Basepairing potential of the 3' terminus of 16S RNA: dependence on the functional state of the 30S subunit and the presence of protein S21.

The deoxyoctanucleotide 5'd (AAGGAGGT) which is complementary to the 3' terminus of 16S RNA has been used as a probe to measure the potential of this rRNA region to engage in intermolecular basepairing. The site specific binding of the octanucleotide is shown by labeling 16S RNA in situ at its 3' end with [32P]pCp and T4 RNA ligase (EC 6.5.1.3.). The label can be released as pA[32P]pCp by the simultaneous action of RNAse H (EC 3.1.4.34) and 5'd(AAGGAGGT). WE show that (1) 30S subunits prepared according to standard procedures, bind less than one copy of 5'd(AAGGAGGT); (2) isolated 16S RNA and 30S subunits inactivated by transcient exposure to 0.5 mM Mg2+ do not bind the octanucleotide; (3) binding to inactive subunits can be restored by a brief heat treatment; (4) 30S subunits lacking protein S21 do not bind 5'd(AAGGAGGT) even when submitted to heat treatment; (5) addition of protein S21 to subunits lacking S21 restores octamer binding; (6) the apparent exposure of the 16S RNA 3' terminus brought about by protein S21 is accompanied by the potential of the subunits to accept MS2 RNA as messenger; (7) the presence or absence of S1 on 30S subunits has no effect on their octanucleotide binding property.     

Properties and Location of Poly(A) in Rous Sarcoma Virus RNA

The poly(A) sequence of 30 to 40S Rous sarcoma virus RNA, prepared by digestion of the RNA with RNase T(1), showed a rather homogenous electrophoretic distribution in formamide-polyacrylamide gels. Its size was estimated to be about 200 AMP residues. The poly(A) appears to be located at or near the 3' end of the 30 to 40S RNA because: (i) it contained one adenosine per 180 AMP residues, and because (ii) incubation of 30 to 40S RNA with bacterial RNase H in the presence of poly(dT) removed its poly(A) without significantly affecting its hydrodynamic or electrophoretic properties in denaturing solvents. The viral 60 to 70S RNA complex was found to consist of 30 to 40S subunits both with (65%) and without (approximately 30%) poly(A). The heteropolymeric sequences of these two species of 30 to 40S subunits have the same RNase T(1)-resistant oligonucleotide composition. Some, perhaps all, RNase T(1)-resistant oligonucleotides of 30 to 40S Rous sarcoma virus RNA appear to have a unique location relative to the poly(A) sequence, because the complexity of poly(A)-tagged fragments of 30 to 40S RNA decreased with decreasing size of the fragment. Two RNase T(1)-resistant oligonucleotides which distinguish sarcoma virus Prague B RNA from that of a transformation-defective deletion mutant of the same virus appear to be associated with an 11S poly(A)-tagged fragment of Prague B RNA. Thus RNA sequences concerned with cell transformation seem to be located within 5 to 10% of the 3' terminus of Prague B RNA.     

Cellular Origin of a Mouse Leukemia Viral Ribonucleic Acid

Mouse erythroblastosis virus, a member of the mouse leukemia virus group, was obtained from chronically infected C(3)H mouse embryo cells and purified on sucrose gradients. The ribonucleic acid (RNA) extracted from ribonuclease-treated virus consisted of a rapidly sedimenting (72S) species and a more slowly sedimenting component (4 to 30S). The 72S RNA did not contain base sequences homologous to deoxyribonucleic acid (DNA) from infected cells as determined by hybridization studies. In contrast, the slowly sedimenting RNA enclosed within the virus had base sequences homologous to DNA from infected and uninfected C(3)H mouse embryo cells.     

Separation of mutant and wild-type ribosomes based on differences in their anti Shine-Dalgarno sequence.

We describe a system to isolate 30S ribosomal subunits which contain targeted mutations in their 16S rRNA. The mutations of interest should be present in so-called specialized 30S subunits which have an anti-Shine-Dalgarno sequence that is altered from 5' ACCUCC to 5' ACACAC. These plasmid-encoded specialized 30S subunits are separated from their chromosomally encoded wild-type counterparts by affinity chromatography that exploits the different Shine-Dalgarno complementarity. An oligonucleotide complementary to the 3' end of wild-type 16S rRNA and attached to a solid phase matrix retains the wild-type 30S subunits. The flow-through of the column contains close to 100% mutant 30S subunits. Toeprinting assays demonstrate that affinity column treatment does not cause significant loss of activity of the specialized particles in initiation complex formation, whereas elongation capacity as determined by poly(Phe) synthesis is only slightly decreased. The method described offers an advantage over total reconstitution from in vitro transcribed mutant 16S rRNA since our 30S subunits contain the naturally occurring base modifications in their 16S rRNA.     

