Phylogeny of the Centrohelida inferred from SSU rRNA, tubulins, and actin genes

Horizontally-acquired genetic elements in the mitochondrial genome of a centrohelid Marophrys sp. SRT127

Mitochondrial genomes exhibit diverse features among eukaryotes in the aspect of gene content, genome structure, and the mobile genetic elements such as introns and plasmids. Although the number of published mitochondrial genomes is increasing at tremendous speed, those of several lineages remain unexplored. Here, we sequenced the complete mitochondrial genome of a unicellular heterotrophic eukaryote, Marophrys sp. SRT127 belonging to the Centroheliozoa, as the first report on this lineage. The circular-mapped mitochondrial genome, which is 113,062 bp in length, encodes 69 genes typically found in mitochondrial genomes. In addition, the Marophrys mitochondrial genome contains 19 group I introns. Of these, 11 introns have genes for homing endonuclease (HE) and phylogenetic analyses of HEs have shown that at least five Marophrys HEs are related to those in green algal plastid genomes, suggesting intron transfer between the Marophrys mitochondrion and green algal plastids. We also discovered a putative mitochondrial plasmid in linear form. Two genes encoded in the circular-mapped mitochondrial genome were found to share significant similarities to those in the linear plasmid, suggesting that the plasmid was integrated into the mitochondrial genome. These findings expand our knowledge on the diversity and evolution of the mobile genetic elements in mitochondrial genomes.

Untangling the early diversification of eukaryotes: a phylogenomic study of the evolutionary origins of Centrohelida, Haptophyta and Cryptista

Assembling the global eukaryotic tree of life has long been a major effort of Biology. In recent years, pushed by the new availability of genome-scale data for microbial eukaryotes, it has become possible to revisit many evolutionary enigmas. However, some of the most ancient nodes, which are essential for inferring a stable tree, have remained highly controversial. Among other reasons, the lack of adequate genomic datasets for key taxa has prevented the robust reconstruction of early diversification events. In this context, the centrohelid heliozoans are particularly relevant for reconstructing the tree of eukaryotes because they represent one of the last substantial groups that was missing large and diverse genomic data. Here, we filled this gap by sequencing high-quality transcriptomes for four centrohelid lineages, each corresponding to a different family. Combining these new data with a broad eukaryotic sampling, we produced a gene-rich taxon-rich phylogenomic dataset that enabled us to refine the structure of the tree. Specifically, we show that (i) centrohelids relate to haptophytes, confirming Haptista; (ii) Haptista relates to SAR; (iii) Cryptista share strong affinity with Archaeplastida; and (iv) Haptista + SAR is sister to Cryptista + Archaeplastida. The implications of this topology are discussed in the broader context of plastid evolution.

A wide diversity of previously undetected free-living relatives of diplomonads isolated from marine/saline habitats

Over the last 15 years classical culturing and environmental PCR techniques have revealed a modest number of genuinely new major lineages of protists; however, some new groups have greatly influenced our understanding of eukaryote evolution. We used culturing techniques to examine the diversity of free-living protists that are relatives of diplomonads and retortamonads, a group of evolutionary and parasitological importance. Until recently, a single organism, Carpediemonas membranifera, was the only representative of this region of the tree. We report 18 new isolates of Carpediemonas-like organisms (CLOs) from anoxic marine sediments. Only one is a previously cultured species. Eleven isolates are conspecific and were classified within a new genus, Kipferlia n. gen. The remaining isolates include representatives of three other lineages that likely represent additional undescribed genera (at least). Small-subunit ribosomal RNA gene phylogenies show that CLOs form a cloud of six major clades basal to the diplomonad-retortamonad grouping (i.e. each of the six CLO clades is potentially as phylogenetically distinct as diplomonads and retortamonads). CLOs will be valuable for tracing the evolution of diplomonad cellular features, for example, their extremely reduced mitochondrial organelles. It is striking that the majority of CLO diversity was undetected by previous light microscopy surveys and environmental PCR studies, even though they inhabit a commonly sampled environment. There is no reason to assume this is a unique situation - it is likely that undersampling at the level of major lineages is still widespread for protists.

