Secondary structure of the 5' end of bacteriophage MS2 RNA Methoxyamine and kethoxal modification.

To refine the secondary structure model of the 5' end of the bacteriophage MS2 genome, 32P-labeled MS2 RNA was partially digested with T1 RNase or with Cm-RNase and the 5'-end fragment was isolated, renatured and submitted to treatment with methoxyamine or kethoxal. The resulting modified RNA was digested with T1 RNase and the products were separated by minifingerprinting. Methoxyamine-induced modification of exposed cytidines was detected by differential mobility of modified oligonucleotides, while kethoxal-induced alteration of exposed guanosines was monitored by resistance to T1 ribonuclease digestion. The positions of the modified residues are discussed in terms of an improved secondary structure model proposed for the 5' end of the viral RNA. The structure itself is discussed in relation to sequence conservation and biological function.     

Role of 3'-end sequences in infectivity of poliovirus transcripts made in vitro

It has been shown by van der Werf et al. (S. van der Werf, J. Bradley, E. Wimmer, F. W. Studier, and J. Dunn, Proc. Natl. Acad. Sci. USA 83:2330-2334, 1986) that in vitro synthesis of poliovirus RNA by T7 RNA polymerase gives rise to infectious RNA molecules; however, these molecules are only 5% as infectious as RNA isolated from virions. A plasmid, T7D-polio, was constructed that allows the in vitro synthesis of full-length RNA molecules with two additional guanine residues at the 5' end. However, T7D-polio differed from the construct of van der Werf et al. in that RNA transcribed from T7D-polio has an authentic 3' end, ending with only a polyadenine nucleotide sequence. Transfection of these RNA molecules into mammalian cells produced wild-type poliovirus with an efficiency similar to that of virion RNA. The use of this vector in the characterization of viral mutants in vivo and in vitro is discussed.     

5'' termini of poliovirus RNA: difference between virion and nonencapsidated 35S RNA.

Poliovirus cytoplasmic, nonencapsidated 35S RNA yields approximately one pUp per molecule upon T2 RNase digestion, indicating that this RNA has the same 5'' end as the polyribosome-associated viral RNA fraction. Double-stranded, replicative form RNA after the same treatment yielded approximately four pNp structures per molecule, 65% of which was pUp. In contrast, the 35S RNA from mature virions contained no detectable pNp, indicating that the 5'' end of the virion RNA is different from that of the nonencapsidated RNA. None of the above molecules contained pppNp, ppNp, or GpppNp structures present in host mRNA. The virion RNA molecules, as we have shown previously for thenonencapsidated 35S viral RNA (Fernandez-Muñoz and Darnell, 1976), is not labeled with [methyl-3H]methionine.     

The virulent satellite RNA of turnip crinkle virus has a major domain homologous to the 3' end of the helper virus genome

RNA C (355 bases), RNA D (194 bases) and RNA F (230 bases) are small, linear satellite RNAs of turnip crinkle virus (TCV) which have been cloned as cDNAs and sequenced in this study. These RNAs produce dramatically different disease symptoms in infected plants. RNA C is a virulent satellite that intensifies virus symptoms when co-inoculated with its helper virus in turnip plants, while RNA D and RNA F are avirulent. RNA D and RNA F, the avirulent satellites, are closely related to each other except that RNA F has a 36-base insert near its 3' end, not found in RNA D. The 189 bases at the 5' end of RNA C, the virulent satellite, are homologous to the entire sequence of RNA D. However, the 3' half of RNA C, is composed of 166 bases which are nearly identical to two regions at the 3' end of the TCV helper virus genome. Hence, the virulent satellite is a composite molecule with one domain at its 5' end homologous to the other avirulent satellites and another domain at its 3' end homologous to the helper virus genome. All four TCV RNAs, RNAs C, D and F and the helper virus genome have identical 7 bases at their 3' ends. The secondary structure of RNA C deduced from the sequence can be folded into two separate domains — the domain of helper virus genome homology and the domain homologous to other TCV satellite RNAs. Comparative sequences of several different RNA C clones reveal that this satellite is a population of molecules with sequence and length heterogeneity.     

