Molecular identification and classification of Cochlonema euryblastum, a zoopagalean parasite of Thecamoeba quadrilineata

Free-living amoebae can serve a great variety of organisms, predominantly bacteria but to a certain extent also fungi, as a suitable host supplying them with nutrients and protecting them from adverse environmental conditions. In the current study 18S rDNA sequencing was performed to identify a fungal parasite in a Thecamoeba quadrilineata isolate. This parasite morphologically resembled Cochlonema euryblastum, a member of the order Zoopagales, which comprises parasitic species on fungi and invertebrates. Sequence analysis corroborated the morphological identification and the fungal parasite clearly can be assigned to the Zoopagales. Phylogenetic analysis revealed C. euryblastum clustering with two representatives of the mycoparasitic family Piptocephalidaceae. This zooparasitic-mycoparasitic clade represents a sister group of a clade including another member of the Piptocephalidaceae and two other zooparasitic families. Thus, the addition of C. euryblastum to the zoopagalean tree further confirms the finding that molecular data do not support the traditional classification of the Zoopageles.     

Molecular phylogeny of truffles (Pezizales: Terfeziaceae, Tuberaceae) derived from nuclear rDNA sequence analysis.

Extensive morphological convergence or divergence, a common occurrence in fungi, tends to obscure recognition of phylogenetic relationships among Pezizales, widespread filamentous Ascomycetes with either enclosed underground (hypogeous) or exposed (epigeous) fruit bodies, that often establish mutualistic interactions with arboreous plants. Focusing on hypogeous Pezizales commonly known as truffles, we sequenced the 18S rDNA from nine species belonging to three different families (Tuberaceae, Terfeziaceae, and Balsamiaceae). A data set consisting of 1700 secondary structure-aligned sites, including 24 homologous sequences from the GenBank DNA database and using three reconstruction methods, was employed to infer phylogenies in an interval ranging from the subordinal to the subgeneric level. As revealed by the 18S phylogenetic scheme, Balsamiaceae represent a monophyletic clade, comprising the hypogeous taxa Balsamia and Barssia, nested within Helvellaceae. Similarly, the terfeziacean genera Pachyphloeus and Terfezia constitute together with Cazia a distinct hypogeous clade nested within Pezizaceae. The lack of clustering between Terfezia arenaria and Terfezia terfezioides strongly supports the reassignment of the latter taxon to the original monotypic genus Mattirolomyces. Within Tuberaceae, which are sister to the highly evolved Helvellaceae, the genus Tuber cannot be considered monophyletic if Choiromyces is recognized. The paraphyly of Tuber and other relationships that were not supported by high bootstrap values, nor corroborated by morphological evidence, were supported by a parallel analysis of the faster evolving internal transcribed spacer (ITS) rDNA. Distinct episodes of fruit body morphology shifts are discernable in the 18S rDNA phylogenetic tree. In all cases, the shift from an epigeous to a hypogeous form is the most parsimonious interpretation of character transformation, without any instance of character reversal.     

Phylogenetic relationships of land plants using mitochondrial small-subunit rDNA sequences

Phylogenetic relationships among embryophytes (tracheophytes, mosses, liverworts, and hornworts) were examined using 21 newly generated mitochondrial small-subunit (19S) rDNA sequences. The "core" 19S rDNA contained more phylogenetically informative sites and lower homoplasy than either nuclear 18S or plastid 16S rDNA. Results of phylogenetic analyses using parsimony (MP) and likelihood (ML) were generally congruent. Using MP, two trees were obtained that resolved either liverworts or hornworts as the basal land plant clade. The optimal ML tree showed hornworts as basal. That topology was not statistically different from the two MP trees, thus both appear to be equally viable evolutionary hypotheses. High bootstrap support was obtained for the majority of higher level embryophyte clades named in a recent morphologically based classification, e.g., Tracheophyta, Euphyllophytina, Lycophytina, and Spermatophytata. Strong support was also obtained for the following monophyletic groups: hornworts, liverworts, mosses, lycopsids, leptosporangiate and eusporangiate ferns, gymnosperms and angiosperms. This molecular analysis supported a sister relationship between Equisetum and leptosporangiate ferns and a monophyletic gymnosperms sister to angiosperms. The topologies of deeper clades were affected by taxon inclusion (particularly hornworts) as demonstrated by jackknife analyses. This study represents the first use of mitochondrial 19S rDNA for phylogenetic purposes and it appears well-suited for examining intermediate to deep evolutionary relationships among embryophytes.     

