#95;cap or CLS&#95;pld occurred in this lineage. On the other hand, in the other stramenopile lineage composed of Ochrophyta, Pseudofungi, and Labyrinthulomycetes (to the exclusion of the most basal lineage), only CLS&#95;cap was found, and therefore a common ancestor of these three groups likely lost CLS&#95;pld. Based on our findings, the evolution of CLS&#95;cap/CLS&#95;pld in stramenopiles appears to be more complex than previously thought., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

26. Heme pathway evolution in kinetoplastid protists.

Author

Cenci U, Moog D, Curtis BA, Tanifuji G, Eme L, Lukeš J, and Archibald JM

Subjects

Animals, Biological Evolution, Eukaryota classification, Gene Transfer, Horizontal, Kinetoplastida classification, Phylogeny, Symbiosis, Eukaryota physiology, Heme metabolism, Kinetoplastida genetics, Kinetoplastida physiology

Abstract

Background: Kinetoplastea is a diverse protist lineage composed of several of the most successful parasites on Earth, organisms whose metabolisms have coevolved with those of the organisms they infect. Parasitic kinetoplastids have emerged from free-living, non-pathogenic ancestors on multiple occasions during the evolutionary history of the group. Interestingly, in both parasitic and free-living kinetoplastids, the heme pathway-a core metabolic pathway in a wide range of organisms-is incomplete or entirely absent. Indeed, Kinetoplastea investigated thus far seem to bypass the need for heme biosynthesis by acquiring heme or intermediate metabolites directly from their environment., Results: Here we report the existence of a near-complete heme biosynthetic pathway in Perkinsela spp., kinetoplastids that live as obligate endosymbionts inside amoebozoans belonging to the genus Paramoeba/Neoparamoeba. We also use phylogenetic analysis to infer the evolution of the heme pathway in Kinetoplastea., Conclusion: We show that Perkinsela spp. is a deep-branching kinetoplastid lineage, and that lateral gene transfer has played a role in the evolution of heme biosynthesis in Perkinsela spp. and other Kinetoplastea. We also discuss the significance of the presence of seven of eight heme pathway genes in the Perkinsela genome as it relates to its endosymbiotic relationship with Paramoeba.

Published

2016

27. Comparative genomics of mitochondria in chlorarachniophyte algae: endosymbiotic gene transfer and organellar genome dynamics.

Author

Tanifuji G, Archibald JM, and Hashimoto T

Subjects

Species Specificity, Cercozoa genetics, DNA, Mitochondrial genetics, DNA, Protozoan genetics, Gene Transfer, Horizontal, Genome, Mitochondrial, Genome, Protozoan, Symbiosis

Abstract

Chlorarachniophyte algae possess four DNA-containing compartments per cell, the nucleus, mitochondrion, plastid and nucleomorph, the latter being a relic nucleus derived from a secondary endosymbiont. While the evolutionary dynamics of plastid and nucleomorph genomes have been investigated, a comparative investigation of mitochondrial genomes (mtDNAs) has not been carried out. We have sequenced the complete mtDNA of Lotharella oceanica and compared it to that of another chlorarachniophyte, Bigelowiella natans. The linear mtDNA of L. oceanica is 36.7 kbp in size and contains 35 protein genes, three rRNAs and 24 tRNAs. The codons GUG and UUG appear to be capable of acting as initiation codons in the chlorarachniophyte mtDNAs, in addition to AUG. Rpl16, rps4 and atp8 genes are missing in L.oceanica mtDNA, despite being present in B. natans mtDNA. We searched for, and found, mitochondrial rpl16 and rps4 genes with spliceosomal introns in the L. oceanica nuclear genome, indicating that mitochondrion-to-host-nucleus gene transfer occurred after the divergence of these two genera. Despite being of similar size and coding capacity, the level of synteny between L. oceanica and B. natans mtDNA is low, suggesting frequent rearrangements. Overall, our results suggest that chlorarachniophyte mtDNAs are more evolutionarily dynamic than their plastid counterparts.

