Bipartite 3'-cis-acting signal for replication in yeast 23 S RNA virus and its repair

23 S RNA narnavirus is a persistent positive strand RNA virus found in Saccharomyces cerevisiae. The viral genome is small (2.9 kb) and only encodes its RNA-dependent RNA polymerase. Recently, we have succeeded in generating 23 S RNA virus from an expression vector containing the entire viral cDNA sequence. Using this in vivo launching system, we analyzed the 3'-cis-acting signals for replication. The 3'-non-coding region of 23 S RNA contains two cis-elements. One is a stretch of 4 Cs at the 3' end, and the other is a mismatched pair in a stem-loop structure that partially overlaps the terminal 4 Cs. In the latter element, the loop or stem sequence is not important but the stem structure with the mismatch pair is essential. The mismatched bases should be purines. Any combination of purines at the mismatch pair bestowed capability of replication on the RNA, whereas converting it to a single bulge at either side of the stem abolished the activity. The terminal and penultimate Cs at the 3' end could be eliminated or modified to other nucleotides in the launching plasmid without affecting virus generation. However, the viruses generated regained or restored these Cs at the 3' terminus. Considering the importance of the viral 3' ends in RNA replication, these results suggest that this 3' end repair may contribute to the persistence of 23 S RNA virus in yeast by maintaining the genomic RNA termini intact. We discuss possible mechanisms for this 3' end repair in vivo.     

The tRNA-like structure at the 3' terminus of turnip yellow mosaic virus RNA. Differences and similarities with canonical tRNA.

The 3' terminus of TYMV RNA, which possesses tRNA-like properties, has been studied. A 3' terminal fragment of 112 nucleotides was obtained by cleavage with RNase H after hybridization of a synthetic oligodeoxynucleotide to the viral RNA. The accessibility of cytidine and adenosine residues was probed with chemical modification. Enzymatic digestion studies were performed with RNase T1, nuclease S1 and the double-strand specific RNase from the venom of the cobra Naja naja oxiana. A model is proposed for the secondary structure of the 3' terminal region of TYMV RNA comprising 86 nucleotides. The main feature of this secondary structure is the absence of a conventional acceptor stem as present in canonical tRNA. However, the terminal 42 nucleotides can be folded in a tertiary structure which bears strong resemblance with the acceptor arm of canonical tRNA. Comparison of this region of TYMV RNA with that of other RNAs from both the tymovirus group and the tobamovirus group gives support to our proposal for such a three-dimensional arrangement. The consequences for the recognition by TYMV RNA of tRNA-specific enzymes is discussed.     

The initiation region of the SV40 VP1 gene.

The sequence of 15 nucleotides located at the 5' terminus of the plus strand of the SV40 Hind K fragment has been determined as (5') A-G-C-T-T-A-T-G-A-A-G-A-T-G-G (3'). The 3' on OH terminal G of this segment is part of the G-C-C codeword for the N terminal alanine of the VP1 protein. This region therefore presumably corresponds to a ribosome binding site on the 16S late mRNA. Complementarily to the 3' OH of eucaryotic 18S ribosomal RNA and homology with the BMV coat ribosome binding site are discussed.     

Cotranscription and processing of 23S, 4.5S and 5S rRNA in chloroplasts from Zea mays

The termini of rRNA processing intermediates and of mature rRNA species encoded by the 3' terminal region of 23S rDNA, by 4.5S rDNA, by the 5' terminal region of 5S rDNA and by the 23S/4.5S/5S intergenic regions from Zea mays chloroplast DNA were determined by using total RNA isolated from maize chloroplasts and 32P-labelled rDNA restriction fragments of these regions for nuclease S1 and primer extension mapping. Several processing sites detectable by both 3' and 5' terminally labelled probes could be identified and correlated to the secondary structure for the 23S/4.5S intergenic region. The complete 4.5S/5S intergenic region can be reverse transcribed and a common processing site for maturation of 4.5S and 5S rRNA close to the 3' end of 4.5S rRNA was detected. It is therefore concluded that 23S, 4.5S and 5S rRNA are cotranscribed.     

The terminal sequences of Bombyx mori 18S ribosomal RNA.

The 5' and 3' terminal T1 oligonucleotides of 32p-labelled B. mori 18S ribosomal RNA were isolated by a two dimensional electrophoretic (diagonal) technique. Nucleotide sequence analysis showed that the 3' terminal fragment, (G)AUCAUUAOH, is identical to that previously obtained from the 18S rRNA of several other eukaryotic species. The sequence of the B. mori 5' terminal fragment is pUCCUCG.     

Homology of the 3'' terminal sequences of the 18S rRNA of Bombyx mori and the 16S rRNA of Escherchia coli.

