Location of single-stranded and double-stranded regions in rat liver ribosomal 5S RNA and 5.8S RNA.

Rat liver 5S rRNA and 5.8S rRNA were end-labelled with 32P at 5'-end or 3'-end of the polynucleotide chain and partially digested with single-strand specific S1 nuclease and double-strand specific endonuclease from the cobra Naja naja oxiana venom. The parallel use of these two structure-specific enzymes in combination with rapid sequencing technique allowed the exact localization of single-stranded and double-stranded regions in 5S RNA and 5.8 S RNA. The most accessible regions to S1 nuclease in 5S RNA are regions 33-42, 74-78, 102-103 and in 5.8 S RNA 16-20, 26-29, 34-36, 74-80 and a region around 125-130. The cobra venom endonuclease cleaves the following areas in 5S RNA: 7-8, 17-20, 28-30, 49-51, 56-57, 60-64, 69-70, 81-82, 95-97, 106-112. In 5.8S RNA the venom endonuclease cleavage sites are 4-7, 10-13, 21-22, 33-35, 43-45, 51-55, 72-74, 85-87, 98-99, 105-106, 114-115, 132-135. According to these results the tRNA binding sequences proposed by Nishikawa and Takemura [(1974) FEBS Lett. 40, 106-109], in 5S RNA are located in partly single-stranded region, but in 5.8S RNA in double-stranded region.     

The nucleotide sequence at the 5'' end of foot and mouth disease virus RNA.

Foot and mouth disease virus RNA has been treated with RNase H in the presence of oligo (dG) specifically to digest the poly(C) tract which lies near the 5' end of the molecule (10). The short (S) fragment containing the 5' end of the RNA was separated from the remainder of the RNA (L fragment) by gel electrophoresis. RNA ligase mediated labelling of the 3' end of S fragment showed that the RNase H digestion gave rise to molecules that differed only in the number of cytidylic acid residues remaining at their 3' ends and did not leave the unique 3' end necessary for fast sequence analysis. As the 5' end of S fragment prepared form virus RNA is blocked by VPg, S fragment was prepared from virus specific messenger RNA which does not contain this protein. This RNA was labelled at the 5' end using polynucleotide kinase and the sequence of 70 nucleotides at the 5' end determined by partial enzyme digestion sequencing on polyacrylamide gels. Some of this sequence was confirmed from an analysis of the oligonucleotides derived by RNase T1 digestion of S fragment. The sequence obtained indicates that there is a stable hairpin loop at the 5' terminus of the RNA before an initiation codon 33 nucleotides from the 5' end. In addition, the RNase T1 analysis suggests that there are short repeated sequences in S fragment and that an eleven nucleotide inverted complementary repeat of a sequence near the 3' end of the RNA is present at the junction of S fragment and the poly(C) tract.     

Sequence and translation of the murine coronavirus 5''-end genomic RNA reveals the N-terminal structure of the putative RNA polymerase.

A 28-kilodalton protein has been suggested to be the amino-terminal protein cleavage product of the putative coronavirus RNA polymerase (gene A) (M.R. Denison and S. Perlman, Virology 157:565-568, 1987). To elucidate the structure and mechanism of synthesis of this protein, the nucleotide sequence of the 5' 2.0 kilobases of the coronavirus mouse hepatitis virus strain JHM genome was determined. This sequence contains a single, long open reading frame and predicts a highly basic amino-terminal region. Cell-free translation of RNAs transcribed in vitro from DNAs containing gene A sequences in pT7 vectors yielded proteins initiated from the 5'-most optimal initiation codon at position 215 from the 5' end of the genome. The sequence preceding this initiation codon predicts the presence of a stable hairpin loop structure. The presence of an RNA secondary structure at the 5' end of the RNA genome is supported by the observation that gene A sequences were more efficiently translated in vitro when upstream noncoding sequences were removed. By comparing the translation products of virion genomic RNA and in vitro transcribed RNAs, we established that our clones encompassing the 5'-end mouse hepatitis virus genomic RNA encode the 28-kilodalton N-terminal cleavage product of the gene A protein. Possible cleavage sites for this protein are proposed.     