Published

2016

28. Proposal of a Twin Aarginine Translocator System-Mediated Constraint against Loss of ATP Synthase Genes from Nonphotosynthetic Plastid Genomes.

Author

Kamikawa R, Tanifuji G, Ishikawa SA, Ishii K, Matsuno Y, Onodera NT, Ishida K, Hashimoto T, Miyashita H, Mayama S, and Inagaki Y

Published

2016

29. Gene Loss and Error-Prone RNA Editing in the Mitochondrion of Perkinsela, an Endosymbiotic Kinetoplastid.

Author

David V, Flegontov P, Gerasimov E, Tanifuji G, Hashimi H, Logacheva MD, Maruyama S, Onodera NT, Gray MW, Archibald JM, and Lukeš J

Subjects

Amoebozoa parasitology, Computational Biology, DNA, Mitochondrial chemistry, DNA, Mitochondrial genetics, High-Throughput Nucleotide Sequencing, Kinetoplastida growth & development, Sequence Analysis, DNA, Gene Deletion, Kinetoplastida genetics, Mitochondria genetics, RNA Editing

Abstract

Unlabelled: Perkinsela is an enigmatic early-branching kinetoplastid protist that lives as an obligate endosymbiont inside Paramoeba (Amoebozoa). We have sequenced the highly reduced mitochondrial genome of Perkinsela, which possesses only six protein-coding genes (cox1, cox2, cox3, cob, atp6, and rps12), despite the fact that the organelle itself contains more DNA than is present in either the host or endosymbiont nuclear genomes. An in silico analysis of two Perkinsela strains showed that mitochondrial RNA editing and processing machineries typical of kinetoplastid flagellates are generally conserved, and all mitochondrial transcripts undergo U-insertion/deletion editing. Canonical kinetoplastid mitochondrial ribosomes are also present. We have developed software tools for accurate and exhaustive mapping of transcriptome sequencing (RNA-seq) reads with extensive U-insertions/deletions, which allows detailed investigation of RNA editing via deep sequencing. With these methods, we show that up to 50% of reads for a given edited region contain errors of the editing system or, less likely, correspond to alternatively edited transcripts., Importance: Uridine insertion/deletion-type RNA editing, which occurs in the mitochondrion of kinetoplastid protists, has been well-studied in the model parasite genera Trypanosoma, Leishmania, and Crithidia. Perkinsela provides a unique opportunity to broaden our knowledge of RNA editing machinery from an evolutionary perspective, as it represents the earliest kinetoplastid branch and is an obligatory endosymbiont with extensive reductive trends. Interestingly, up to 50% of mitochondrial transcripts in Perkinsela contain errors. Our study was complemented by use of newly developed software designed for accurate mapping of extensively edited RNA-seq reads obtained by deep sequencing., (Copyright © 2015 David et al.)

Published

2015

30. Proposal of a Twin Arginine Translocator System-Mediated Constraint against Loss of ATP Synthase Genes from Nonphotosynthetic Plastid Genomes. [Corrected].

Author

Kamikawa R, Tanifuji G, Ishikawa SA, Ishii K, Matsuno Y, Onodera NT, Ishida K, Hashimoto T, Miyashita H, Mayama S, and Inagaki Y

Subjects

Models, Biological, Phylogeny, Physical Chromosome Mapping, Chloroplast Proton-Translocating ATPases metabolism, Diatoms genetics, Genome, Plastid, Photosynthesis, Twin-Arginine-Translocation System metabolism

Abstract

Organisms with nonphotosynthetic plastids often retain genomes; their gene contents provide clues as to the functions of these organelles. Yet the functional roles of some retained genes-such as those coding for ATP synthase-remain mysterious. In this study, we report the complete plastid genome and transcriptome data of a nonphotosynthetic diatom and propose that its ATP synthase genes may function in ATP hydrolysis to maintain a proton gradient between thylakoids and stroma, required by the twin arginine translocator (Tat) system for translocation of particular proteins into thylakoids. Given the correlated retention of ATP synthase genes and genes for the Tat system in distantly related nonphotosynthetic plastids, we suggest that this Tat-related role for ATP synthase was a key constraint during parallel loss of photosynthesis in multiple independent lineages of algae/plants., (© The Author 2015. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2015

31. Plastid genome-based phylogeny pinpointed the origin of the green-colored plastid in the dinoflagellate Lepidodinium chlorophorum.

