Collection of published 5S and 5.8S ribosomal RNA sequences

Evolution of green plants as deduced from 5S rRNA sequences

We have constructed a phylogenic tree for green plants by comparing 5S rRNA sequences. The tree suggests that the emergence of most of the uni- and multicellular green algae such as Chlamydomonas, Spirogyra, Ulva, and Chlorella occurred in the early stage of green plant evolution. The branching point of Nitella is a little earlier than that of land plants and much later than that of the above green algae, supporting the view that Nitella-like green algae may be the direct precursor to land plants. The Bryophyta and the Pteridophyta separated from each other after emergence of the Spermatophyta. The result is consistent with the view that the Bryophyta evolved from ferns by degeneration. In the Pteridophyta, Psilotum (whisk fern) separated first, and a little later Lycopodium (club moss) separated from the ancestor common to Equisetum (horsetail) and Dryopteris (fern). This order is in accordance with the classical view. During the Spermatophyta evolution, the gymnosperms (Cycas, Ginkgo, and Metasequoia have been studied here) and the angiosperms (flowering plants) separated, and this was followed by the separation of Metasequoia and Cycas (cycad)/Ginkgo (maidenhair tree) on one branch and various flowering plants on the other.

Macronuclear genome sequence of the ciliate Tetrahymena thermophila, a model eukaryote

The ciliate Tetrahymena thermophila is a model organism for molecular and cellular biology. Like other ciliates, this species has separate germline and soma functions that are embodied by distinct nuclei within a single cell. The germline-like micronucleus (MIC) has its genome held in reserve for sexual reproduction. The soma-like macronucleus (MAC), which possesses a genome processed from that of the MIC, is the center of gene expression and does not directly contribute DNA to sexual progeny. We report here the shotgun sequencing, assembly, and analysis of the MAC genome of T. thermophila, which is approximately 104 Mb in length and composed of approximately 225 chromosomes. Overall, the gene set is robust, with more than 27,000 predicted protein-coding genes, 15,000 of which have strong matches to genes in other organisms. The functional diversity encoded by these genes is substantial and reflects the complexity of processes required for a free-living, predatory, single-celled organism. This is highlighted by the abundance of lineage-specific duplications of genes with predicted roles in sensing and responding to environmental conditions (e.g., kinases), using diverse resources (e.g., proteases and transporters), and generating structural complexity (e.g., kinesins and dyneins). In contrast to the other lineages of alveolates (apicomplexans and dinoflagellates), no compelling evidence could be found for plastid-derived genes in the genome. UGA, the only T. thermophila stop codon, is used in some genes to encode selenocysteine, thus making this organism the first known with the potential to translate all 64 codons in nuclear genes into amino acids. We present genomic evidence supporting the hypothesis that the excision of DNA from the MIC to generate the MAC specifically targets foreign DNA as a form of genome self-defense. The combination of the genome sequence, the functional diversity encoded therein, and the presence of some pathways missing from other model organisms makes T. thermophila an ideal model for functional genomic studies to address biological, biomedical, and biotechnological questions of fundamental importance.

Broad issues to consider for library involvement in bioinformatics

BACKGROUND

The information landscape in biological and medical research has grown far beyond literature to include a wide variety of databases generated by research fields such as molecular biology and genomics. The traditional role of libraries to collect, organize, and provide access to information can expand naturally to encompass these new data domains.

METHODS

This paper discusses the current and potential role of libraries in bioinformatics using empirical evidence and experience from eleven years of work in user services at the National Center for Biotechnology Information.

FINDINGS

Medical and science libraries over the last decade have begun to establish educational and support programs to address the challenges users face in the effective and efficient use of a plethora of molecular biology databases and retrieval and analysis tools. As more libraries begin to establish a role in this area, the issues they face include assessment of user needs and skills, identification of existing services, development of plans for new services, recruitment and training of specialized staff, and establishment of collaborations with bioinformatics centers at their institutions.

CONCLUSIONS

Increasing library involvement in bioinformatics can help address information needs of a broad range of students, researchers, and clinicians and ultimately help realize the power of bioinformatics resources in making new biological discoveries.

