Phylogenetic inference regarding Parergodrilidae and Hrabeiella periglandulata ('Polychaeta', Annelida) based on 18S rDNA, 28S rDNA and COI sequences

Parergodrilidae and Hrabeiella periglandulata are Annelida showing different combinations of clitellate-like and aclitellate characters. Similarities between both of these taxa and Clitellata have widely been regarded as the result of convergent evolution due to similar selection pressures. The position of the three taxa in the phylogenetic system of Annelida is still in debate. However, in analyses based on 18S rDNA sequences a close relationship of Parergodrilidae with Orbiniidae and Questidae was suggested. To infer their phylogeny the sequences of the 28S rDNA and of the cytochrome oxidase I (COI) gene of Stygocapitella subterranea , Parergodrilus heideri and H. periglandulata were determined. The data were extended by sequences of various species including species from Clitellata and Orbiniidae. Prior to tree reconstruction the dataset was analysed in detail for phylogenetic content by applying a sliding window analysis, a likelihood mapping and Modeltest V.3.04. Subsequently, generalized parsimony and maximum likelihood methods were employed. Clade robustness was estimated by bootstrapping. In addition, combined analyses of the sequences of 18S rDNA and 28S rDNA as well as of 18S rDNA, 28S rDNA and COI were performed. The combination of the data of the two structure genes and a mitochondrial gene improved the resolution obtained with the single datasets slightly. These analyses support a close relationship of Parergodrilidae and Orbiniidae but cannot resolve the position of H. periglandulata . In every analysis Clitellata cluster within 'Polychaeta', confirming previous investigations.     

Molecular systematics of the Kakaducarididae (Crustacea: Decapoda: Caridea)

The systematic relationships of the freshwater shrimp family, Kakaducarididae, were examined using mitochondrial and nuclear DNA sequences. Combined nuclear (18S rDNA, 28S rDNA, Histone) and mitochondrial (16S rDNA) analyses placed the kakaducaridid genera, Kakaducaris and Leptopalaemon, as a strongly supported clade within the Palaemonidae, in a close relationship with the genus Macrobrachium. Monophyly of the Australian Kakaducarididae was strongly supported by the molecular data. Estimated net divergence times between Kakaducaris and Leptopalaemon using mitochondrial 16S rDNA equate to a late Miocene/Pliocene split. Within Leptopalaemon, each locality was distinct for mitochondrial COI haplotypes, suggesting long-term isolation or recent genetic bottlenecks, a lack of contemporary gene flow amongst sites and a small Ne. Mitochondrial groupings within Leptopalaemon were largely congruent with several previously recognised morphotypes. Estimated net divergence times between L. gagadjui and the new Leptopalaemon morphotypes equate to a split in the late Pliocene/early Pleistocene. The hypothesis that the Kakaducarididae is comprised of relict species in specialised ecological niches is not supported by the molecular data, which instead suggest a relatively recent origin for the group in northern Australia, sometime in the late Miocene or Pliocene.     

Phylogenetic relationships among Acanthamoeba spp. based on PCR-RFLP analyses of mitochondrial small subunit rRNA gene.

We investigated the value of mitochondrial small subunit rRNA gene (mt SSU rDNA) PCR-RFLP as a taxonomic tool for Acanthamoeba isolates with close inter-relationships. Twenty-five isolates representing 20 species were included in the analysis. As in nuclear 18S rDNA analysis, two type strains (A. astronyxis and A. tubiashi) of morphological group 1 diverged earliest from the other strains, but the divergence between them was less than in 18S riboprinting. Acanthamoeba griffini of morphological group 2 branched between pathogenic (A. culbertsoni A-1 and A. healyi OC-3A) and nonpathogenic (A. palestinensis Reich, A. pustulosa GE-3a, A. royreba Oak Ridge, and A lenticulata PD2S) strains of morphological group 3. Among the remaining isolates of morphological group 2, the Chang strain had the identical mitochondrial riboprints as the type strain of A. hatchetti. AA2 and AA1, the type strains of A. divionensis and A. paradivionensis, respectively, had the identical riboprints as A. quina Vil3 and A. castellanii Ma. Although the branching orders of A. castellanii Neff, A. polyphaga P23, A. triangularis SH621, and A. lugdunensis L3a were different from those in 18S riboprinting analysis, the results obtained from this study generally coincided well with those from 18S riboprinting. Mitochondrial riboprinting may have an advantage over nuclear 18S rDNA riboprinting because the mt SSU rDNAs do not seem to have introns that are found in the 18S genes of Acanthamoeba and that distort phylogenetic analyses.     