Predicted Folding of β-Structure in Myelin Basic Protein

Predictions of myelin basic protein secondary structure have not previously considered a major role for beta-structure in the organization of the native molecule because optical rotatory dispersion and circular dichroism studies have provided little, if any, evidence for beta-structure, and because a polycationic protein is generally considered to resist folding into a compact structure. However, the Chou-Fasman, Lim, and Robson algorithms identify a total of five beta-strands in the amino acid sequence. Four of these hydrophobic amino acid sequences (37-45, 87-95, 110-118, and 150-158) could form a hairpin intermediate that initiates folding of a Greek-key-type beta-structure. A second fold on the more hydrophobic side, with the addition of a strand from the N-terminus (residues 13-21), would complete the five-stranded antiparallel beta-sheet. A unique strand alignment can be predicted by phasing the hydrophobic residues. The unusual triproline sequence of myelin basic protein (100-102) is enclosed in the 14-residue hairpin loop. If these prolines are in the trans conformation, models show that a reverse turn could occur at residues 102-105 (Pro-Ser-Gln-Gly). Algorithms do not agree on the prediction of alpha-helices, but each of the two large loops could accommodate an alpha-helix. Myelin basic protein is known to be phosphorylated in vivo on as many as five Ser/Thr residues. Phosphorylation might alter the dynamics of folding if the nascent polypeptide were phosphorylated in the cytoplasm. In particular, phosphorylation of Thr-99 could neutralize cationic residues Lys-106 and Arg-108 within the hairpin loop. In addition, the methylation of Arg-108 might stabilize the hairpin loop structure through hydrophobic interaction with the side chain of Pro-97. The cationic side chains of arginine and lysine residues located on the faces of the beta-sheet (Arg-43, Arg-114, Lys-13, Lys-92, Lys-153, and Lys-156) could provide sites for interaction with phospholipids and other anionic structures on the surface of the myelin lipid bilayer.     

Analysis of a sequence region of 5S RNA from E. coli cross-linked in situ to the ribosomal protein L25.

70S ribosomes from E. coli were chemically cross-linked under conditions of in vitro protein biosynthesis. The ribosomal RNAs were extracted from reacted ribosomes and separated on sucrose gradients. The 5S RNA was shown to contain the ribosomal protein L25 covalently bound. After total RNase T1 hydrolysis of the covalent RNA-protein complex several high molecular weight RNA fragments were obtained and identified by sequencing. One fragment, sequence region U103 to U120, was shown to be directly linked to the protein first by protein specific staining of the particular fragment and second by phosphor cellulose chromatography of the covalent RNA-protein complex. The other two fragments, U89 to G106 and A34 to G51, could not be shown to be directly linked to L25 but were only formed under cross-linking conditions. While the fragment U89 to G106 may be protected from RNase T1 digestion because of a strong interaction with the covalent RNA-protein complex, the formation of the fragment A34 to G51 is very likely the result of a double monovalent modification of two neighbouring guanosines in the 5S RNA. The RNA sequences U103 to U120 established to be in direct contact to the protein L25 within the ribosome falls into the sequence region previously proposed as L25 binding site from studies with isolated 5S RNA-protein complexes.     

Characterization of the Escherichia coli 23S Ribosomal RNA region associated with ribosomal protein L1. Evidence for homologies with the 5''-end region of the L11 operon.

The results previously obtained upon studying the L1-23S RNA complex by the fingerprint technique have been reexamined in the light of new data on 23S RNA primary structure. The 23S RNA region that remains associated with the L1 ribosomal protein after RNase digestion of the synthetic complex lies between nucleotides 2067 and 2235 from the 5'-end of the molecule. This region contains a m7G near to the 5'-end and possesses a high degree of mutability in E. coli. Three different sequences were observed in E. coli MRE 600. All three sequences differ in two positions relative to the corresponding sequence in rrnB cistron from E. coli K12. Striking homology is observed between the 23S RNA region associated with protein L1 and the 5'-part of L11 operon. This observation supports the model of feedback regulation of r-proteins synthesis proposed by Yates et al. (PNAS, 77, 1837) and strongly suggests that the region of 23S RNA located between positions 2155 and 2202 is essential for the binding of protein L1.     

Structure of the 5'-terminal untranslated region of the genomic RNAs from two strains of alfalfa mosaic virus.

We report the sequences of the 5'-terminal regions of the 3 Alfalfa Mosaic Virus genomic RNAs for the Strasbourg strain (AlMV-S) and for a new isolate, AlMV-B; they are compared to similar data obtained by Koper-Zwarthoff et al. (Nucleic Acids Res. 1980, 8, 5635-5647) for strain 425. The structure of these leaders is highly conserved in RNAs 1 and 2. The length of the leader is 102, 100 and 101 nucleotides in RNA1 for strains S, B and 425 respectively; 55 and 56 in RNA2 for strains S and B respectively. In RNA3 however, there are important differences near the 5'-terminus between strain S and the other two: The total leader length is 258 nucleotides for strain S and 242 for strain B. The secondary structure models show a conserved hairpin near the 5'-end of each genomic RNA of AlMV-S. This hairpin is inexistent in RNA3 of the B and 425 strains. The degree of base-pairing increases with leader length. The initiator codon is located in a single stranded region in RNA2 whereas it is found in a hairpin stem in RNA 3.     