Compilation of ribosomal 5S ribonucleic acid nucleotide sequences: eukaryotic 5S rRNAs

5S Ribosomal RNA is the smallest RNA component of the ribosomes. Due to relatively simple isolation and sequencing procedures as well as a potential use of the sequence data in evolutionary analyses, the amount of known nucleotide sequences on both RNA and DNA levels was rapidly growing. In this paper we present the updated (March 1996) compilation of eukaryotic 5D rRNA and 5S rDNA sequences.

Specific identification of Candida albicans by hybridization with oligonucleotides derived from ribosomal DNA internal spacers

In order to develop DNA probes for rapid, sensitive and specific detection of the pathogenic yeast species Candida albicans, we carried out comparative sequence analysis of the two internal transcribed spacer regions (ITS1 and ITS2) of the ribosomal DNA (rDNA) units of C. albicans and the closely related pathogenic species C. tropicalis. While overall sequence similarity between the two species was considerable (65-75%), both ITS1 and ITS2 were found to contain distinct regions with sufficient sequence divergence to make them suitable as specific target sites for the identification of C. albicans. On the basis of these results one ITS1-derived (ANAB1) and two ITS2-derived (ANAB2 and ANAB3) oligonucleotides were selected, chemically synthesized, and used as hybridization probes. Their specificity and reliability were evaluated in dot-blot hybridization experiments with total genomic DNA from 13 strains of medically important Candida species, six strains of other yeast genera associated with man and animals, and ten strains previously identified as C. albicans by phenotypic criteria. Under well-defined hybridization conditions the three probes hybridized exclusively with DNA derived from strains belonging to the species C. albicans, thus demonstrating their potential clinical usefulness. The failure of four of the (presumed) C. albicans strains to show hybridization to the ITS probes sheds doubt upon their taxonomic classification, which is reinforced by other phenotypic aspects of these strains.

Phylogenetic relationships of the Santalales and relatives

Determining relationships among parasitic angiosperms has often been difficult owing to frequent morphological reductions in floral and vegetative features. We report 18S (small-subunit) rRNA sequences for representative genera of three families within the Santalales (Olacaceae, Santalaceae, and Viscaceae) and six outgroup dicot families (Celastraceae, Cornaceae, Nyssaceae, Buxaceae, Apiaceae, and Araliaceae). Using Wagner parsimony analysis, one most parsimonious tree resulted that shows the Santalales to be a holophyletic taxon most closely related to Euonymus (Celastraceae). The santalalean taxa showed approximately 13% more transitional mutations than the group of seven other dicot species. This suggests a higher fixation rate for mutations in these organisms, possibly owing to a relaxation of selection pressures at the molecular level in parasitic vs nonparasitic plants. Outgroup relationships are generally in accord with current taxonomic classifications, such as the grouping of Nyssaceae and Cornaceae together (Cornales) and the grouping of Araliaceae with Apiaceae (Apiales). These data provide the first nucleotide sequences for any parasitic flowering plant and support the contention that rRNA sequence analysis can result in robust phylogenetic comparisons at the family level and above.

5S-rRNA genes in rice embryos

The 5S-rRNA from the ungerminated and 48-h-germinated rice embryos differs from the wheat, rye and maize by two nucleotides. The 48-h-germinated embryos contain another species of 5S-rRNA which differs by 3 nucleotides from the ungerminated embryos, thereby showing the expression of two 5S-rRNA genes during germination. The 5S-rRNA genes are present in tandem repeats of a 0.3-kb sequence with some length heterogeneity in the rice genome. The 5S-rRNA gene that was sequenced is identical to that of wheat and maize, except for two nucleotides, C and T, which are interchanged at positions 107 and 117. The insert of continuous 5S-rRNA gene in pBR322 was transcribed in vitro much more efficiently than the discontinuous gene. There was no homology between the 184-bp spacer sequence of 5S-rRNA genes in rice and other systems except the presence of the oligo(T) transcription terminator sequence.