基因序列在蚜虫分子系统发育研究中的应用

总结了核基因和线粒体基因在半翅目蚜虫分子系统发育研究中的应用。核基因中EF-1α应用最广泛,适用于探讨属级及属以上的问题; 核rDNA在蚜虫中应用较少,18S rDNA适用于探讨科级以上高级阶元的问题;LWO是新近在蚜虫中开发使用的一个新基因。线粒体基因中,COⅠ/COⅡ使用最多,12S rDNA/16S rDNA、ND1、Cyt b以及F-ATP6均有应用,探讨的问题从属、种级到科级不等。核基因和线粒体基因间以及不同线粒体基因间的联合分析在解决不同层次的问题中均有应用。建议不断尝试新基因以找出适合蚜虫类群的“标准基因”。并对未来蚜虫分子系统发育研究趋势进行了展望。     

Molecular phylogeny of leeches: Congruence of nuclear and mitochondrial rDNA data sets and the origin of bloodsucking

Complete 18S rDNA sequences and sequences of domain III of mitochondrial 12S rDNA were obtained to assess phylogenetic relationships among major suprageneric taxa of leeches and the possibly closely related clitellate taxa Branchiobdellida and Acanthobdellida. The monophyly of the families Erpobdellidae, Piscicolidae, and Glossiphoniidae, the suborders Erpobdelliformes and Hirudiniformes, and the order Arhynchobdellida have been confirmed by parsimony and maximum likelihood phylogenetic analysis of separate and combined data sets. Both the nuclear 18S rDNA sequences and the mitochondrial 12S rDNA sequences were consistent in not supporting a monophyletic order Rhynchobdellida, represented by the families Piscicolidae and Glossiphoniidae. A topology with the Piscicolidae as the first branch in the leech tree followed by the Glossiphoniidae received the highest support in terms of taxonomic, character, and outgroup congruence. According to this topology, the putative apomorphies of the Rhynchobdellidae (e.g. the proboscis) can be parsimoniously explained as plesiomorphies already present in the ancestral leech. This common ancestor was probably a bloodsucking leech with a proboscis rather than an unspecialized ectocommensal, as suggested by previous hypotheses. During the course of leech evolution, a reduction of the proboscis could have taken place in predatory arhynchobdellid ancestors to enable swallowing of larger prey. A second gain of sanguivory by the jawed Hirudiniformes could have been facilitated by pre-adaptations to ectoparasitic blood feeding. The 18S rDNA analysis further indicates a close relationship between the clitellate groups Branchiobdellida and Acanthobdellida, although this relationship is not strongly supported.     

Bryophyte 5S rDNA was inserted into 45S rDNA repeat units after the divergence from higher land plants

The 5S ribosomal RNA genes (5S rDNA) are located independently from the 45S rDNA repeats containing 18S, 5.8S and 26S ribosomal RNA genes in higher eukaryotes. Southern blot and fluorescence in situ hybridization analyses demonstrated that the 5S rDNAs are encoded in the 45S rDNA repeat unit of a liverwort, Marchantia polymorpha, in contrast to higher plants. Sequencing analyses revealed that a single-repeat unit of the M. polymorpha nuclear rDNA, which is 16103 bp in length, contained a 5S rDNA downstream of 18S, 5.8S and 26S rDNA. To our knowledge, this is the first report on co-localization of the 5S and 45S rDNAs in the rDNA repeat of land plants. Furthermore, we detected a 5S rDNA in the rDNA repeat of a moss, Funaria hygrometrica, by a homology search in a database. These findings suggest that there has been structural re-organization of the rDNAs after divergence of the bryophytes from the other plant species in the course of evolution.     

Suitability of chloroplast LSU rDNA and its diverse group I introns for species recognition and phylogenetic analyses of lichen-forming Trebouxia algae

To date, species identification of lichen photobionts has been performed principally on the basis of microscopic examinations and molecular data from nuclear-encoded genes. In plants, the chloroplast genome has been more readily exploited than the nuclear genome for systematic investigations. At the present time, very little information is available about the chloroplast genome of lichen-forming algae. For this reason, we have sequenced a portion of the gene encoding for the chloroplast large sub-unit rRNA (LSU rDNA) as a new molecular marker. Sequencing of the chloroplast LSU rDNAs revealed the existence of an unusual diversity of group I introns (a total of 31) within 15 analyzed Trebouxia species. The number, sequence and insertion site of these introns were very different among species, contributing to their recognition. A relatively large intron-free portion of the chloroplast LSU rDNA and part of the nuclear ribosomal cistron (18S–5.8S–26S) between the nuclear internal transcribed spacers (nrITS) were subjected to phylogenetic analyses. The obtained results indicate that data combination from both nuclear and chloroplast sequences can improve phylogenetic accuracy. Herein, we propose the suitability of both intronic and exonic sequences of the chloroplast LSU rDNA for species recognition, and an exonic sequence spanning from position 879 to 1837 in the Escherichia coli 23S rDNA for phylogenetic analyses of Trebouxia phycobionts.     