从18SrDNA序列初探散胞盘菌亚科属间亲缘关系

散胞盘菌亚科Encoelioideae建于1932年,为盘菌纲Discomycetes锤舌菌目Leotiales锤舌菌科（广义）Leotiaceae的成员,它包括腐生、植物寄生、真菌上生的盘状子囊菌,现含18属,其中若干为单种属。传统分类从形态学角度将外囊盘表层细胞松散结合或者表面覆盖短的菌丝延伸物视为此亚科的主要特征,宏观上,其成员的共性表现为外囊盘被表面糠皮状、鳞屑状或霜状。迄今,学者们从未对散孢盘菌亚科这一性状是否反映属间亲缘关系进行过任何探讨,国际基因库中亦无此亚科的可利用序列。为了探明此性状在系统演化过程中的作用以及散胞盘菌亚科的属间亲缘关系,我们对此亚科中绿散胞盘菌Chlorencoelia、复柄盘菌属Cordierites、散胞盘菌属Encoelia、霍氏盘菌属Holwaya、拟爪毛盘菌属Unguiculariopsis、 以及丝绒盘菌属Velutarina代表种的18S rDNA片段进行了序列测定,受实验材料所限,每属只获得了一个种的18S rDNA序列。为了分析和比较,还对同一科内锤舌菌亚科Leotioideae中绿杯菌属Chlorociboria一个种的相关序列进行了测定。在构建系统树的过程中,核盘菌科的核盘菌Sclerotinia sclerotiorum被选为外群;从基因库中调入属于同一个目的地舌菌科和锤舌菌亚科几个属的代表即胶鼓菌属Bulgaria、锤舌菌属Leotia、?     

Phylogenetic relationships of the enigmatic angiosperm family Podostemaceae inferred from 18S rDNA and rbcL sequence data

The phylogenetic relationships of some angiosperm families have remained enigmatic despite broad phylogenetic analyses of rbcL sequences. One example is the aquatic family Podostemaceae, the relationships of which have long been controversial because of major morphological modifications associated with their aquatic habit. Podostemaceae have variously been associated with Piperaceae, Nepenthaceae, Polygonaceae, Caryophyllaceae, Scrophulariaceae, Rosaceae, Crassulaceae, and Saxifragaceae. Two recent analyses of rbcL sequences suggest a possible sister-group relationship of Podostemaceae to Crassulaceae (Saxifragales). However, the branch leading to Podostemaceae was long, and use of different outgroups resulted in alternative placements. We explored the phylogenetic relationships of Podostemaceae using 18S rDNA sequences and a combined rbcL + 18S rDNA matrix representing over 250 angiosperms. In analyses based on 18S rDNA data, Podostemaceae are not characterized by a long branch; the family consistently appears as part of a Malpighiales clade that also includes Malpighiaceae, Turneraceae, Passifloraceae, Salicaceae, Euphorbiaceae, Violaceae, Linaceae, Chrysobalanaceae, Trigoniaceae, Humiriaceae, and Ochnaceae. Phylogenetic analyses based on a combined 18S rDNA + rbcL data set (223 ingroup taxa) with basal angiosperms as the outgroup also suggest that Podostemaceae are part of a Malpighiales clade. These searches swapped to completion, and the shortest trees showed enhanced resolution and increased internal support compared to those based on 18S rDNA or rbcL alone. However, when Gnetales are used as the outgroup, Podostemaceae appear with members of the nitrogen fixing clade (e.g., Elaeagnaceae, Ulmaceae, Rhamnaceae, Cannabaceae, Moraceae, and Urticaceae). None of the relationships suggested here for Podostemaceae receives strong bootstrap support. Our analyses indicate that Podostemaceae are not closely allied with Crassulaceae or with other members of the Saxifragales clade; their closest relatives, although still uncertain, appear to lie elsewhere in the rosids.     