Author

Kamikawa R, Tanifuji G, Kawachi M, Miyashita H, Hashimoto T, and Inagaki Y

Subjects

Dinoflagellida classification, Molecular Sequence Data, Plastids genetics, Dinoflagellida genetics, Evolution, Molecular, Genome, Plastid, Phylogeny

Abstract

Unlike many other photosynthetic dinoflagellates, whose plastids contain a characteristic carotenoid peridinin, members of the genus Lepidodinium are the only known dinoflagellate species possessing green alga-derived plastids. However, the precise origin of Lepidodinium plastids has hitherto remained uncertain. In this study, we completely sequenced the plastid genome of Lepidodinium chlorophorum NIES-1868. Our phylogenetic analyses of 52 plastid-encoded proteins unite L. chlorophorum exclusively with a pedinophyte, Pedinomonas minor, indicating that the green-colored plastids in Lepidodinium spp. were derived from an endosymbiotic pedinophyte or a green alga closely related to pedinophytes. Our genome comparison incorporating the origin of the Lepidodinium plastids strongly suggests that the endosymbiont plastid genome acquired by the ancestral Lepidodinium species has lost genes encoding proteins involved in metabolism and biosynthesis, protein/metabolite transport, and plastid division during the endosymbiosis. We further discuss the commonalities and idiosyncrasies in genome evolution between the L. chlorophorum plastid and other plastids acquired through endosymbiosis of eukaryotic photoautotrophs., (© The Author(s) 2015. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2015

32. Complete genome of a nonphotosynthetic cyanobacterium in a diatom reveals recent adaptations to an intracellular lifestyle.

Author

Nakayama T, Kamikawa R, Tanifuji G, Kashiyama Y, Ohkouchi N, Archibald JM, and Inagaki Y

Subjects

Chromosomes, Bacterial genetics, Electron Transport, Genome Size, Molecular Sequence Data, Nitrogen Fixation genetics, Organelles metabolism, Symbiosis genetics, Thylakoids metabolism, Adaptation, Physiological, Cyanobacteria genetics, Diatoms microbiology, Genome, Bacterial genetics, Intracellular Space microbiology, Photosynthesis genetics

Abstract

The evolution of mitochondria and plastids from bacterial endosymbionts were key events in the origin and diversification of eukaryotic cells. Although the ancient nature of these organelles makes it difficult to understand the earliest events that led to their establishment, the study of eukaryotic cells with recently evolved obligate endosymbiotic bacteria has the potential to provide important insight into the transformation of endosymbionts into organelles. Diatoms belonging to the family Rhopalodiaceae and their endosymbionts of cyanobacterial origin (i.e., "spheroid bodies") are emerging as a useful model system in this regard. The spheroid bodies, which appear to enable rhopalodiacean diatoms to use gaseous nitrogen, became established after the divergence of extant diatom families. Here we report what is, to our knowledge, the first complete genome sequence of a spheroid body, that of the rhopalodiacean diatom Epithemia turgida. The E. turgida spheroid body (EtSB) genome was found to possess a gene set for nitrogen fixation, as anticipated, but is reduced in size and gene repertoire compared with the genomes of their closest known free-living relatives. The presence of numerous pseudogenes in the EtSB genome suggests that genome reduction is ongoing. Most strikingly, our genomic data convincingly show that the EtSB has lost photosynthetic ability and is metabolically dependent on its host cell, unprecedented characteristics among cyanobacteria, and cyanobacterial symbionts. The diatom-spheroid body endosymbiosis is thus a unique system for investigating the processes underlying the integration of a bacterial endosymbiont into eukaryotic cells.

