球状绿藻的隐性生物多样性及其分类学进展

球状绿藻主要指绿藻门中多为单细胞, 形状为球形、近球形, 或由球形衍生出来的其他形状的藻类。球状绿藻分布广泛, 遍布全球, 生活于淡水、海水和亚气生等生境中, 其相似的简单形态下隐藏着复杂的物种多样性。球状绿藻分类学上主要位于绿藻门的两纲四目及其一些独立支系的类群。球状绿藻分类学正由传统的基于形态特征向基于分子信息的复合分类方法转变。球状绿藻隐性的物种多样性涉及约40属, 其中15属是依据新标本材料而建立的新属, 12个属是依据新证据建立的新组合。本文重点介绍了1998年以后在共球藻纲和绿藻纲中新发现和命名的单细胞球状绿藻, 介绍了它们的形态特征、分类学迁移及理由, 特别对常见的小球藻属和栅藻属的分类学概念变迁作了详细介绍, 对一些尚没有中文名的拉丁学名给出了中文命名。另外, 本文讨论了基于DNA的分类学方法在球状绿藻分类学中的应用, 目前系统发育位置的不同已经成为球状绿藻分类的主要依据。目前球状绿藻分类面临的问题是大多分类位置未用分子系统发育方法的验证。 未来, 球状绿藻分类学家应用系统发育研究结合形态学研究探索单细胞球状绿藻的生物多样性。     

Molecular phylogeny and evolution of the order Tribonematales (Heterokonta, Xanthophyceae) based on analysis of plastidial genes rbcL and psaA

Tribonematales is an order of filamentous algae in the class Xanthophyceae (Heterokonta). Few molecular studies, all with a limited taxon sampling, have previously investigated its evolutionary history and phylogenetic relationships. We sequenced the chloroplast-encoded rbcL and psaA genes of several tribonematalean species and of several coccoid and siphonous forms that previous studies revealed to be strictly related to Tribonematales. Multiple alignments included mostly new sequences obtained from 42 taxa. Phylogenetic reconstructions were performed using the maximum likelihood method. The rbcL and psaA data sets were analyzed independently and combined in a single multiple alignment. Neither rbcL nor psaA genes showed intraspecific sequence variation. The former proved to be a better diagnostic marker than the latter for characterization of species. We explored effects produced on phylogenetic outcomes by selected genes. Congruent results were obtained from analyses performed on single gene multiple alignments as well as on the combined data set. There is strong statistical support for trees that show several currently recognized taxonomic groups to be polyphyletic. The siphonous orders Botrydiales and Vaucheriales do not form a clade. Botrydiales and Tribonematales are polyphyletic as are the families Botrydiaceae, Centritractaceae and Tribonemataceae and the genera Xanthonema and Bumilleriopsis. We tentatively define new boundaries of the Tribonematales to include both coccoid and filamentous species having a bipartite cell wall and also the siphonous members of the genus Botrydium. Also, our results support morphological convergence at all taxonomic ranks in the evolution of the Xanthophyceae.     

Molecular diversity of green corticolous microalgae from two sub-Mediterranean European localities

Green algae in corticolous biofilms are simple coccoid cells or filamentous thalli with strikingly low morphological diversity. Consequently, microscopic identification of these organisms is difficult, and often possible only to higher taxonomic units. We investigated the taxonomic and phylogenetic composition of green microalgae isolated from biofilms growing on the bark of Quercus pubescens and Pinus nigra. The study was based on 122 partial sequences of the plastid-encoded rbcL gene. In total, 29 operational taxonomic units (OTUs), differing in their rbcL sequences, were encountered. Members of the Trebouxiophyceae formed 97.5% of the isolates; Streptophyta made up 2.5%. The most frequently occurring OTUs were in the genera Coccomyxa, Parachloroidium and Stichococcus. Within the Watanabea clade, we have probably discovered an as-yet undescribed generic lineage with chlorelloid morphology. OTUs belonging to the recently described trebouxiophycean genera Kalinella, Leptochlorella and Xylochloris were also encountered, which indicates that these genera are probably widely distributed in subaerial microhabitats, such as tree bark. The samples taken from oak trees were more diverse in their OTU composition than those taken from pine trees, but the average phylogenetic distances of OTUs in samples did not differ between the host tree taxa. Host tree species had a stronger effect on the community structure of algae than the sampling locality. This indicates that habitat filtering is important for the distribution of individual microalgal phylogenetic taxa.     