Complementarity of sequences in low molecular weight RNAs to regions of messenger and ribosomal RNAs

Total low molecular weight nuclear RNAs of mouse ascites cells have been labeled in vitro and used as probes to search for complementary sequences contained in nuclear or cytoplasmic RNA. From a subset of hybridizing lmw RNAs, two major species of 58,000 and 35,000 mol. wt. have been identified as mouse 5 and 5.8S ribosomal RNA. Mouse 5 and 5.8S rRNA hybridize not only to 18 and 28S rRNA, respectively, but also to nuclear and cytoplasmic poly(A+) RNA. Northern blot analysis and oligo-dT cellulose chromatography have confirmed the intermolecular base-pairing of these two small rRNA sequences to total poly(A+) RNA as well as to purified rabbit globin mRNA. 5 and 5.8S rRNA also hybridize with positive (coding) but not negative (noncoding) strands of viral RNA. Temperature melting experiments have demonstrated that their hybrid stability with mRNA sequences is comparable to that observed for the 5S:18S and 5.8S:28S hybrids. The functional significance of 5 and 5.8S rRNA base-pairing with mRNAs and larger rRNAs is unknown, but these interactions could play important coordinating roles in ribosome structure, subunit interaction, and mRNA binding during translation.

Comparison of the structure of ribosomal 5S RNA from E. coli and from rat liver using X-ray scattering and dynamic light scattering

The structure of eukaryotic ribosomal 5S RNA from rat liver and of prokaryotic 5S RNA from E. coli (A-conformer) have been investigated by scattering methods. For both molecules, a molar mass of 44,500 +/- 4,000 was determined from small angle X-ray scattering as well as from dynamic light scattering. The shape parameters of the two rRNAs, volume Vc, surface Oc, radius of gyration Rs, maximum dimension of the molecule L, thickness D, and cross section radius of gyration Rsq, agree within the experimental error limits. The mean values are Vc = 57 +/- 3 nm3, Oc = 165 +/- 10 nm2, Rs = 3.37 +/- 0.05 nm, L = 10.8 +/- 0.7 nm, D = 1.57 +/- 0.07 nm, Rsq = 0.92 +/- 0.01 nm. Identical structures for the E. coli 5S rRNA and the rat liver 5S rRNA at a resolution of 1 nm can be deduced from this agreement and from the comparison of experimental X-ray scattering curves and of experimental electron distance distribution functions. The flat shape model derived for prokaryotic and eukaryotic 5S rRNA shows a compact region and two protruding arms. Double helical stems are eleven-fold helices with a mean base pair distance of 0.28 nm. Combining the shape information obtained from X-ray scattering with the information about the frictional behaviour of the molecules, deduced from the diffusion coefficients D020, w = (5.9 +/- 0.2) X 10(-7) cm2 s-1 and (6.2 +/- 0.2) X 10(-7) cm2 s-1 for rat liver 5S rRNA and E. coli 5S rRNA, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Immunological homologies between ribosomal proteins amongst lower eukaryotes

Polyclonal antibodies were raised against the purified ribosomal proteins L1 and L2, the 5S rRNA binding protein L3, all from Saccharomyces cerevisiae, and against L1 and L2 from Schizosaccharomyces pombe (numbering according to Otaka and Osawa 1981; Otaka et al. 1983, respectively). For clarity prefixes Sc and Sp have been added to the numbering of proteins derived from S. cerevisiae and S. pombe, respectively. Ribosomal proteins from these yeasts and from Kluyveromyces marxianus, Rhodotorula glutinis, the slime mold Dictyostelium discoideum and the protozoan Tetrahymena thermophila were checked for antigenic cross-reactivity by the immunoblot technique. Anti-ScL1 bound to the largest ribosomal proteins of all organisms but not with equal strength. A fast migrating protein band from R. glutinis was also reactive. Anti-ScL2 reacted strongly with L2 or analogous proteins derived exclusively from the yeasts. Anti-ScL3 cross-reacted only with one protein band from K. marxianus, whereas anti-SpL1 cross-reacted with L1 or its analogues from the other organisms, but also with proteins of lower molecular weight. In S. cerevisiae, these proteins are located exclusively on the small ribosomal subunit. L2 or analogous ribosomal proteins of all organisms were recognized by anti-SpL2 but additionally the ribosomal protein YL28 of S. cerevisiae and fast migrating proteins of T. thermophila exhibited anti-SpL2 binding.