Published

2014

33. Nucleomorph and plastid genome sequences of the chlorarachniophyte Lotharella oceanica: convergent reductive evolution and frequent recombination in nucleomorph-bearing algae.

Author

Tanifuji G, Onodera NT, Brown MW, Curtis BA, Roger AJ, Ka-Shu Wong G, Melkonian M, and Archibald JM

Subjects

Base Sequence, Biological Evolution, Cercozoa classification, Chromosome Mapping, Chromosomes genetics, Chromosomes metabolism, Cryptophyta genetics, Introns, Molecular Sequence Data, Phylogeny, Recombination, Genetic, Sequence Analysis, DNA, Cercozoa genetics, Genome, Plastid, Plastids genetics

Abstract

Background: Nucleomorphs are residual nuclei derived from eukaryotic endosymbionts in chlorarachniophyte and cryptophyte algae. The endosymbionts that gave rise to nucleomorphs and plastids in these two algal groups were green and red algae, respectively. Despite their independent origin, the chlorarachniophyte and cryptophyte nucleomorph genomes share similar genomic features such as extreme size reduction and a three-chromosome architecture. This suggests that similar reductive evolutionary forces have acted to shape the nucleomorph genomes in the two groups. Thus far, however, only a single chlorarachniophyte nucleomorph and plastid genome has been sequenced, making broad evolutionary inferences within the chlorarachniophytes and between chlorarachniophytes and cryptophytes difficult. We have sequenced the nucleomorph and plastid genomes of the chlorarachniophyte Lotharella oceanica in order to gain insight into nucleomorph and plastid genome diversity and evolution., Results: The L. oceanica nucleomorph genome was found to consist of three linear chromosomes totaling ~610 kilobase pairs (kbp), much larger than the 373 kbp nucleomorph genome of the model chlorarachniophyte Bigelowiella natans. The L. oceanica plastid genome is 71 kbp in size, similar to that of B. natans. Unexpectedly long (~35 kbp) sub-telomeric repeat regions were identified in the L. oceanica nucleomorph genome; internal multi-copy regions were also detected. Gene content analyses revealed that nucleomorph house-keeping genes and spliceosomal intron positions are well conserved between the L. oceanica and B. natans nucleomorph genomes. More broadly, gene retention patterns were found to be similar between nucleomorph genomes in chlorarachniophytes and cryptophytes. Chlorarachniophyte plastid genomes showed near identical protein coding gene complements as well as a high level of synteny., Conclusions: We have provided insight into the process of nucleomorph genome evolution by elucidating the fine-scale dynamics of sub-telomeric repeat regions. Homologous recombination at the chromosome ends appears to be frequent, serving to expand and contract nucleomorph genome size. The main factor influencing nucleomorph genome size variation between different chlorarachniophyte species appears to be expansion-contraction of these telomere-associated repeats rather than changes in the number of unique protein coding genes. The dynamic nature of chlorarachniophyte nucleomorph genomes lies in stark contrast to their plastid genomes, which appear to be highly stable in terms of gene content and synteny.

Published

2014

34. Reduced nuclear genomes maintain high gene transcription levels.

Author

Tanifuji G, Onodera NT, Moore CE, and Archibald JM

Subjects

Symbiosis genetics, Cell Nucleus genetics, Cryptophyta genetics, Eukaryota genetics, Gene Expression Regulation, Genome Size genetics, Transcription, Genetic

Abstract

Reductive genome evolution is seen in organisms living in close association with each other, such as in endosymbiosis, symbiosis, and parasitism. The reduced genomes of endosymbionts and parasites often exhibit similar features such as high gene densities and A+T compositional bias. Little is known about how the regulation of gene expression has been affected in organisms with highly compacted genomes. We studied gene transcription patterns in "nucleomorph" genomes, which are relic nuclear genomes of algal endosymbionts found in cryptophytes and chlorarachniophytes. We examined nuclear and nucleomorph gene transcription patterns using RNA-Seq transcriptome and genome mapping analyses in representatives of both lineages. In all four examined genomes, the most highly transcribed nucleomorph gene category was found to be plastid-associated genes. Remarkably, only 0.49-3.37% of the nucleomorph genomes of these organisms did not have any mRNA counterpart in our RNA-Seq data sets, and nucleomorph genes show equal or higher levels of transcription than their counterparts in the nuclear genomes. We hypothesize that elevated levels of nucleomorph gene transcription may serve to counteract the degradation or modification of protein function due to the loss of interacting proteins in the nucleomorph and nucleomorph-associated subcellular compartments.