蓖麻蚕18S rRNA基因3′末端的顺序特征

本文测定了蓖麻蚕18S rRNA基因(rDNA) 3′末端及其外侧的DNA顺序。将这一顺序与家蚕、果蝇、大鼠 18S rDNA 3′末端顺序以及大肠杆菌16 S rDNA 3′末端顺序作了比较,发现它们间有惊人的同源性。不仅如此,这些基因的3′末端所形成的茎环结构也十分相似,在3′末端还有保守的EcoRI切点。这些研究结果对了解18S rRNA 3′末端在蛋白质合成中的功能及在rRNA前体加工成熟中的作用;对于了解rRNA基因的进化打下了基础。     

Systematics of the subfamily Haplorchiinae (Trematoda: Heterphyidae), based on nuclear ribosomal DNA genes and ITS2 region

Phylogenetic relationships of 6 species in the trematode subfamily Haplorchiinae were analyzed using small and large subunit of ribosomal DNA genes (18S rDNA and 28S rDNA) and internal transcribed spacer subunit II (ITS2) region as molecular markers. Maximum Likelihood and Bayesian inference analyses of combined rDNAs and ITS2 indicated a close relationship between the genera Haplorchis and Procerovum, while these two genera were distinct from Stellantchasmus falcatus. These phylogenetic relationships were consistent with the number of testes but not with the characters of the modification of the seminal vesicle or of the ventral sucker. Although three Haplorchis spp. were, together with Procerovum, in the same cluster, their mutual topology was incongruent between rDNA and ITS2 trees. Phylogenetic analyses using other molecular markers with more species are necessary to work out solid phylogenetic relationships among the species in this subfamily.     

Phylogenetic relationships and biodiversity in Hylids (Anura: Hylidae) from French Guiana

We evaluated two biodiversity criteria, higher taxonomic diversity and phylogenetic diversity in French Guiana. For this, we used a recent assessment of the knowledge accumulated since 30 years of study on the amphibian species currently known in French Guiana. We focused on two well-represented genera, Hyla and Scinax, belonging to the subfamily Hylinae. We used partial sequences of two mitochondrial genes (16S rDNA and 12S rDNA, 813 bp) and two nuclear genes (tyrosinase and 18S rRNA, 1590 bp) covering a total of 2403 bp. According to the high bootstrap support in phylogenetic analysis of the complete dataset, the genus Scinax is a homophyletic clade formed by two species groups (rubra and rostrata) in French Guiana. The genus Hyla was confirmed to be a paraphyletic group formed by two species groups as well (30 chromosomes and the 'gladiator frogs'). We confirmed that these genera should be taxonomically reconsidered. Moreover, at the genus, subfamily and family levels, the use of only morphological characters or only molecular DNA markers would hamper estimations of biodiversity. Thus, we strongly advise the combined use of both morphology and molecular data (nuclear and mitochondrial markers).     

Secondary structure models of 18S and 28S rRNAs of the true bugs based on complete rDNA sequences of Eurydema maracandica Oshanin, 1871 (Heteroptera,?Pentatomidae)

The sequences of 18S and 28S rDNAs have been used as molecular markers to resolve phylogenetic relationships of Heteroptera for two decades. The complete sequences of 18S rDNAs have been used in many studies, while in most studies only partial sequences of 28S rDNAs have been used due to technical difficulties of amplifying the complete lengths. In this study, we amplified the complete 18S and 28S rDNA sequences of Eurydema maracandica Oshanin, 1871, and reconstructed the secondary structure models of the corresponding rRNAs. In addition, and more importantly, all of the length variable regions of 18S rRNA were compared among 37 families of Heteroptera based on 140 sequences, and the D3 region of 28S rRNA was compared among 51 families based on 84 sequences. It was found that 8 length variable regions could potentially serve as molecular synapomorphies for some monophyletic groups. Therefore discoveries of more molecular synapomorphies for specific clades can be anticipated from amplification of complete 18S and 28S rDNAs of more representatives of Heteroptera.     

The complete nucleotide sequence of a rice 17S rRNA gene.

