单细胞生物进化研究的进步

20世纪60年代,生物大致分为5界的谱系图,　经历了几次翻新,开始提出了线粒体和叶绿体的内共生学说。 由于分子生物学的发展,首先将各种生物的蛋白质的分子进行比较,构建成蛋白质的分子系统树。再转向核糖核酸,将核糖体的小亚单位,作为区别生命类型之间亲缘关系的指标。发现有些嗜极端条件的细菌,它们不同于原核生物也不同于真核生物,是第三种类型的生命形式。因此,在 80年代为生命建立了细菌、古细菌和真核生物三界的系统树。对许许多多单个基因的系统树的分析,又使人们认识到,古细菌与细菌和真核微生物之间以及各个物种之间,显然皆发生过大量的基因交换。对单细胞进化来说,基因除垂直传递外,横向的或叫侧向的基因转移也十分繁多。在一张完全的系统图中,要同时表现几千个不同的基因家族的超联结的种系型式才符合实际。因而,最新版本的系统树是分枝交缠、无主干的。 Abstract:In 1960s,kimgdoms of organisms were charted generally in a five branching form.Later,the endosymbiont hypothesis for the mitochondria and the chloroplast was proposed.The life-form is divided into two forms,the prokaryotes (bacteria) and the eukaryotes.The study of the molecular biology made the progress faster.In 1980s,Woese,CR.asserted that two-domain view of life was no longer true,a three-domain construct,the Bacteria,the Archaea,and the Eukaryotes had to take its place.At first,phylogeny trees based on differences in the amino acid sequences,then among ribosomal RNAs and also nuclear gene from hundreds of microbial species were depicted and many mini phylogenetic trees grouped the species according to their differences in the sequences.It was found that they shared genes between their contemporaries and across the species barriers.At the root of the phylogeny tree,there was not a single common cell,it was replaced by a common ancestral community of primitive cells.Genes transfered rather freely as the transposons swapping between those cells.There was no last universal common ancestor of single cell that could be found in the revised Tree of Life,It was not easy to represent the genealogical patterns of thousands of different families of genes,in one systematic map,therefor there was no trunk at all.     

LVTree Viewer:An Interactive Display for the All-Species Living Tree Incorporating Automatic Comparison with Prokaryotic Systematics

We describe an interactive viewer for the All-Species Living Tree (LVTree). The viewer incorporates treeing and lineage information from the ARB-SILVA website. It allows collapsing the tree branches at different taxonomic ranks and expanding the collapsed branches as well, keeping the overall topology of the tree unchanged. It also enables the user to observe the consequence of trial lineage modifications by re-collapsing the tree. The system reports taxon statistics at all ranks automatically after each collapsing and re-collapsing. These features greatly facilitate the compar-ison of the 16S rRNA sequence phylogeny with prokaryotic taxonomy in a taxon by taxon manner. In view of the fact that the present prokaryotic systematics is largely based on 16S rRNA sequence analysis, the current viewer may help reveal discrepancies between phylogeny and taxonomy. As an application, we show that in the latest release of LVTree, based on 11,939 rRNA sequences, as few as 24 lineage modifications are enough to bring all but two phyla (Proteobacteria and Firmicutes) to monophyletic clusters.     

Nelumbonaceae:Systematic position and species diversification revealed by the complete chloroplast genome

<正>Nelumbonaceae is a morphologically unique family of angiosperms and was traditionally placed in Nymphaeales;more recently,it was placed in Proteales based on molecular data,or in an order of its own,Nelumbonales. To determine the systematic position of the family and to date the divergence time of the family and the divergence time of its two intercontinentally disjunct species,we sequenced the entire chloroplast genome of Nelumbo lutea and most of the chloroplast genes of,N.nucifera.We carried out phylogenetic and molecular dating analyses of the two species and representatives of 47 other plant families,representing the major lineages of angiosperms, using 83 plastid genes.The N.lutea genome was 163 510 bp long,with a total of 130 coding genes and an overall GC content of 38%.No significant structural differences among the genomes of N.lutea,Nymphaea alba, and Platanus occidentalis were observed.The phylogenetic relationships based on the 83 plastid genes revealed a close relationship between Nelumbonaceae and Platanaceae.The divergence times were estimated to be 109 Ma between the two families and 1.5 Ma between the two Nelumbo species.The estimated time was only slightly longer than the age of known Nelumbo fossils,suggesting morphological stasis within Nelumbonaceae.We conclude that Nelumbonaceae holds a position in or close to Proteales.We further conclude that the two species of Nelumbo diverged recently from a common ancestor and do not represent ancient relicts on different continents.     