Phylogenetic position of the Oedogoniales within the green algae (Chlorophyta) and the evolution of the absolute orientation of the flagellar apparatus

The order Oedogoniales is made up of green algae with an unusual form of cytokinesis, a ring of flagella on the zoids, and a complex sexual reproduction. The genera included in this order, Oedogonium, Oedocladium and Bulbochaete, differ in their type of habit. In this contribution we report a phylogenetic analysis using 18S ribosomal DNA sequences from 66 species of green algae, including ten species of Oedogonium isolated from fresh water bodies in Argentina. The phylogenetic study demonstrates the monophyly of the Oedogoniales within the green algae, and suggests that in this group the flagellar apparatus of the stephanokont zoid could have derived from a DO configuration. It is also found that the genus Oedogonium does not appear to be monophyletic and that the morphological characters traditionally used for the taxonomic classification of Oedogonium species do not define natural groups.     

Brandtia ciliaticola gen. et sp. nov. (Chlorellaceae,Trebouxiophyceae) a common symbiotic green coccoid of various ciliate species

Many freshwater protists harbor unicellular green algae within their cells and these host‐symbiont relationships slowly are becoming better understood. Recently, we reported that several ciliate species shared a single species of symbiotic algae. Nonetheless, the algae from different host ciliates were each distinguishable by their different genotypes, and these host‐algal genotype combinations remained unchanged throughout a 15‐month period of sampling from natural populations. The same algal species had been reported as the shared symbiont of several ciliates from a remote lake. Consequently, this alga appears to play a key role in ciliate‐algae symbioses. In the present study, we successfully isolated the algae from ciliate cells and established unialgal cultures. This species is herein named Brandtia ciliaticola gen. et sp. nov. and has typical ‘Chlorella‐like’ morphology, being a spherical autosporic coccoid with a single chloroplast containing a pyrenoid. The alga belongs to the Chlorella‐clade in Chlorellaceae (Trebouxiophyceae), but it is not strongly connected to any of the other genera in this group. In addition to this phylogenetic distinctiveness, a unique compensatory base change in the SSU rRNA gene is decisive in distinguishing this genus. Sequences of SSU‐ITS (internal transcribed spacer) rDNA for each isolate were compared to those obtained previously from the same host ciliate. Consistent algal genotypes were recovered from each host, which strongly suggests that B. ciliaticola has established a persistent symbiosis in each ciliate species.     

Morphological convergence characterizes the evolution of Xanthophyceae (Heterokontophyta): evidence from nuclear SSU rDNA and plastidial rbcL genes

Xanthophyceae are a group of heterokontophyte algae. Few molecular studies have investigated the evolutionary history and phylogenetic relationships of this class. We sequenced the nuclear-encoded SSU rDNA and chloroplast-encoded rbcL genes of several xanthophycean species from different orders, families, and genera. Neither SSU rDNA nor rbcL genes show intraspecific sequence variation and are good diagnostic markers for characterization of problematic species. New sequences, combined with those previously available, were used to create different multiple alignments. Analyses included sequences from 26 species of Xanthophyceae plus three Phaeothamniophyceae and two Phaeophyceae taxa used as outgroups. Phylogenetic analyses were performed according to Bayesian inference, maximum likelihood, and maximum parsimony methods. We explored effects produced on the phylogenetic outcomes by both taxon sampling as well as selected genes. Congruent results were obtained from analyses performed on single gene multiple alignments as well as on a data set including both SSU rDNA and rbcL sequences. Trees obtained in this study show that several currently recognized xanthophycean taxa do not form monophyletic groups. The order Mischococcales is paraphyletic, while Tribonematales and Botrydiales are polyphyletic even if evidence for the second order is not conclusive. Botrydiales and Vaucheriales, both including siphonous taxa, do not form a clade. The families Botrydiopsidaceae, Botryochloridaceae, and Pleurochloridaceae as well as the genera Botrydiopsis and Chlorellidium are polyphyletic. The Centritractaceae and the genus Bumilleriopsis also appear to be polyphyletic but their monophyly cannot be completely rejected with current evidence. Our results support morphological convergence at any taxonomic rank in the evolution of the Xanthophyceae. Finally, our phylogenetic analyses exclude an origin of the Xanthophyceae from a Vaucheria-like ancestor and favor a single early origin of the coccoid cell form.     