Isolation and anaylsis of (Gp)nXp sequences of rat liver 5S RNA by means of restricted ribonucleas T2 hydrolysis

Essentual difficulties arise when base number in oligoguanylic blocks and location of these blocks along the polynucleotide chain need to be determined in the course of determination of the nucleotide sequences in ribonucleic acids. To overcome this difficulty it is suggested to take advantage of a recently discovered resistance of phosphodiester bond between kethoxalated G and its 3'-neighbour against T(2) RNase hydrolysis 1,2. The approach is illustrated by analysis of 5S RNA from rat liver. Sequences of general formula (Gp)(n)Xp were isolated from T(2) RNase hydrolysate of 5 S RNA rapidly and quantitatively. The information obtained greatly facilitates the whole procedure of sequencing. It is expected that the method proposed would be effective for analysis of 5 S and 4 S RNA and for highmolecular weight fragments of ribosomal and viral RNAs.     

The CafA protein required for the 5'-maturation of 16 S rRNA is a 5'-end-dependent ribonuclease that has context-dependent broad sequence specificity

The CafA protein, which was initially described as having a role in either Escherichia coli cell division or chromosomal segregation, has recently been shown to be required for the maturation of the 5'-end of 16 S rRNA. The sequence of CafA is similar to that of the N-terminal ribonucleolytic half of RNase E, an essential E. coli enzyme that has a central role in the processing of rRNA and the decay of mRNA and RNAI, the antisense regulator of ColE1-type plasmids. We show here that a highly purified preparation of CafA is sufficient in vitro for RNA cutting. We detected CafA cleavage of RNAI and a structured region from the 5'-untranslated region of ompA mRNA within segments cleavable by RNaseE, but not CafA cleavage of 9 S RNA at its "a" RNase E site. The latter is consistent with the finding that the generation of 5 S rRNA from its 9 S precursor can be blocked by inactivation of RNase E in cells that are wild type for CafA. Interestingly, however, a decanucleotide corresponding in sequence to the a site of 9 S RNA was cut efficiently indicating that cleavage by CafA is regulated by the context of sites within structured RNAs. Consistent with this notion is our finding that although 23 S rRNA is stable in vivo, a segment from this RNA is cut efficient by CafA at multiple sites in vitro. We also show that, like RNase E cleavage, the efficiency of cleavage by CafA is dependent on the presence of a monophosphate group on the 5'-end of the RNA. This finding raises the possibility that the context dependence of cleavage by CafA may be due at least in part to the separation of a cleavable sequence from the 5'-end of an RNA. Comparison of the sites surrounding points of CafA cleavage suggests that this enzyme has broad sequence specificity. Together with the knowledge that CafA can cut RNAI and ompA mRNA in vitro within segments whose cleavage in vivo initiates the decay of these RNAs, this finding suggests that CafA may contribute at some point during the decay of many RNAs in E. coli.     

500-MHz proton homonuclear Overhauser evidence for additional base pair in the common arm of eukaryotic ribosomal 5S RNA: wheat germ

A "common-arm" fragment from wheat germ (Triticum aestivum) 5S RNA has been produced by enzymatic cleavage with RNase T1 and sequenced via autoradiography of electrophoresis gels for the end-labeled fragments obtained by further RNase T1 partial digestion. The existence, base pair composition, and base pair sequence of the common arm are demonstrated for the first time by means of proton 500-MHz nuclear magnetic resonance. From Mg2+ titration, temperature variation, ring current calculations, sequence comparisons, and proton homonuclear Overhauser enhancement experiments, additional base pairs in the common arm of the eukaryotic 5S RNA secondary structure are detected. Two base pairs, G41 X C34 and A42 X U33 in the hairpin loop, could account for the lack of binding between the conserved GAAC segment of 5S RNA and the conserved Watson-Crick-complementary GT psi C segment of tRNAs.     