基于28S rRNA基因D2序列的优茧蜂亚科分子系统发育（膜翅目：茧蜂科）

The D2 variable region of 28S ribosomal RNA was sequenced from ethanol specimens or obtained from the literature to provide the first phylogenetie reconstruction of the subfamily Euphorinae (Hymenoptera;Braconidae). Phylogenetic relationships were established by comparing the results using two different methods (distance-based neighbor-joining, NJ; and maximum parsimony, MP) and three different outgroups. The monophyly of the Euphorinae is well supported by all trees generated from molecular data. All phylogenetic reconstructions yielded trees with very similar topologies that only partially resolved the morphologically defined tribes and the relationships within the subfamily. We found no evidence for the monophyletic natures of the tribes Euphorinl, Dinocampini,Perilitini, Syntretini, Comsophorini and Centisitini, but we did find some evidence for the tribes Meteorini and Microctonini. The monophyletic nature of the tribe Meteodnl was well-supported in all trees. We also found the clade containing the LecythodeUa,Microctonus, Orionis and Streblocera to be a monophyletic group, which corresponded to the tribe Microtonini, with Orionis transferred from the tribe Eupholini into Microtonini.Among the genera of Euphorini our results showed strong support for a paraphyletic nature of this group, which can be roughly divided into two clades, one consisting of Aridelus Wesmaelia, the other of Leiophron Peristenus, suggesting both of which may be given tribal rank. The placement of the genus Chrysopophorus is largely uncertain. Two clades,Dinocampus Perilitus and Cosmophorus Rhopalophorus, were constantly resolved in our analyses, with 42-96 and 97-100 bootstrap value support, respectively, suggesting that both of them form monophyletic groups. For members of the Centistini, Pygostolus may be removed and included in Microctonini or other relative tribe.     

Genetic Diversity and Population Structure of the Oriental Garden Lizard,Calotes versicolor Daudin, 1802(Squamata: Agamidae) along the Mekong River in Thailand and Lao PDR

Calotes versicolor Daudin,1802,is geographically widespread along the Mekong River basin.The Mekong River is play important role as a significant natural barrier to several terrestrial animals living on different sides.This study aims to analyze the genetic diversity and population structure of C.versicolor populations collected from different sides of Mekong River using mitochondrial cytochrome c oxidase subunit 1(CO1)sequences.We obtained sequences of 200 individuals from 18 sampling localities from left and right sides of the Mekong River in Lao PDR and Thailand respectively.Overall,91 haplotypes were detected,which reflect high levels of genetic diversity in this species at the study areas.Haplotype network and phylogenetic analyses revealed that there were six major lineages(lineage C–lineage H)of C.versicolor populations within the Mekong River,whereas lineages A and B have previously been found from China and Vietnam.The genetic distance among C.versicolor was significantly related to spatial distance,however,the Mekong River had no significant effect on genetic distance.Our findings,together with previous studies,suggests that C.versicolor in Asia is a species complex with other cryptic lineages being likely but there is a need for further exploration.Thus,comprehensive genetic,biological and ecological studies of C.versicolor should be conducted throughout its entire distribution range.     

Duck egg drop syndrome virus: an emerging Tembusu-related flavivirus in China

Duck egg drop syndrome virus(DEDSV) is a newly emerging pathogenic flavivirus isolated from ducks in China.DEDSV infection mainly results in severe egg drop syndrome in domestic poultry,which leads to huge economic losses.Thus,the discovery of ways and means to combat DEDSV is urgent.Since 2010,a remarkable amount of progress concerning DEDSV research has been achieved.Here,we review current knowledge on the epidemiology,symptomatology,and pathology of DEDSV.A detailed dissection of the viral genome and polyprotein sequences,comparative analysis of viral antigenicity and the corresponding potential immunity against the virus are also summarized.Current findings indicate that DEDSV should be a distinct species from Tembusu virus.Moreover,the adaption of DEDSV in wildlife and its high homology to pathogenic flaviviruses(e.g.,West Nile virus,Japanese encephalitis virus,and dengue virus),illustrate its reemergence and potential to become a zoonotic pathogen that should not be overlooked.Detailed insight into the antigenicity and corresponding immunity against the virus is of clear significance for the development of vaccines and antiviral drugs specific for DEDSV.     