Kalinella bambusicola gen. et sp. nov. (Trebouxiophyceae, Chlorophyta), a novel coccoid Chlorella-like subaerial alga from Southeast Asia

The traditional green algal genus Chlorella , which comprised coccoid algae surrounded by a smooth cell wall and reproducing solely by autosporulation, has proved to be polyphyletic and extremely diverse in phylogenetic terms. We studied a new subaerial Chlorella -like strain CAUP H7901 and morphological, ultrastructural, and molecular phylogenetic investigations indicated that it represents a new lineage of the trebouxiophycean Watanabea clade, dissimilar from other members of this group. The alga has globular coccoid cells with a single parietal pyrenoid-bearing chloroplast. The pyrenoid is transected by multiple radial thylakoid bands. The alga reproduces exclusively by means of asexual autospores of unequal size. In 18S rDNA sequence phylogenies, it was nested within the Watanabea clade close to lineages containing Chlorella saccharophila , Chlorella luteoviridis , Heveochlorella hainangensis , and two uncharacterized strains, but alternative positions within the Watanabea clade could not be rejected by an approximately unbiased (AU) test. Here we describe this organism as a new genus and species Kalinella bambusicola gen. et sp. nov. Furthermore, we describe Heterochlorella gen. nov. to accommodate a species previously referred to as Chlorella luteoviridis .     

Chloroplast gene arrangement variation within a closely related group of green algae (Trebouxiophyceae, Chlorophyta)

The 22 published chloroplast genomes of green algae, representing sparse taxonomic sampling of diverse lineages that span over one billion years of evolution, each possess a unique gene arrangement. In contrast, many of the >190 published embryophyte (land plant) chloroplast genomes have relatively conserved architectures. To determine the phylogenetic depth at which chloroplast gene rearrangements occur in green algae, a 1.5-4 kb segment of the chloroplast genome was compared across nine species in three closely related genera of Trebouxiophyceae (Chlorophyta). In total, four distinct gene arrangements were obtained for the three genera Elliptochloris, Hemichloris, and Coccomyxa. In Elliptochloris, three distinct chloroplast gene arrangements were detected, one of which is shared with members of its sister genus Hemichloris. Both species of Coccomyxa examined share the fourth arrangement of this genome region, one characterized by very long spacers. Next, the order of genes found in this segment of the chloroplast genome was compared across green algae and land plants. As taxonomic ranks are not equivalent among different groups of organisms, the maximum molecular divergence among taxa sharing a common gene arrangement in this genome segment was compared. Well-supported clades possessing a single gene order had similar phylogenetic depth in green algae and embryophytes. When the dominant gene order of this chloroplast segment in embryophytes was assumed to be ancestral for land plants, the maximum molecular divergence was found to be over two times greater in embryophytes than in trebouxiophyte green algae. This study greatly expands information about chloroplast genome variation in green algae, is the first to demonstrate such variation among congeneric green algae, and further illustrates the fluidity of green algal chloroplast genome architecture in comparison to that of many embryophytes.     

Analysis of a New Strain of Pseudomuriella engadinensis (Sphaeropleales,Chlorophyta) for Possible Use in Biotechnology

Russian Journal of Plant Physiology - The species diversity of green coccoid algae is often difficult to study using light microscopy due to their complex morphology. Algae, which have...     

Symbiosis between hydra and chlorella: Molecular phylogenetic analysis and experimental study provide insight into its origin and evolution

Although many physiological studies have been reported on the symbiosis between hydra and green algae, very little information from a molecular phylogenetic aspect of symbiosis is available. In order to understand the origin and evolution of symbiosis between the two organisms, we compared the phylogenetic relationships among symbiotic green algae with the phylogenetic relationships among host hydra strains. To do so, we reconstructed molecular phylogenetic trees of several strains of symbiotic chlorella harbored in the endodermal epithelial cells of viridissima group hydra strains and investigated their congruence with the molecular phylogenetic trees of the host hydra strains. To examine the species specificity between the host and the symbiont with respect to the genetic distance, we also tried to introduce chlorella strains into two aposymbiotic strains of viridissima group hydra in which symbiotic chlorella had been eliminated in advance. We discussed the origin and history of symbiosis between hydra and green algae based on the analysis.     