Large-scale phylogenomic analyses reveal that two enigmatic protist lineages, telonemia and centroheliozoa, are related to photosynthetic chromalveolates

Understanding the early evolution and diversification of eukaryotes relies on a fully resolved phylogenetic tree. In recent years, most eukaryotic diversity has been assigned to six putative supergroups, but the evolutionary origin of a few major “orphan” lineages remains elusive. Two ecologically important orphan groups are the heterotrophic Telonemia and Centroheliozoa. Telonemids have been proposed to be related to the photosynthetic cryptomonads or stramenopiles and centrohelids to haptophytes, but molecular phylogenies have failed to provide strong support for any phylogenetic hypothesis. Here, we investigate the origins of Telonema subtilis (a telonemid) and Raphidiophrys contractilis (a centrohelid) by large-scale 454 pyrosequencing of cDNA libraries and including new genomic data from two cryptomonads (Guillardia theta and Plagioselmis nannoplanctica) and a haptophyte (Imantonia rotunda). We demonstrate that 454 sequencing of cDNA libraries is a powerful and fast method of sampling a high proportion of protist genes, which can yield ample information for phylogenomic studies. Our phylogenetic analyses of 127 genes from 72 species indicate that telonemids and centrohelids are members of an emerging major group of eukaryotes also comprising cryptomonads and haptophytes. Furthermore, this group is possibly closely related to the SAR clade comprising stramenopiles (heterokonts), alveolates, and Rhizaria. Our results link two additional heterotrophic lineages to the predominantly photosynthetic chromalveolate supergroup, providing a new framework for interpreting the evolution of eukaryotic cell structures and the diversification of plastids.

Tracing back EFL gene evolution in the cryptomonads-haptophytes assemblage: separate origins of EFL genes in haptophytes, photosynthetic cryptomonads, and goniomonads

A recently identified GTPase, elongation factor-like (EFL) protein is proposed to bear the principal functions of translation elongation factor 1alpha (EF-1alpha). Pioneering studies of EF-1alpha/EFL evolution have revealed the phylogenetically scattered distribution of EFL amongst eukaryotes, suggesting frequent eukaryote-to-eukaryote EFL gene transfer events and subsequent replacements of EF-1alpha functions by EFL. We here determined/identified seven new EFL sequences of the photosynthetic cryptomonad Cryptomonas ovata, the non-photosynthetic cryptomonad (goniomonad) Goniomonas amphinema, the foraminifer Planoglabratella opecularis, the haptophyte Chrysochromulina sp., the centroheliozoan Raphidiophrys contractilis, and two red algae Chondrus crispus and Gracilaria changii. The analyses of these EFL sequences successfully brought new insights into lateral EFL gene transfer amongst eukaryotes. Of most interest is a complex EFL evolution in a monophyletic assemblage comprised of cryptomonads and haptophytes. Since our analyses rejected any phylogenetic affinity amongst the EFL sequences from Goniomonas, photosynthetic cryptomonads, and haptophytes, the EFL genes of the three lineages most likely originated from different phylogenetic sources.

Molecular characterization of ciliate diversity in stream biofilms

Free-living protozoa are thought to be of fundamental importance in aquatic ecosystems, but there is limited understanding of their diversity and ecological role, particularly in surface-associated communities such as biofilms. Existing eukaryote-specific PCR primers were used to survey 18S rRNA gene sequence diversity in stream biofilms but poorly revealed protozoan diversity, demonstrating a need for protozoan-targeted primers. Group-specific PCR primers targeting 18S rRNA genes of the protozoan phylum Ciliophora were therefore designed and tested using DNA extracted from cultured protozoan isolates. The two most reliable primer combinations were applied to stream biofilm DNA, followed by cloning and sequencing analysis. Of 44 clones derived from primer set 384F/1147R, 86% were of probable ciliate origin, as were 25% of 44 clones detected by primer set 121F/1147R. A further 29% of 121F/1147R-detected clones matched sequences from the closely related phylum Apicomplexa. The highly ciliate-specific primer set 384F/1147R was subsequently used in PCRs on biofilm DNA from four streams exhibiting different levels of human impact, revealing differences in ciliate sequence diversity in samples from each site. Of a total of 240 clones, 73% were of probable ciliate origin; 54 different putative ciliate sequences were detected from throughout seven taxonomic ciliate classes. Sequences from Oligohymenophorea were most commonly detected in all samples, followed by either Spirotrichea or Phyllopharyngea. Restriction fragment length polymorphism profile-based analysis of clones suggested a potentially higher level of diversity than did sequencing. Nevertheless, newly designed PCR primers 384F/1147R were considered to provide an effective molecular basis for characterization of ciliate diversity in stream biofilms.