Whole genome duplication of intra- and inter-chromosomes in the tomato genome

Whole genome duplication(WGD)events have been proven to occur in the evolutionary history of most angiosperms.Tomato is considered a model species of the Solanaceae family.In this study,we describe the details of the evolutionary process of the tomato genome by detecting collinearity blocks and dating the WGD events on the tree of life by combining two different methods:synonymous substitution rates(Ks)and phylogenetic trees.In total,593 collinearity blocks were discovered out of 12 pseudo-chromosomes constructed. It was evident that chromosome 2 had experienced an intra-chromosomal duplication event.Major inter-chromosomal duplication occurred among all the pseudo-chromosome.We calculated the Ks value of these collinearity blocks.Two peaks of Ks distribution were found,corresponding to two WGD events occurring approximately 36-82 million years ago(MYA)and 148-205 MYA.Additionally, the results of phylogenetic trees suggested that the more recent WGD event may have occurred after the divergence of the rosidasterid clade,but before the major diversification in Solanaceae.The older WGD event was shown to have occurred before the divergence of the rosid-asterid clade and after the divergence of rice-Arabidopsis(monocot-dicot).     

The origin and diversification of eukaryotes: problems with molecular phylogenetics and molecular clock estimation

Determining the relationships among and divergence times for the major eukaryotic lineages remains one of the most important and controversial outstanding problems in evolutionary biology. The sequencing and phylogenetic analyses of ribosomal RNA (rRNA) genes led to the first nearly comprehensive phylogenies of eukaryotes in the late 1980s, and supported a view where cellular complexity was acquired during the divergence of extant unicellular eukaryote lineages. More recently, however, refinements in analytical methods coupled with the availability of many additional genes for phylogenetic analysis showed that much of the deep structure of early rRNA trees was artefactual. Recent phylogenetic analyses of a multiple genes and the discovery of important molecular and ultrastructural phylogenetic characters have resolved eukaryotic diversity into six major hypothetical groups. Yet relationships among these groups remain poorly understood because of saturation of sequence changes on the billion-year time-scale, possible rapid radiations of major lineages, phylogenetic artefacts and endosymbiotic or lateral gene transfer among eukaryotes. Estimating the divergence dates between the major eukaryote lineages using molecular analyses is even more difficult than phylogenetic estimation. Error in such analyses comes from a myriad of sources including: (i) calibration fossil dates, (ii) the assumed phylogenetic tree, (iii) the nucleotide or amino acid substitution model, (iv) substitution number (branch length) estimates, (v) the model of how rates of evolution change over the tree, (vi) error inherent in the time estimates for a given model and (vii) how multiple gene data are treated. By reanalysing datasets from recently published molecular clock studies, we show that when errors from these various sources are properly accounted for, the confidence intervals on inferred dates can be very large. Furthermore, estimated dates of divergence vary hugely depending on the methods used and their assumptions. Accurate dating of divergence times among the major eukaryote lineages will require a robust tree of eukaryotes, a much richer Proterozoic fossil record of microbial eukaryotes assignable to extant groups for calibration, more sophisticated relaxed molecular clock methods and many more genes sampled from the full diversity of microbial eukaryotes.     

PHYLOGENOMICS AND SECONDARY PLASTIDS: A LOOK BACK AND A LOOK AHEAD1

Despite their importance to evolution, ecology, and cell biology, eukaryotes that acquired plastids through secondary endosymbiosis remain poorly studied from a genomic standpoint. Chromalveolata, a eukaryotic supergroup proposed to have descended from a heterotrophic eukaryote that acquired a red algal plastid by secondary endosymbiosis, includes four major lineages (alveolates, cryptophytes, haptophytes, and heterokonts). The chromalveolates exhibit remarkable diversity of cellular organization, and the available data suggest that they exhibit equal diversity in their genome organization. One of the most obvious differences in cellular organization is the retention of a highly reduced red algal nucleus in cryptophytes (also known as cryptomonads), but there are other major differences among chromalveolate lineages, including the loss of photosynthesis in multiple lineages. Although the hypothesis of chromalveolate monophyly is appealing, there is limited support for the hypothesis from nuclear genes, and questions have even been raised about the monophyly of chromalveolate plastids. Evidence for the chromalveolate hypothesis from large‐scale nuclear data sets is reviewed, and alternative hypotheses are described. The potential for integrating information from chromalveolate genomics into functional genomics is described, emphasizing both the methodological challenges and the opportunities for future phylogenomic analyses of these groups.     