Severe Acute Respiratory Syndrome Coronavirus nsp1 Facilitates Efficient Propagation in Cells through a Specific Translational Shutoff of Host mRNA

Severe acute respiratory syndrome (SARS) coronavirus (SCoV) is an enveloped virus containing a single-stranded, positive-sense RNA genome. Nine mRNAs carrying a set of common 5' and 3' untranslated regions (UTR) are synthesized from the incoming viral genomic RNA in cells infected with SCoV. A nonstructural SCoV nsp1 protein causes a severe translational shutoff by binding to the 40S ribosomal subunits. The nsp1-40S ribosome complex further induces an endonucleolytic cleavage near the 5'UTR of host mRNA. However, the mechanism by which SCoV viral proteins are efficiently produced in infected cells in which host protein synthesis is impaired by nsp1 is unknown. In this study, we investigated the role of the viral UTRs in evasion of the nsp1-mediated shutoff. Luciferase activities were significantly suppressed in cells expressing nsp1 together with the mRNA carrying a luciferase gene, while nsp1 failed to suppress luciferase activities of the mRNA flanked by the 5'UTR of SCoV. An RNA-protein binding assay and RNA decay assay revealed that nsp1 bound to stem-loop 1 (SL1) in the 5'UTR of SCoV RNA and that the specific interaction with nsp1 stabilized the mRNA carrying SL1. Furthermore, experiments using an SCoV replicon system showed that the specific interaction enhanced the SCoV replication. The specific interaction of nsp1 with SL1 is an important strategy to facilitate efficient viral gene expression in infected cells, in which nsp1 suppresses host gene expression. Our data indicate a novel mechanism of viral gene expression control by nsp1 and give new insight into understanding the pathogenesis of SARS.     

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.     

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.     

The methylation state of poly A-containing messenger RNA from cultured hamster cells.

The poly A-containing mRNA of cultured hamster (BHK-21) cells has been examined with regard to methylation status. Steady state-labeled mRNA was obtained by incubating cells for 20-22h in the presence of [methyl-3H]-methionine and 32Pi. The degree of methylation of this RNA was 1.8 methyl groups per 1000 nucleotides, or 4-5 methyl groups on the average per molecule. The nature of the methylated residues was determined by paper chromatography and electrophoresis of acid and alkaline hydrolysates, by DEAE cellulose chromatography of alkaline hydrolysates and of T2 RNase digests, and by examining the effect of subjecting samples to "beta-elimination." Approx. half of the methyl groups occurred in standard ("internal") linkage, 10% as m5Cp and 40% as m6Ap residues. The remainder occurred at least for the most part in "blocked" 5'-termini with the presumptive structure m7G(5')ppp(Nm)p.., where Nm was Gm, m6Am, Um, or Cm.     

5'-Terminal and internal methylated nucleosides in herpes simplex virus type 1 mRNA.

RNA labeled with [methyl-3H]methionine and/or [32P]orthophosphate was isolated from the polyribosomes of herpes simplex virus (HSV) types 1-infected cells and separated into polyadenylylated [poly(A+)]and non-polyadenylylated [poly(A-)] fractions. Virus-specific RNA was obtained by hybridization in liquid to either excess HSV DNA or filters containing immobilized HSV DNA. Analysis in denaturing sucrose gradients indicated that HSV-specific poly(A+) RNA sedimented in a broad peak, with a modal S value of 20. The ratio of [3H]methyl to 32P decreased with increasing size of RNA, suggesting that each RNA chain contains a similar sumber of methyl groups. Further analysis indicated an average of one RNase-resistant structure of the type m7G(5')pppNmpNp or m7G(5')pppNmpNmpNp per 2,780 nucleotides. The following components were identified in the 5'-terminal oligonucleotides of polyribosome-associated HSV-specific poly(A+) and poly(A-) RNA: 7-methylguanosine, N6,2'-O-dimethyladenosine, and the 2'-O-methyl derivatives of guanosine, adenosine, uridine, and denosine, and the 2'-O-methyl derivatives of guanosine, adenosine, uridine, and cytidine. The most common 5'-terminal sequences were m7G(5')pppm6Am and m7G(5')pppGm. An additional modified nucleoside, N6-methyladenosine, was present in an internal position of HSV-specific RNA.     

