Raymond De Baere

Phylogenetic relationships of nonaxenic filamentous cyanobacterial strains based on 16S rRNA sequence analysis.

In order to determine the nearly complete 16S rRNA gene sequences of cyanobacteria originating from nonaxenic cultures, a cyanobacterium-specific oligonucleotide probe was developed to distinguish polymerase chain reaction (PCR) products of the cyanobacterial rRNA operons from those resulting from amplification of contaminating bacteria. Using this screening method the 16S rRNA genes of four nonaxenic filamentous cyanobacterial strains belonging to the generaLeptolyngbya andOscillatoria were cloned and sequenced. For the genusLeptolyngbya, the 16S rRNA sequence of the axenic strain PCC 73110 was also determined. Phylogenetic trees were constructed based on complete and partial sequences. The results show that the strainsLeptolyngbya foveolarum Komárek 1964/112,Leptolyngbya sp. VRUC 135 Albertano 1985/1, andLeptolyngbya boryanum PCC 73110 belong to the same cluster. StrainOscillatoria cf.corallinae SAG 8.92, which contains the rare photosynthetic pigment CU-phycoerythrin, is not closely related to other CU-phycoerythrin-containing cyanobacteria.Oscillatoria agardhii CYA 18, which is a representative of planktonicOscillatoria species that form toxic blooms in Norwegian inland waters, has no close relatives in the tree.

Evolutionary Relationships Among Higher Fungi Inferred from Small Ribosomal Subunit RNA Sequence Analysis

The primary structure of the small ribosomal subunit RNA. (SSU rRNA) was determined for 13 species belonging to 10 ascomycete families and for the basidiomycetous anamorphic yeast Rhodotorula glutinis. The sequences were fitted into an alignment of all hitherto published complete or nearly complete eukaryotic small subunit rRNA sequences. The evolutionary relationships within the fungi were examined by construction of a tree from 87 SSU rRNA sequences, corresponding to 71 different species, by means of a distance matrix method and bootstrap analysis. It confirms the early divergence of the zygomycetes and the classical division of the higher fungi into basidiomycetes and ascomycetes. The basidiomycetes are divided into true basidiomycetes and ustomycetes. Within the ascomycetes, the major subdivisions hemiascomycetes and euascomycetes can be recognized. However, Schizosaccharomyces pombe does not belong to the cluster of the hemiascomycetes, to which it is assigned in classical taxonomic schemes, but forms a distinct lineage. Among the euascomycetes, the plectomycetes and the pyrenomycetes can be distinguished. Within the hemiascomycetes, the polyphyly of genera like Pichia or Candida and of families like the Dipodascaceae and the Saccharomycetaceae can be observed.

Coniosporium perforans and C-apollinis, two new rock-inhabiting fungi isolated from marble in the Sanctuary of Delos (Cyclades, Greece)

Coniosporium perforans and C. apollinis, orginating from marble in the Mediterranean basin, are described as new species of rock inhabiting microcolonial fungi. The morphologically similar species Monodictys castaneae (Wallr.) S. Hughes, Phaeosclera dematioides Sigler et al., and a Coniosporium-like strain are compared using 18S rDNA phylogeny and Restriction Length Fragment Polymorphism analysis of Internal Transcribed Spacer regions. Sarcinomyces crustaceus Lindner is additionally compared on the basis of 18S rDNA sequencing data. Phylogenetic analysis suggests that Phaeosclera dematioides is related to the ascomycetous order Dothideales and Monodictys castaneae to the Pleosporales, whereas the three Coniosporium species studied are a sister group to the Herpotrichiellaceae (Chaetothyriales). A similar affinity was suggested previously for the recently described meristematic rock-fungus Sarcinomyces petricola Wollenzien & de Hoog. Sarcinomyces crustaceus appears unrelated to this group, and hence the present new taxa cannot be described in this genus.

Phylogenetic relationships among algae based on complete large-subunit rRNA sequences.

The complete or nearly complete large-subunit rRNA (LSU rRNA) sequences were determined for representatives of several algal groups such as the chlorarachniophytes, cryptomonads, haptophytes, bacillariophytes, dictyochophytes and pelagophytes. Our aim was to study the phylogenetic position and relationships of the different groups of algae, and in particular to study the relationships among the different classes of heterokont algae. In LSU rRNA phylogenies, the chlorarachniophytes, cryptomonads and haptophytes seem to form independent evolutionary lineages, for which a specific relationship with any of the other eukaryotic taxa cannot be demonstrated. This is in accordance with phylogenies inferred on the basis of the small-subunit rRNA (SSU rRNA). Regarding the heterokont algae, which form a well-supported monophyletic lineage on the basis of LSU rRNA, resolution between the different classes could be improved by combining the SSU and LSU rRNA data. Based on a concatenated alignment of both molecules, the phaeophytes and the xanthophytes are sister taxa, as well as the pelagophytes and the dictyochophytes, and the chrysophytes and the eustigmatophytes. All these sister group relationships are highly supported by bootstrap analysis and by different methods of tree construction.