Eukaryotic pyruvate formate lyase and its activating enzyme were acquired laterally from a Firmicute

Most of the major groups of eukaryotes have microbial representatives that thrive in low oxygen conditions. Those that have been studied in detail generate ATP via pathways involving anaerobically functioning enzymes of pyruvate catabolism that are typically absent in aerobic eukaryotes and whose origins remain controversial. These enzymes include pyruvate:ferredoxin oxidoreductase, pyruvate:NADP(+) oxidoreductase, and pyruvate formate lyase (Pfl). Pfl catalyzes the nonoxidative generation of formate and acetyl-Coenzyme A (CoA) from pyruvate and CoA and is activated by Pfl activating enzyme (Pfla). Within eukaryotes, this extremely oxygen-sensitive pathway was first described in the hydrogenosomes of anaerobic chytrid fungi and has more recently been characterized in the mitochondria and chloroplasts of the chlorophyte alga Chlamydomonas reinhardtii. To clarify the origins of this pathway, we have comprehensively searched for homologs of Pfl and Pfla in publicly available large-scale eukaryotic genomic and cDNA sequencing data, including our own from the anaerobic amoebozoan Mastigamoeba balamuthi. Surprisingly, we find that these enzymes are widely distributed and are present in diverse facultative or obligate anaerobic eukaryotic representatives of the archaeplastidan, metazoan, amoebozoan, and haptophyte lineages. Using maximum likelihood and Bayesian phylogenetic methods, we show that the eukaryotic Pfl and Pfla sequences each form monophyletic groups that are most closely related to homologs in firmicute gram-positive bacteria. Topology tests exclude both α-proteobacterial and cyanobacterial affinities for these genes suggesting that neither originated from the endosymbiotic ancestors of mitochondria or chloroplasts. Furthermore, the topologies of the eukaryote portion of the Pfl and Pfla trees significantly differ from well-accepted eukaryote relationships. Collectively, these results indicate that the Pfl pathway was first acquired by lateral gene transfer into a eukaryotic lineage most probably from a firmicute bacterial lineage and that it has since been spread across diverse eukaryotic groups by more recent eukaryote-to-eukaryote transfer events.     

The rate and pattern of cladogenesis in microbes

Theories of macroevolution rarely have been extended to include microbes; however, because microbes represent the most ancient and diverse assemblage of organismal diversity, such oversight limits our understanding of evolutionary history. Our analysis of phylogenetic trees for microbes suggests that macroevolution may differ between prokaryotes and both micro- and macroeukaryotes (mainly plants and animals). Phylogenetic trees inferred for prokaryotes and some microbial eukaryotes conformed to expectations assuming a constant rate of cladogenesis over time and among lineages: nevertheless, microbial eukaryote trees exhibited more variation in rates of cladogenesis than prokaryote trees. We hypothesize that the contrast of macroevolutionary dynamics between prokaryotes and many eukaryotes is due, at least in part, to differences in the prevalence of lateral gene transfer (LGT) between the two groups. Inheritance is predominantly, if not wholly, vertical within eukaryotes, a feature that allows for the emergence and maintenance of heritable variation among lineages. By contrast, frequent LGT in prokaryotes may ameliorate heritable variation in rate of cladogenesis resulting from the emergence of key innovations; thus, the inferred difference in macroevolution might reflect exclusivity of key innovations in eukaryotes and their promiscuous nature in prokaryotes.     

Aggregative multicellularity evolved independently in the eukaryotic supergroup Rhizaria

Multicellular forms of life have evolved many times, independently giving rise to a diversity of organisms such as animals, plants, and fungi that together comprise the visible biosphere. Yet multicellular life is far more widespread among eukaryotes than just these three lineages. A particularly common form of multicellularity is a social aggregative fruiting lifestyle whereby individual cells associate to form a "fungus-like" sorocarp. This complex developmental process that requires the interaction of thousands of cells working in concert was made famous by the "cellular slime mold"Dictyostelium discoideum, which became an important model organism. Although sorocarpic protistan lineages have been identified in five of the major eukaryote groups, the ubiquitous and globally distributed species Guttulinopsis vulgaris has eluded proper classification. Here we demonstrate, by phylogenomic analyses of a 159-protein data set, that G. vulgaris is a member of Rhizaria and is thus the first member of this eukaryote supergroup known to be capable of aggregative multicellularity.     

