A PHYSICAL MAP OF THE CHLAMYDOMONAS REINHARDTII NUCLEAR GENOME

Shin, W., Zimmermann, S. & Triemer, R. E. Department of Life Science, Rutgers University, Piscataway, NJ 08854, USA In 1985, Willey and Wibel described the existence of a cytoplasmic pocket formed from the reservoir membrane in Colacium. A band of microtubules derived from the ventral flagellar root (MTR) lined the pocket and a dense fibrillar mesh was associated with the membrane. A comparison of bodonid cytostomes, colorless euglenoid cytostomes, and the reservoir pocket found in Colacium suggested that the three structures were homologous and that photosynthetic euglenoids arose from phagotrophic ancestors. MTR/pockets have since been reported in other photosynthetic euglenoids including Euglena, Eutreptia, Eutreptiella, Cryptoglena, and Tetreutreptia. We now report on MTR/pockets in Lepocinclis, Trachelomonas, Strombomonas and Phacus thereby demonstrating the presence of this complex in representatives of all of the major photosynthetic genera. A comparison of the MTR/complex across genera indicates a reduction in structural complexity that is consistent with recent phylogenetic schemes based on molecular characters.     

PHYLOGENY OF THE EUGLENOPHYTES: ANALYSIS USING SSU RDNA AND ULTRASTRUCTURAL CHARACTERS

The use of both molecular and morphological data to determine relationships among the euglenoids is vital for a complete understanding of their phylogeny, and the development of an accurate taxonomy. Analyses of the SSU (18S) rDNA from 12 euglenoid genera have resulted in tree topologies that are in agreement with many defining morphological characters. The euglenoid lineage is formed by phagotrophic euglenoids at its base, followed by the divergence of phototrophs that in-turn gave rise to osmotrophs. The photosynthetic lineage is anchored by euglenoids with two emergent flagella, Eutreptia and Eutreptiella , while the remainder of the lineage is composed of euglenoids with a single emergent flagellum. Among the photosynthetic euglenoids with a single emergent flagellum those that secrete mucilaginous stalks, Colacium , or form a lorica, Trachelomonas and Strombomonas , are closely associated. The remaining photosynthetic genera Euglena , Phacus , and Lepocinclis are intermixed with each other and the osmotrophic genera Astasia , and Khawkinea. Hence, they are not monophyletic, sensu Hennig. To reinforce molecular phylogenies, a robust morphological character database is necessary. For taxa with complex internal structures complete serial reconstruction is required. Serial reconstruction of the flagellar and feeding apparatuses in Ploeotia costata illustrate this necessity. Originally described as having both an MTR (Type I) and a Type II feeding apparatus, reconstruction has shown P. costata to have a single, Type II, feeding apparatus. Moreover, the Type II now appears to be an autapomorphy for Ploeotia species, while euglenoid feeding apparatuses, in toto, appear to form a continuum of structural types.     

A MOLECULAR ANALYSIS OF THE EUGLENOPHYTES USING SSU RDNA

Almost since the creation of the genus Euglena (Ehrenberg), the taxa assigned to it have been separated, split apart, and reorganized into new genera based on morphological relationships, resulting in the creation of the genera Phacus (Dujardin) , Lepocinclis (Perty) , Astasia (Pringsheim), and Khawkinea ( Jahn and McKibben) based on intuitive methods. In an effort to assess the validity of these genera, we have used small subunit (SSU) rDNA data to generate a phylogenetic framework for these genera, with particular attention to the genus Euglena . Using the conserved sequence areas, we performed a phylogenetic analysis using parsimony, maximum likelihood, and distance methods. These different criteria have resulted in trees of the same topology. The euglenoid clade was composed of phagotrophic euglenoids at the base, which gave rise to phototrophs that in turn gave rise to osmotrophs. Among the photosynthetic taxa, the biflagellate form diverged prior to the uniflagellate form. Additionally, the need for a revision in the taxonomy of some of these genera was demonstrated. Currently, taxa from the photosynthetic genera Euglena, Phacus, and Lepocinclis do not form monophyletic clades, but are intermixed with each other as well as with the osmotrophic taxa, Astasia and Khawkinea.     

