Incorporation of 5S RNA into 16S-23S RNA complex

5S RNA as such is not incorporated into 16S-23S RNA complex formed under reconstitution condition. However, the addition of 50S ribosomal proteins, L5, L18 and L25/L15 results in its incorporation in stoichiometric amount. None of the proteins added individually is capable of incorporating 5S RNA into the complex. Of the different combinations in pairs that are possible out of the four proteins, the pairs L5, L18 and L15, L18 stimulate the incorporation to some extent. Of the four possible triplets, L5, L18, L25 or L5, L15, L18 is the most efficient for maximum incorporation of 5S RNA. The presence of all the four proteins is no more effective than the combinations of the three.     

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/.     

In vitro association of unique species of cellular 4S RNA with 35S RNA of RNA tumor viruses

Unique 4S RNA species from AKR mouse embryo cells hybridize with AKR murine leukemia virus and avian myeloblastosis virus 35S RNAs $\text{in vitro}$. Analyses by reversed-phase column chromatography indicate that the major 4S species that hybridize with the two viral RNAs are probably the same. A 4S RNA species with similar chromatographic properties is a major component of the AKR viral 4S RNA which associates with the viral 70S RNA $\text{in vivo}$.     

Photo-induced protein cross-linking to 5S RNA and 28-5.8S RNA within rat-liver 60S ribosomal subunits

Rat liver 60S ribosomal subunits were irradiated with 254-nm ultraviolet light (1.26 X 10(4) quanta/subunit), under conditions which preserved their functional activity. Cross-linked RNA-protein complexes were recovered after unreacted proteins had been removed by repeated acetic acid extractions. Proteins linked to the whole rRNA, to 5S RNA and to 28-5.8 S RNAs were identified by two-dimensional gel electrophoresis after RNA hydrolysis by ribonucleases T1 and A. Our results showed that numerous proteins interact with rRNAs (at least ten with 28-5.8 S RNA, eight with 5S RNA and among these three are common to both) and have been discussed in the light of all the available data.     

6S RNA regulates E. coli RNA polymerase activity

The E. coli 6S RNA was discovered more than three decades ago, yet its function has remained elusive. Here, we demonstrate that 6S RNA associates with RNA polymerase in a highly specific and efficient manner. UV crosslinking experiments revealed that 6S RNA directly contacts the sigma70 and beta/beta' subunits of RNA polymerase. 6S RNA accumulates as cells reach the stationary phase of growth and mediates growth phase-specific changes in RNA polymerase. Stable association between sigma70 and core RNA polymerase in extracts is only observed in the presence of 6S RNA. We show 6S RNA represses expression from a sigma70-dependent promoter during stationary phase. Our results suggest that the interaction of 6S RNA with RNA polymerase modulates sigma70-holoenzyme activity.     

Nucleotide sequence of 7 S RNA. Homology to Alu DNA and La 4.5 S RNA

7 S RNA, a component of normal higher eukaryotic cells and several oncornaviruses, was shown to be conserved in evolution (Erikson, E., Erikson, R. L., Henry, B., and Pace, N. R. (1973) Virology 53, 40-46). Recently, 7 S RNA was shown to be partially complementary to Alu family DNA sequences (Weiner, A. (1980) Cell 22, 209-218). In the present study the nucleotide sequence of Novikoff hepatoma 7 S RNA was determined to be: (formula, see text) Comparison of 7 S RNA, Alu and B1 family DNA, and La 4.5 S RNA sequences for homologies showed that 1) one-third of 7 S RNA, mainly the 5'-end, was homologous to Alu and B1 family sequences; 2) one 300-nucleotide long Alu family sequence contained two binding sites for 7 S RNA; and 3) the 5'-ends of 7 S RNA and La 4.5 S RNA also had extensive (60%) homologies. A model for the secondary structure of 7 S RNA based on maximal base pairing and preferential nuclease cleavage sites is also presented.     