The terminal 220 base pairs (bp) of the gene for 18S rRNA and 18 bp of the adjoining spacer rDNA of the silkworm Bombyx mori have been sequenced. Comparison with the sequence of the 16S rRNA gene of Escherichia coli has shown that a region including 45 bp of the B. mori sequence at the 3' end is remarkably homologous with the 3' terminal E. coli sequence. Other homologies occur in the terminal regions of the 18S and 16S rRNAs, including a perfectly conserved stretch of 13 bp within a longer homology located 150--200 bp from the 3' termini. These homologies are the most extensive so far reported between prokaryotic and eukaryotic genomic DNA.     

Generation of a uniform 3'' end RNA of murine leukemia virus.

Using the S1 nuclease mapping technique, we demonstrated that the majority of Moloney murine leukemia RNA molecules, isolated either from the nucleus or cytoplasm of infected mouse cells, share a uniform 3' end located at the border of the R and U-5 regions of the long terminal repeat. When the long terminal repeat sequences were inserted in the pSV plasmid downstream of the simian virus 40 late promoter, the 3' end of the viral RNA was also generated close to the R region of the long terminal repeat. These results demonstrate that the long terminal repeat signals the generation of an authentic 3' end when situated downstream of an actively transcribed region.     

Studies on the primary structure of the ribosomal 23S RNA of Escherichia coli: II. A characterisation and an alignment of 24 sections spanning the entire molecule and its application to the localisation of specific fragments.

We have employed new methodology to obtain 23S RNA fragments which includes a) the digestion of the RNA within 50S subunits and b) the limited hydrolysis of the 13S and 18S fragments. By comparing all 23S RNA fragments, obtained heretofore, we have characterised and aligned 24 sections of this RNA spanning nearly the entire molecule. These results allow the localisation of any new 23S RNA fragment by comparison of the fingerprint of its T1 ribonuclease digest to the characteristic ones of the different sections. In this way we obtained a more definite localisation of the binding sites of the 50S proteins L1, L5, L9, L18, L20, L23 and L25. We also specified a ribonuclease sensitive region of 23S RNA in native 50S subunits, extending from the 1100th nucleotide from the 5' end to the 1000th nucleotide from the 3' end; this region contains a cluster of 5 modified nucleotides and may be at the subunit interface.     

Structural complexity of defective-interfering RNAs of Semliki Forest virus as revealed by analysis of complementary DNA.

The 18S defective interfering RNA of Semliki Forest virus has been reverse transcribed to cDNA, which was shown to be heterogeneous by restriction enzyme analysis. After transformation to E.coli, using pBR322 as a vector, two clones, pKTH301 and pKTH309 with inserts of 1.7 kb and 2 kb, were characterized, respectively. The restriction maps of the two clones were different but suggested that both contained repeating units. At the 3' terminus, pKTH301 had preserved 106 nucleotides and pKTH309 102 nucleotides from the 3' end of the viral 42S genome. The conserved 3' terminal sequence was joined to a different sequence in the two clones, and these sequences were not derived from the region coding for the viral structural proteins. The DI RNAs represented by the two clones are generated from the viral 42S RNA by several noncontinuous internal deletions, since the largest colinear regions with 42S RNA are 320 nucleotides in pKTH301, and 430 and 340 nucleotides in pKTH309. All these fragments had unique RNase T1 oligonucleotide fingerprints, suggesting that they were derived from different regions of 42S RNA.     

An RNA domain within the 5' untranslated region of the tomato bushy stunt virus genome modulates viral RNA replication

The terminal half of the 5' untranslated region (UTR) in the (+)-strand RNA genome of tomato bushy stunt virus was analyzed for possible roles in viral RNA replication. Computer-aided thermodynamic analysis of secondary structure, phylogenetic comparisons for base-pair covariation, and chemical and enzymatic solution structure probing were used to analyze the 78 nucleotide long 5'-terminal sequence. The results indicate that this sequence adopts a branched secondary structure containing a three-helix junction core. The T-shaped domain (TSD) formed by this terminal sequence is closed by a prominent ten base-pair long helix, termed stem 1 (S1). Deletion of either the 5' or 3' segment forming S1 (coordinates 1-10 or 69-78, respectively) in a model subviral RNA replicon, i.e. a prototypical defective interfering (DI) RNA, reduced in vivo accumulation levels of this molecule approximately 20-fold. Compensatory-type mutational analysis of S1 within this replicon revealed a strong correlation between formation of the predicted S1 structure and efficient DI RNA accumulation. RNA decay studies in vivo did not reveal any notable changes in the physical stabilities of DI RNAs containing disrupted S1s, thus implicating RNA replication as the affected process. Further investigation revealed that destabilization of S1 in the (+)-strand was significantly more detrimental to DI RNA accumulation than (-)-strand destabilization, therefore S1-mediated activity likely functions primarily via the (+)-strand. The essential role of S1 in DI RNA accumulation prompted us to examine the 5'-proximal secondary structure of a previously identified mutant DI RNA, RNA B, that lacks the 5' UTR but is still capable of low levels of replication. Mutational analysis of a predicted S1-like element present within a cryptic 5'-terminal TSD confirmed the importance of the former in RNA B accumulation. Collectively, these data support a fundamental role for the TSD, and in particular its S1 subelement, in tombusvirus RNA replication.     

