Nucleotide sequence of a crustacean 18S ribosomal RNA gene and secondary structure of eukaryotic small subunit ribosomal RNAs

The primary structure of the gene for 18 S rRNA of the crustacean Artemia salina was determined. The sequence has been aligned with 13 other small ribosomal subunit RNA sequences of eukaryotic, archaebacterial, eubacterial, chloroplastic and plant mitochondrial origin. Secondary structure models for these RNAs were derived on the basis of previously proposed models and additional comparative evidence found in the alignment. Although there is a general similarity in the secondary structure models for eukaryotes and prokaryotes, the evidence seems to indicate a different topology in a central area of the structures.     

Evolutionary relationships amongst archaebacteria. A comparative study of 23 S ribosomal RNAs of a sulphur-dependent extreme thermophile, an extreme halophile and a thermophilic methanogen

The 23 S RNA genes representative of each of the main archaebacterial subkingdoms, Desulfurococcus mobilis an extreme thermophile, Halococcus morrhuae an extreme halophile and Methanobacterium thermoautotrophicum a thermophilic methanogen, were cloned and sequenced. The inferred RNA sequences were aligned with all the available 23 S-like RNAs of other archaebacteria, eubacteria/chloroplasts and the cytoplasm of eukaryotes. Universal secondary structural models containing six major structural domains were refined, and extended, using the sequence comparison approach. Much of the present structure was confirmed but six new helices were added, including one that also exists in the eukaryotic 5.8 S RNA, and extensions were made to several existing helices. The data throw doubt on whether the 5' and 3' ends of the 23 S RNA interact, since no stable helix can form in either the extreme thermophile or the methanogen RNA. A few secondary structural features, specific to the archaebacterial RNAs were identified; two of these were supported by a comparison of the archaebacterial RNA sequences, and experimentally, using chemical and ribonuclease probes. Seven tertiary structural interactions, common to all 23 S-like RNAs, were predicted within unpaired regions of the secondary structural model on the basis of co-variation of nucleotide pairs; two lie in the region of the 23 S RNA corresponding to 5.8 S RNA but they are not conserved in the latter. The flanking sequences of each of the RNAs could base-pair to form long RNA processing stems. They were not conserved in sequence but each exhibited a secondary structural feature that is common to all the archaebacterial stems for both 16 S and 23 S RNAs and constitutes a processing site. Kingdom-specific nucleotides have been identified that are associated with antibiotic binding sites at functional centres in 23 S-like RNAs: in the peptidyl transferase centre (erythromycin-domain V) the archaebacterial RNAs classify with the eukaryotic RNAs; at the elongation factor-dependent GTPase centre (thiostrepton-domain II) they fall with the eubacteria, and at the putative amino acyl tRNA site (alpha-sarcin-domain VI) they resemble eukaryotes. Two of the proposed tertiary interactions offer a structural explanation for how functional coupling of domains II and V occurs at the peptidyl transferase centre. Phylogenetic trees were constructed for the archaebacterial kingdom, and for the other two kingdoms, on the basis of the aligned 23 S-like RNA sequences.(ABSTRACT TRUNCATED AT 400 WORDS)     

Genes encoding the 7S RNA and tRNA(Ser) are linked to one of the two rRNA operons in the genome of the extremely thermophilic archaebacterium Methanothermus fervidus

Analysis of gene structure in the extremely thermophilic archaebacterium, Methanothermus fervidus, has revealed the presence of a cluster of stable RNA-encoding genes arranged 5'-7S RNA-tRNA(Ser)-16S rRNA-tRNA(Ala)-23S rRNA-5S rRNA. The genome of M. fervidus contains two rRNA operons but only one operon has the closely linked 7S RNA-encoding gene. The sequences upstream from the two rRNA operons are identical for 206 bp but diverge at the 3' base of the tRNA(Ser) gene. The secondary structures predicted for the M. fervidus 7S, 16S rRNA, tRNA(Ala) and tRNA(Ser) have been compared with those of functionally homologous molecules from moderately thermophilic and mesophilic archaebacteria. A consensus secondary structure for archaebacterial 7S RNAs has been developed which incorporates bases and structural features also conserved in eukaryotic signal-recognition-particle RNAs and eubacterial 4.5S RNAs.     