The complete nucleotide sequence of a rice nuclear 17S rRNA gene (rDNA) has been determined. The rice rDNA is 1812 bp long and its G + C content is 51.3%. This nucleotide sequence shows 79%, 80% and 80% homology to those of yeast, Xenopus laevis and rat 18S rDNAs, respectively. Divergency of nucleotide sequences is largely attributed to five blocks of highly variable regions, where eukaryotic specific sequences can be observed.     

河南省西峡恐龙蛋化石DNA序列数据的再分析

利用ＩＮＴＥＲＮＥＴ网络上ＢＬＡＳＴ服务器和ＦＡＳＴＡ服务器程序对文献中发表的西峡县恐龙蛋化石的ＤＮＡ序列数据进行了序列数据库的类似性检索和分子系统学分析,证实克隆ＤＡ１８Ｓｌ和ＤＡ１８Ｓ７分别属于真菌和植物１８ＳｒＤＮＡ。文中还就在分子序列水平上对古ＤＮＡ的甄别与鉴定进行了讨论。     

The sister group relationship of Aeolosomatidae and Potamodrilidae (Annelida: “Polychaeta”) — a molecular phylogenetic approach based on 18S rDNA and cytochrome oxidase I

Aeolosomatidae and Potamodrilidae are small meiofauna annelids of apparently simple organization and uncertain phylogenetic position. Potamodrilidae was regarded either as a subtaxon of Aeolosomatidae, united with them as Aphanoneura, or entirely unrelated to Aeolosomatidae. Moreover, the groups have been placed in various positions within Annelida: as sister group of Clitellata, as a highly derived clitellate taxon, or excluded from Clitellata and not closely related to them due to great morphological differences. Although molecular studies give strong support for the exclusion of these two taxa from Clitellata their questionable sister group relationship to each other has not been addressed specifically. In the present study sequences of the nuclear 18S rDNA and the mitochondrial Cytochrome Oxidase I gene were used for addressing this question. In addition to the available nuclear 18S rDNA sequences, partial sequences of Cytochrome Oxidase I of Rheomorpha neiswestnovae (Lastochkin, 1935) and Potamodrilus fluviatilis Lastochkin, 1935 along with other polychaete taxa were determined. Combined analyses of these two genes were conducted using Maximum Parsimony and Bayesian analysis. A sister group relationship of Aeolosomatidae and Potamodrilidae is significantly supported in all. As in previous studies a relationship to Clitellata is not supported but the phylogenetic position of both Aeolosomatidae and Clitellata within the polychaetes remains enigmatic.     

Phylogenies based on combined mitochondrial and nuclear sequences conflict with morphologically defined genera in the eimeriid coccidia (Apicomplexa)

Partial mitochondrial (mt) cytochrome c oxidase subunit I (COI) and near-complete nuclear (nu) 18S rDNA sequences were obtained from various eimeriid coccidia infecting vertebrates. New and published sequences were used in phylogenetic reconstructions based on nu 18S rDNA, mt COI and concatenated sequence datasets. Bayesian analyses of nu 18S rDNA sequences used secondary structure-based alignments with a doublet nucleotide substitution model; the codon nucleotide substitution model was applied to COI sequences. Although alignment of the mt COI sequences was unambiguous, substitution saturation was evident for comparisons of COI sequences between ingroup (eimeriid) and outgroup (sarcocystid) taxa. Consequently, a combined dataset applying partition-specific analytical and alignment improvements was used to generate a robust molecular phylogeny. Most eimeriid parasites that infect closely related definitive hosts were found in close proximity on the resulting tree, frequently in a single clade. Whether this represents coevolution or co-accommodation or a combination remains an open point. Unlike host associations, basic oocyst configuration (number of sporocysts per oocyst and sporozoites per sporocyst) was not correlated with phylogeny. Neither ‘Eimeria-type’ nor ‘Isospora-type’ oocyst morphotypes formed monophyletic groups. In the combined dataset tree (representing only a tiny fraction of described eimeriid coccidia), at least 10 clades of Eimeria spp. would need to be re-assigned to nine distinct genera to resolve their paraphyly. The apparent lack of congruence between morphotype and genotype will require taxonomists to balance nomenclatural stability and diagnostic ease against the ideal of monophyletic genera. For now, recognition of paraphyletic eimeriid genera defined by basic oocyst configuration may be necessary for reasons of taxonomic stability and diagnostic utility. Future taxonomic revisions to produce monophyletic eimeriid genera will ultimately require the identification of reliable phenotypic characters that agree with the molecular phylogeny of these parasites or, less optimally, acceptance that genotyping may be needed to support monophyletic supraspecific taxonomic groups.     

