Nucleotide sequence and structure of cytoplasmic 5S RNA and 5.8S RNA of Chlamydomonas reinhardii.

Three small RNAs of the cytoplasmic 8OS ribosomes of the green unicellular alga Chlamydomonas reinhardii have been sequenced. They include two species of ribosomal 5S RNA, a major and a minor one of 122 and 121 nucleotides respectively, which differ from each other by 17 bases, and also the ribosomal 5.8S RNA of 156 nucleotides. Novel structural features can be recognized in the 5S RNAs of C. reinhardii by a comparison with published 5S RNA sequences. In addition the secondary structure of these small RNA molecules has been examined using a newly developed method based on differential nuclease susceptibility.     

S1 nuclease as a probe of yeast ribosomal 5 S RNA conformation.

5 S RNA was isolated from Saccharomyces cerevisiae grown in the presence of 32P-phosphate and digested with nuclease S1, a single-strand specific nuclease. Two different procedures were employed to determine the sites of attack on the RNA. First, 5 S RNA was isolated from nuclease S1 digests, digested to completion with ribonuclease T1, and then 'fingerprinted' by two-dimensional electrophoresis. Quantitation of each of the characteristic RNAase T1-derived oligonucleotides was employed to determine the relative susceptibility of various regions of the molecule to nuclease S1. A second procedure to define nuclease S1-susceptible sites in the molecule employed polyacrylamide gel electrophoretic fractionation of nuclease S1 digests followed by identification of the nucleotide sequences of the released RNA fragments. Both procedures showed that the region of the molecule between residues 9 and 60 was most susceptible to nuclease S1, with preferential cleavage occurring between residues 12-25 and 50-60. These results are discussed in relation to a proposed model for the secondary structure of yeast 5 S RNA.     

The conformation of 16S RNA in the 30S ribosomal subunit from Escherichia coli.

The digestion of E. coli 16S RNA with a single-strand-specific nuclease produced two fractions separable by gel filtration. One fraction was small oligonucleotides, the other, comprising 67.5% of the total RNA, was highly structured double helical fragments of mol. wt. 7,600. There are thus about 44 helical loops of average size corresponding to 12 base pairs in each 16S RNA. 10% of the RNA could be digested from native 30S subunits. Nuclease attack was primarily in the intraloop single-stranded region but two major sites of attack were located in the interloop single-stranded regions. Nuclease digestion of unfolded subunits produced three classes of fragments, two of which, comprising 80% of the total RNA, were identical to fragments from 16S RNA. The third, consisting of 20% RNA, together with an equal weight of peotein, was a resistant core (sedimentation coefficient 7S).     

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.     

Apparent association constants for E. coli ribosomal proteins S4, S7, S8, S15, S17 and S20 binding to 16S RNA.

We have previously reported the development of a technique utilizing nitrocellulose filters, which rapidly separates ribosomal protein-ribosomal RNA complexes from unbound protein. We have used this technique to obtain binding data for the association of proteins S4, S7, S8, S15, S17, and S20 with 16S RNA. With the exception of protein S17, the association behavior for each of these proteins exhibits a single binding site with a unique binding constant. The apparent association constants have been calculated and have been found to have a range from 1.6 x 10(6) M-1 for protein S7 to 7.1 x 10(7) M-1 for protein S17. The Scatchard plot for the protein S17 binding data is biphasic, suggesting that within the RNA population two different binding sites exist, each with a different apparent association constant.     

Quantitative Measurement of Rates of 5S RNA and Transfer RNA Synthesis in Sea Urchin Embryos

Embryonic differentiation is believed to be due to a programmed expression of genes, which includes their time of activation, sequence of appearance, and amount transcribed into the immediate gene product, RNA. Differential synthesis of the major RNA classes, such as the ribosomal RNAs (28S, 18S, 5S) and transfer RNA (tRNA), characterizes many animal developing systems, including the sea urchin embryological system. Previous work has shown that the genes for 5S RNA and tRNA are active during early cleavage in sea urchin embryos. The present study focused on quantitatively measuring and comparing the rate of 5S RNA and tRNA synthesis in cleavage, early blastula, and early pluteus embryos of Arbacia punctulata. At each stage, embryos were labeled for 3 h with [8-³H]-guanosine. Total cellular RNA was extracted using the cold (4°C)-phenol-sodium dodecyl sulfate method and purified (LiCl-soluble) RNA preparations were fractionated by electrophoresis on 10% polyacrylamide gels. The amount of 5S RNA and tRNA synthesized at each stage was calculated from the radioactivity coincident with the 5S RNA and with the tRNA absorbance peaks (A_{260 nm}) on each gel, from the known guanosine monophosphate (GMP) compositions of sea urchin 5S RNA and tRNA and from the average specific radioactivity of the GTP precursor pool during each 3 h labeling period. The results showed that on a per embryo basis the rates of 5S RNA and tRNA synthesis increased slightly (about 1.4-fold) from cleavage through pluteus stages, while on a per cell basis the rates declined severalfold (about 3-fold) during embryogenesis. The rates of 5S RNA and tRNA synthesis determined here parallel previously-reported levels of RNA polymerase III in sea urchin embryos, suggesting that cellular levels of RNA polymerase III may exert some positive control over 5S RNA and tRNA synthesis during sea urchin embryogenesis.     