Consensus structure and evolution of 5S rRNA

A consensus structure model of 5S rRNA presenting all conserved nucleotides in fixed positions has been deduced from the primary and secondary structure of 71 eubacterial, archaebacterial, eukaryotic cytosolic and organellar molecules. Phylogenetically related groups of molecules are characterized by nucleotide deletions in helices III, IV and V, and by potential base pair interactions in helix IV. The group-specific deletions are correlated with the early branching pattern of a dendrogram calculated from nucleotide substitution data: the first major division separates the group of eubacterial and organellar molecules from a second group containing the common ancestors of archaebacterial and eukaryotic/cytosolic molecules. The earliest diverging branch of the eubacterial/organellar group includes molecules from Thermus thermophilus, T. aquaticus, Rhodospirillum rubrum, Paracoccus denitrificans and wheat mitochondria.     

Evolutionary changes in the higher order structure of the ribosomal 5S RNA.

Comparative studies have been undertaken on the higher order structure of ribosomal 5S RNAs from diverse origins. Competitive reassociation studies show that 5S RNA from either a eukaryote or archaebacterium will form a stable ribonucleoprotein complex with the yeast ribosomal 5S RNA binding protein (YL3); in contrast, eubacterial RNAs will not compete in a similar fashion. Partial S1 ribonuclease digestion and ethylnitrosourea reactivity were used to probe the structural differences suggested by the reconstitution experiments. The results indicate a more compact higher order structure in eukaryotic 5S RNAs as compared to eubacteria and suggest that the archaebacterial 5S RNA contains features which are common to either group. The potential significance of these results with respect to a generalized model for the tertiary structure of the ribosomal 5S RNA and to the heterogeneity in the protein components of 5S RNA-protein complexes are discussed.     

The nucleotide sequence of the gene coding for the 16S rRNA from the archaebacterium Halobacterium halobium

The complete 1473-bp sequence of the 16S rRNA gene from the archaebacterium Halobacterium halobium has been determined. Alignment with the sequences of the 16S rRNA gene from the archaebacteria Halobacterium volcanii and Halococcus morrhua reveals similar degrees of homology, about 88%. Differences in the primary structures of H. halobium and eubacterial (Escherichia coli) 16S rRNA or eukaryotic (Dictyostelium discoideum) 18S rRNA are much higher, corresponding to 63% and 56% homology, respectively. A comparison of the nucleotide sequence of the H. halobium 16S rRNA with those of its archaebacterial counterparts generally confirms a secondary structure model of the RNA contained in the small subunit of the archaebacterial ribosome.     

Sequences of the 5S rRNAs of the thermo-acidophilic archaebacterium Sulfolobus solfataricus (Caldariella acidophila) and the thermophilic eubacteria Bacillus acidocaldarius and Thermus aquaticus.

We have determined the nucleotide sequences of the 5 S rRNAs of three thermophilic bacteria: the archaebacterium Sulfolobus solfataricus, also named Caldariella acidophila, and the eubacteria Bacillus acidocaldarius and Thermus aquaticus. A 5 S RNA sequence for the latter species had already been published, but it looked suspect on the basis of its alignment with other 5 S RNA sequences and its base-pairing pattern. The corrected sequence aligns much better and fits in the universal five helix secondary structure model, as do the sequences for the two other examined species. The sequence found for Sulfolobus solfataricus is identical to that determined by others for Sulfolobus acidocaldarius. The secondary structure of its 5 S RNA shows a number of exceptional features which distinguish it not only from eubacterial and eukaryotic 5 S RNAs, but also from the limited number of archaebacterial 5 S RNA structures hitherto published. The free energy change of secondary structure formation is large in the three examined 5 S RNAs.     

