18S rRNA alignments derived from different secondary structure models can produce alternative phylogenies

Molecular sequence data are often aligned on the basis of secondary and/or tertiary structure models. However, these models are regularly updated and sometimes differ depending on the way in which they were constructed. We examined whether the choice of a particular 18S rRNA secondary structure model as alignment basis influences phylogeny inference. We therefore compared 18S rRNA phylogenies derived from alignments based on different models. We used: 1. Maximum parsimony; 2. The neighbour-joining method; 3. The maximum-likelihood approach; and 4. Evolutionary parsimony. This demonstrated that the secondary structure model on which an alignment is based may influence: 1. The tree topologies found by these four methods; 2. The numbers of most parsimonious trees found; and 3. The statistical values calculated by the evolutionary parsimony method.     

Phylogenetic relationships within the Mysidae (Crustacea, Peracarida, Mysida) based on nuclear 18S ribosomal RNA sequences

Species of the order Mysida (Crustacea, Peracarida) are shrimp-like animals that occur in vast numbers in coastal regions of the world. The order Mysida comprises 1,053 species and 165 genera. The present study covers 25 species of the well-defined Mysidae, the most speciose family within the order Mysida. 18S rRNA sequence analysis confirms that the subfamily Siriellinae is monophyletic. On the other hand the subfamily Gastrosaccinae is paraphyletic and the subfamily Mysinae, represented in this study by the tribes Mysini and Leptomysini, consistently resolves into three independent clades, and hence is clearly not monophyletic. The tribe Mysini is not monophyletic either, and forms two clades of which one appears to be closely related to the Leptomysini. Our results are concordant with a number of morphological differences urging a taxonomic revision of the Mysidae.     

Analysis of environmental 18S ribosomal RNA sequences reveals unknown diversity of the cosmopolitan phylum Telonemia

Telonemia has recently been described as a new eukaryotic phylum with uncertain evolutionary origin. So far, only two Telonemia species, Telonema subtilis and Telonema antarcticum, have been described, but there are substantial variations in size and morphology among Telonema isolates and field observations, indicating a hidden diversity of Telonemia-like species and populations. In this study, we investigated the diversity and the global distribution of this group by analyzing 18S rDNA sequences from marine environmental clone libraries published in GenBank as well as several unpublished sequences from the Indian Ocean. Phylogenetic analyses of the identified sequences suggest that the Telonemia phylum includes several undescribed 18S rDNA phylotypes, probably corresponding to a number of different species and/or populations. The Telonemia phylotypes form two main groups, here referred to as Telonemia Groups 1 and 2. Some of the closely related sequences originate from separate oceans, indicating worldwide distributions of various Telonemia phylotypes, while other phylotypes seem to have limited geographical distribution. Further investigations of the evolutionary relationships within Telonemia should be conducted on isolated cultures of Telonema-like strains using multi-locus sequencing and morphological data.     

Patterns of nucleotide change in mitochondrial ribosomal RNA genes and the phylogeny of piranhas

The patterns and rates of nucleotide substitution in mitochondrial ribosomal RNA genes are described and applied in a phylogenetic analysis of fishes of the subfamily Serrasalminae (Teleostei, Characiformes, Characidae). Fragments of 345 bp of the 12S and 535 bp of the 16S genes were sequenced for 37 taxa representing all but three genera in the subfamily. Secondary-structure models based on comparative sequence analysis were derived to characterize the pattern of change among paired and unpaired nucleotides, forming stem and loop regions, respectively. Base compositional biases were in the direction of A-rich loops and G-rich stems. Ninety-five percent of substitutions in stem regions were compensatory mutations, suggesting that selection for maintenance of base pairing is strong and that independence among characters cannot be assumed in phylogenetic analyses of stem characters. The relative rate of nucleotide substitution was similar in both fragments sequenced but higher in loop than in stem regions. In both genes, C-T transitions were the most common type of change, and overall transitions outnumbered transversions by a factor of two in 16S and four in 12S. Phylogenetic analysis of the mitochondrial DNA sequences suggests that a clade formed by the generaPiaractus, Colossoma, andMylossoma is the sister group to all other serrasalmins and that the generaMyleus, Serrasalmus, andPristobrycon are paraphyletic. A previous hypothesis concerning relationships for the serrasalmins, based on morphological evidence, is not supported by the molecular data. However, phylogenetic analysis of host-specific helminth parasites and cytogenetic data support the phylogeny of the Serrasalminae obtained in this study and provide evidence for coevolution between helminth parasites and their fish hosts.     