Secondary structure of Tetrahymena thermophilia 5S ribosomal RNA as revealed by enzymatic digestion and microdensitometric analysis

The secondary structure of [32P] end-labeled 5S rRNA from Tetrahymena thermophilia (strain B) has been investigated using the enzymes S1 nuclease, cobra venom ribonuclease and T2 ribonuclease. The results, analyzed by scanning microdensitometry and illustrated by three-dimensional computer graphics, support the secondary structure model of Curtiss and Vournakis for 5S rRNA. Aberrent mobility of certain RNA fragments on sequencing gels was observed as regions of band compression. These regions are postulated to be caused by stable internal base-pairing. The molecule was probed with T2 RNase in neutral (pH 7.5) and acidic (pH 4.5) buffers and only minor structural differences were revealed. One of the helices was found to be susceptible to enzymatic attack by both the single-strand and double-strand specific enzymes. These observations are evidence for the existence of dynamic structural equilibria in 5S rRNA.

Nuclease S1 analysis of eubacterial 5S rRNA secondary structure

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 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.

Ultraviolet light-induced crosslinking reveals a unique region of local tertiary structure in potato spindle tuber viroid and HeLa 5S RNA

The positions of intramolecular crosslinks induced by irradiation with ultraviolet light were mapped into potato spindle tuber viroid RNA and HeLa 5S rRNA. Crosslinking in each of these molecules occurred at a single major site, which was located by RNA fingerprinting and secondary analysis (and additional primer extension studies in the case of the viroid). Various lines of evidence suggest that these crosslinks identify a previously undescribed element of local tertiary structure common to these two widely divergent RNA molecules: (i) both crosslinks occur in an identical eight-base context, with the sequence 5' GGGAA 3' on one side and the sequence 5' UAC 3' on the other; (ii) both crosslinks connect bases that are not thought to be involved in conventional hydrogen bonding, within regions usually depicted as single-stranded loops flanked by short helical segments; and (iii) both crosslinks connect a purine and a pyrimidine residue, and both may generate the same G-U dimer. Furthermore, it is likely that the crosslinking site is of functional significance because it is located within the most highly conserved region of the viroid sequence and involves bases that are essentially invariant among eukaryotic 5S rRNA molecules.

The secondary structure of the 7SL RNA in the signal recognition particle: functional implications

The secondary structure of the 7SL RNA in the signal recognition particle was determined by applying both a theoretical and an experimental approach. The compensatory base change approach was taken comparing the published sequences of human, Drosophila and Xenopus 7SL RNA's. The deduced secondary structure was confirmed by post-labeling of an RNase V1-nicked dog SRP with P32-pCp and RNA-ligase and analysis of the labeled RNA-fragments by non-denaturing/denaturing 2D polyacrylamide gel electrophoresis. Two interesting features in the secondary structure were revealed: Firstly, bases at positions 122 to 127 of the human 7SL RNA are not only able to pair with bases at positions 167 to 170, but also with a single-stranded region of the bases at positions 223 to 228, suggesting an alternative base pairing scheme for the 7SL RNA in all three organisms. In agreement with this finding, four different conformations were identified after transcription of the 7SL RNA from the genomic human clone. The involvement of the particular basepairing interaction postulated was confirmed by the analysis of a 7SL RNA deletion mutant (Sma1-409). Secondly, a significant sequence homology of the paired bases at positions 236 to 255 and 104 to 109 in 7SL RNA with bases in 5S ribosomal RNA at the positions 84 to 110 was noticed, suggesting that 5S ribosomal and 7SL RNA interact with the same target during protein biosynthesis. These findings are summarized by proposing a mechanism for the translational arrest of protein synthesis by the signal recognition particle using specific sequences and an alternative configuration in the 7SL RNA.