ORIGINS AND AFFINITIES OF THE FILAMENTOUS GREEN ALGAL ORDERS CHAETOPHORALES AND OEDOGONIALES BASED ON 18S rRNA GENE SEQUENCES

The order Chaetophorales includes filamentous green algae whose taxonomic relationships to other chlorophycean orders is uncertain. Chaetophoralean taxa include filamentous species which are both branched and unbranched. Ultrastructural studies of zoospores have revealed similar flagellar apparatuses in a number of genera, including Uronema, Stigeoclonium, and Fritschiella, suggesting a close phylogenetic relationship among these taxa. The order Oedogoniales represents a second group of branched and unbranched filamentous green algae whose relationships to other chlorophycean orders also has been unclear. A possible close relationship between the Chaetophorales and Oedogoniales has been suggested. Using DNA sequences from the small-subunit ribosomal RNA gene (SSU rRNA) of several members of each order, we have examined the monophyly of the Chaetophorales and Oedogoniales, as well as the nature of their relationship to other chlorophycean orders. Our results show that chaetophoralean and oedogonialean taxa form separate monophyletic groups. Results also suggest that the two orders are not closely related to each other.     

MARINICHLORELLA KAISTIAE GEN. ET SP. NOV. (TREBOUXIOPHYCEAE,CHLOROPHYTA) BASED ON POLYPHASIC TAXONOMY1

We describe three coccoid green algal strains belonging to a new genus and species, Marinichlorella kaistiae Z. Aslam, W. Shin, M. K. Kim, W.‐T. Im et S.‐T. Lee, in seawater samples from the South Sea of Korea. These strains were maintained at 25°C–30°C under a 12:12 light:dark (L:D) photoregime in an ASN‐III medium at a pH of 7.5. These strains were tolerant of high salinity (7.5% NaCl) (w/v) and temperature (40°C). Molecular phylogenetic analyses using 18S rRNA gene sequence data resolved these organisms to a clade separate from green coccoid algae with similar morphology. The DNA–DNA hybridization results demonstrated very low relatedness of these organisms to phylogenetically related species of the genera Chlorella and Parachlorella. The molar guanine + cytosine content (G + C mol%) of the genomic DNA of these organisms ranged from 64.7 to 69.1 mol%. Based on molecular phylogeny, DNA–DNA hybridization, and other morphological studies, we propose a new taxon, Marinichlorella kaistiae, to describe these strains and classify them in the family Chlorellaceae. The type strain is KAS007^T (= KCTC AG10303^T = IAM C‐620^T).     

New insights into diversity and selectivity of trentepohlialean lichen photobionts from the extratropics

Aerial green algae of Trentepohliaceae can form conspicuous free-living colonies, be parasites of plants or photobionts of lichen-forming ascomycetes. So far, their diversity in temperate regions is still poorly known as it has been mostly studied by phenotypic approaches only. We present new insights in the phylogenetic relationships of lichenized representatives from temperate and Mediterranean parts of Europe by analysis of 18S rRNA and rbcL gene fragments, and nuclear ITS sequence data. For this purpose we isolated the trentepohlialean photobionts from lichens representing different genera. Algal cultures from lichenized and free-living Trentepohliaceae were used to design new primers for amplification of the marker loci. We constructed a phylogenetic hypothesis to reveal the phylogenetic placements of lichenized lineages with 18S rRNA and rbcL sequences. ITS variation among the clades was substantial and did not allow including them in the general phylogenetic assessment, yet ITS appears to be a promising marker for DNA-barcoding approaches. Specific algae were found in particular lichen but the overall diversity of photobionts was limited. The multilocus tree does not support the current morphological classification of genera in Trentepohliaceae, suggesting that morphology is more variable than previously thought in this group of algae.     