Phylogenetic relationships among ascomycetes: evidence from an RNA polymerse II subunit

In an effort to establish a suitable alternative to the widely used 18S rRNA system for molecular systematics of fungi, we examined the nuclear gene RPB2, encoding the second largest subunit of RNA polymerase II. Because RPB2 is a single-copy gene of large size with a modest rate of evolutionary change, it provides good phylogenetic resolution of Ascomycota. While the RPB2 and 18S rDNA phylogenies were highly congruent, the RPB2 phylogeny did result in much higher bootstrap support for all the deeper branches within the orders and for several branches between orders of the Ascomycota. There are several strongly supported phylogenetic conclusions. The Ascomycota is composed of three major lineages: Archiascomycetes, Saccharomycetales, and Euascomycetes. Within the Euascomycetes, plectomycetes, and pyrenomycetes are monophyletic groups, and the Pleosporales and Dothideales are distinct sister groups within the Loculoascomycetes. We confirm the placement of Neolecta within the Archiascomycetes, suggesting that fruiting body formation and forcible discharge of ascospores were characters gained early in the evolution of the Ascomycota. These findings show that a slowly evolving protein-coding gene such as RPB2 is useful for diagnosing phylogenetic relationships among fungi.     

Phylogenetic investigations of the stephanoberyciformes and beryciformes, particularly whalefishes (Euteleostei: Cetomimidae), based on partial 12S rDNA and 16S rDNA sequences

DNA data were collected from a number of acanthomorph fishes for 12S rDNA (30 sequences) and 16S rDNA (39 sequences) to investigate the phylogenetic relationships of genera within Cetomimidae (whalefishes) and of this family within the Stephanoberyciformes/Beryciformes assemblage. The Cetomimidae are apparently monophyletic. Within the family, species of Gyrinomimus and Cetomimus form a clade but the former genus is paraphyletic with respect to the latter. Cetostoma is sister to Ditropichthys rather than to Gyrinomimus plus Cetomimus as suggested by morphological analyses. Rondeletiidae + Cetomimidae + Barbourisiidae are shown, as expected from morphological analyses, as a monophyletic group in the 12S rDNA analyses, but not in the 16S rDNA or combined analyses, although the shortest trees showing the group require only one extra step in each case. These three families plus Melamphaidae (our sample of Stephanoberyciformes) are not shown as a group in any analysis, with Melamphaidae being sister to Berycidae in the 16S and combined analyses, but dispersed in the 12S analyses. Maximum-parsimony trees without imposed constraints are notably shorter than trees constrained to show ordinal groupings or either of the two main current hypotheses of Stephanoberyciformes/Beryciformes relationships. The length difference is highly significant for most comparisons using either 12S or 16S rDNA sets or their combination, and significant or nearly so for all comparisons. In particular, the Beryciformes is unlikely to be monophyletic. The Holocentridae are included, with high bootstrap and Bremer support, in a clade of non-beryciforms comprising the Gempylidae, Zeidae, and Atheriniformes (the only higher acanthomorphs sampled) and not with other Beryciform families. In these data, the Berycidae are the sister to the Melamphaidae, a stephanoberyciform family.     