4.5S RNA: does form predict function?

4.5S RNA is a stable RNA of Escherichia coli, and functional homologs of the molecule apparently exist in all prokaryotes: eubacteria, archebacteria, and mycoplasma. Genetic and physiological measurements of the function of 4.5S RNA in E. coli indicate a role for this RNA in protein synthesis. A conserved domain of 4.5S RNA displays structural similarity with the eukaryotic 7S RNA that functions in protein secretion. Although complementation by eukaryotic 7S RNAs remains to be demonstrated, a number of archaebacterial 7S RNAs are able to replace 4.5S RNA for growth of E. coli, and 4.5S RNA is able to mediate a number of 7S RNA functions in vitro. Surprisingly, no effects on protein secretion in E. coli have been directly attributed to 4.5S RNA. These observations raise the question of whether molecules of similar structure necessarily perform the same function.     

Sequence comparison of glyceraldehyde-3-phosphate dehydrogenases from the three urkingdoms: evolutionary implication

The primary structure of the glyceraldehyde-3-phosphate dehydrogenase from the archaebacteria shows striking deviation from the known sequences of eubacterial and eukaryotic sequences, despite unequivocal homologies in functionally important regions. Thus, the structural similarity between the eubacterial and eukaryotic enzymes is significantly higher than that between the archaebacterial enzymes and the eubacterial and eukaryotic enzymes. This preferred similarity of eubacterial and eukaryotic glyceraldehyde-3-phosphate dehydrogenase structures does not correspond to the phylogenetic distances among the three urkingdoms as deduced from comparisons of ribosomal ribonucleic acid sequences. Indications will be presented that the closer relationship of the eubacterial and eukaryotic glyceraldehyde-3-phosphate dehydrogenase resulted from a gene transfer from eubacteria to eukaryotes after the segregation of the three urkingdoms.     

Relatedness of archaebacterial RNA polymerase core subunits to their eubacterial and eukaryotic equivalents.

The sequence of the genes encoding the four largest subunits of the RNA polymerase of the archaebacterium Methanobacterium thermoautotrophicum was determined and putative translation signals were identified. The genes are more strongly homologous to eukaryotic than to eubacterial RNA polymerase genes. Analysis of the polypeptide sequences revealed colinearity of two pairs of adjacent archaebacterial genes encoding the B" and B' or A and C genes, respectively, with two eubacterial and two eukaryotic genes each encoding the two largest RNA polymerase subunits. This difference in sequence organization is discussed in terms of gene fusion in the course of evolution. The degree of conservation is much higher between the archaebacterial and the eukaryotic polypeptides than between the archaebacterial and the eubacterial enzyme. Putative functional domains were identified in two of the subunits of the archaebacterial enzyme.     

Phylogenetic analysis and evolution of RNase P RNA in proteobacteria.

The secondary structures of the eubacterial RNase P RNAs are being elucidated by a phylogenetic comparative approach. Sequences of genes encoding RNase P RNA from each of the recognized subgroups (alpha, beta, gamma, and delta) of the proteobacteria have now been determined. These sequences allow the refinement, to nearly the base pair level, of the phylogenetic model for RNase P RNA secondary structure. Evolutionary change among the RNase P RNAs was found to occur primarily in four discrete structural domains that are peripheral to a highly conserved core structure. The new sequences were used to examine critically the proposed similarity (C. Guerrier-Takada, N. Lumelsky, and S. Altman, Science 246:1578-1584, 1989) between a portion of RNase P RNA and the "exit site" of the 23S rRNA of Escherichia coli. Phylogenetic comparisons indicate that these sequences are not homologous and that any similarity in the structures is, at best, tenuous.     

The structure of the archaebacterial ribosomal protein S7 and its possible interaction with 16S rRNA.