Centrohelida is still searching for a phylogenetic home: analyses of seven Raphidiophrys contractilis genes

By recent advance in evolutionary biology, the majority of eukaryotes are classified into six eukaryotic assemblages called as "supergroups". However, several eukaryotic groups show no clear evolutionary affinity to any of the six supergroups. Centrohelida, one of major heliozoan groups, are such an unresolved lineage. In this study, we newly determined the genes encoding translation elongation factor 2 (EF2), cytosolic heat shock protein 70 (HSP70), and cytosolic heat shock protein 90 (HSP90) from the centroheliozoan Raphidiophrys contractilis. The three Raphidiophrys genes were then combined with previously determined actin, alpha-tubulin, beta-tubulin, and SSU rRNA sequences to phylogenetically analyze the position of Centrohelida in global eukaryotic phylogeny. Although the multi-gene data sets examined in this study are the largest ones including the centroheliozoan sequences, the relationships between Centrohelida and the eukaryotic groups considered were unresolved. Our careful investigation revealed that the phylogenetic estimates were highly sensitive to genes included in the multi-gene alignment. The signal of SSU rRNA and that of alpha-tubulin appeared to conflict with one another: the former strongly prefers a monophyly of Diplomonadida (e.g., Giardia), Parabasalia (e.g., Trichomonas), Heterolobosea (e.g., Naegleria), and Euglenozoa (e.g., Trypanosoma), while the latter unites Diplomonadida, Parabasalia, Metazoa, and Fungi. In addition, EF2 robustly unites Rhodophyta and Viridiplantae, while the remaining genes considered in this study do not positively support the particular relationship. Thus, it is difficult to identify the phylogenetic relatives of Centrohelida in the present study, since strong (and some are conflicting) gene-specific "signals" are predominant in the current multi-gene data. We concluded that larger scale multi-gene phylogenies are necessary to elucidate the origin and evolution of Centrohelida.

A close relationship between Cercozoa and Foraminifera supported by phylogenetic analyses based on combined amino acid sequences of three cytoskeletal proteins (actin, α-tubulin, and β-tubulin)

Recently, there has been increasing molecular evidence of phylogenetic affinity between Cercozoa and Foraminifera in the eukaryotic lineage. We performed phylogenetic analyses based on the combined (concatenated) amino acid sequence data of actin, alpha-tubulin, and beta-tubulin from a wide variety of eukaryotes, including the foraminifers Planoglabratella opercularis and Reticulomyxa filosa, as well as cercomonad and chlorarachniophyte members of Cercozoa. A monophyletic lineage composed of two foraminiferan species branched with the centroheliozoan species Raphidiophrys contractilis was reconstructed in both Bayesian and maximum-likelihood (ML) analyses under 'linked' models, enforcing a single set of the parameters (the parameter for among-site rate variation and branch lengths) on the entire combined alignment. Considering the extremely divergent nature of Foraminifera and Raphidiophyrs tubulins, the union of these lineages recovered is most probably a long-branch attraction artifact due to ignoring gene-specific evolutionary processes. On the other hand, the foraminiferan lineage was within the radiation of Cercozoa in Bayesian analyses under 'unlinked' model conditions, accommodating differences in evolutionary processes across the three genes in the combined alignment. The Foraminifera+Cercozoa affinity recovered in the latter multi-gene analyses is most likely genuine, and thus our data presented here provide further support for the close relationship between these two protist lineages.