Relationship of the genusCordyceps and related genera, based on parsimony and spectral analysis of partial 18S and 28S ribosomal gene sequences

A molecular phylogenetic study of selected species of three sub-genera of the genusCordyceps was undertaken, along with representatives of the generaAkanthomyces, Aschersonia, Gibellula, Hymenostilbe, Hypocrella, Nomuraea andTorrubiella, to examine their inter-relationship. Phylogenetic analyses of the data indicated that the Clavicipitaceae form a monophyletic group within the Hypocreales, while the monophyly ofCordyceps was not supported. Four clades were identified:Cor. militaris/Cor. pseudomilitaris; Cor. iranginesis/Cor. sphecocephala; Cor. intermedia/Cor. capitata; andCor. cylindrica/Nom. atypicola. The sub-genusNeocordyceps was shown to be monophyletic while the sub-generaEucordyceps andOphiocordyceps do not form monophyletic groups. The genusHypocrella appeared monophyletic, and radiated after the formation of the generaCordyceps, andTorrubiella. Akanthomyces arachnophilus andGi. pulchra, anamorphs ofTorrubiella species, formed a distinct clade that was separate from one formed by the scale insect pathogens,To. luteorostrata andPaecilomyces cinnamomeus, suggesting that this genus may be polyphyletic.     

Phylogenetic analysis of basidiomycetous yeasts by means of 18S ribosomal RNA sequences: relationship ofErythrobasidium hasegawianum and other basidiomycetous yeast taxa

The basidiomycetous yeast genusErythrobasidium Hamamoto, Sugiyama & Komagata, based on the type speciesE. hasegawianum Hamamoto et al., is characterized by filobasidiaceous basidia and the Q-10 (H₂) system as its major ubiquinone. It is tentatively placed in the Filobasidiaceae. The molecular characterization is based on 18S ribosomal RNA sequence comparisons among the basidiomycetous yeasts, and the ultrastructural characterization on the cell wall and hyphal septal pores inE. hasegawianum clearly indicate a close relationship with the teliospore-forming yeastsRhodosporidium toruloides andLeucosporidium scottii. Our molecular phylogeny with statistical analysis suggests that the existing taxonomic system of basidiomycetous yeasts, based primarily on the morphology of basidia including the teliospores (probasidia), should be revised.     

The solution structure of ribosomal protein L18 from Bacillus stearothermophilus

A medium resolution solution structure has been obtained for L18 from Bacillus stearothermophilus (BstL18), a ribosomal protein that stabilizes the tertiary structure of 5S rRNA and mediates its interaction with the rest of the large subunit. The N-terminal 22 amino acid residues of BstL18 are unstructured in solution. Its remaining 98 residues form a globular domain that has the same topology as the globular domains of other L18s, but the orientation of helices is different. This conformational peculiarity should not prevent BstL18 from functioning in the ribosome the same way as other L18s.     

Nucleotide sequence of Citrus limon 26S rRNA gene and secondary structure model of its RNA

The complete nucleotide sequence of Citrus limon 26S rDNA has been determined. The sequence has been aligned with large ribosomal RNA (L-rRNA) sequences of Escherichia coli, Saccharomyces cerevisiae and Oryza sativa. Nine extensive expansion segments in dicot 26S rRNA relative to E. coli 23S rRNA have been identified and compared with analogous segments of monocot, yeast, amphibian and human L-rRNAs. A secondary structure model for lemon 26S rRNA has been derived based on the refined model of E. coli 23S rRNA. It has been compared with other eukaryotic L-rRNAs models in terms of location of functionally important regions. Origin and evolution of L-rRNA expansion segments are discussed.     

基于18S rRNA和线粒体16S rRNA基因序列的柳蚕进化分析

为探讨柳蚕Actias selene Hübner与鳞翅目昆虫的系统发育关系,本研究利用PCR扩增获得了柳蚕核糖体18S rRNA和线粒体16S rRNA基因的部分序列,长度分别为391bp和428bp。并采用邻近距离法(NJ)、最大简约法(MP)、类平均聚类法(UPGMA)构建系统进化树。结果表明,柳蚕线粒体16SrRNA基因序列与大蚕蛾科昆虫的16SrRNA基因序列均表现出偏好于碱基AT的倾向。柳蚕与所研究的其它蚕类的遗传距离介于0.016至0.140之间,其中与温带柞蚕Antheraea roylii的遗传距离最小,与野桑蚕Bombyx mandarina的遗传距离最大。而基于鳞翅目昆虫18S rRNA基因部分序列的进化分析显示,柳蚕与柞蚕Antheraea pernyi之间的遗传距离最小(0.010),与蓖麻蚕Samia ricini的遗传距离最大(0.017)。     