Translation of Sindbis virus 26 S RNA and 49 S RNA in lysates of rabbit reticulocytes

Sindbis virus-specific polypeptides were synthesized in lysates of rabbit reticulocytes in response to added 26 S or 49 S RNA. Sindbis 26 S RNA was translated into as many as three polypeptides which co-migrate in acrylamide gels with proteins found in infected cells.Wild type 26 S RNA was translated primarily into two polypeptides, which appear to be the Sindbis nucleocapsid protein (mol. wt 30,000) and the precursor of the two glycoproteins of the virion (mol. wt 100,000). A larger polypeptide (mol. wt 130,000) was synthesized in response to ts2 26 S RNA, a species of RNA which was isolated from cells infected with the ts2 mutant of Sindbis virus. This large polypeptide is apparently the protein which accumulates in cells infected with the mutant virus and which is thought to be a precursor of all three viral structural proteins.These results support the hypothesis that 26 S RNA is the messenger for the three structural proteins of the virion and that the RNA codes for one large polypeptide precursor. The precursor may then be cleaved at a specific site to yield the nucleocapsid protein and a second polypeptide which, in infected cells, is cleaved in a series of steps to yield the two glycoproteins of the virion.Sindbis 49 S RNA was translated into eight or nine polypeptides ranging from 60,000 to 180,000 molecular weights. The viral structural proteins, as such, were not synthesized in response to the added 49 S RNA.     

Computer modeling 16 S ribosomal RNA

A three-dimensional structure for 16 S RNA has been produced with a computer protocol that is not dependent on human intervention. This protocol improves upon traditional modeling techniques by using distance geometry to fold the molecule in an objective and reproducible fashion. The method is based on the secondary structure of RNA and treats the molecule as a set of double-stranded helices that are linked by flexible single-strands of variable length. Data derived from chemical cross-linking studies of 16 S RNA and tertiary phylogenetic relationships provide the constraints used to fold the molecule into a compact three-dimensional form. Possibly subjective evaluation of the input data are transformed into verifiable quantitative parameters. Relationships based on general locations within the 30 S subunit or on protein-RNA interactions have been specifically excluded. The resolution of the model exceeds that of electron micrographs and approaches that obtained in preliminary X-ray crystal structures. The model size of 245 x 190 x 140 A is compatible with that of the 30 S subunit as determined by electron microscopy. The volume of the model is 1.87 x 10(6) A which is similar to that of the small subunit in a preliminary X-ray crystal structure. The radius of gyration of the model structure of 76 A is intermediate to that seen for partially denatured and fully folded 16 S RNA. Computer graphics are used to display the results in a manner that maximizes the opportunities for human visual interpretation of the models. A format for displaying the structures has been developed that will make it possible for researchers who have not devoted themselves to ribosomal modeling to comprehend and make use of the information that the models embody. On this basis the computer-generated models are compared with models developed by other researchers and with structural data not included in the folding parameter data set.     

Linkage of 5S RNA and 16S+23S RNA genes on the E. coli chromosome.

Summary Episomes carrying limited regions of the chromosome where 5S RNA genes have previously been located are described. The DNA purified from each of these episomes contains one gene per molecule for each of the three ribosomal RNA species as shown by hybridization experiments.This work was supported in part by a grant from the C.E.A.     

Is 20S RNA naked?

The 20S RNA of Saccharomyces cerevisiae is a single-stranded, circular RNA virus. A previous study suggested that this RNA is part of a 32S ribonucleoprotein particle, being associated with multiple copies of a 23-kilodalton protein. We show here that this protein is, in fact, the chromosome-encoded heat shock protein Hsp26. Furthermore, it is apparently not associated with 20S RNA and plays no obvious role in the life cycle of the virus.     

Molecular evolution of 5S RNA

Summary Based on the comparative analyses of the primary structure of 5S RNAs from 19 organisms, a secondary structure model of 5S RNA is proposed. 5S RNA has essentially the same structure among all prokaryotic species. The same is true for eukaryotic 5S RNAs. Prokaryotic and eukaryotic 5S RNAs are also quite similar to each other, except for a difference in a specific region.By comparing the nucleotide alignment from the juxtaposed 5S RNA secondary structures, a phylogenic tree of nineteen organisms was constructed. The time of divergence between prokaryotes and eukaryotes was estimated to be 2.5×10⁹ years ago (minimum estimate: 2.1×10⁹).