Published

2014

35. Paratrypanosoma is a novel early-branching trypanosomatid.

Author

Flegontov P, Votýpka J, Skalický T, Logacheva MD, Penin AA, Tanifuji G, Onodera NT, Kondrashov AS, Volf P, Archibald JM, and Lukeš J

Subjects

Amino Acid Sequence, Animals, Culex parasitology, Female, Genome, Molecular Sequence Data, RNA, Ribosomal chemistry, Sequence Alignment, Sequence Analysis, Protein, Sequence Analysis, RNA, Trypanosomatina genetics, Trypanosomatina isolation & purification, Trypanosomatina ultrastructure, Phylogeny, Trypanosomatina classification

Abstract

The kinetoplastids are a widespread and important group of single-celled eukaryotes, many of which are devastating parasites of animals, including humans. We have discovered a new insect trypanosomatid in the gut of Culex pipiens mosquitoes. Glyceraldehyde-3-phosphate dehydrogenase- and SSU rRNA-based phylogenetic analyses show this parasite to constitute a distinct branch between the free-living Bodo saltans and the obligatory parasitic clades represented by the genus Trypanosoma and other trypanosomatids. From draft genome sequence data, we identified 114 protein genes shared among the new flagellate, 15 trypanosomatid species, B. saltans, and the heterolobosean Naegleria gruberi, as well as 129 protein genes shared with the basal kinetoplastid Perkinsela sp. Individual protein phylogenies together with analyses of concatenated alignments show that the new species, here named Paratrypanosoma confusum n. gen., n. sp., branches with very high support at the base of the family Trypanosomatidae. P. confusum thus represents a long-sought-after missing link between the ancestral free-living bodonids and the derived parasitic trypanosomatids. Further analysis of the P. confusum genome should provide insight into the emergence of parasitism in the medically important trypanosomatids., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published

2013

36. Algal genomes reveal evolutionary mosaicism and the fate of nucleomorphs.

Author

Curtis BA, Tanifuji G, Burki F, Gruber A, Irimia M, Maruyama S, Arias MC, Ball SG, Gile GH, Hirakawa Y, Hopkins JF, Kuo A, Rensing SA, Schmutz J, Symeonidi A, Elias M, Eveleigh RJ, Herman EK, Klute MJ, Nakayama T, Oborník M, Reyes-Prieto A, Armbrust EV, Aves SJ, Beiko RG, Coutinho P, Dacks JB, Durnford DG, Fast NM, Green BR, Grisdale CJ, Hempel F, Henrissat B, Höppner MP, Ishida K, Kim E, Kořený L, Kroth PG, Liu Y, Malik SB, Maier UG, McRose D, Mock T, Neilson JA, Onodera NT, Poole AM, Pritham EJ, Richards TA, Rocap G, Roy SW, Sarai C, Schaack S, Shirato S, Slamovits CH, Spencer DF, Suzuki S, Worden AZ, Zauner S, Barry K, Bell C, Bharti AK, Crow JA, Grimwood J, Kramer R, Lindquist E, Lucas S, Salamov A, McFadden GI, Lane CE, Keeling PJ, Gray MW, Grigoriev IV, and Archibald JM