Phylogenetic position of the adeleorinid coccidia (Myzozoa, Apicomplexa, Coccidia, Eucoccidiorida, Adeleorina) inferred using 18S rDNA sequences

Investigating the evolutionary relationships of the major groups of Apicomplexa remains an important area of study. Morphological features and host-parasite relationships continue to be important in the systematics of the adeleorinid coccidia (suborder Adeleorina), but the systematics of these parasites have not been well-supported or have been constrained by data that were lacking or difficult to interpret. Previous phylogenetic studies of the Adeleorina have been based on morphological and developmental characters of several well-described species or based on nuclear 18S ribosomal DNA (rDNA) sequences from taxa of limited taxonomic diversity. Twelve new 18S rDNA sequences from adeleorinid coccidia were combined with published sequences to study the molecular phylogeny of taxa within the Adeleorina and to investigate the evolutionary relationships of adeleorinid parasites within the Apicomplexa. Three phylogenetic methods supported strongly that the suborder Adeleorina formed a monophyletic clade within the Apicomplexa. Most widely recognized families within the Adeleorina were hypothesized to be monophyletic in all analyses, although the single Hemolivia species included in the analyses was the sister taxon to a Hepatozoon sp. within a larger clade that contained all other Hepatozoon spp. making the family Hepatozoidae paraphyletic. There was an apparent relationship between the various clades generated by the analyses and the definitive (invertebrate) host parasitized and, to lesser extent, the type of intermediate (vertebrate) host exploited by the adeleorinid parasites. We conclude that additional taxon sampling and use of other genetic markers apart from 18S rDNA will be required to better resolve relationships among these parasites.     

从18S rDNA序列初探散胞盘菌亚科属间亲缘关系

散胞盘菌亚科Encoelioideae建于1932年,为盘菌纲Discomycetes锤舌菌目Leotiales锤舌菌科（广义）Leotiaceae的成员,它包括腐生、植物寄生、真菌上生的盘状子囊菌,现含18属,其中若干为单种属。传统分类从形态学角度将外囊盘表层细胞松散结合或者表面覆盖短的菌丝延伸物视为此亚科的主要特征,宏观上,其成员的共性表现为外囊盘被表面糠皮状、鳞屑状或霜状。迄今,学者们从未对散孢盘菌亚科这一性状是否反映属间亲缘关系进行过任何探讨,国际基因库中亦无此亚科的可利用序列。为了探明此性状在系统演化过程中的作用以及散胞盘菌亚科的属间亲缘关系,我们对此亚科中绿散胞盘菌Chlorencoelia、复柄盘菌属Cordierites、散胞盘菌属Encoelia、霍氏盘菌属Holwaya、拟爪毛盘菌属 Unguiculariopsis、以及丝绒盘菌属Velutarina代表种的18SrDNA片段进行了序列测定,受实验材料所限,每属只获得了一个种的18SrDNA序列。为了分析和比较,还对同一科内锤舌菌亚科Leotioideae中绿杯菌属Chlorociboria一个种的相关序列进行了测定。在构建系统树的过程中,核盘菌科的核盘菌Sclerotiniasclerotiorum被选为外群;从基因库中调入属于同一个目的地舌菌科和锤舌菌亚科几个属的代表即胶鼓菌属Bulgaria、锤舌菌属Leotia、小舌菌属Microglossum、新胶鼓菌属Neobulgaria和地勺菌属Spathularia的序列;利用ClustalW和TreeView软件,构建出Neighbour-joining系统进化树。初步的研究结果表明,散孢盘菌亚科不是单源的,该亚科的成员与其他亚科或者其他科的物种一起形成四个系统演化分支。散胞盘菌亚科的Holwaya与另一亚科的Bulgaria（Leotiaceae,Leotioideae）聚在一起,具有95%的序列相似性和97.4%支持率（bootstrapvalue）;此二属与Leotia（Leotiaceae,Leotioideae）和Microglossum（Geoglossaceae）组成姐妹群。散胞盘菌亚科Cordierites和Encoelia接近,支持率为93.6%;它们是Leotioideae中Chlorociboria和Neobulgaria两属的姐妹群。散胞盘菌亚科的Unguiculariopsis与Velutarina在一起,独立成为一个分支,支持率高达99.3%。Chlorencoelia与本研究所涉及的散胞盘菌亚科其他成员的关系都比较远。以上研究结果表明,散胞盘菌亚科很可能是多源的;但是,由于该亚科大多数属缺乏分子生物学证据,本研究结果只能作为推断。     