PSEUDOFILAMENTOUS GREEN ALGAE FORM INDEPENDENT CHLOROPHYTE AND STREPTOPHYTE LINEAGES

The pseudofilamentous condition in green algae has been characterized as the formation of a linear array of autospores. Although it is likely that this characterization will be found to be an over-simplification, it serves as a logical starting point for a study of diversity among pseudofilamentous taxa. Therefore, given that molecular phylogenetic analyses have revealed that coccoid, autospore-formers are found in a number of independent green algal lineages, it is reasonable to expect that pseudofilamentous taxa are likely to be found in a number of distinct lineages. In order to test this hypothesis, data from the nuclear-encoded 18S r   RNA gene were collected from several pseudofilamentous, green algal genera ( Geminella , Gloeotila , Hazenia , Interfilum , Microspora , and Sphaeroplea ) and incorporated into an 18S rRNA database of chlorobiont taxa. Results from phylogenetic analyses of these data support (1) an alliance of Interfilum , two Geminella isolates, and Klebsormidium within the streptophyte lineage, (2) an alliance of two Geminella isolates and Microspora as a sister group to the ulvophycean/chlorophycean/trebouxiophycean clade or as a sister group to trebouxiophycean taxa, (3) an alliance of Hazenia with ulotrichalean taxa, (4) of Gloeotila with trebouxiophycean taxa and (5) an alliance of Sphaeroplea with chlorophycean taxa. These data confirm that the filamentous condition has evolved in a number of independent lineages. Moreover, these data further illustrate that the extent of molecular variability within the green algae is far from fully appreciated.     

Phylogeny of the quadriflagellate Volvocales (Chlorophyceae) based on chloroplast multigene sequences

Since the phylogenetic relationships of the green plants (green algae and land plants) have been extensively studied using 18S ribosomal RNA sequences, change in the arrangement of basal bodies in flagellate cells is considered to be one of the major evolutionary events in the green plants. However, the phylogenetic relationships between biflagellate and quadriflagellate species within the Volvocales remain uncertain. This study examined the phylogeny of three genera of quadriflagellate Volvocales (Carteria, Pseudocarteria, and Hafniomonas) using concatenated sequences from three chloroplast genes. Using these multigene sequences, all three quadriflagellate genera were basal to other members (biflagellates) of the CW (clockwise) group (the Volvocales and their relatives, the Chlorophyceae) and formed three robust clades. Since the flagellar apparatuses of these three quadriflagellate lineages are diverse, including counter clockwise (CCW) and CW orientation of the basal bodies, the CW orientation of the basal bodies might have evolved from the CCW orientation in the ancestral quadriflagellate volvocalean algae, giving rise to the biflagellates, major members of the CW group.     

178 Molecular Systematics of the Ulvellaceae (Ulvales, Ulvophyceae) Inferred from Nuclear and Chloroplast DNA Sequences

The traditional use of thallus morphology to define lineages within the Ulvophyceae proved problematic because parallelism and convergence obscured natural relationships. The advent of transmission electron microscopy led to a re-evaluation of groups on the basis of zoid characters. Within TEM-defined lineages, the Ulotrichales and Ulvales were considered closely related orders, and molecular evidence has substantiated this hypothesis. In our molecular systematic studies of ulvophyceous green algae, we have broadened taxon sampling among these two orders. We show that the Ulvales and Ulotrichales are indeed monophyletic orders. However, the phylogenetic placement of species in the genera Bolbocoleon, Ctenocladus, Phaeophila, Pseudendoclonium and Acroblaste indicates that one or more additional lineages, placed between Ulvales and Ulotrichales in gene sequence trees, must be recognized. These species may constitute a separate order (Ctenocladales) consisting of multiple families. Our findings will be compared with taxonomic concepts based on morphological criteria.     

Systematics and Ecology of Chlorophyte Picoplankton in German Inland Waters along a Nutrient Gradient

The community structure and succession of autotrophic picoplankton in several oligotrophic to hypertrophic German freshwater ecosystems were studied with emphasis on the occurrence and characterization of chlorophyte picoplankton. Depending on the trophic status and the time of the year, the relation of green eukaryotic picoplankton to picocyanobacteria, the contribution of the picoplankton to the total phytoplankton biomass, and the succession and dominance of picoplankton groups changed considerably. A significant correlation between the picoplankton abundances, their biomass and their biomass contribution could not be found. Although the chlorophyte picoplankton were similar with respect to their ultrastructure, phylogenetic analyses of the rbcL genes revealed that these organisms evolved independently within several green algal lineages. The most common picoplanktonic green algae in the lakes that were studied belong to the genera Choricystis and Pseudodictyosphaerium. Considering the new molecular biological findings, the systematics of picoplanktonic green algae from freshwater and marine habitats are discussed.     

