Evolutionary change in 5S rRNA secondary structure and a phylogenic tree of 352 5S rRNA species

The secondary structure models of 5S rRNA have been constructed from the primary structure of 352 5S rRNA species available at present. All the 5S rRNAs examined can take essentially the same secondary structure, however they reveal characteristic differences between eukaryotes, metabacteria (= archaebacteria) and eubacteria. These three types of models can be further subgrouped by minor but characteristic differences. A phylogenic tree of organisms has been constructed using these 5S rRNA sequences by the weighted pairing method (WPG method). The tree reveals that there exist several major groups of eubacteria which seem to have diverged into different directions in the early stages of bacterial evolution. After emergence of eubacteria, metabacteria and eukaryotes separated from each other from their common ancestor. In the eukaryotic evolution, red algae (Rhodophyta) emerged first, and thereafter, thraustocytrids-Proctista, Ascomycota, green plants (green algae and land plants), Basidiomycota, Chromophyta (brown algae, diatoms and golden-yellow algae), slime- and water molds, various protozoans, and animals emerged in this order.     

Intermolecular hybridization of 5S rRNA with 18S rRNA: identification of a 5'-terminally-located nucleotide sequence in mouse 5S rRNA which base-pairs with two specific complementary sequences in 18S rRNA.

Eukaryotic 5S rRNA hybridizes specifically with 18S rRNA in vitro to form a stable intermolecular RNA:RNA hybrid. We have used 5S rRNA/18S rRNA fragment hybridization studies coupled with ribonuclease digestion and primer extension/chain termination analysis of 5S rRNA:18S rRNA hybrids to more completely map those mouse 5S rRNA and 18S rRNA sequences responsible for duplex formation. Fragment hybridization analysis has defined a 5'-terminal region of 5S rRNA (nucleotides 6-27) which base-pairs with two independent sequences in 18S rRNA designated Regions 1 (nucleotides 1157-1180) and 2 (nucleotides 1324-1339). Ribonuclease digestion of isolated 5S rRNA:18S rRNA hybrids with both single-strand- and double-strand-specific nucleases supports the involvement of this 5'-terminal 5S rRNA sequence in 18S rRNA hybridization. Primer extension/chain termination analysis of isolated 5S rRNA:18S rRNA hybrids confirms the base-pairing of 5S rRNA to the designated Regions 1 and 2 of 18S rRNA. Using these results, 5S rRNA:18S rRNA intermolecular hybrid structures are proposed. Comparative sequence analysis revealed the conservation of these hybrid structures in higher eukaryotes and the same but smaller core hybrid structures in lower eukaryotes and prokaryotes. This suggests that the 5S rRNA:16S/18S rRNA hybrids have been conserved in evolution for ribosome function.     

Identification of a structural motif of 23S rRNA interacting with 5S rRNA.

To identify RNA motifs interacting with 5S rRNA, a systematic evolution of ligands by exponential enrichment experiment was applied. Some of the resulting RNA aptamers contained a consensus sequence similar to the sequence in the loop region of helix 89 of 23S rRNA. We show that the synthetic helix 89 RNA motif indeed interacted with 5S rRNA and that the region around loop B of 5S rRNA was involved in this interaction. These results suggest the presence of a novel RNA-RNA interaction between 23S rRNA and 5S rRNA which may play an important role in the ribosome function.     

Interrelationships among major protistan groups based on a parsimony network of 5S rRNA sequences

To test the validity of the maximum parsimony approach to discern protistan interrelationships, we have derived an optimal network of 16S-like rRNA sequences using our parsimony algorithm and compared it with those reported using the distance matrix method. We have also derived an optimal network topology of 50 5S rRNA sequences through an interactive search using our algorithm. In both these networks, the kinetoplastids and euglenoids form a linkage group with Dictyostelium emerging from its neighbourhood. The cryptophytes, dinoflagellates and chromophytes and green algae emerge as independent lines suggesting that plastids arose more than once during protistan evolution. The large 5S rRNA tree further indicates independent origins of mesozoa and metazoa; kinetoplastids and ciliates; and diphyletic origin of fungi. Comparatively close positions of charales and land plants, chytrids and Zygomycetes, Physarum and amoeba, and red algae and green algae are also seen in this network.     

5S rRNA and ribosome

5S rRNA is an integral component of the ribosome of all living organisms. It is known that the ribosome without 5S rRNA is functionally inactive. However, the question about the specific role of this RNA in functioning of the translation apparatus is still open. This review presents a brief history of the discovery of 5S rRNA and studies of its origin and localization in the ribosome. The previously expressed hypotheses about the role of this RNA in the functioning of the ribosome are discussed considering the unique location of 5S rRNA in the ribosome and its intermolecular contacts. Based on analysis of the current data on ribosome structure and its functional complexes, the role of 5S rRNA as an intermediary between ribosome functional domains is discussed.     

5S rRNA Data Bank.

In this paper we present the updated version of the compilation of 5S rRNA and 5S rDNA nucleotide sequences. It contains 1622 primary structures of 5S rRNAs and 5S rRNA genes from 888 species. These include 58 archaeal, 427 eubacterial, 34 plastid, nine mitochondrial and 1094 eukaryotic DNA or RNA nucleotide sequences. The sequence entries are divided according to the taxonomic position of the organisms. All individual sequences deposited in the 5S rRNA Database can be retrieved using the WWW-based, taxonomic browser at http://rose.man.poznan.pl/5SData/5SRNA.html++ + or http://www.chemie. fu-berlin.de/fb_chemie/agerdmann/5S_rRNA.html . The files with complete sets of data as well as sequence alignments are available via anonymous ftp.     