Nuclease S1 analysis of eubacterial 5S rRNA secondary structure

Summary Single-strand-specific nuclease S₁ was employed as a structural probe to confirm locations of unpaired nucleotide bases in 5S rRNAs purified from prokaryotic species of rRNA superfamily I. Limited nuclease S₁ digests of 3- and 5-end-labeled [³²P]5S rRNAs were electrophoresed in parallel with reference endoribonuclease digests on thin allel with reference endoribonuclease digests on thin sequencing gels. Nuclease S₁ primary hydrolysis patterns were comparable for 5S rRNAs prepared from all 11 species examined in this study. The locations of base-paired regions determined by enzymatic analysis corroborate the general features of the proposed universal five-helix model for prokaryotic 5S rRNA, although the results of this study suggest a significant difference between prokaryotic and eukaryotic 5S rRNAs in the evolution of helix IV. Furthermore, the extent of base-pairing predicted by helix IV needs to be reevaluated for eubacterial species. Clipping patterns in helices II and IV appear to be consistent with a secondary structural model that undergoes a conformational rearrangement between two (or more) structures. Primary clipping patterns in the helix II region, obtained by S₁ analysis, may provide useful information concerning the tertiary structure of the 5S rRNA molecule.     

Use of ribosomal DNA sequence data to characterize and detect a neogregarine pathogen of Solenopsis invicta (Hymenoptera: Formicidae)

A neogregarine parasite of the red imported fire ant, Solenopsis invicta, was discovered recently in Florida and tentatively placed in the Mattesia genus based on morphological characterization. S. invicta infected with this Mattesia species exhibited a characteristic yellowing of the cuticle which was designated Mattesia "yellow-head disease" (YHD). The 18S rRNA gene sequence from Mattesia YHD was elucidated and compared with the neogregarine pathogens, Mattesia geminata and Ophriocystis elektroscirrha. The sequence data support the previous conclusion that Mattesia YHD is a new species that infects S. invicta. Furthermore, high sequence identity between Mattesia YHD, M. geminata (95.7%), and O. elektroscirrha (86.2%) correctly place the YHD organism in the Mattesia genus and Neogregarinorida order. Oligonucleotide primer pairs were designed to unique areas of the 18S rRNA genes of Mattesia YHD and S. invicta. Multiplex PCR resulted in sensitive and specific detection of Mattesia YHD infection of S. invicta.     

Fragmentation heterogeneity of 23S ribosomal RNA in Haemophilus species

The fragmentation of 23S rRNA of 22 Haemophilus influenzae strains and eight strains belonging to other Haemophilus species was investigated. Instead of intact molecules, the 23S rRNA molecules were found to be cleaved into two to five smaller conserved fragments in most strains examined, especially in H. influenzae type b (5/6) and nontypeable strains (5/5). One or two conserved potential cleavage sites were identified by PCR analysis of the strains showing a fragmented 23S rRNA pattern. The relevant nucleotide sequences were determined and compared to H. influenzae Rd, which contains intact 23S rRNA molecules. An identical 112 bp long intervening sequence (IVS) at position 542 and a conserved 121–123 bp IVS sequence at position 1171 were found in two H. influenzae type b strains and one nontypeable strain. Among the strains with fragmented 23S rRNA, nearly half showed a heterogeneous cleavage pattern due to the dispersion of IVSs among different 23S rRNA operons. The localization of the conserved H. influenzae IVSs coincided well with the extensively studied IVSs among other bacteria, but differed in nucleotide sequence from any other reported IVSs. Therefore, the IVSs of Haemophilus 23S rRNA may originate from a common source that is independent of other bacteria.     

18S ribosomal RNA gene sequences of Cochliopodium (Himatismenida) and the phylogeny of Amoebozoa

Cochliopodium is a very distinctive genus of discoid amoebae covered by a dorsal tectum of carbohydrate microscales. Its phylogenetic position is unclear, since although sharing many features with naked gymnamoebae, the tectum sets it apart. We sequenced 18S ribosomal RNA genes from three Cochliopodium species (minus, spiniferum and Cochliopodium sp., a new species resembling C. minutum). Phylogenetic analysis shows Cochliopodium as robustly holophyletic and within Amoebozoa, in full accord with morphological data. Cochliopodium is always one of the basal branches within Amoebozoa but its precise position is unstable. In Bayesian analysis it is sister to holophyletic Glycostylida, but distance trees mostly place it between Dermamoeba and a possibly artifactual long-branch cluster including Thecamoeba. These positions are poorly supported and basal amoebozoan branching ill-resolved, making it unclear whether Discosea (Glycostylida, Himatismenida, Dermamoebida) is holophyletic; however, Thecamoeba seems not specifically related to Dermamoeba. We also sequenced the small-subunit rRNA gene of Vannella persistens, which constantly grouped with other Vannella species, and two Hartmannella strains. Our trees suggest that Vexilliferidae, Variosea and Hartmannella are polyphyletic, confirming the existence of two very distinct Hartmannella clades: that comprising H. cantabrigiensis and another divergent species is sister to Glaeseria, whilst Hartmannella vermiformis branches more deeply.     