The phylogeny of termites (Dictyoptera: Isoptera) based on mitochondrial and nuclear markers: Implications for the evolution of the worker and pseudergate castes, and foraging behaviors

A phylogenetic hypothesis of termite relationships was inferred from DNA sequence data. Seven gene fragments (12S rDNA, 16S rDNA, 18S rDNA, 28S rDNA, cytochrome oxidase I, cytochrome oxidase II and cytochrome b) were sequenced for 40 termite exemplars, representing all termite families and 14 outgroups. Termites were found to be monophyletic with Mastotermes darwiniensis (Mastotermitidae) as sister group to the remainder of the termites. In this remainder, the family Kalotermitidae was sister group to other families. The families Kalotermitidae, Hodotermitidae and Termitidae were retrieved as monophyletic whereas the Termopsidae and Rhinotermitidae appeared paraphyletic. All of these results were very stable and supported with high bootstrap and Bremer values. The evolution of worker caste and foraging behavior were discussed according to the phylogenetic hypothesis. Our analyses suggested that both true workers and pseudergates (“false workers”) were the result of at least two different origins. Our data support a traditional hypothesis of foraging behavior, in which the evolutionary transition from a one-piece type to a separate life type occurred through an intermediate behavioral form.     

Is 16S rDNA a Reliable Phylogenetic Marker to Characterize Relationships Below the Family Level in the Enterobacteriaceae?

The phylogenetic relationships of multiple enterobacterial species were reconstructed based on 16S rDNA gene sequences to evaluate the robustness of this housekeeping gene in the taxonomic placement of the enteric plant pathogens Erwinia, Brenneria, Pectobacterium, and Pantoea. Four data sets were compiled, two of which consisted of previously published data. The data sets were designed in order to evaluate how 16S rDNA gene phylogenies are affected by the use of different plant pathogen accessions and varying numbers of animal pathogen and outgroup sequences. DNA data matrices were analyzed using maximum likelihood (ML) algorithms, and character support was determined by ML bootstrap and Bayesian analyses. As additional animal pathogen sequences were added to the phylogenetic analyses, taxon placement changed. Further, the phylogenies varied in their placement of the plant pathogen species, and only the genus Pantoea was monophyletic in all four trees. Finally, bootstrap and Bayesian support values were low for most of the nodes, and all nonterminal branches collapsed in strict consensus trees. Inspection of 16S rDNA nucleotide alignments revealed several highly variable blocks punctuated by regions of conserved sequence. These data suggest that 16S rDNA, while effective for both species-level and family-level phylogenetic reconstruction, may underperform for genus-level phylogenetic analyses in the Enterobacteriaceae.     

Phylogenetic analysis of the subclass Pteriomorphia (Bivalvia) from mtDNA COI sequences

Phylogenetic relationships within the subclass Pteriomorphia (Bivalvia) were examined using sequences of the mitochondrial cytochrome c oxidase subunit I gene. The resultant Minimum Evolution phylogenetic tree strongly supports the existing superfamily-level classification with all the members of each superfamily forming clades. At the same time, it is suggested that: (1) Ostreoidea shows a closer relationship to Pinnoidea and Pterioidea than to the other superfamilies; (2) Pectinoidea, Anomioidea, and Limoidea form a clade, (3) Arcoidea and Limopsoidea form a clade; (4) The subclass Anomalodesmata is closer to the subclass Heterodonta than to Mytiloidea; and (5) The subclass Pteriomorphia is monophyletic. Taking these results as well as published data for nuclear 18S ribosomal DNA (18S rDNA) and Myosin analyses into consideration, a new order-level classification system for Pteriomorphia is proposed.     