Phylogenetic analyses of various euglenoid taxa (euglenozoa) based on 18s rdna sequence data

18S rRNA genes (SSU rDNA) of five newly sequenced species were used as molecular markers to infer phylogenetic relationships within the euglenoids. Two members of the order Euglenales ( Lepocinclis ovata Playfair , Phacus similis Christen), two of the order Eutreptiales ( Distigma proteus Ehrenberg, , D. curvata Pringsheim) and Gyropaigne lefévrei Bourelly et Georges of the order Rhabdomonadales were used in parsimony, maximum likelihood, and distance analyses. All trees derived from SSU rRNA data strongly supported the monophyletic origin of the Euglenozoa, with kinetoplastids as sister clade to the euglenoids and Petalomonas cantuscygni Cann et Pennick diverging at the base of the monophyletic euglenoid lineage. The data also supported the theory that phagotrophic euglenoids arose prior to osmotrophs and phototrophs. A lineage of Peranema trichophorum Ehrenberg and all sequenced Euglenales formed a sister clade to the osmotrophs. This suggests that the evolution of phototrophy within the euglenoids radiated from a single event.     

EVOLUTION OF PHACUS (EUGLENOPHYCEAE) AS INFERRED FROM PELLICLE MORPHOLOGY AND SSU rDNA

This research integrates a large morphological data set into a molecular context. Nineteen pellicle characters and 62 states from 13 euglenid taxa were analyzed cladistically. The pellicle morphology of Euglena tripteris (Klebs), Lepocinclis ovata (Conrad), Phacus brachykentron (Pochmann), P. oscillans (Klebs), P. pyrum (Stein), and P. triqueter (Dujardin) is described comprehensively. These data are compared with new information on the pellicle morphology of Euglena acus (Ehrenberg), E. stellata (Mainx), and Peranema trichophorum (Stein) in addition to published data on Entosiphon sulcatum (Dujardin), Euglena gracilis (Klebs), Distigma proteus (Pringsheim), and Petalomonas cantuscygni (Cann and Pennick). Nuclear small subunit (SSU) rDNA sequences provided an independent test for establishing a robust organismal pedigree of the same taxa. A synthetic tree derived from the combined phylogenetic analyses of pellicle morphology and SSU rDNA enabled us to parsimoniously map morphological character states. This approach demonstrated the utility of pellicle morphology for inferring phylogenetic relationships of euglenids and establishing apomorphy-based clade definitions. Three robust clades with unambiguous pellicle-based apomorphies can be recognized within taxa traditionally classified as Phacus : (1) L. ovata and P. pyrum , (2) E. tripteris and P. triqueter , and (3) P. brachykentron and P. oscillans. Taxonomic concerns that emerged from these results are discussed.     

The chloroplast genome of Phacus orbicularis (Euglenophyceae): an initial datum point for the phacaceae

The Euglenophyceae chloroplast was acquired when a heterotrophic euglenoid engulfed a green alga and subsequently retained the algal chloroplast, in a process known as secondary endosymbiosis. Since this event, Euglenophyceae have diverged widely and their chloroplast genomes (cpGenomes) have as well. Changes to the cpGenome include extensive gene rearrangement and the proliferation of introns, the analyses of which have proven to be useful in examining cpGenome changes throughout the Euglenophyceae. The Euglenales fall into two families, Euglenaceae and Phacaceae. Euglenaceae contains eight genera and at least one cpGenome has been published for each genus. Phacaceae, on the other hand, contains three genera, none of which have had a representative chloroplast genome sequenced. Members of this family have many small disk‐shaped chloroplasts that lack pyrenoids. We sequenced and annotated the cpGenome of Phacus orbicularis in order to fill in the large gap in our understanding of Euglenophyceae cpGenome evolution, especially in regard to intron number and gene order. We compared this cpGenome to those of species from both the Euglenaceae and Eutreptiales of the Euglenophyceae phylogenetic tree. The cpGenome showed characteristics that were more derived than that of the basal species Eutreptia viridis, with extensive gene rearrangements and nearly three times as many introns. In contrast, it contained fewer introns than all but one of the previously reported Euglenaceae cpGenomes, had a smaller estimated genome size, and shared greater synteny with two main branches of that family.     