The participation of 5S rRNA in the co-translational formation of a eukaryotic 5S ribonucleoprotein complex

The eukaryotic ribosomal 5S RNA–protein complex (5S rRNP) is formed by a co-translational event that requires 5S rRNA binding to the nascent peptide chain of eukaryotic ribosomal protein L5. Binding between 5S rRNA and the nascent chain is specific: neither the 5S rRNA nor the nascent chain of L5 protein can be substituted by other RNAs or other ribosomal proteins. The region responsible for binding 5S rRNA is located at positions 35–50 with amino acid sequence RLVIQDIKNKYNTPKYRM. Eukaryotic 5S rRNA binds a nascent chain having this sequence, but such binding is not substantive enough to form a 5S-associated RNP complex, suggesting that 5S rRNA binding to the nascent chain is amino acid sequence dependent and that formation of the 5S rRNP complex is L5 protein specific. Microinjection of 5S rRNP complex into the cytoplasm of Xenopus oocytes results in both an increase in the initial rate and also in the extent of net nuclear import of L5. This suggests that the 5S rRNP complex enhances nuclear transport of L5. We propose that 5S rRNA plays a chaperone-like role in folding of the nascent chain of L5 and directs L5 into a 5S rRNP complex for nuclear entry.     

An unusual 5S rRNA, from Sulfolobus acidocaldarius, and its implications for a general 5S rRNA structure.

The nucleotide sequence of the 5S ribosomal RNA of the thermoacidophilic archaebacterium Sulfolobus acidocaldarius was determined. The high degree of evident secondary structure in the molecule has implications for the common higher order structure of other 5S rRNAs, both bacterial and eukaryotic.     

Chemical modification of adenine residues in mouse 5S rRNA with monoperphthalate: the secondary structure of 5S rRNA

The chemical modification of adenine residues in mouse 5S rRNA with monoperphthalate was carried out to investigate the higher ordered structure of 5S rRNA. The adenine residues at positions 11, 22 (or/and 23), 49 (or/and 50), 54 (or/and 55), 77, 83, 88, 90 and 100 (or/and 101) were modified. This result further confirmed the secondary structure of 5S rRNA constituted of 5 helices and 5 loops postulated by other chemical modifications.     

An in silico exploration of the neutral network in protein sequence space

Designating amino-acid sequences that fold into a common main-chain structure as "neutral sequences" for the structure, regardless of their function or stability, we investigated the distribution of neutral sequences in protein sequence space. For four distinct target structures (alpha, beta,alpha/beta and alpha+beta types) with the same chain length of 108, we generated the respective neutral sequences by using the inverse folding technique with a knowledge-based potential function. We assumed that neutral sequences for a protein structure have Z scores higher than or equal to fixed thresholds, where thresholds are defined as the Z score for the corresponding native sequence (case 1) or much greater Z score (case 2). An exploring walk simulation suggested that the neutral sequences mapped into the sequence space were connected with each other through straight neutral paths and formed an inherent neutral network over the sequence space. Through another exploring walk simulation, we investigated contiguous regions between or among the neutral networks for the distinct protein structures and obtained the following results. The closest approach distance between the two neutral networks ranged from 5 to 29 on the Hamming distance scale, showing a linear increase against the threshold values. The sequences located at the "interchange" regions between the two neutral networks have intermediate sequence-profile-scores for both corresponding structures. Introducing a "ball" in the sequence space that contains at least one neutral sequence for each of the four structures, we found that the minimal radius of the ball that is centered at an arbitrary position ranged from 35 to 50, while the minimal radius of the ball that is centered at a certain special position ranged from 20 to 30, in the Hamming distance scale. The relatively small Hamming distances (5-30) may support an evolution mechanism by transferring from a network for a structure to another network for a more beneficial structure via the interchange regions.     

Saturation Mutagenesis of 5S rRNA in Saccharomyces cerevisiae

rRNAs are the central players in the reactions catalyzed by ribosomes, and the individual rRNAs are actively involved in different ribosome functions. Our previous demonstration that yeast 5S rRNA mutants (called mof9) can impact translational reading frame maintenance showed an unexpected function for this ubiquitous biomolecule. At the time, however, the highly repetitive nature of the genes encoding rRNAs precluded more detailed genetic and molecular analyses. A new genetic system allows all 5S rRNAs in the cell to be transcribed from a small, easily manipulated plasmid. The system is also amenable for the study of the other rRNAs, and provides an ideal genetic platform for detailed structural and functional studies. Saturation mutagenesis reveals regions of 5S rRNA that are required for cell viability, translational accuracy, and virus propagation. Unexpectedly, very few lethal alleles were identified, demonstrating the resilience of this molecule. Superimposition of genetic phenotypes on a physical map of 5S rRNA reveals the existence of phenotypic clusters of mutants, suggesting that specific regions of 5S rRNA are important for specific functions. Mapping these mutants onto the Haloarcula marismortui large subunit reveals that these clusters occur at important points of physical interaction between 5S rRNA and the different functional centers of the ribosome. Our analyses lead us to propose that one of the major functions of 5S rRNA may be to enhance translational fidelity by acting as a physical transducer of information between all of the different functional centers of the ribosome.     

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.