Research Article
Secondary structure model of the RNA recognized by the reverse transcriptase from the R2 retrotransposable element
- DAVID H. MATHEWS, ALOKE R. BANERJEE, DONGMEI D. LUAN, THOMAS H. EICKBUSH, DOUGLAS H. TURNER
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- Published online by Cambridge University Press:
- 01 January 1997, pp. 1-16
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RNA transcripts corresponding to the 250-nt 3′ untranslated region of the R2 non-LTR retrotransposable element are recognized by the R2 reverse transcriptase and are sufficient to serve as templates in the target DNA-primed reverse transcription (TPRT) reaction. The R2 protein encoded by the Bombyx mori R2 can recognize this region from both the B. mori and Drosophila melanogaster R2 elements even though these regions show little nucleotide sequence identity. A model for the RNA secondary structure of the 3′ untranslated region of the D. melanogaster R2 retrotransposon was developed by sequence comparison of 10 species aided by free energy minimization. Chemical modification experiments are consistent with this prediction. A secondary structure model for the 3′ untranslated region of R2 RNA from the R2 element from B. mori was obtained by a combination of chemical modification data and free energy minimization. These two secondary structure models, found independently, share several common sites. This study shows the utility of combining free energy minimization, sequence comparison, and chemical modification to model an RNA secondary structure.
Identification of specific nucleotide sequences and structural elements required for intronic U14 snoRNA processing
- LING XIA, NICHOLAS J. WATKINS, E. STUART MAXWELL
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- Published online by Cambridge University Press:
- 01 January 1997, pp. 17-26
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Vertebrate U14 snoRNAs are encoded within hsc70 pre-mRNA introns and U14 biosynthesis occurs via an intron-processing pathway. We have shown previously that essential processing signals are located in the termini of the mature U14 molecule and replacement of included boxes C or D with oligo C disrupts snoRNA synthesis. The experiments detailed here now define the specific nucleotide sequences and structures of the U14 termini that are essential for intronic snoRNA processing. Mutagenesis studies demonstrated that a 5′, 3′-terminal stem of at least three contiguous base pairs is required. A specific helix sequence is not necessary and this stem may be extended to as many as 15 base pairs without affecting U14 processing. The spatial positioning of boxes C and D with respect to the terminal stem is also important. Detailed analysis of boxes C and D revealed that both consensus sequences possess essential nucleotides. Some, but not all, of these critical nucleotides correspond to those required for the stable accumulation of nonintronic yeast U14 snoRNA. The presence of box C and D consensus sequences flanking a terminal stem in many snoRNA species indicates the importance of this “terminal core motif” for snoRNA processing.
RNA-dependent RNA polymerase activity associated with the yeast viral p91/20S RNA ribonucleoprotein complex
- MARÍA P. GARCÍA-CUÉLLAR, ROSA ESTEBAN, TSUTOMU FUJIMURA
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- Published online by Cambridge University Press:
- 01 January 1997, pp. 27-36
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20S RNA is a noninfectious viral single-stranded RNA found in most laboratory strains of the yeast Saccharomyces cerevisiae. 20S RNA encodes a protein of 91 kDa (p91) that contains the common motifs found among RNA-dependent RNA polymerases from RNA viruses. p91 and 20S RNA are noncovalently associated in vivo, forming a ribonucleoprotein complex. We detected an RNA polymerase activity in p91/20S RNA complexes isolated by high-speed centrifugation. The activity was not inhibited by actinomycin D nor α-amanitin. The majority of the in vitro products was 20S RNA and the rest was the complementary strands of 20S RNA. Because the extracts were prepared from cells accumulating 20S RNA over its complementary strands, these in vitro products reflect the corresponding activities in vivo. When the p91/20S RNA complexes were subjected to sucrose gradient centrifugation, the polymerase activity cosedimented with the complexes. Furthermore, an RNA polymerase activity was detected in the complex by an antibody-linked polymerase assay using anti-p91 antiserum, suggesting that p91 is present in the active RNA polymerase machinery. These results together indicate that p91 is the RNA-dependent RNA polymerase or a subunit thereof responsible for 20S RNA replication.