The effect of tRNA binding on the structure of 5 S RNA in Escherichia coli. A chemical modification study

The structure of 5 S RNA within the 70 S ribosome from Escherichia coli was studied using the chemical reagent kethoxal (alpha-keto-beta-ethoxybutyraldehyde) to modify accessible guanosines. The modification pattern of 5 S RNA from free 70 S ribosomes was compared with that of poly(U) programmed ribosomes where tRNA had been bound to both the A- and P-sites. Binding to the ribosomal A-site was achieved enzymatically using the elongation factor Tu and GTP in the presence of deacylated tRNA which blocks the ribosomal P-site. Modified guanosines were identified after partial RNase T1 hydrolysis and separation of the hydrolysis products on sequencing gels. Binding of tRNA to the ribosome leads to a strong protection of 5 S RNA guanosine G-41 and to some degree G-44 from kethoxal modification. The limited RNase T1 hydrolysis pattern provides evidence for the existence of a 5 S RNA conformation different from the known 5 S RNA A- and B-forms which are characterized by their gel electrophoretic mobility. The importance of 5 S RNA for the binding of tRNA to the ribosome is discussed.     

Non-ribosomal nucleotide sequences in 7-S RNA, the immediate precursor of 5.8-S ribosomal RNA in yeast.

The topography and the length of the non-ribosomal sequences present in 7-S RNA, the immediate precursor of 5.8-S ribosomal RNA, from the yeast Saccharomyces carlsbergensis were determined by analyzing the nucleotide sequences of the products obtained after complete digestion of 7-S RNA with RNase T1. The results show that 7-S RNA contains approximately 150 non-ribosomal nucleotides. The majority (90%) of the 7-S RNA molecules was found to have the same 5'-terminal pentadecanucleotide sequence as mature 5.8-S rRNA. The remaining 10% exhibited 5'-terminal sequences identical to those of 5.9-S RNA, which has the same primary structure as 5.8-S rRNA except for a slight extension at the 5' end [Rubin, G.M. (1974) Eur. J. Biochem. 41, 197--202]. These data show that the non-ribosomal nucleotides present in 7-S RNA are all located 3'-distal to the mature 5.8-S rRNA sequence. Moreover, it can be concluded that 5.9-S RNA is a stable rRNA rather than a precursor of 5.8-S rRNA. The 3'-terminal sequence of 5.8-S rRNA (U-C-A-U-U-UOH) is recovered in a much longer oligonucleotide in the T1 RNase digest of 7-S RNA having the sequence U-C-A-U-U-U-(C-C-U-U-C-U-C)-A-A-A-C-A-(U-U-C-U)-Gp. The sequences enclosed in brackets are likely to be correct but could not be established with absolute certainty. The arrow indicates the bond cleaved during processing. The octanucleotide sequence -A-A-A-C-A-U-U-C- located near the cleavage site shows a remarkable similarity to the 5'-terminal octanucleotide sequence of 7-S RNA (-A-A-A-C-U-U-U-C-). We suggest that these sequences may be involved in determining the specificity of the cleavages resulting in the formation of the two termini of 5.8-S rRNA.     

RNase-stable RNA: conformational parameters of the nucleic acid backbone for binding to RNase T1.

An RNA sequence showing high stability with respect to digestion by ribonuclease T1 (RNase T1) was isolated by in vitro selection from an RNA library. Although ribonuclease T1 cleaves single-stranded RNA specifically after guanosine residues, secondary structure calculations predict several guanosines in single-stranded areas. Two of these guanosines are part of a GGCA-tetraloop, a recurring structure element in the secondary structure predictions. Molecular dynamics simulations of the conformation space of the nucleotides involved in this tetraloop show on the one hand that the nucleic acid backbone of the guanosines cannot realise the conformation required for cleavage by RNase T1. On the other hand, it could be shown that an RNA molecule not forced into a tetraloop occupies this conformation several times in the course of the simulation. The simulations confirm the GGCA-tetraloop as an RNase-stable secondary structure element. Our results show that, besides the known prerequisite of a single-stranded RNA, RNase T1 has additional demands on the substrate conformation.