5S RNA may not have highly ordered structure like 4S RNAS

The rates of hydrolysis of the following polyribonucleotides as catalysed by RNase I, an enzyme specific for single stranded RNAs, follow the sequence shown; poly (A) > 23S RNA > 5S RNA ? 16S RNA > 4S RNA = poly (I). poly (C). The rates were measured by direct spectrophotometric as well as by trichloroacetic acid precipitation methods. The extents of inhibition of RNase I-catalysed hydrolysis of poly (A) by each of the above-mentioned polyribonucleotides follow the reverse order. Taking into account the fact that double stranded RNAs are inhibitory to RNase I it may be concluded from the above results that 5S RNA has much less ordered structure than 4S RNAs. This prediction is contrary to expectations and its validity will be known when the tertiary structure of 5S RNA will be worked out. These results also indicate that 16S RNA may have more folded structure than 23S RNA.     

Transcription of 70S RNA by DNA polymerases from mammalian RNA viruses.

DNA polymerases purified by the same procedure from four mammalian RNA viruses, simian sarcoma virus type 1, gibbon ape lymphoma virus, Mason-Pfizer monkey virus, and Rauscher murine leukemia virus are capable of transcribing heteropolymeric regions of viral 70S RNA without any other primer. In this reconstituted system the enzymes from simian sarcoma virus type 1, Mason-Pfizer monkey virus, and Rauscher murine leukemia virus transcribe viral 70S RNA almost as efficiently as the DNA polymerase from the avian myeloblastosis virus, but gibbon ape lymphoma virus DNA polymerase is approximately three-to fivefold less efficient. Although there is a substantial difference among the sizes of these DNA polymerases (160,000 daltons for the avian myeloblastosis virus enzyme, 110,000 daltons for the Mason-Pfizer monkey virus enzyme, and 70,000 daltons for the mammalian type C viral polymerases), the ability to transcribe viral 70S RNA is a characteristic common to these enzymes.     

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).     

Both yeast W double-stranded RNA and its single-stranded form 20S RNA are linear.

Most yeast strains carry a cytoplasmic double-stranded RNA (dsRNA) molecule called W, of 2.5 kb in size. We have cloned and sequenced most of W genome (1), and we proposed that W (+) strands were identical to 20S RNA, a single-stranded RNA (ssRNA) species, whose copy number is highly induced under stress conditions. Recently it was proposed that 20S RNA was circular (2). In this paper, however, we demonstrate that both W dsRNA and 20S RNA are linear. Linearity of W dsRNA is shown by the stoichiometric labelling of both strands of W with 32P-pCp and T4 RNA ligase. The last 3' end nucleotide of both strands is about 70 to 80% C and 20 to 30% A. Linearity of 20S RNA is directly demonstrated by a site-specific cleavage of 20S RNA with RNase H, using an oligodeoxynucleotide complementary to an internal site of 20S RNA. The cleavage produced not one but two RNA fragments expected from the linearity of 20S RNA.     

Nucleotide sequence study of mouse 5.8S ribosomal RNA.

The primary structure of 5.8S mouse ribosomal RNA has been studied and compared to the structures previously established for other animal species. The results obtained show that mouse 5.8S ribosomal RNA yields pancreatic oligonucleotides with the same nucleotide sequence as the homologous oligonucleotides from rat cells. Furthermore T1 oligonucleotides of 5.8S ribosomal RNA from rat, mouse and human cells behave identically on fingerprinting fractionation and have the same composition as judged by pancreatic digestion. These results strongly suggest that the primary structures of 5.8S ribosomal RNA from rat, mouse and human cells are identical. This identity of structure is also found when the presence of several modified bases (psi and methylated bases) is considered. The findings emphasize the remarkable evolutionary stability of ribosomal gene structure. Comparison of the terminal regional of 5.8S RNA with those of 18S RNA reveals differences which imply a more complex mechanism underlying the maturation of 45S precursor RNA than the finding of identical structure would have suggested.     

Escherichia coli 4.5S RNA gene function can be complemented by heterologous bacterial RNA genes.

The essential 4.5S RNA gene of Escherichia coli can be complemented by 4.5S RNA-like genes from three other eubacteria, including both gram-positive and gram-negative organisms. Two of the genes encode RNAs similar in size to the E. coli species; the third, from Bacillus subtilis, specifies an RNA more than twice as large. The heterologous genes are expressed efficiently in E. coli, and the product RNAs resemble those produced by cognate cells. We conclude that the heterologous RNAs can replace E. coli 4.5S RNA and that the essential function of 4.5S RNA is evolutionarily conserved. A consensus structure is presented for the functionally related 4.5S RNA homologs.     

Oocyte and somatic 5S ribosomal RNA and 5S RNA encoding genes in Xenopus tropicalis.

We have investigated the structure of oocyte and somatic 5S ribosomal RNA and of 5S RNA encoding genes in Xenopus tropicalis. The sequences of the two 5S RNA families differ in four positions, but only one of these substitutions, a C to U transition in position 79 within the internal control region of the corresponding 5S RNA encoding genes, is a distinguishing characteristic of all Xenopus somatic and oocyte 5S RNAs characterized to date, including those from Xenopus laevis and Xenopus borealis. 5S RNA genes in Xenopus tropicalis are organized in clusters of multiple repeats of a 264 base pair unit; the structural and functional organization of the Xenopus tropicalis oocyte 5S gene is similar to the somatic but distinct from the oocyte 5S DNA in Xenopus laevis and Xenopus borealis. A comparative sequence analysis reveals the presence of a strictly conserved pentamer motif AAAGT in the 5'-flanking region of Xenopus 5S genes which we demonstrate in a separate communication to serve as a binding signal for an upstream stimulatory factor.