Ribosomal protein S7 is one of the ubiquitous components of the small subunit of the ribosome. It is a 16S rRNA-binding protein positioned close to the exit of the tRNA, and it plays a role in initiating assembly of the head of the 30S subunit. Previous structural analyses of eubacterial S7 have shown that it has a stable alpha-helix core and a flexible beta-arm. Unlike these eubacterial proteins, archaebacterial or eukaryotic S7 has an N-terminal extension of approximately 60 residues. The crystal structure of S7 from archaebacterium Pyrococcus horikoshii (PhoS7) has been determined at 2.1 A resolution. The final model of PhoS7 consists of six major alpha-helices, a short 3(10)-helix and two beta-stands. The major part (residues 18-45) of the N-terminal extension of PhoS7 reinforces the alpha-helical core by well-extended hydrophobic interactions, while the other part (residues 46-63) is not visible in the crystal and is possibly fixed only by interacting with 16S rRNA. These differences in the N-terminal extension as well as in the insertion (between alpha1 and alpha2) of the archaebacterial S7 structure from eubacterial S7 are such that they do not necessitate a major change in the structure of the currently available eubacterial 16S rRNA. Some of the inserted chains might pass through gaps formed by helices of the 16S rRNA.     

Archaebacteria and eukaryotes possess DNA-dependent RNA polymerases of a common type

DNA-dependent RNA polymerases of archaebacteria not only resemble the nuclear RNA polymerases of eukaryotes rather than the eubacterial enzymes in their complex component patterns but also show striking immunochemical, i.e., structural, homology with the eukaryotic polymerases at the level of single components. Thus, eukaryotic and archaebacterial RNA polymerases are indeed of the same type, distinct from the eubacterial enzymes, which, however, are also derived from a common ancestral structure.     

The nucleotide sequence of the 16S ribosomal RNA gene of the archaebacterium Halococcus morrhua.

The sequence of the 16S rRNA gene from the archaebacterium Halococcus morrhua was determined by the dideoxynucleotide sequencing method. It is 1475 nucleotides long. This is the second archaebacterial sequence to be determined and it provides sequence comparison evidence for the secondary structural elements confined to the RNAs of this kingdom and, also, support for controversial or additional base pairing in the eubacterial RNAs. Six structural features are localized that have varied during the evolution of the archaebacteria, eubacteria and eukaryotes. Moreover, although the secondary structures of both sequenced archaebacterial RNAs strongly resemble those of eubacteria, they contain sufficient eukaryotic-like structural characteristics to reinforce the view that they belong to a separate line of evolutionary descent.     

Comparison of eubacterial and eukaryotic 5S RNA structures: a chemical modification study

The 5S RNAs from Bacillus stearothermophilus and Saccharomyces cerevisiae were probed by nucleotide-specific reagents, with a view to compare and contrast their higher order structures. The progressive unfolding of the RNAs during heating, in the presence and absence of magnesium, was monitored. Evidence was provided for the double-helical segments which occur in the secondary structural models of both RNAs. The results also placed constraints on the possible structuring of the remainder of the RNA and yielded some insight into ways of folding up the molecule. Together with the data from our earlier studies, employing ribonucleases, these results provide a detailed picture of the structuring and topography of the 5S RNAs. The main structural differences between the eubacterial and eukaryotic RNAs occur throughout the loop D/helix IV/loop E/helix V arm; in particular strong evidence is provided for loop D of the eukaryotic RNA being involved in a tertiary interaction.     

5S Ribosomal RNA Database

Ribosomal 5S RNA (5S rRNA) is an integral component of the large ribosomal subunit in all known organisms with the exception only of mitochondrial ribosomes of fungi and animals. It is thought to enhance protein synthesis by stabilization of a ribosome structure. This paper presents the updated database of 5S rRNA and their genes (5S rDNA). Its short characteristics are presented in the Introduction. The database contains 2280 primary structures of 5S rRNA and 5S rRNA genes. These include 536 eubacterial, 61 archaebacterial, 1611 eukaryotic and 72 organelle sequences. The database is available on line through the World Wide Web at http://biobases.ibch.poznan.pl/5SData/.