Subjects

Algal Proteins genetics, Algal Proteins metabolism, Alternative Splicing genetics, Cercozoa cytology, Cercozoa metabolism, Cryptophyta cytology, Cryptophyta metabolism, Cytosol metabolism, Gene Duplication genetics, Gene Transfer, Horizontal genetics, Genes, Essential genetics, Genome, Mitochondrial genetics, Genome, Plant genetics, Genome, Plastid genetics, Molecular Sequence Data, Phylogeny, Protein Transport, Proteome genetics, Proteome metabolism, Transcriptome genetics, Cell Nucleus genetics, Cercozoa genetics, Cryptophyta genetics, Evolution, Molecular, Genome genetics, Mosaicism, Symbiosis genetics

Abstract

Cryptophyte and chlorarachniophyte algae are transitional forms in the widespread secondary endosymbiotic acquisition of photosynthesis by engulfment of eukaryotic algae. Unlike most secondary plastid-bearing algae, miniaturized versions of the endosymbiont nuclei (nucleomorphs) persist in cryptophytes and chlorarachniophytes. To determine why, and to address other fundamental questions about eukaryote-eukaryote endosymbiosis, we sequenced the nuclear genomes of the cryptophyte Guillardia theta and the chlorarachniophyte Bigelowiella natans. Both genomes have >21,000 protein genes and are intron rich, and B. natans exhibits unprecedented alternative splicing for a single-celled organism. Phylogenomic analyses and subcellular targeting predictions reveal extensive genetic and biochemical mosaicism, with both host- and endosymbiont-derived genes servicing the mitochondrion, the host cell cytosol, the plastid and the remnant endosymbiont cytosol of both algae. Mitochondrion-to-nucleus gene transfer still occurs in both organisms but plastid-to-nucleus and nucleomorph-to-nucleus transfers do not, which explains why a small residue of essential genes remains locked in each nucleomorph.

Published

2012

37. Nucleomorph genome sequence of the cryptophyte alga Chroomonas mesostigmatica CCMP1168 reveals lineage-specific gene loss and genome complexity.

Author

Moore CE, Curtis B, Mills T, Tanifuji G, and Archibald JM

Subjects

Cells, Cultured, Chromosome Mapping, Chromosomes, Evolution, Molecular, Genetic Variation genetics, Molecular Sequence Data, Sequence Analysis, DNA, Species Specificity, Symbiosis genetics, Cryptophyta genetics, Gene Deletion, Genetic Speciation, Genome genetics, Genome Size genetics

Abstract

Cryptophytes are a diverse lineage of marine and freshwater, photosynthetic and secondarily nonphotosynthetic algae that acquired their plastids (chloroplasts) by "secondary" (i.e., eukaryote-eukaryote) endosymbiosis. Consequently, they are among the most genetically complex cells known and have four genomes: a mitochondrial, plastid, "master" nuclear, and residual nuclear genome of secondary endosymbiotic origin, the so-called "nucleomorph" genome. Sequenced nucleomorph genomes are ∼1,000-kilobase pairs (Kbp) or less in size and are comprised of three linear, compositionally biased chromosomes. Although most functionally annotated nucleomorph genes encode proteins involved in core eukaryotic processes, up to 40% of the genes in these genomes remain unidentifiable. To gain insight into the function and evolutionary fate of nucleomorph genomes, we used 454 and Illumina technologies to completely sequence the nucleomorph genome of the cryptophyte Chroomonas mesostigmatica CCMP1168. At 702.9 Kbp in size, the C. mesostigmatica nucleomorph genome is the largest and the most complex nucleomorph genome sequenced to date. Our comparative analyses reveal the existence of a highly conserved core set of genes required for maintenance of the cryptophyte nucleomorph and plastid, as well as examples of lineage-specific gene loss resulting in differential loss of typical eukaryotic functions, e.g., proteasome-mediated protein degradation, in the four cryptophyte lineages examined.