Unique sequence characteristics account for good DGGE separation of almost full-length 18S rDNAs

A major limiting factor for DGGE-based microbial community studies is that the fragments should not be much longer than 500 bp for successful analysis. However, relatively high-resolution was achieved based on DGGE of the long 18S rDNA fragment (>1500 bp), which might be surprising due to the known decrease in DGGE resolution of DNA molecules with large melted regions. A unique sequence characteristic was found in a specific region (ca. 275 bp, named the NS1-end region) of 18S rDNAs, and fungal communities separated from Hong Qu glutinous rice wine brewing system was used to reveal the relationship between high resolution capacity and the unique sequence characteristics. The results showed that DGGE separation of the long 18S rDNA fragments depended on their NS1-end regions. The region is composed of a sequence-variable and short-length GC-poor region (ca. 160 bp) and a GC-rich region (ca. 110 bp), which contribute to the high resolution capacity achieved for DGGE of the long 18S rDNA fragments. Thus DGGE of the long 18S rDNA fragment is recommended as a target fragment for studies of fungal communities whose 18S rDNAs possess similar sequence characteristics. Good resolution and almost full-length 18S rDNA sequences can thus be obtained to provide more accurate and reliable analysis of fungal communities. Since more sequences are obtained directly from the PCR product through the long rDNA fragment approach, this is a convenient and effective approach for sequence-based analysis without using other complementary methods such as an rDNA clone library method.     

A Unique Box in 28S rRNA Is Shared by the Enigmatic Insect Order Zoraptera and Dictyoptera

The position of the Zoraptera remains one of the most challenging and uncertain concerns in ordinal-level phylogenies of the insects. Zoraptera have been viewed as having a close relationship with five different groups of Polyneoptera, or as being allied to the Paraneoptera or even Holometabola. Although rDNAs have been widely used in phylogenetic studies of insects, the application of the complete 28S rDNA are still scattered in only a few orders. In this study, a secondary structure model of the complete 28S rRNAs of insects was reconstructed based on all orders of Insecta. It was found that one length-variable region, D3-4, is particularly distinctive. The length and/or sequence of D3-4 is conservative within each order of Polyneoptera, but it can be divided into two types between the different orders of the supercohort, of which the enigmatic order Zoraptera and Dictyoptera share one type, while the remaining orders of Polyneoptera share the other. Additionally, independent evidence from phylogenetic results support the clade (Zoraptera+Dictyoptera) as well. Thus, the similarity of D3-4 between Zoraptera and Dictyoptera can serve as potentially valuable autapomorphy or synapomorphy in phylogeny reconstruction. The clades of (Plecoptera+Dermaptera) and ((Grylloblattodea+Mantophasmatodea)+(Embiodea+Phasmatodea)) were also recovered in the phylogenetic study. In addition, considering the other studies based on rDNAs, this study reached the highest congruence with previous phylogenetic studies of Holometabola based on nuclear protein coding genes or morphology characters. Future comparative studies of secondary structures across deep divergences and additional taxa are likely to reveal conserved patterns, structures and motifs that can provide support for major phylogenetic lineages.     

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.     

Molecular genetic divergence of the centric diatom Cyclotella and Discostella (Bacillariophyceae) revealed by nuclear ribosomal DNA comparisons

The centric diatom Cyclotella, including the recently separated Discostella, is commonly present in freshwater and several species are important bio-indicators. Here, we describe molecular characteristics of the nuclear rDNA, spanning 18S to D1/D2 region of the 28S rDNA, of two genera Cyclotella and Discostella, particularly using Korean isolates of C. meneghiniana, Discostella sp. c.f. D. pseudostelligera. Molecular and morphological analyses showed that our isolates had nearly identical genotypes in rDNA and similar morphology as compared to presumably the same species from other geographical areas. Phylogenetic analyses of individual 18S and partial 28S rDNAs of Cyclotella sensu lato showed that all sequences were separated into two clades: one containing Cyclotella, the other Discostella including C. ocellata and C. bodanica. Statistical tests with pairwise genetic distance scores showed that the two genera were significantly different (one-factor ANOVA, p?<?0.01). In addition, divergence in the partial 28S rDNA was significantly high (p?<?0.01) as compared to 18S rDNA. This provides evidence that the two genera, Cyclotella and Discostella, belong to genetically well-separated groups. In addition, 28S rDNAs is a more suitable molecular marker for the discrimination of Cyclotella sensu lato.