Evidence for light/redox-regulated splicing of psbA pre-RNAs in Chlamydomonas chloroplasts
- NITA N. DESHPANDE, YIJIA BAO, DAVID L. HERRIN
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- 01 January 1997, pp. 37-48
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Efficient splicing in vivo of most self-splicing group I introns is believed to require proteins, raising the possibility that splicing could be regulated; however, examples of such regulation have been lacking. The Chlamydomonas reinhardtii chloroplast psbA gene contains four large group I introns that self-splice efficiently in vitro, but only under nonphysiological conditions. The psbA gene encodes the D1 protein of photosystem II, which is synthesized at very high rates in the light in order to replace photodamaged protein. We show that psbA pre-mRNAs, containing one or more introns, accumulate in wild-type cells in the dark, apparently due to rate-limited splicing. Analysis of the pre-RNAs indicates that splicing of the four introns does not follow a strict order. Exposure of cells to light induced rapid (15–20 min) decreases in precursor levels of ∼3–5-fold (depending on the intron), which were accompanied by transient increases in free intron levels. Because light also stimulated psbA transcription ∼2-fold over the same period, the data suggests that light increases the splicing efficiency of psbA introns ∼6–10-fold. Similar estimates of the extent of light stimulation were obtained by analyzing precursor decay rates in the presence of actinomycin D. The effect of light is specific for psbA introns, because levels of unspliced 23S pre-RNA did not decrease. The light-induced increase in psbA pre-RNA processing was abolished by inhibitors of photosynthetic electron transport, but not by the ATP synthesis inhibitor, carbonylcyanide m-chlorophenylhydrazone, which actually promoted pre-RNA processing in the dark. Finally, nonphotosynthetic mutants, including the tscA-lacking photosystem I mutant, H13, did not show evidence of light-stimulated RNA processing. However, the light response was restored in photosynthetic transformants of H13 that had been complemented with the tscA gene. These data suggest strongly that light coordinately stimulates splicing of all four psbA introns. Moreover, they demonstrate that this response to light is mediated by photosynthetic electron transport. The implications of these results for the regulation of psbA gene expression are discussed.
Identification of 2′-hydroxyl groups required for interaction of a tRNA anticodon stem-loop region with the ribosome
- UWE VON AHSEN, RACHEL GREEN, RENÉE SCHROEDER, HARRY F. NOLLER
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- 01 January 1997, pp. 49-56
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Synthetic RNA stem loops corresponding to positions 28–42 in the anticodon region of tRNAPhe bind efficiently in an mRNA-dependent manner to ribosomes, whereas those made from DNA do not. In order to identify the positions where ribose is required, the anticodon stem-loop region of tRNAPhe (Escherichia coli) was synthesized chemically using a mixture of 2′-hydroxyl- and 2′-deoxynucleotide phosphoramidites. Oligonucleotides whose ribose composition allowed binding were retained selectively on nitrocellulose filters via binding to 30S ribosomal subunits. The binding-competent oligonucleotides were submitted to partial alkaline hydrolysis to identify the positions that were enriched for ribose. Quantification revealed a strong preference for a 2′-hydroxyl group at position U33. This was shown directly by the 50-fold lower binding affinity of a stem loop containing a single deoxyribose at position U33. Similarly, defective binding of the corresponding U33-2′-O-methyl-substituted stem-loop RNA suggests that absence of the 2′-hydroxyl group, rather than an altered sugar pucker, is responsible. Stem-loop oligoribonucleotides from different tRNAs with U33-deoxy substitutions showed similar, although quantitatively different effects, suggesting that intramolecular rather than tRNA-ribosome interactions are affected. Because the 2′-hydroxyl group of U33 was shown to be a major determinant of the U-turn of the anticodon loop in the crystal structure of tRNAPhe in yeast, our finding might indicate that the U-turn conformation in the anticodon loop is required and/or maintained when the tRNA is bound to the ribosomal P site.
Analysis of bacteriophage N protein and peptide binding to boxB RNA using polyacrylamide gel coelectrophoresis (PACE)
- CHRISTOPHER D. CILLEY, JAMES R. WILLIAMSON
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- 01 January 1997, pp. 57-67
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The antitermination protein N from bacteriophage λ (Nλ) interacts with the nut site in its own mRNA, as well as host factors, to facilitate formation of a termination-resistant transcription complex. The conserved, amino-terminal arginine-rich domain of Nλ protein is known to interact with a small RNA hairpin (boxB) derived from the nut site RNA. We have examined the binding of Nλ protein, peptides derived from the amino terminus of Nλ, and the related phage P22 N protein to λ boxB RNAs. To facilitate the study of complexes that are not amenable to gel retardation assays, a new polyacrylamide affinity coelectrophoresis technique (PACE) was developed. Using the PACE assay, we have demonstrated that a 19-amino acid peptide from the amino terminus of Nλ protein binds λ boxB RNA with a Kd,app of 5.2 nM. PACE was also used to study the binding affinity of a number of Nλ peptide and λboxB RNA mutants. The PACE technique is complementary to the traditional gel retardation assay for direct measurement of binding interactions, and will be useful for any procedure that requires a pool of RNAs to be resolved based on their relative affinities for proteins or peptides.