Sequence,chemical, and structural variation of small interfering RNAs and short hairpin RNAs and the effect on mammalian gene silencing

Small interfering RNAs (siRNAs) induce sequence-specific gene silencing in mammalian cells and guide mRNA degradation in the process of RNA interference (RNAi). By targeting endogenous lamin A/C mRNA in human HeLa or mouse SW3T3 cells, we investigated the positional variation of siRNA-mediated gene silencing. We find cell-type-dependent global effects and cell-type-independent positional effects. HeLa cells were about 2-fold more responsive to siRNAs than SW3T3 cells but displayed a very similar pattern of positional variation of lamin A/C silencing. In HeLa cells, 26 of 44 tested standard 21-nucleotide (nt) siRNA duplexes reduced the protein expression by at least 90%, and only 2 duplexes reduced the lamin A/C proteins to <50%. Fluorescent chromophores did not perturb gene silencing when conjugated to the 5'-end or 3'-end of the sense siRNA strand and the 5'-end of the antisense siRNA strand, but conjugation to the 3'-end of the antisense siRNA abolished gene silencing. RNase-protecting phosphorothioate and 2'-fluoropyrimidine RNA backbone modifications of siRNAs did not significantly affect silencing efficiency, although cytotoxic effects were observed when every second phosphate of an siRNA duplex was replaced by phosphorothioate. Synthetic RNA hairpin loops were subsequently evaluated for lamin A/C silencing as a function of stem length and loop composition. As long as the 5'-end of the guide strand coincided with the 5'-end of the hairpin RNA, 19-29 base pair (bp) hairpins effectively silenced lamin A/C, but when the hairpin started with the 5'-end of the sense strand, only 21-29 bp hairpins were highly active.     

Random location of nucleosomes on genes for 5 S rRNA.

The location of nucleosomes on genes for 5 S rRNA in rat liver was determined by the preparation of nucleosome core DNA fragments, hybridization with 5 S rRNA, RNase digestion, and gel electrophoresis. The resulting size distribution of RNA fragments was essentially the same as that found when the experiment was carried out with random DNA fragments.     

Nucleotide sequence of Halobacterium cutirubrum ribosomal 5 S ribonucleic acid. An altered secondary structure in halophilic organisms

The nucleotide sequence of ribosomal 5 S RNA from a halophilic bacterium, Halobacterium cutirubrum, grown in 4 M sodium chloride is U-U-A-A-G-G-C-G-G-C-C-A-U-A-G-C-G-G-U-G-G-G-G-U-U-A-C-U-C-C-C-G-U-A-C-C-C-A-U-C-C-C-G-A-A-C-A-C-G-G-A-A-G-A-U-A-A-G-C-C-C-G-C-C-U-G-C-G-U-U-C-C-G-G-U-C-A-G-U-A-C-U-G-G-A-G-U-G-C-G-A-G-C-C-U-C-U-G-G-G-A-A-A-U-C-C-G-G-U-U-C-G-C-C-G-C-C-U-A-C-U. This nucleotide sequence is the longest prokaryotic 5 S rRNA to be reported and unlike other 5 S species does not contain a terminal mononucleoside diphosphate residue at its 5'-end. When compared to other 5 S rRNA's, the sequence homology is greatest (about 68%) with Bacillus subtilis; there is a lower but similar degree of homology (about 58%) with either Escherichia coli or human 5 S RNA. The comparisons further indicate that among 5 S RNA's, eleven of the nucleotide residues are unique to H. cutirubrum. Estimates of the secondary structure of the H. cutirubrum 5 S RNA molecule contain one additional stable hairpin loop which is not found in other 5 S rRNA species; this unusual structure is probably an adaptation to the high salt environment within H. cutirubrum cells.     

Sequence analysis of 5''[32P] labeled mRNA and tRNA using polyacrylamide gel electrophoresis.

Sequence analysis of 5'-[32P] labeled tRNA and eukaryotic mRNA using an adaptation of a method recently described by Donis-Keller, Maxam and Gilbert for mapping guanines, adenines and pyrimidines from the 5'-end of an RNA is described. In addition, a technique utilizing two-dimensional polyacrylamide gel electrophoresis for identification of pyrimidines within a sequence is described. 5'-[32P] Labeled rabbit beta-globin mRNA and N. crassa mitochondrial initiator tRNA were partially digested with T1- RNase for cleavage at G residues, with U2-RNase for cleavage at A residues, with an extracellular RNase from B. cereus for cleavage at pyrimidine residues and with T2-RNase or with alkali for cleavage at all four residues. The 5'-[32P] labeled partial digestion products were separated according to their size, by electrophoresis in adjacent lanes of a polyacrylamide slab gel and the location of G's, A's and of pyrimidines extending 60-80 nucleotides from the 5'-end of the RNA determined. Two-dimensional polyacrylamide gel electrophoresis was used to separate the 5'-[32P] labeled fragments present in partial alkali digests of a 5'-[32P] labeled mRNA. The mobility shifts corresponding to the difference of a C residue were distinct from those corresponding to a U residue and this formed the basis of a method for distinguishing between the pyrimidines.     