Point mutational analysis of the Xenopus laevis 5S gene promoter

We have introduced C to T transitions into GC and CG base pairs of the Xenopus laevis somatic 5S gene coding region and its 5' flank in order to analyse their effects on transcription activity and regulation. These studies allow us to differentiate between the two promoter elements and their spacer, within the internal control region. Mutations within the 5' element which dissent from the corresponding tRNA consensus sequence reduce transcription activity substantially without significantly affecting transcription factor (TF) III A binding. Mutations in the spacer region have no pronounced effect on transcription. The 3' promoter element is found to extend to position 97, since mutations in this region interfere with transcription activity. This may be, at least partially, attributable to a reduced competition strength for TF III A.

Phylogenetic analysis of the genera Thiobacillus and Thiomicrospira by 5S rRNA sequences

5S rRNA nucleotide sequences from Thiobacillus neapolitanus, Thiobacillus ferrooxidans, Thiobacillus thiooxidans, Thiobacillus intermedius, Thiobacillus perometabolis, Thiobacillus thioparus, Thiobacillus versutus, Thiobacillus novellus, Thiobacillus acidophilus, Thiomicrospira pelophila, Thiomicrospira sp. strain L-12, and Acidiphilium cryptum were determined. A phylogenetic tree, based upon comparison of these and other related 5S rRNA sequences, is presented. The results place the thiobacilli, Thiomicrospira spp., and Acidiphilium spp. in the "purple photosynthetic" bacterial grouping which also includes the enteric, vibrio, pseudomonad, and other familiar eubacterial groups in addition to the purple photosynthetic bacteria. The genus Thiobacillus is not an evolutionarily coherent grouping but rather spans the full breadth of the purple photosynthetic bacteria.

Structure of a Neurospora RNA polymerase I promoter defined by transcription in vitro with homologous extracts

A Neurospora in vitro transcription system has been developed which specifically and efficiently initiates transcription of a cloned Neurospora crassa ribosomal RNA gene by RNA polymerase I. The initiation site of transcription (both in vitro and in vivo) appears to be located about 850 bp from the 5' end of mature 17S rRNA. However, the primary rRNA transcripts are normally cleaved very rapidly at a site 120-125 nt from the 5' end in vitro and in vivo. The nucleotide sequence surrounding the initiation site has been determined. The region from -16 to +9 exhibits partial homology to the corresponding sequences from a wide variety of organisms including yeast, but the most striking similarity is to the initiation region from Dictyostelium discoideum which displays 73% homology to the Neurospora sequence from -23 to +47. The Neurospora sequences from -96 to +97 have been shown to be sufficient for transcription. This region contains two sequences displaying 8/9 bp matches to elements of the 5S rDNA promoter.

Nucleotide sequence, secondary structure and evolution of the 5S ribosomal RNA from five bacterial species

The nucleotide sequences of the 5S ribosomal RNAs of the bacteria Agrobacterium tumefaciens, Alcaligenes faecalis, Pseudomonas cepacia, Aquaspirillum serpens and Acinetobacter calcoaceticus have been determined. The sequences fit in a generally accepted model for 5S RNA secondary structure. However, a closer comparative examination of these and other bacterial 5S RNA primary structures reveals the potential of additional base pairing and of multiple equilibria between a set of slightly different alternative secondary structures in one area of the molecule. The phylogenetic position of the examined bacteria is derived from a 5S RNA sequence alignment by a clustering method and compared with the position derived on the basis of 16S ribosomal RNA oligonucleotide catalogs.

Phylogeny of the 5S ribosomal RNA from Synechococcus lividus II: the cyanobacterial/chloroplast 5S RNAs form a common structural class

The complete nucleotide sequence of the 5S ribosomal RNA from the cyanobacterium Synechococcus lividus II has been determined. The sequence is (sequence in text) This 5S RNA has the cyanobacterial- and chloroplast-specific nucleotide insertion between positions 30 and 31 (using the numbering system of the generalized eubacterial 5S RNA) and the chloroplast-specific nucleotide-deletion signature between positions 34 and 39. The 5S RNA of S. lividus II has 27 base differences compared with the 5S RNA of the related strain S. lividus III. This large difference may reflect an ancient divergence between these two organisms. The electrophoretic mobilities on nondenaturing polyacrylamide gels of renatured 5S RNAs from S. lividus II, S. lividus III, and spinach chloroplasts are identical, but differ considerably from that of Escherichia coli 5S RNA. This most likely reflects differences in higher-order structure between the 5S RNA of E. coli and these cyanobacterial and chloroplast 5S RNAs.