Collodictyon--an ancient lineage in the tree of eukaryotes

The current consensus for the eukaryote tree of life consists of several large assemblages (supergroups) that are hypothesized to describe the existing diversity. Phylogenomic analyses have shed light on the evolutionary relationships within and between supergroups as well as placed newly sequenced enigmatic species close to known lineages. Yet, a few eukaryote species remain of unknown origin and could represent key evolutionary forms for inferring ancient genomic and cellular characteristics of eukaryotes. Here, we investigate the evolutionary origin of the poorly studied protist Collodictyon (subphylum Diphyllatia) by sequencing a cDNA library as well as the 18S and 28S ribosomal DNA (rDNA) genes. Phylogenomic trees inferred from 124 genes placed Collodictyon close to the bifurcation of the "unikont" and "bikont" groups, either alone or as sister to the potentially contentious excavate Malawimonas. Phylogenies based on rDNA genes confirmed that Collodictyon is closely related to another genus, Diphylleia, and revealed a very low diversity in environmental DNA samples. The early and distinct origin of Collodictyon suggests that it constitutes a new lineage in the global eukaryote phylogeny. Collodictyon shares cellular characteristics with Excavata and Amoebozoa, such as ventral feeding groove supported by microtubular structures and the ability to form thin and broad pseudopods. These may therefore be ancient morphological features among eukaryotes. Overall, this shows that Collodictyon is a key lineage to understand early eukaryote evolution.     

The molecular diversity of freshwater picoeukaryotes from an oligotrophic lake reveals diverse, distinctive and globally dispersed lineages

The recent discovery of a diverse phylogenetic assemblage of picoeukaryotes from environments such as oceans, salt marshes and acidic habitats, has expanded the debates about the extent and origin of microbial eukaryotes. However, the diversity of these eukaryote microorganisms, that overlap bacteria in size, and their environmental and biogeographical ubiquity remains poorly understood. Here we survey picoeukaryotes (microbial eukaryotes of 0.2-5 microm in size) from an oligotrophic (nutrient deficient) freshwater habitat using ribosomal RNA gene sequences. Three taxonomic groups the Heterokonta, Cryptomonads and the Alveolata dominated the detected diversity. Most sequences represented previously unsampled species, with several being unassignable to known taxonomic groups and plausibly represent new or unsampled phyla. Many freshwater phylogenetic groups identified in this study appeared unrelated to picoeukaryotic sequences identified in marine ecosystems, suggesting that aspects of eukaryote microbial diversity are specific to certain aquatic environments. Conversely, at least five phylogenetic clusters comprised sequences from freshwater and globally dispersed and often contrasting environments, supporting the concept that a number of picoeukaryotic lineages are widely distributed.     

Only six kingdoms of life

There are many more phyla of microbes than of macro-organisms, but microbial biodiversity is poorly understood because most microbes are uncultured. Phylogenetic analysis of rDNA sequences cloned after PCR amplification of DNA extracted directly from environmental samples is a powerful way of exploring our degree of ignorance of major groups. As there are only five eukaryotic kingdoms, two claims using such methods for numerous novel 'kingdom-level' lineages among anaerobic eukaryotes would be remarkable, if true. By reanalysing those data with 167 known species (not merely 8-37), I identified relatives for all 8-10 'mysterious' lineages. All probably belong to one of five already recognized phyla (Amoebozoa, Cercozoa, Apusozoa, Myzozoa, Loukozoa) within the basal kingdom Protozoa, mostly in known classes, sometimes even in known orders, families or genera. This strengthens the idea that the ancestral eukaryote was a mitochondrial aerobe. Analogous claims of novel bacterial divisions or kingdoms may reflect the weak resolution and grossly non-clock-like evolution of ribosomal rRNA, not genuine phylum-level biological disparity. Critical interpretation of environmental DNA sequences suggests that our overall picture of microbial biodiversity at phylum or division level is already rather good and comprehensive and that there are no uncharacterized kingdoms of life. However, immense lower-level diversity remains to be mapped, as does the root of the tree of life.     

Masters of miniaturization: Convergent evolution among interstitial eukaryotes

Marine interstitial environments are teeming with an extraordinary diversity of coexisting microeukaryotic lineages collectively called “meiofauna.” Interstitial habitats are broadly distributed across the planet, and the complex physical features of these environments have persisted, much like they exist today, throughout the history of eukaryotes, if not longer. Although our general understanding of the biological diversity in these environments is relatively poor, compelling examples of developmental heterochrony (e.g., pedomorphosis) and convergent evolution appear to be widespread among meiofauna. Therefore, an improved understanding of meiofaunal biodiversity is expected to provide some of the deepest insights into the following themes in evolutionary biology: (i) the origins of novel body plans, (ii) macroevolutionary patterns of miniaturization, and (iii) the intersection of evolution and community assembly – e.g., “community convergence” involving distantly related lineages that span the tree of eukaryotes.