Phylogeny of Stephanomeria and related genera (compositae-lactuceae) based on analysis of 18S-26S nuclear rDNA ITS and ETS sequences

A phylogenetic analysis of DNA sequences from the internal transcribed spacer (ITS), the external transcribed spacer (ETS), and the 5.8S regions of 18S-26S nuclear rDNA from all diploid species of Stephanomeria and related genera shows that Stephanomeria does not include either Munzothamnus blairii (previously S. blairii) or Pleiacanthus spinosus (previously S. spinosa). Without these two taxa, Stephanomeria is a well-supported (100% bootstrap), monophyletic group of ten perennial and six annual species. Munzothamnus blairii and Pleiacanthus spinosus, both now considered members of monotypic genera, had been placed in Stephanomeria primarily because they have the same chromosome number as Stephanomeria and similar pollen surface features, but many disparities were ignored in previous classifications. Within Stephanomeria, an unsuspected sister relationship was detected between the montane S. lactucina and coastal S. cichoriacea. A second clade contained all the annual taxa and five of the perennial species. Among the annuals, strong bootstrap support was obtained for the previously recognized relationships between S. diegensis and S. exigua (98%) and between S. malheurensis and its progenitor, S. exigua subsp. coronaria (96%). Among the five perennial species that constitute a clade with the annuals, the recently described S. fluminea was shown to be sister to S. runcinata, and both of them were closely allied to S. tenuifolia and S. thurberi. The clade including the annuals (and five of the perennial species) was subtended by perennial lineages and pairwise divergence values among the annual taxa were much lower than among the perennial taxa as a group (though not too different than among the perennials in the same clade). The annuals probably originated recently within the genus.     

Phylogenetic position of Eimeria antrozoi, a bat coccidium (Apicomplexa: Eimeriidae) and its relationship to morphologically similar Eimeria spp. from bats and rodents based on nuclear 18S and plastid 23S rDNA sequences.

Partial plastid 23S and nuclear 18S rDNA genes were amplified and sequenced from 2 morphologically similar Eimeria species. E. antrozoi from a bat (Antrozous pallidus) and E. arizonensis from deer mice (Peromyscus spp.), as well as some other Eimeria species from bats and rodents. The phylogenetic trees clearly separated E. antrozoi from E. arizonensis. The phylogenies based on plastid 23S rDNA data and combined data of both plastid and nuclear genes grouped 2 bat Eimeria and 3 morphologically similar Eimeria species from rodents into 2 separate clades with high bootstrap support (100%, 3 rodent Eimeria species; 72-97%, 2 bat Eimeria species), which supports E. antrozoi as a valid species. The rodent Eimeria species did not form a monophyletic group. The 2 bat Eimeria species formed a clade with the 3 morphologically similar rodent Eimeria species (E. arizonensis, E. albigulae, E. onychomysis, all from cricetid rodents) with 100% bootstrap support, whereas 2 other rodent Eimeria species (E. nieschulzi, E. falciformis, from murid rodents) formed a separate clade with 100% bootstrap support. This suggests that the 2 Eimeria species from bats might be derived from rodent Eimeria species and may have arisen as a result of lateral host transfer between rodent and bat hosts.     