鄂西地区发现的我国裸藻门新记录

1981年5—6月,作者在鄂西一带,对各种生态环境中的藻类进行了一次采集。随后,又对采得的浮游藻类中的裸藻门植物进行鉴定和研究,发现了不少在我国尚未报道过的种类。有些还是较为罕见的种类。它们分别隶属于裸藻属(Euglena)的有8种(包括变种,下同),扁裸藻属(Phacus)的有5种,囊裸藻属(Trachelomonas)的有1种,陀螺藻属(Strombomonas)的有2种,柄裸藻属(Colacium)的有1种,变     

TAXONOMY OF THE PHACUS OSCILLANS (EUGLENACEAE) AND ITS CLOSE RELATIVES—BALANCING MORPHOLOGICAL AND MOLECULAR FEATURES1

The establishment of epitypes (together with emended diagnoses) for seven species of Phacus Dujard. [Phacus oscillans G. A. Klebs, Phacus parvulus G. A. Klebs, Phacus pusillus Lemmerm., Phacus skujae Skvortzov, Phacus inflexus (Kisselew) Pochm., Phacus polytrophos Pochm., and Phacus smulkowskianus (Zakry?) Kusber] was achieved by literature studies, verification of morphological diagnostic features (cell size, cell shape), as well as molecular characters (SSU rDNA). The investigated Phacus species are mostly well distinguished morphologically, with an SSU rDNA interspecific sequence similarity of 95.1%–99.0% and an intraspecific sequence similarity of 99.0%–99.9%. Some of the phylogenetic relationships among the seven species have not been resolved, but the topology obtained indicates their assignment into two sister clades. The first clade is composed of two sister groups (P. parvulus and P. pusillus), while the second constitutes an assemblage of the remaining five species. The relationships between the clades remain unresolved.     

Diversity of picoplanktonic prasinophytes assessed by direct nuclear SSU rDNA sequencing of environmental samples and novel isolates retrieved from oceanic and coastal marine ecosystems

Picoplanktonic prasinophytes are well represented in culture collections and marine samples. In order to better characterize this ecologically important group, we compared the phylogenetic diversity of picoplanktonic prasinophyte strains available at the Roscoff Culture Collection (RCC) and that of nuclear SSU rDNA sequences from environmental clone libraries obtained from oceanic and coastal ecosystems. Among the 570 strains avalaible, 91 belonged to prasinophytes, 65 were partially sequenced, and we obtained the entire SSU rDNA sequence for a selection of 14 strains. Within the 18 available environmental clone libraries, the prasinophytes accounted for 12% of the total number of clones retrieved (142 partial sequences in total), and we selected 9 clones to obtain entire SSU rDNA sequence. Using this approach, we obtained a subsequent genetic database that revealed the presence of seven independent lineages among prasinophytes, including a novel clade (clade VII). This new clade groups the genus Picocystis, two unidentified coccoid strains, and 4 environmental sequences. For each of these seven lineages, at least one representative is available in culture. The three picoplanktonic genera Ostreococcus, Micromonas, and Bathycoccus (order Mamiellales), were the best represented prasinophytes both in cultures and genetic libraries. SSU rDNA phylogenetic analyses suggest that the genus Bathycoccus forms a very homogeneous group. In contrast, the genera Micromonas and Ostreococcus turned out to be quite complex, consisting of three and four independent lineages, respectively. This report of the overall diversity of picoeukaryotic prasinophytes reveals a group of ecologically important and diverse marine microorganims that are well represented by isolated cultures.     

Genetic diversity and phylogenetic position of the subclass Astomatia (Ciliophora) based on a sampling of six genera from West African oligochaetes (Glossoscolecidae, Megascolecidae), including description of the new genus Paraclausilocola n. gen

To more confidently assess phylogenetic relationships among astome ciliates, we obtained small subunit (SSU) rRNA sequences from nine species distributed in six genera and three families: Almophrya bivacuolata, Eudrilophrya complanata, Metaracoelophrya sp. 1, Metaracoelophrya sp. 2, Metaracoelophrya intermedia, Metaradiophrya sp., Njinella prolifera, Paraclausilocola constricta n. gen., n. sp., and Paraclausilocola elongata n. sp. The two new species in the proposed new clausilocolid genus Paraclausilocola n. gen. are astomes with no attachment apparatus, two files of contractile vacuoles, and an arc-like anterior suture that has differentiations of thigmotactic ciliature on the anterior ends of the left kineties of the upper surface. Phylogenetic analyses were undertaken using neighbor-joining, Bayesian inference, maximum likelihood, and maximum parsimony. The nine species of astomes formed a strongly supported clade, showing the subclass Astomatia to be monophyletic and a weakly supported sister clade to the scuticociliates. There were two strongly supported clades within the astomes. However, genera assigned to the same family were found in different clades, and genera assigned to the same order were found in both clades. Thus, astome taxa appear to be paraphyletic when morphology is used to assign species to genera.