The genetic stability of potato spindle tuber viroid (PSTVd) molecular variants
- ANNA GÓRA-SOCHACKA, ANDRZEJ KIERZEK, THIERRY CANDRESSE, WLODZIMIERZ ZAGÓRSKI
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- Published online by Cambridge University Press:
- 01 January 1997, pp. 68-74
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RNA viruses propagate as a population of genetically related entities composing a quasi-species. Specific representatives are the result of both a high mutation rate during replication and competition between the continuously arising sequence variants. Similar to other RNA pathogens, potato spindle tuber viroid (PSTVd) propagates as a population of similar but nonidentical sequences. The sequence of progeny molecules derived from cloned molecular variants of PSTVd were studied after one and six consecutive plant passages. Although the severe parental sequence S23 was found to be genetically stable, all five other parental sequences analyzed, irrespective of their pathogenicity, led to the appearance of complex populations. Divergence of the progeny was observed at the sequence level, but also, more surprisingly, at the level of the pathogenicity of individual progeny molecules. In two cases, the parental sequence was retained in the progeny population. In the other cases, it was completely out-competed and eliminated, sometimes in as little as one plant passage. Although it has been observed previously that artificially mutated PSTVd molecules may revert rapidly to the wild-type sequence, this study presents direct evidence for the rapid evolution of naturally occurring PSTVd sequence variants.
The expression cassette determines the functional activity of ribozymes in mammalian cells by controlling their intracellular localization
- EDOUARD BERTRAND, DANIELA CASTANOTTO, CHEN ZHOU, CECILE CARBONNELLE, NAN SOOK LEE, PAUL GOOD, SASWATI CHATTERJEE, THIERRY GRANGE, RAYMOND PICTET, DONALD KOHN, DAVID ENGELKE, JOHN J. ROSSI
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- Published online by Cambridge University Press:
- 01 January 1997, pp. 75-88
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In order to better understand the influence of RNA transcript context on RNA localization and catalytic RNA efficacy in vivo, we have constructed and characterized several expression cassettes useful for transcribing short RNAs with well defined 5′ and 3′ appended flanking sequences. These cassettes contain promoter sequences from the human U1 snRNA, U6 snRNA, or tRNAMeti genes, fused to various processing/stabilizing sequences. The levels of expression and the sub-cellular localization of the resulting RNAs were determined and compared with those obtained from Pol II promoters normally linked to mRNA production, which include a cap and polyadenylation signal. The tRNA, U1, and U6 transcripts were nuclear in localization and expressed at the highest levels, while the standard Pol II promoted transcripts were cytoplasmic and present at lower levels.
The ability of these cassettes to confer ribozyme activity in vivo was tested with two assays. First, an SIV-growth hormone reporter gene was transiently transfected into human embryonic kidney cells expressing an anti-SIV ribozyme. Second, cultured T lymphocytes expressing an anti-HIV ribozyme were challenged with HIV. In both cases, we found that the ribozymes were effective only when expressed as capped, polyadenylated RNAs transcribed from Pol II cassettes that generate a cytoplasmically localized ribozyme that facilitates co-localization with its target. We also show that the inability of the other cassettes to support ribozyme-mediated inhibitory activity against their cytoplasmic target is very likely due to the resulting nuclear localization of these ribozymes. These studies demonstrate that the ribozyme expression cassette determines its intracellular localization and, hence, its corresponding functional activity.
Probing the structure of the Escherichia coli 10Sa RNA (tmRNA)
- BRICE FELDEN, HYOUTA HIMENO, AKIRA MUTO, JOHN P. McCUTCHEON, JOHN F. ATKINS, RAYMOND F. GESTELAND
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- Published online by Cambridge University Press:
- 01 January 1997, pp. 89-103
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The conformation of the Escherichia coli 10Sa RNA (tmRNA) in solution was investigated using chemical and enzymatic probes. Single- and double-stranded domains were identified by hydrolysis of tmRNA in imidazole buffer and by lead(II)-induced cleavages. Ribonucleases T1 and S1 were used to map unpaired nucleotides and ribonuclease V1 was used to identify paired bases or stacked nucleotides. Specific atomic positions of bases were probed with dimethylsulfate, a carbodiimide, and diethylpyrocarbonate. Covariations, identified by sequence alignment with nine other tmRNA sequences, suggest the presence of several tertiary interactions, including pseudoknots. Temperature-gradient gel electrophoresis experiments showed structural transitions of tmRNA starting around 40°C, and enzymatic probing performed at selected temperatures revealed the progressive melting of several predicted interactions.
Based on these data, a secondary structure is proposed, containing two stems, four stem-loops, four pseudoknots, and an unstable structural domain, some connected by single-stranded A-rich sequence stretches. A tRNA-like domain, including an already reported acceptor branch, is supported by the probing data. A second structural domain encompasses the coding sequence, which extends from the top of one stem-loop to the top of another, with a 7-nt single-stranded stretch between. A third structural module containing pseudoknots connects and probably orients the tRNA-like domain and the coding sequence. Several discrepancies between the probing data and the phylogeny suggest that E. coli tmRNA undergoes a conformational change.