Primary structure of mammalian ribosomal protein S6

Ribosomal protein S6 was isolated from rat liver ribosomes by reversed-phase high-performance liquid chromatography (HPLC) and subjected to cyanogen bromide and proteolytic cleavages. The cleavage fragments were resolved by HPLC and sequenced by automated Edman degradation. The overall amino acid sequence of S6 (249 residues) was determined by alignment of the overlapping sequences of selected cyanogen bromide, chymotryptic, tryptic, and clostripain cleavage fragments. The only protein found to exhibit close homology with the S6 sequence is yeast ribosomal protein S10 (61% sequence identity). Previously, characterized phosphopeptide derivatives of S6 containing phosphorylation sites for adenosine 3',5'-cyclic phosphate dependent and protease-activated protein kinases originate from the carboxy-terminal region of S6 encompassing residues 233-249.     

Identification of the nucleotide sequences involved in the interaction between Escherichia coli 5 RNA and specific 50 S subunit proteins

Pancreatic RNase partial digests of ³²P-labelled 5 S RNA-protein complexes have been fractionated by electrophoresis on polyacrylamide gels. Specific fragments of the 5 S RNA molecule have been recovered from electrophoresis bands containing polynucleotide-protein complexes. These digestion-resistant complexes are only found if RNase treatment is carried out in the presence of at least one of the two 50 S subunit proteins L18 and L25, which are able to bind to 5 S RNA individually and specifically. The sequences of the isolated fragments have been determined. From the results, it can be concluded that sequence 69 to 120 and, possibly, sequence 1 to 11, are involved in the 5 S RNA-protein interactions which are responsible for the insertion of 5 S RNA in the 50 S subunit structure. Sequence 12 to 68, on the other hand, has no strong interactions with proteins L18 and L25. Each protein certainly binds to several nucleotide residues, which are not contiguous in the primary structure. In particular, good experimental evidence has been obtained in favour of the binding of protein L25 to two distant regions of the 5 S RNA molecule, which must have a bihelical secondary structure. The importance of the 5 S RNA conformation for its proper insertion in the 50 S subunit is thus confirmed.     

Targeting degradation of RNA by RNase H using DNA hairpins

RNase H degradation of two 15 nt RNA target sites was examined in the presence of hairpin DNAs with a 5 nt loop and a 10 bp stem or single-stranded 15 nt DNAs. One target site was a segment of a 79 nt RNA, and the other was part of a 53 nt RNA. Secondary structure predictions indicate that the 53 nt RNA target site is entirely single stranded, while a portion of the 79 nt RNA target site forms an intramolecular duplex. Less RNase H and DNA were needed to cleave the 53 nt RNA target site than the less accessible 79 nt RNA site. The hairpin DNAs had their 5 nt loop and 3' side of the stem fully complementary to the target sites or had sequence changes that produced one to nine mismatched pairs. T(m) values ranged from 57 to 80 degrees C. The stability of the hairpin DNAs relative to the stability of their corresponding RNA-DNA hybrids influenced the extent of RNase H degradation at 37 degrees C. Under the assay conditions employed, the amount of degradation directed by the hairpin DNAs was correlated with their predicted DeltaG(o) (37) of binding to the RNA targets. A DNA hairpin with one mismatch to the target site of the 79 nt RNA did not induce degradation under conditions where fully complementary DNA hairpins produced 50-80% degradation. The in vitro results indicate that DNA hairpins can enhance the stringency of RNase H targeted degradation of the RNA sites.     

Isolation and analysis of (Gp)nXp sequences of rat liver 5S RNA by means of restricted ribonuclease T2 hydrolysis

Essentual difficulties arise when base number in oligoguanylic blocks and location of these blocks along the polynucleotide chain need to be determined in the course of determination of the nucleotide sequences in ribonucleic acids. To overcome this difficulty it is suggested to take advantage of a recently discovered resistance of phosphodiester bond between kethoxalated G and its 3′-neighbour against T₂ RNase hydrolysis 1,2. The approach is illustrated by analysis of 5S RNA from rat liver. Sequences of general formula (Gp)_nXp were isolated from T₂ RNase hydrolysate of 5 S RNA rapidly and quantitatively. The information obtained greatly facilitates the whole procedure of sequencing. It is expected that the method proposed would be effective for analysis of 5 S and 4 S RNA and for highmolecular weight fragments of ribosomal and viral RNAs.