Membrane-bound ribosomes of myeloma cells. III. The role of the messenger RNA and the nascent polypeptide chain in the binding of ribosomes to membranes

Mild ribonuclease treatment of the membrane fraction of P3K cells released three types of membrane-bound ribosomal particles: (a) all the newly made native 40S subunits detected after 2 h of [3H]uridine pulse. Since after a 3-min pulse with [35S]methionine these membrane native subunits appear to contain at least sevenfold more Met-tRNA per particle than the free native subunits, they may all be initiation complexes with mRNA molecules which have just become associated with the membranes; (b) about 50% of the ribosomes present in polyribosomes. Evidence is presented that the released ribosomes carry nascent chains about two and a half to three times shorter than those present on the ribosomes remaining bound to the membranes. It is proposed that in the membrane-bound polyribosomes of P3K cells, only the ribosomes closer to the 3' end of the mRNA molecules are directly bound, while the latest ribosomes to enter the polyribosomal structures are indirectly bound through the mRNA molecules; (c) a small number of 40S subunits of polyribosomal origin, presumably initiation complexes attached at the 5' end of mRNA molecules of polyribosomes. When the P3K cells were incubated with inhibitors acting at different steps of protein synthesis, it was found that puromycin and pactamycin decreased by about 40% the proportion of ribosomes in the membrane fraction, while cycloheximide and anisomycin had no such effect. The ribosomes remaining on the membrane fraction of puromycin-treated cells consisted of a few polyribosomes, and of an accumulation of 80S and 60S particles, which were almost entirely released by high salt treatment of the membranes. The membrane-bound ribosomes found after pactamycin treatment consisted of a few polyribosomes, with a striking accumulation of native 60S subunits and an increased number of native 40S subunits. On the basis of the observations made in this and the preceding papers, a model for the binding of ribosomes to membranes and for the ribosomal cycle on the membranes is proposed. It is suggested that ribosomal subunits exchange between free and membrane-bound polyribosomes through the cytoplasmic pool of free native subunits, and that their entry into membrane-bound ribosomes is mediated by mRNA molecules associated with membranes.     

Subcellular localization of RNAs in transfected cells: role of sequences at the 5' terminus

We have investigated the intracellular location of RNAs transcribed from transfected DNA. COS cells transfected with a clone containing the human adult beta globin gene contain three classes of globin RNAs. Their 3' termini and splice sites are indistinguishable from those of mature reticulocyte beta globin mRNA, and they are polyadenylated. However, as determined by S1 mapping, their 5' sequences are different. The 5' terminus of one is the same as that of mature beta globin mRNA (+1, cap site). The presumed 5' terminus of the second is located 30 nucleotides downstream from the cap site (+30). The third class contains additional nucleotides transcribed from sequences located 5' to the cap site (5' upstream RNA). The 5' upstream RNA molecules are restricted to the nucleus and are more stable than heterogeneous nuclear RNA. The +30 and +1 RNAs are located primarily in the cytoplasm. The data support the notion that nucleotide sequences and/or secondary modifications in the 5' region determine if an RNA is to be transported.     

Methylation of high-molecular-weight subunit RNA of feline leukemia virus.

The high-molecular-weight subunit RNA of feline leukemia virus (Rickard strain) (FeLV-R) was analyzed for the presence of methyl groups. After purification of native 50-60S FeLV-R RNA on nondenaturing aqueous sucrose density gradients. FeLV-R 28S subunit RNA, doubly labeled with [14C]uridine and [methyl-3H]methionine, was isolated by centrifugation through denaturing sucrose density gradients in dimethyl sulfoxide. As calculated from their respective 3H/14C ratios. FeLV-R 28S RNA was methylated to the same degree as host cell poly(A)+ mRNA. When the 28S FeLV-R RNA was hydrolyzed to completion with RNase T2 or alkali, all of the methyl-3H chromatographed with mononucleotides on Pellionex-WAX, a weak anion exchanger. The methyl-labeled material co-chromatographed with 6-methyladenosine if the mononucleotide fraction obtained by Pellionex-WAX chromatography was hydrolyzed to nucleosides by bacterial alkaline phosphatase or with 6-methyladenine if purine bases were released from the mononucleotides by acid hydrolysis. In another experiment in which FeLV-R 28S RNA uniformly labeled with 32P was hydrolyzed and then analyzed by Pellionex-WAX chromatography, all of the 32P label again co-chromatographed with mononucleotides. Thus FeLV-R 28S RNA does not appear to contain a 5' structure, either methylated or nonmethylated similar to those recently reported for cellular and some animal virus mRNA's.     