The secondary structure of human 28S rRNA: The structure and evolution of a mosaic rRNA gene

Summary We have determined the secondary structure of the human 28S rRNA molecule based on comparative analysis of available eukaryotic cytoplasmic and prokaryotic large-rRNA gene sequences. Examination of large-rRNA sequences of both distantly and closely related species has enabled us to derive a structure that accounts both for highly conserved sequence tracts and for previously unanalyzed variable-sequence tracts that account for the evolutionary differences in size among the large rRNAs.Human 28S rRNA is composed of two different types of sequence tracts: conserved and variable. They differ in composition, degree of conservation, and evolution. The conserved regions demonstrate a striking constancy of size and sequence. We have confirmed that the conserved regions of large-rRNA molecules are capable of forming structures that are superimposable on one another. The variable regions contain the sequences responsible for the 83% increase in size of the human large-rRNA molecule over that ofEscherichia coli. Their locations in the gene are maintained during evolution. They are G+C rich and largely nonhomologous, contain simple repetitive sequences, appear to evolve by frequent recombinational events, and are capable of forming large, stable hairpins.The secondary-structure model presented here is in close agreement with existing prokaryotic 23S rRNA secondary-structure models. The introduction of this model helps resolve differences between previously proposed prokaryotic and eukaryotic large-rRNA secondary-structure models.     

5S and 5.8S ribosomal RNA evolution in the suborder tetrahymenina (Ciliophora: Hymenostomatida)

Summary The nucleotide sequences of the 5S and 5.8S rRNAs of eight strains of tetrahymenine ciliates have been determined. The sequences indicate a clear distinction betweenTetrahymena paravorax and its suggested conspecificT. vorax, but leave the taxonomic distinction betweenT. vorax andT. leucophrys in doubt. The rRNA sequences of sixTetrahymena species and of three other species of the suborder Tetrahymenina have been used to deduce evolutionary schemes in which ancestral rRNA sequences and changes are proposed. These schemes suggest the predominant acceptance of GA and CT transitions in the 5S rDNA during the evolution of the suborder.     

Phylogenetic positions of the aberrant branchiobdellidans and aphanoneurans within the Annelida as derived from 18S ribosomal RNA gene sequences

Different hypotheses have been proposed on the phylogenetic relationships of branchiobdellidans and aphanoneurans among the Annelida based on the anatomical and embryological characters. The 18S ribosomal RNA gene sequences have been analyzed from representatives of the three major taxa of the Annelida plus the branchiobdellidans and aphanoneurans to assess their phylogenetic relationships to each other. In this preliminary study, all of the phylogenetic analyses show the branchiobdellidans as a sister group to the leeches, rather than the oligochaetes. The position of the aphanoneurans is stable as an independent taxon that evolved after the polychaetes branched from the evolutionary stem, but before the ancestral oligochaetes emerged.     

Phylogenetic relationship of Alexandrium monilatum (Dinophyceae) to other Alexandrium species based on 18S ribosomal RNA gene sequences

The phylogenetic relationship of Alexandrium monilatum to other Alexandrium spp. was explored using 18S rDNA sequences. Maximum likelihood phylogenetic analysis of the combined rDNA sequences established that A. monilatum paired with Alexandrium taylori and that the pair was the first of the Alexandrium taxa to diverge, followed by Alexandrium margalefii. All three are members of the Alexandrium subgenus Gessnerium Halim nov. comb.     

First successful amplification of 18S ribosomal DNA ofCordyceps spp. by the PCR method

The 18S ribosomal DNAs ofCordyceps spp. were amplified for the first time by the PCR method. New primers were designed based on the sequence of the 18S ribosomal DNA ofSclerotinia sclerotiorum.     

Mapping of the 18S and 5S ribosomal RNA genes in the fish Prochilodus argenteus Agassiz, 1829 (Characiformes,Prochilodontidae)

A single NOR-bearing chromosome pair was identified by silver nitrate staining in a previous study of the fish Prochilodus argenteus from the S ã o Francisco River (MG, Brazil), with a third metacentric chromosome sporadically bearing active NOR. The present study focused on an analysis of the chromosomal localization of both the major (45S) and the minor (5S) rRNA genes using FISH. The use of the 18S rDNA probe confirmed the previous Ag-NOR sites interstitially located in a large metacentric pair and also identified up to three other sites located in the telomeric regions of distinct chromosomes, characterizing an interindividual variation of these sites. In addition, the 5S rDNA site was revealed adjacent to the major NOR site, identified at the end of the large Ag-NOR bearing metacentric chromosome. In a few metaphases, an additional weak hybridization signal was observed in a third chromosome, possibly indicating the presence of another 5S rDNA cluster. Despite a lower karyotype diversification (2n=54 and FN=108) often observed among species of Prochilodontidae, variations involving both 45S and 5S rRNA genes could play an important role in their chromosome diversification.