Published

2012

38. Genomic characterization of Neoparamoeba pemaquidensis (Amoebozoa) and its kinetoplastid endosymbiont.

Author

Tanifuji G, Kim E, Onodera NT, Gibeault R, Dlutek M, Cawthorn RJ, Fiala I, Lukes J, Greenwood SJ, and Archibald JM

Subjects

Amoebozoa microbiology, DNA, Kinetoplast genetics, Genome, Karyotype, Kinetoplastida microbiology, Molecular Sequence Data, Phylogeny, Sequence Analysis, DNA, Symbiosis, Amoebozoa genetics, Kinetoplastida genetics

Abstract

We have performed a genomic characterization of a kinetoplastid protist living within the amoebozoan Neoparamoeba pemaquidensis. The genome of this "Ichthyobodo-related organism" was found to be unexpectedly large, with at least 11 chromosomes between 1.0 and 3.5 Mbp and a total genome size of at least 25 Mbp.

Published

2011

39. Complete nucleomorph genome sequence of the nonphotosynthetic alga Cryptomonas paramecium reveals a core nucleomorph gene set.

Author

Tanifuji G, Onodera NT, Wheeler TJ, Dlutek M, Donaher N, and Archibald JM

Subjects

Base Sequence, Chlorophyta genetics, Chromosome Structures, Conserved Sequence, Genes, Molecular Sequence Data, Open Reading Frames, Plastids genetics, Rhodophyta genetics, Symbiosis, Cell Nucleus genetics, Chromosome Mapping, Cryptophyta genetics, Genome, Sequence Analysis, DNA

Abstract

Nucleomorphs are the remnant nuclei of algal endosymbionts that were engulfed by nonphotosynthetic host eukaryotes. These peculiar organelles are found in cryptomonad and chlorarachniophyte algae, where they evolved from red and green algal endosymbionts, respectively. Despite their independent origins, cryptomonad and chlorarachniophyte nucleomorph genomes are similar in size and structure: they are both <1 million base pairs in size (the smallest nuclear genomes known), comprised three chromosomes, and possess subtelomeric ribosomal DNA operons. Here, we report the complete sequence of one of the smallest cryptomonad nucleomorph genomes known, that of the secondarily nonphotosynthetic cryptomonad Cryptomonas paramecium. The genome is 486 kbp in size and contains 518 predicted genes, 466 of which are protein coding. Although C. paramecium lacks photosynthetic ability, its nucleomorph genome still encodes 18 plastid-associated proteins. More than 90% of the "conserved" protein genes in C. paramecium (i.e., those with clear homologs in other eukaryotes) are also present in the nucleomorph genomes of the cryptomonads Guillardia theta and Hemiselmis andersenii. In contrast, 143 of 466 predicted C. paramecium proteins (30.7%) showed no obvious similarity to proteins encoded in any other genome, including G. theta and H. andersenii. Significantly, however, many of these "nucleomorph ORFans" are conserved in position and size between the three genomes, suggesting that they are in fact homologous to one another. Finally, our analyses reveal an unexpected degree of overlap in the genes present in the independently evolved chlorarachniophyte and cryptomonad nucleomorph genomes: ∼80% of a set of 120 conserved nucleomorph genes in the chlorarachniophyte Bigelowiella natans were also present in all three cryptomonad nucleomorph genomes. This result suggests that similar reductive processes have taken place in unrelated lineages of nucleomorph-containing algae.

Published

2011

40. Actin gene family dynamics in cryptomonads and red algae.

Author

Tanifuji G and Archibald JM

Subjects

Evolution, Molecular, Introns genetics, Phylogeny, Plant Proteins genetics, Sequence Alignment, Symbiosis, Actins genetics, Cryptophyta genetics, Rhodophyta genetics