Characterization of a Yellowstone hot spring microbial community by 5S rRNA sequences

The microorganisms inhabiting a 91 degrees C hot spring in Yellowstone National Park were characterized by sequencing 5S rRNAs isolated from the mixed, natural microflora without cultivation. By comparisons of these sequences with reference sequences, the phylogenetic relationships of the hot spring organisms to better characterized ones were established. Quantitation of the total 5S-sized rRNAs revealed a complex microbial community of three dominant members, a predominant archaebacterium affiliated with the sulfur-metabolizing (dependent) branch of the archaebacteria, and two eubacteria distantly related to Thermus spp. The archaebacterial and the eubacterial 5S rRNAs each constituted about half the examined population.

Primary and secondary structure of 26S ribosomal RNA of Oenothera mitochondria

The primary structure of 26S ribosomal RNA from mitochondria of the dicotyledoneous plant Oenothera berteriana is inferred from the sequence of a cloned rDNA restriction fragment. A tentative secondary structure model valid for Oenothera and for the major part of maize mitochondrial 26S rRNA has been constructed in analogy to the refined german model for E. coli L-rRNA (Maly and Brimacombe 1983). The derived structure generally matches the eubacterial model providing further support to the E. coli consensus structure. Some structural features however show eukaryotic characteristics. Possible interactions between L-rRNA, 5S rRNA and initiator-tRNA are discussed.

The 5.8S ribosomal RNA gene of Trypanosoma brucei: structural and transcriptional studies

To further investigate the process of discontinuous transcription in trypanosomes, the 5.8S rRNA gene, present in the trypanosome genome as part of the multicopy rRNA gene cluster, has been cloned, sequenced, chromosomally mapped, and used in transcriptional studies. The gene's sequence confirms its identity and indicates that it is less conserved evolutionarily than the trypanosome 5S rRNA gene previously described by our laboratory (6). Examination of the chromosomal locations of the gene by pulsed-field gradient gel electrophoresis shows that the 5.8S rRNA genes occur on at least four differently-sized chromosomes in T. b. rhodesiense and at least three differently-sized chromosomes in T. b. brucei. The 5.8S transcript was analyzed by a run-off transcription assay using isolated nuclei. These studies strongly suggest that the 5.8S rRNA gene is transcribed spliced leader RNA and by a different RNA polymerase than either the spliced leader or 5S rRNA transcripts. Transcription of the trypanosome 5.8S rRNA is insensitive to very high levels of alpha-amanitin, a feature of the 5.8S rRNA in higher eukaryotes.

Computer generation and statistical analysis of a data bank of protein sequences translated from GenBank

We describe PGtrans, a new and freely available protein sequence databank (2625 sequences, 554198 amino-acids). This data bank is routinely produced by automatic computer translation of the nucleotide sequence library GenBank. The information needed for the translation process (transcriptional orientation, location of coding regions, splice sites and pertinent genetic code) is gathered by the translation program through an "intelligent" scanning of the documentary field of each GenBank entry. Inconsistencies resulting in unexpected termination codons are detected and reported thus allowing the correction of data bank errors. PGtrans is intended as a tool for protein similarity searches. Its reasonable overall size (2 Moctets) makes it suitable for micro-computer environments. Up to date amino-acid composition data and relative abundances of di-, tri-, and tetra-peptides in proteins of known sequences are presented and discussed.