Phylogenetic relationships of the carabid subfamily Harpalinae (Coleoptera) based on molecular sequence data

The carabid subfamily Harpalinae contains most of the species of carabid beetles. This subfamily, with over 19,000 species, radiated in the Cretaceous to yield a large clade that is diverse in morphological form and ecological habit. While there are several morphological, cytological, and chemical characters that unite most harpalines, the placement of some tribes within the subfamily remains controversial, as does the sister group relationships to this large group. In this study, DNA sequences from the 28S rDNA gene and the wingless nuclear protein-coding gene were collected from 52 carabid genera representing 31 harpaline tribes in addition to more than 21 carabid outgroup taxa to reconstruct the phylogeny of this group. Molecular sequence data from these genes, along with additional data from the 18S rDNA gene, were analyzed with a variety of phylogenetic analysis methods, separately for each gene and in a combined data approach. Results indicated that the subfamily Harpalinae is monophyletic with the enigmatic tribes of Morionini, Peleciini, and Pseudomorphini included within it. Brachinine bombardier beetles are closely related to Harpalinae as they form the sister group to harpalines or, in some analyses, are included within it or with austral psydrines. The austral psydrines are the sister group to Harpalinae+Brachinini clade in most analyses and austral psydrines+Brachinini+Harpalinae clade is strongly supported.     

Phylogeny of the nuthatches of the Sitta canadensis group and its evolutionary and biogeographic implications

A phylogeny of ten species of nuthatch (Sittidae), including the newly described Kabylie Nuthatch Sitta ledanti of North Africa, was constructed using a sequence of 491 bp of the cytochrome-b gene of mtDNA. On the basis of trees derived using parsimony analysis and neighbour-joining methods, and assessments of robustness based on bootstrap analysis, the following phylogenetic relationships were inferred: the five species of the Sitta canadensis group are a monophyletic group, within which S. canadensis, S. whiteheadi and S. villosa form the sister clade of S. krueperi and S. ledanti; the other relations are not so well supported. These phylogenetic relationships are congruent with morphology. Differences in behavioural and ecological characters as well as biogeographic patterns are discussed.     

Urochordates are monophyletic within the deuterostomes

Understanding the phylogenetic relationships of the three major urochordate groups within the deuterostomes is central to understanding the evolution of the chordates. We have prepared a detailed phylogenetic analysis of urochordates based on comparisons of 10 new urochordate 18S ribosomal DNA sequences with other urochordate sequences in GenBank. Maximum parsimony, neighbor-joining, minimum evolution, and maximum likelihood analyses of this large urochordate data set are consistent with a topology in which the urochordates are monophyletic within the deuterostomes and there are four separate clades of urochordates. These four distinct clades--styelid + pyurid ascidians, molgulid ascidians, phlebobranch ascidians + thaliaceans, and larvaceans--are mostly consistent with traditional morphological hypotheses and classifications. However, we find that the ascidians may not be a monophyletic group (as they have been considered traditionally) but instead appear paraphyletic. Another disparity with traditional classification is that the thaliaceans do not form a separate urochordate clade but rather cluster with the phlebobranch ascidians. Larvaceans have long branch lengths, which can be problematic for molecular phylogenetic methods, and their position within the urochordates cannot be unequivocally determined with 18S rDNA. This is important because the tadpole morphology of larvacean and ascidian larvae is the key trait of interest that distinguishes urochordates as chordates. Nevertheless, the present data set resolves at least three clades of urochordates and suggests strongly that urochordates form a monophyletic clade within the deuterostomes.     

Molecular phylogeny of Zygomycota based on EF-1alpha and RPB1 sequences: limitations and utility of alternative markers to rDNA