Abstract

Here we present evidence for a complex evolutionary history of actin genes in red algae and cryptomonads, a group that acquired photosynthesis secondarily through the engulfment of a red algal endosymbiont. Four actin genes were found in the nuclear genome of the cryptomonad, Guillardia theta, and in the genome of the red alga, Galdieria sulphuraria, a member of the Cyanidiophytina. Phylogenetic analyses reveal that the both organisms possess two distinct sequence types, designated "type-1" and "type-2." A weak but consistent phylogenetic affinity between the cryptomonad type-2 sequences and the type-2 sequences of G. sulphuraria and red algae belonging to the Rhodophytina was observed. This is consistent with the possibility that the cryptomonad type-2 sequences are derived from the red algal endosymbiont that gave rise to the cryptomonad nucleomorph and plastid. Red algae as a whole possess two very different actin sequence types, with G. sulphuraria being the only organism thus far known to possess both. The common ancestor of Rhodophytina and Cyanidiophytina may have had two actin genes, with differential loss explaining the distribution of these genes in modern-day groups. Our study provides new insight into the evolution and divergence of actin genes in cryptomonads and red algae, and in doing so underscores the challenges associated with heterogeneity in actin sequence evolution and ortholog/paralog detection.

Published

2010

41. The complete plastid genome sequence of the secondarily nonphotosynthetic alga Cryptomonas paramecium: reduction, compaction, and accelerated evolutionary rate.

Author

Donaher N, Tanifuji G, Onodera NT, Malfatti SA, Chain PS, Hara Y, and Archibald JM

Abstract

The cryptomonads are a group of unicellular algae that acquired photosynthesis through the engulfment of a red algal cell, a process called secondary endosymbiosis. Here, we present the complete plastid genome sequence of the secondarily nonphotosynthetic species Cryptomonas paramecium CCAP977/2a. The approximately 78 kilobase pair (Kbp) C. paramecium genome contains 82 predicted protein genes, 29 transfer RNA genes, and a single pseudogene (atpF). The C. paramecium plastid genome is approximately 50 Kbp smaller than those of the photosynthetic cryptomonads Guillardia theta and Rhodomonas salina; 71 genes present in the G. theta and/or R. salina plastid genomes are missing in C. paramecium. The pet, psa, and psb photosynthetic gene families are almost entirely absent. Interestingly, the ribosomal RNA operon, present as inverted repeats in most plastid genomes (including G. theta and R. salina), exists as a single copy in C. paramecium. The G + C content (38%) is higher in C. paramecium than in other cryptomonad plastid genomes, and C. paramecium plastid genes are characterized by significantly different codon usage patterns and increased evolutionary rates. The content and structure of the C. paramecium plastid genome provides insight into the changes associated with recent loss of photosynthesis in a predominantly photosynthetic group of algae and reveals features shared with the plastid genomes of other secondarily nonphotosynthetic eukaryotes.

Published

2009

42. Diversity of secondary endosymbiont-derived actin-coding genes in cryptomonads and their evolutionary implications.

Author

Tanifuji G, Erata M, Ishida K, Onodera N, and Hara Y

Subjects

Base Sequence, Gene Expression Regulation, Plant, Phylogeny, Symbiosis genetics, Actins genetics, Cryptophyta genetics, Cryptophyta metabolism, Evolution, Molecular, Genetic Variation

Abstract

In the secondary endosymbiotic organisms of cryptomonads, the symbiont actin genes have been found together with the host one. To examine whether they are commonly conserved and where they are encoded, host and symbiont actin genes from Pyrenomonas helgolandii were isolated, and their specific and homologous regions were digoxigenin (DIG) labeled separately. Using these probes, Southern hybridization was performed on 13 species of cryptomonads. They were divided into three groups: (1) both host and symbiont actin gene signals were detected, (2) only the host actin gene signal was detected, and (3) host and unknown actin signals were detected. The phylogenetic analysis of these actin gene sequences indicated that the evolutionary rates of the symbiont actin genes were accelerated more than those of the hosts. The unknown actin signals were recognized as the highly diverged symbiont actin genes. One of the diverged symbiont actin sequences from Guillardia theta is presumed to be as a pseudogene or to its precursor. Southern hybridizations based on the samples divided by pulsed-field gel electrophoresis showed that all actin genes were encoded by the host nuclei. These results possibly represent the evolutionary fate of the symbiont actin gene in cryptomonads, which was firstly transferred from the symbiont nucleus or nucleomorph, to the host nucleus and became a pseudogene and then finally disappeared there.

Published

2006