Pattern analysis of 5S rRNA

Some 200 different 5S rRNA sequences from eubacteria, chloroplasts, mitochondria, archaebacteria, and eukaryotes were analyzed for evolutionary kinship relationships and associated sequential features. Group-specific occupation schemes for the 149 positions of an overall alignment were established. Eubacterial, archaebacterial, and intermediate occupation schemes all yield a strongly biased base triplet pattern in one of the three possible reading frames strongest for eubacterial, chloroplastic, and archaebacterial, but still detectable for mitochondrial and eukaryotic cytoplasmic sequences. The frequency of triplets decays in the order RNY greater than RNR greater than YNY greater than YNR; R being a purine (guanine or adenine), Y is a pyrimidine (cytosine or uracil), and N is any base. A strong preference for guanine or cytosine was found in all triplet positions. The effects show no exceptions and are clearly above the level of statistical fluctuations.

5 S and 5.8 S ribosomal RNA sequences and protist phylogenetics

More than 100 5 S 5.8 S rRNA sequences from protists, including fungi, are known. Through a combination of quantitative treeing and special consideration of "signature' nucleotide combinations, the most significant phylogenetic implications of these data are emphasized. Also, limitations of the data for phylogenetic inferences are discussed and other significant data are brought to bear on the inferences obtained. 5 S sequences from red algae are seen as the most isolated among eukaryotics. A 5 S sequence lineage consisting of oomycetes, euglenoids, most protozoa, most slime molds and perhaps dinoflagellates and mesozoa is defined. Such a lineage is not evident from 5.8 S rRNA or cytochrome c sequence data. 5 S sequences from Ascomycota and Basidiomycota are consistent with the proposal that each is derived from a mycelial form with a haploid yeast phase and simple septal pores, probably most resembling present Taphrinales. 5 S sequences from Chytridiomycota and Zygomycota are not clearly distinct from each other and suggest that a major lineage radiation occurred in the early history of each. Qualitative biochemical data clearly supports a dichotomy between an Ascomycota-Basidiomycota lineage and a Zygomycota-Chytridiomycota lineage.

Characterization of the Trypanosoma brucei 5S ribosomal RNA gene and transcript: the 5S rRNA is a spliced-leader-independent species

Recent studies have shown that transcription occurs discontinuously for many genes in Trypanosoma brucei. To further investigate details of transcription in trypanosomes, the genes for the 5S ribosomal RNA from Trypanosoma brucei rhodesiense and Trypanosoma brucei brucei were cloned. Sequence analysis and Southern blotting showed the genes to be arranged in highly conserved tandem repeats of approx. 740 bp, which have no relation to the conserved 35-base spliced-leader repeat element. The genes contain internal control regions similar to 5S genes of other species, and studies of the 5S gene transcript show that it does not contain the conserved 35-base spliced-leader found at the 5' end of other trypanosome transcripts. Moreover, the 5S rRNA can be capped by guanylyltransferase from vaccinia virus, indicating that it has a 5' di- or triphosphate terminus. These results strongly suggest that the spliced-leader does not take part in the transcription of the 5S gene and that discontinuous transcription may be limited to particular classes of transcripts determined, as in other species, by the type of RNA polymerase used in their transcription. The DNA sequences of the 5S gene repeat from T.b. brucei and T.b. rhodesiense are presented, and their evolutionary significance is discussed.

Molecular organization of dinoflagellate ribosomal DNA: evolutionary implications of the deduced 5.8 S rRNA secondary structure

The 5.8 S rRNA gene of Prorocentrum micans, a primitive dinoflagellate, has been cloned and its 159 base pairs (bp) have been sequenced along with the two flanking internal transcribed spacers (ITS 1 and 2), respectively, 212 and 195 bp long. Nucleotide sequence homologies between several previously published 5.8 S rRNA gene sequences including those from another dinoflagellate, an ascomycetous yeast, protozoans, a higher plant and a mammal have been determined by sequence alignment. Two prokaryotic 5'-ends of the 23 S rRNA gene have been compared owing to their probable common origin with eucaryotic 5.8 S rRNA genes. Several nucleotides are distinctive for dinoflagellates when compared with either typical eucaryotes or procaryotes. This is consistent with an early divergence of the dinoflagellate lineage from the typical eucaryotes. The secondary structure of dinoflagellate 5.8 S rRNA molecules fits the model of Walker et al. (1983). Conserved nucleotides which distinguish dinoflagellate 5.8 S rRNA from that of other eucaryotes are located in specific loops which are assumed to play a structural role in the ribosome. A 5.8 S rRNA phylogenetic tree which is proposed, based on sequence data, supports our initial assumption of the dinoflagellates.