Evolutionary relationships among heterokont algae (the autotrophic stramenopiles) based on combined analyses of small and large subunit ribosomal RNA.

In order to study the phylogenetic relationships within the stramenopiles, and particularly among the heterokont algae, we have determined complete or nearly complete large-subunit ribosomal RNA sequences for different species of raphidophytes, phaeophytes, xanthophytes, chrysophytes, synurophytes and pinguiophytes. With the small- and large-subunit ribosomal RNA sequences of representatives for nearly all known groups of heterokont algae, phylogenetic trees were constructed from a concatenated alignment of both ribosomal RNAs, including more than 5,000 positions. By using different tree construction methods, inferred phylogenies showed phaeophytes and xanthophytes as sister taxa, as well as the pelagophytes and dictyochophytes, and the chrysophytes/synurophytes and eustigmatophytes. All these relationships are highly supported by bootstrap analysis. However, apart from these sister group relationships, very few other internodes are well resolved and most groups of heterokont algae seem to have diverged within a relatively short time frame.

Evolution of green plants and their relationship with other photosynthetic eukaryotes as deduced from 5S ribosomal RNA sequences.

The nucleotide sequence of cytoplasmic 5S ribosomal RNAs from three gymnosperms,Pinus contorta, Taxus baccata andJuniperus media and from one fern,Pteridium aquilinum, have been determined. These sequences were aligned with all hitherto known cytoplasmic 5S ribosomal RNA sequences of photosynthetic eukaryotes. A dendrogram based on that set of sequences was constructed by a distance matrix method and the resulting tree compared with established views concerning plant and algal evolution. The following monophyletic groups of photosynthetic eukaryotes are recognizable: theRhodophyta, a group consisting ofPhaeophyta, Bacillariophyta andChrysophyta, and the green plants, the latter comprising green algae,Bryophyta, Pteridophyta andSpermatophyta. According to our 5S ribosomal RNA tree, green plants may have originated from some type of a green flagellated organism such asChlamydomonas. The land plants seem to have originated from some form of charophyte such asNitella. 5S ribosomal RNA seems to be less appropriate to estimate dissimilarities between species which have diverged relatively recently, like the angiosperms. Therefore, a precise evolutionary process is difficult to reconstruct for members of this group.

The 5S ribosomal RNA sequences of a red algal rhodoplast and a gymnosperm chloroplast. Implications for the evolution of plastids and cyanobacteria

SummaryThe 5S ribosomal RNA sequences have been determined for the rhodoplast of the red algaPorphyra umbilicalis and the chloroplast of the coniferJuniperus media. The 5S RNA sequence of theVicia faba chloroplast is corrected with respect to a previous report. A survey of the known sequences and secondary structures of 5S RNAs from plastids and cyanobacteria shows a close structural similarity between all 5S RNAs from land plant chloroplasts. The algal plastid 5S RNAs on the other hand show much more structural diversity and have certain structural features in common with bacterial 5S RNAs. A dendrogram constructed from the aligned sequences by a clustering algorithm points to a common ancestor for the present-living cyanobacteria and the land plant plastids. However, the algal plastids branch off at an early stage within the plastid-cyanobacteria cluster, before the divergence between cyanobacteria and land plant chloroplasts. This evolutionary picture points to the occurrence of multiple endosymbiotic events, with the ancestors of the present algal plastids already established as photosynthetic endosymbionts at a time when the ancestors of the present land plant chloroplasts were still free-living cells.

Primary and secondary structure of the 18 S ribosomal RNA of the insect species Tenebrio molitor

The sequence of the 18 S rRNA of Tenebrio molitor is reported. A detailed secondary structure model for eukaryotic small subunit rRNAs is proposed. The model comprises 48 universal helices that eukaryotic and prokaryotic small subunit rRNAs have in common, plus a number of helices in areas of variable secondary structure. For the central area of the model, an alternative structure is possible, applicable only to eukaryotic small subunit rRNAs. Possibly, small subunit rRNA switched to this alternative conformation after the eukaryotic branch had been established in evolution. Another possibility is that the two conformers represent a dynamic structural switch functioning during the translational activity of the eukaryotic ribosome.

Structure of 5S rRNA in actinomycetes and relatives and evolution of eubacteria

SummaryThe primary structure of 5S ribosomal RNA has been determined in five species belonging to the genusMycobacterium and inMicrococcus luteus. The sequences of 5S RNAs from Actinomycetes and relatives point to the existence in this taxon of a bulge on the helix that joins the termini of the molecule. An attempt was made to reconstruct bacterial evolution from a sequence dissimilarity matrix based on 142 eubacterial 5S RNA sequences and corrected for multiple mutation. The algorithm is based on weighted pairwise clustering, and incorporates a correction for divergent mutation rates, as derived by comparison of sequence dissimilarities with an external reference group of eukaryotic 5S RNAs. The resulting tree is compared with the eubacterial phylogeny built on 16S rRNA catalog comparison. The bacteria for which the 5S RNA sequence is known form a number of clusters also discernible in the 16S rRNA phylogeny. However, the branching pattern leading to these clusters shows some notable discrepancies with the aforementioned phylogeny.