A new strategy for introducing photoactivatable 4-thiouridine ((4S)U) into specific positions in a long RNA molecule.

We describe a new protocol, which does not require (4S)UpG, for introducing (4S)U into specific sites in a pre-mRNA substrate. A 5'-half and a full-length RNA are first synthesized by phage RNA polymerase. p(4S)Up, which is derived from (4S)UpU and can therefore be 32P-labeled, is then ligated to the 3' end of the 5'-half RNA with T4 RNA ligase. The 3' phosphate of the ligated product is removed subsequently by CIP (calf intestinal alkaline phosphatase) to produce a 3'-OH group. The 3'-half RNA with a 5' phosphate is produced by site-specific RNase H cleavage of the full-length pre-mRNA directed by a 2'-O-methyl RNA-DNA chimera. The two half RNAs are then aligned with a bridging oligonucleotide and ligated with T4 DNA ligase. Our results show that 32P-p(4S)Up ligation to the 3' end of the 5'-half RNA is comparable to 32P-pCp ligation. Also, the efficiency of the bridging oligonucleotide-mediated two-piece ligation is quite high, approximately 30-50%. This strategy has been applied to the P120 pre-mRNA containing an AT-AC intron, but should be applicable to many other RNAs.     

A distinct group of hepacivirus/pestivirus-like internal ribosomal entry sites in members of diverse picornavirus genera: evidence for modular exchange of functional noncoding RNA elements by recombination

The 5' untranslated regions (UTRs) of the RNA genomes of Flaviviridae of the Hepacivirus and Pestivirus genera contain internal ribosomal entry sites (IRESs) that are unrelated to the two principal classes of IRESs of Picornaviridae. The mechanism of translation initiation on hepacivirus/pestivirus (HP) IRESs, which involves factor-independent binding to ribosomal 40S subunits, also differs fundamentally from initiation on these picornavirus IRESs. Ribosomal binding to HP IRESs requires conserved sequences that form a pseudoknot and the adjacent IIId and IIIe domains; analogous elements do not occur in the two principal groups of picornavirus IRESs. Here, comparative sequence analysis was used to identify a subset of picornaviruses from multiple genera that contain 5' UTR sequences with significant similarities to HP IRESs. They are avian encephalomyelitis virus, duck hepatitis virus 1, duck picornavirus, porcine teschovirus, porcine enterovirus 8, Seneca Valley virus, and simian picornavirus. Their 5' UTRs are predicted to form several structures, in some of which the peripheral elements differ from the corresponding HP IRES elements but in which the core pseudoknot, domain IIId, and domain IIIe elements are all closely related. These findings suggest that HP-like IRESs have been exchanged between unrelated virus families by recombination and support the hypothesis that RNA viruses consist of modular coding and noncoding elements that can exchange and evolve independently.     

Size analysis and relationship of murine leukemia virus-specific mRNA's: evidence for transposition of sequences during synthesis and processing of subgenomic mRNA.

Virus-specific mRNA from purified polyribosomes of mouse cells infected with Moloney murine leukemia virus (M-MuLV) was analyzed by electrophoresis in agarose gels, followed by hybridization of gel slices with M-MuLV-specific complementary DNA (cDNA). The size resolution of the gels was better than that of sucrose gradients used in previous analyses, and two virus-specific mRNA's of 38S and 24S were detected. The 24S virus-specific mRNA is predominantly derived from the 3' half of the M-MuLV genome, since cDNAgag(pol) (complementary to the 5' half of the M-MuLV genome) could not efficiently anneal with this mRNA. However, sequences complementary to cDNA synthesized from the extreme 5' end of M-MuLV 38S RNA (cDNA 5') are present in the 24S virus-specific mRNA, since cDNA 5' (130 nucleotides) efficiently annealed with this mRNA. The annealing of cDNA 5' was not due to repetition of 5' terminal nucleotide sequences at the 3' end of M-MuLV 38S RNA, since smaller cDNA 5' molecules (60 to 70 nucleotides), which likely lack the terminal repetition, also efficiently annealed with the 24S mRNA. The sequences in 24S virus-specific mRNA recognized by cDNA 5' are not present in 3' fragments of virion RNA that are the same length. Therefore, it appears that RNA sequences from the extreme 5' end of the M-MuLV genome may be transposed to sequences from the 3' half of the M-MuLV 38S RNA during synthesis and processing of the 24S virus-specific mRNA. These results may indicate a phenomenon similar to the RNA splicing processes that occur during synthesis of adenovirus and papovavirus mRNA's.