The 5' end of U3 snRNA can be crosslinked in vivo to the external transcribed spacer of rat ribosomal RNA precursors

From previous work it was known that U3 RNA is hydrogen bonded to nucleolar 28 S to 35 S RNA and can be covalently crosslinked to RNA of greater than 28 S by irradiation in vivo with long-wave ultraviolet light in the presence of 4'-aminomethyl-4,5',8-trimethylpsoralen (AMT psoralen). Here we use a novel sandwich blot technique to identify these large nucleolar RNA species as rRNA precursors and to map the site(s) of crosslinking in vivo. The crosslink occurs between one or more residues near the 5' end of U3 RNA and a 380 nucleotide region of the rat rRNA external transcribed spacer (ETS1). We have sequenced this region of the rat ETS and we show that it includes an RNA-processing site analogous to those previously mapped to approximately 3.5 kb upstream from the 5' end of mouse and human 18 S rRNAs.     

Isolation from rat liver and sequence of a RNA fragment containing 32 nucleotides from position 5 to 36 from the 3'' end of ribosomal 18S RNA.

Crude tRNA isolated from rat liver by the method of Rogg et al. (Biochem. Biophys. Acta 195, 13-15 1969) contains N6-dimethyladenosine (m6-2A) and was therefore fractionated in order to identify the m6-2A-containing RNAs. A unique species of RNA was purified which contained all the m62A present in the crude tRNA. Sequence analysis by postlabeling with gamma-32p-ATP and polynucleotide kinase revealed that this RNA represents the 32 nucleotides AAGGUUUC(C)U GUAGGUGm62Am62ACCUGCGGAAGGAUC from position 5 to 36 of the 3' terminus of ribosomal 18S RNA. The 36 nucleotide long sequence from the 3' end of rat liver 18S rRNA exhibits extensive homology with the corresponding sequence of E. coli 16S rRNA and with the 21 nucleotide long 3' terminal sequence so far known from Saccharomyces carlsbergensis 17S rRNA. A heterogeneity in this sequence provides the first evidence on the molecular level for the existence of (at least) two sets of redundant ribosomal 18S RNA genes in the rat.     

蓖麻蚕18S rRNA基因3′末端的顺序特征

本文测定了蓖麻蚕18S rRNA基因(rDNA) 3′末端及其外侧的DNA顺序。将这一顺序与家蚕、果蝇、大鼠 18S rDNA 3′末端顺序以及大肠杆菌16 S rDNA 3′末端顺序作了比较,发现它们间有惊人的同源性。不仅如此,这些基因的3′末端所形成的茎环结构也十分相似,在3′末端还有保守的EcoRI切点。这些研究结果对了解18S rRNA 3′末端在蛋白质合成中的功能及在rRNA前体加工成熟中的作用;对于了解rRNA基因的进化打下了基础。     

Locations of methyl groups in 28 S rRNA of Xenopus laevis and man. Clustering in the conserved core of molecule

28 S ribosomal RNA from several vertebrate species contains some 68 to 70 methyl groups. Evidence described in this paper enables some 58 methyl groups to be located in the primary structure of 28 S ribosomal RNA from Xenopus laevis. Most of the locations are unambiguous but a few are currently tentative. In human 28 S ribosomal RNA the great majority of the same sites are methylated as in Xenopus, but there are a few differences between the respective methyl group distributions. The main features of the methyl group distribution are as follows. (1) All of the identified methyl groups are in conserved core regions of 28 S ribosomal RNA. (2) Methylation is much more heavily concentrated in the 3' region of the molecule than in the 5' region (in contrast to 18 S ribosomal RNA, in which there is a major cluster of 2'-O-methyl groups in the 5' region). (3) In addition to the heavily methylated 3' region, clusters of methyl groups occur elsewhere in 28 S ribosomal RNA in the vicinity of domain boundaries. For domains 3 to 6, the two ends of each domain are united in a helix and are linked to adjacent domains either directly or by short single-stranded regions. It therefore follows that the methyl groups near the boundaries of these domains come together into the same general region of the three-dimensional structure. Within this large-scale pattern of distribution, methyl groups occur in a variety of local environments, examples of which are discussed. The triply methylated sequence Am-Gm-Cm-A occurs in a short single-stranded region which links domain 3 to domain 4. Near the 3' end of domain 5 there is a cluster of 11 methyl groups including a 2'-O-methyl pseudouridine in a tract of 160 nucleotides whose sequence is totally conserved between Xenopus and man. These methyl groups are variously distributed between single-stranded regions and short or imperfect but conserved helices. A further cluster of methyl groups including the highly conserved Um-Gm-psi sequence occurs in a region of domain 6 which is implicated in peptidyl transfer. Possible relationships between methylation and other events in ribosome maturation are discussed.