Earlier molecular phylogenetic analyses based on nuclear small subunit ribosomal DNA (nSSU rDNA) suggest that the Zygomycota are polyphyletic within the Chytridiomycota. However, these analyses failed to resolve almost all interordinal relationships among basal fungi (Chytridiomycota and Zygomycota), due to lack of sufficient characters within the nSSU rDNA. To further elucidate the higher-level phylogeny of Zygomycota, we have sequenced partial RPB1 (DNA dependent RNA polymerase II largest subunit) and EF-1alpha (translation elongation factor 1 alpha) genes from 10 and 3 zygomycete fungi, respectively. Independent molecular phylogenetic analyses were performed based on each sequence by distance and maximum likelihood methods. Although deep phylogenetic relationships among basal fungi still remain poorly resolved using either gene, the RPB1-based phylogeny identified a novel monophyletic clade consisting of the Dimargaritales, Harpellales, and Kickxellales. This result suggests that regularly formed septa (cross walls that divide hyphae into segments) with a lenticular cavity are plesiomorphic for this clade, and indicates the importance of septal pore ultrastructure in zygomycete phylogeny. In addition, a peculiar mucoralean genus Mortierella, which was considered to be distantly related to the other Mucorales based on previous nSSU rDNA analyses, was resolved as the basal most divergence within the Mucorales, consistent with traditional phenotypic-based taxonomy. Although the taxa included in our analysis are restricted, the monophyly of each order suggested by nSSU rDNA phylogeny is supported by the present RPB1-based analysis. These results support the potential use of RPB1 as an alternative marker for fungal phylogenetic studies. Conversely, the overall fungal phylogeny based on EF-1alpha sequence is poorly resolved. A comparison of numbers of observed substitutions versus inferred substitutions within EF-1alpha indicates that this gene is much more saturated than RPB1. This result suggests that the EF-1alpha gene is unsuitable for resolving higher-level phylogenetic relationships within the Fungi.     

Phylogeny of Capitata and Corynidae (Cnidaria, Hydrozoa) in light of mitochondrial 16S rDNA data

New sequences of the partial rDNA gene coding for the mitochondrial large ribosomal subunit, 16S, are derived from 47 diverse hydrozoan species and used to investigate phylogenetic relationships among families of the group Capitata and among species of the capitate family Corynidae. Our analyses identify a well-supported clade, herein named Aplanulata, of capitate hydrozoans that are united by the synapomorphy of undergoing direct development without the ciliated planula stage that is typical of cnidarians. Aplanulata includes the important model organisms of the group Hydridae, as well as species of Candelabridae, Corymorphidae, and Tubulariidae. The hypothesis that Hydridae is closely related to brackish water species of Moerisiidae is strongly controverted by 16S rDNA data, as has been shown for nuclear 18S rDNA data. The consistent phylogenetic signal derived from 16S and 18S data suggest that both markers would be useful for broad-scale multimarker analyses of hydrozoan relationships. Corynidae is revealed as paraphyletic with respect to Polyorchidae, a group for which information about the hydroid stage is lacking. Bicorona , which has been classified both within and outside of Corynidae, is shown to have a close relationship with all but one sampled species of Coryne . The corynid genera Coryne , Dipurena , and Sarsia are not revealed as monophyletic, further calling into question the morphological criteria used to classify them. The attached gonophores of the corynid species Sarsia lovenii are confirmed as being derived from an ancestral state of liberated medusae. Our results indicate that the 16S rDNA marker could be useful for a DNA-based identification system for Cnidaria, for which it has been shown that the commonly used cytochrome c oxidase subunit 1 gene does not work.     

速足目主要类群系统发育的分子证据

文章基于速足目现生主要类群18S rDNA、28S rDNA和COI基因序列,采用贝叶斯法、邻接法和最大简约法,尝试构建速足目的分子系统树;结合形态特征和化石记录,主要对速足目各超科级分类阶元的系统发育关系进行探讨。结果表明,速足目现生超科Bairdiacea、Darwinulacea、Cypridacea和Cytheracea均为单系群,支持形态学上关于上述4个超科的的界定;3种基因均支持形态学上Darwinulacea和Cypridacea具有较近的亲缘关系的观点。18S rDNA序列分析在较显著水平上支持Darwinulacea和Bairdiacea为姐妹群,Darwinulacea可能从Bairdia-cea中的一支演化而来;Bairdiacea和Darwinulacea组成的分支是Cypridacea的姐妹群,支持将三者合并为Bairdio-copina亚目的观点;Cytheracea是Cypridacea(Darwinulacea Bairdiacea)的姐妹群,可提升为Cytheracopina亚目。