OCCURRENCE OF GLYCOLATE DEHYDROGENASE AND GLYCOLATE OXIDASE IN SOME COCCOID,ZOOSPORE-PRODUCING GREEN ALGAE1

Twenty-seven species of coccoid, zoospore-producing green algae representing 16 genera in the Chlorococcales and Chlorosarcinales were assayed for glycolate oxidase or glycolate dehydrogenase. Only Planophila terrestris Groover & Bold and Fasciculochloris boldii Trainor, contained glycolate oxidase whereas the others contained glycolate dehydrogenase. Representative algae were grown under varying conditions and assayed to determine any effects on these glycolate enzymes. Although specific rates of enzyme activity often varied widely, the form of glycolate enzyme present was not affected.     

Toward Modern Classification of Eustigmatophytes,Including the Description of Neomonodaceae Fam. Nov. and Three New Genera1

The class Eustigmatophyceae includes mostly coccoid, freshwater algae, although some genera are common in terrestrial habitats and two are primarily marine. The formal classification of the class, developed decades ago, does not fit the diversity and phylogeny of the group as presently known and is in urgent need of revision. This study concerns a clade informally known as the Pseudellipsoidion group of the order Eustigmatales, which was initially known to comprise seven strains with oval to ellipsoidal cells, some bearing a stipe. We examined those strains as well as 10 new ones and obtained 18S rDNA and rbcL gene sequences. The results from phylogenetic analyses of the sequence data were integrated with morphological data of vegetative and motile cells. Monophyly of the Pseudellipsoidion group is supported in both 18S rDNA and rbcL trees. The group is formalized as the new family Neomonodaceae comprising, in addition to Pseudellipsoidion, three newly erected genera. By establishing Neomonodus gen. nov. (with type species Neomonodus ovalis comb. nov.), we finally resolve the intricate taxonomic history of a species originally described as Monodus ovalis and later moved to the genera Characiopsis and Pseudocharaciopsis. Characiopsiella gen. nov. (with the type species Characiopsiella minima comb. nov.) and Munda gen. nov. (with the type species Munda aquilonaris) are established to accommodate additional representatives of the polyphyletic genus Characiopsis. A morphological feature common to all examined Neomonodaceae is the absence of a pyrenoid in the chloroplasts, which discriminates them from other morphologically similar yet unrelated eustigmatophytes (including other Characiopsis-like species).     

98 Phylodiversity of green algae (chlorophyta) from desert microbiotic crusts

Deserts are not thought of as biodiversity hotspots, but desert microbiotic crust communities represent a largely unknown community type rich in diversity of eukaryotic and prokaryotic taxa. These ecologically important communities have received much attention because of their role in nutrient cycling and soil stabilization in deserts, but they defy characterization by the traditional approach to assessing biodiversity by counting species. While genetically diverse, taxa characteristic of desert crusts are difficult to identify to the species level due to convergent evolution toward simple morphologies, phenotypic plasticity, or poor knowledge about particular lineages. Focusing on the green algae, we show that while biodiversity is difficult to measure in these communities, phylodiversity provides a surrogate measure that more accurately portrays the diversity of organisms, and one that is standardized across the variety of life histories, reproductive strategies and morphological variability that creates problems with species‐counting measures. Bayesian phylogenetic inference uses MCMC simulation to generate phylogenies sampled in proportion to their Bayesian posterior probability. The length of a segment in any of these trees corresponds to the amount of change in the lineage, measured as the expected number of substitutions/nucleotide site. Comparisons of segment lengths corresponding to desert vs. other green algal lineages provides a means of addressing questions of relative genetic diversity, or phylodiversity, without complications arising from the difficulty of counting species. Our data illustrate the impact of desert green algae to overall knowledge of the green algal phylogenetic tree.