Partial methylation of two adjacent adenosines in ribosomes from Euglena gracilis chloroplasts suggests evolutionary loss of an intermediate stage in the methyl-transfer reaction

Bacterial, cytoplasmic and organellar ribosomes from a wide phylogenetic spectrum of organisms have a characteristic m6(2)Am6(2)A structure near the 3' end of the RNA of the small ribosomal subunit (SSU). We have studied one of the few exceptions to this extremely conserved post-transcriptionally modified sequence, i.e. dimethylation of only one of the two A's in chloroplasts from Euglena gracilis. It was established that only the A closest to the 5' end is dimethylated, the other one being unmodified. The methylation reaction was studied in vitro using ribosomes from a kasugamycin resistant mutant (ksgA) of Escherichia coli and purified methyl-transferase. Using limited amounts of the methyl donor S-adenosylmethionine (SAM) a partial level of methylation (50% of control) was attained. It is shown that in this case the 3' proximal A is dimethylated while the other is not. This suggests that dimethylation takes place in two successive stages. Apparently in E. gracilis chloroplasts the first stage of methylation does not occur.

Tandemly arranged variant 5S ribosomal RNA genes in the yeast Saccharomyces cerevisiae

Most of the ribosomal RNA genes of the yeast Saccharomyces cerevisiae are about 9 kilobases (kb) in size and encode both the 35S rRNA (processed to produce the 25S, 18S, and 5.8S species) and 5S rRNA. These genes are arranged in a single tandem array of 100 repeats. Below, we present evidence that at the centromere-distal end of this array is a tandem arrangement of a different type of rRNA gene. Each of these repeats is 3.6 kb in length and encodes a single 5S rRNA. The coding sequence of this gene is different from that of the "normal" 5S gene in three positions located at the 3' end of the gene.

Transcriptionally active and inactive gene repeats within the D. melanogaster 5S RNA gene cluster

Transcription of isolated repeat units of D. melanogaster 5S DNA in a Drosophila KcO cell extract revealed three types of template activities. 5SI DNA encodes the known 5S rRNA of D. melanogaster and has a relatively high transcription efficiency. 5SII DNA is identical to 5SI DNA except for a two-nucleotide deletion at 5S rRNA positions 28 and 29; the efficiency of transcription is approximately 40% that of 5SI DNA and because of the deletion, the primary transcript is two nucleotides shorter. 5SIII DNA does not support in vitro transcription (less than 2% 5SI DNA), but has the same sequence as 5SI DNA except for a single G to A transition at position 86. This is the first reported point-mutation in a 5S RNA gene resulting in loss of transcription function. Of approximately 23 5S rRNA gene copies in a cloned 5S DNA sub-cluster (p12D1) 19 appear to be of the transcriptionally inactive 5SIII DNA type.

Nucleotide base sequence of vibrionaceae 5 S rRNA

Nucleotide base sequences of 5 S rRNAs isolated from Vibrio vulnificus, Vibrio anguillarum, and Aeromonas hydrophila were determined. Comparisons among these and sequences of 5 S rRNAs from other species of Vibrionaceae provide information useful in the evaluation of the evolution of bacterial species.

Equilibria in 5-S ribosomal RNA secondary structure. Bulges and interior loops in 5-S RNA secondary structure may serve as articulations for a flexible molecule

The basic assumption in this paper is that the secondary structure of a 5-S ribosomal RNA cannot be represented by a single model. We propose that the molecule can adopt, at least within the ribosome, a series of slightly different structures of nearly equal stability. The different structures arise from the existence of ambiguous base-pairing opportunities in bulged helices and the adjacent interior loops. In eubacterial 5-S RNAs there is one such an area, in eukaryotic 5-S RNAs two such areas that can give rise to structural switches. We explain how a change in secondary structure in these areas may influence the relative orientation of the surrounding helices, in other words how bulges and interior loops may serve as articulations and give rise to a flexible tertiary structure.