Replication of RNA by the DNA-dependent RNA polymerase of phage T7

The DNA-dependent RNA polymerase of bacteriophage T7 utilizes a specific RNA as a template and replicates it efficiently and accurately. The RNA product (X RNA), approximately 70 nucleotides long, is initiated with either pppC or pppG and contains an AU-tich sequence. Replication of X RNA involves synthesis of complementary strands. Both strands are also significantly self-complementary, producing RNA with an extensive hairpin secondary structure. Replication of X RNA by T7 RNA polymerase is both template and enzyme specific. No other RNA serves as template for replication; neither do other polymerases, including the closely related T3 RNA polymerase, replicate X RNA. The T7 RNA polymerase-X RNA system provides an interesting model for studying replication of RNA by DNA-dependent RNA polymerases. Such a mechanism has been proposed to propagate viroids and hepatitis delta, pathogenic RNAs whose replication seems to depend on cellular RNA polymerases.     

Autonomous replication and expression of RNA 1 from black beetle virus

Black beetle virions contain two RNAs. The smaller one, RNA 2, has previously been shown to be a messenger for viral coat protein. It is shown here, by infecting sensitized Drosophila cells with the individually purified RNAs, that the larger one, RNA 1, carries the viral gene(s) required for RNA polymerase functions. RNA 2 was dispensible for synthesis of viral RNA 1 and subgenomic RNA 3 but was essential for synthesis of RNA 2 and virions. Cells infected with RNA 1 alone produced RNA 3 in proportions 10- to 20-fold greater than cells infected with virions. This overproduction of RNA 3 decreased with increasing proportions of RNA 2 in the infecting RNA 1. We conclude that RNA 1 is the previously unidentified progenitor of subgenomic RNA 3, whereas RNA 2 regulates the amount of RNA 3 produced in the infected cell.     

Roles of the coding and noncoding regions of rift valley Fever virus RNA genome segments in viral RNA packaging

We characterized the RNA elements involved in the packaging of Rift Valley fever virus RNA genome segments, L, M, and S. The 5'-terminal 25 nucleotides of each RNA segment were equally competent for RNA packaging and carried an RNA packaging signal, which overlapped with the RNA replication signal. Only the deletion mutants of L RNA, but not full-length L RNA, were efficiently packaged, implying the possible requirement of RNA compaction for L RNA packaging.     

Asynchronous accumulation of lettuce infectious yellows virus RNAs 1 and 2 and identification of an RNA 1 trans enhancer of RNA 2 accumulation

Time course and mutational analyses were used to examine the accumulation in protoplasts of progeny RNAs of the bipartite Crinivirus, Lettuce infectious yellow virus (LIYV; family Closteroviridae). Hybridization analyses showed that simultaneous inoculation of LIYV RNAs 1 and 2 resulted in asynchronous accumulation of progeny LIYV RNAs. LIYV RNA 1 progeny genomic and subgenomic RNAs could be detected in protoplasts as early as 12 h postinoculation (p.i.) and accumulated to high levels by 24 h p.i. The LIYV RNA 1 open reading frame 2 (ORF 2) subgenomic RNA was the most abundant of all LIYV RNAs detected. In contrast, RNA 2 progeny were not readily detected until ca. 36 h p.i. Mutational analyses showed that in-frame stop codons introduced into five of seven RNA 2 ORFs did not affect accumulation of progeny LIYV RNA 1 or RNA 2, confirming that RNA 2 does not encode proteins necessary for LIYV RNA replication. Mutational analyses also supported that LIYV RNA 1 encodes proteins necessary for replication of LIYV RNAs 1 and 2. A mutation introduced into the LIYV RNA 1 region encoding the overlapping ORF 1B and ORF 2 was lethal. However, mutations introduced into only LIYV RNA 1 ORF 2 resulted in accumulation of progeny RNA 1 near or equal to wild-type RNA 1. In contrast, the RNA 1 ORF 2 mutants did not efficiently support the trans accumulation of LIYV RNA 2. Three distinct RNA 1 ORF 2 mutants were analyzed and all exhibited a similar phenotype for progeny LIYV RNA accumulation. These data suggest that the LIYV RNA 1 ORF 2 encodes a trans enhancer for RNA 2 accumulation.     

Replication of RNA viruses: analysis by liquid polymer phase partition of the binding of Q RNA polymerase to nucleic acid

The number of RNA sites bound by the Qβ RNA polymerase and the affinity of the enzyme for different RNA sites was measured by equilibrium partition of enzyme and enzyme-nucleic acid complexes between two liquid polymer phases. At 0 °C and in the absence of other components required for RNA synthesis the enzyme bound to many regions of Qβ RNA, f2 RNA, 16S rRNA, double-stranded RNA, and circular DNA. Under conditions of enzyme excess, the maximum numbers of enzyme molecules bound per molecule of Qβ RNA, f2 RNA, and 16S rRNA were 32, 26, and 12, respectively. The enzyme bound to most, if not all, of the Qβ RNA sites with the same affinity. Nevertheless, the association constant for enzyme binding to Qβ RNA was more than 10-fold greater than for binding to f2 RNA over a wide range of salt concentrations.     

Messenger Ribonucleic Acid of Dormant Spores of Bacillus subtilis

Evidence of the presence of messenger ribonucleic acid (mRNA) in dormant spores of Bacillus subtilis has been obtained. The bulk RNA from spores was isolated and labeled in vitro with tritiated dimethyl sulfate. The spore RNA hybridized to 2.4 to 3.2% of the B. subtilis genome. The RNA hybridized to both the complementary heavy and light fractions of deoxyribonucleic acid (DNA). Bulk RNA from log-phase cells competed with virtually all the spore RNA for the heavy DNA fraction and with part of the spore RNA for the light DNA fraction. Bulk RNA from stage IV cells in sporulation also competed with all of the spore RNA for the heavy DNA fraction and with essentially all the spore RNA for the light DNA fraction. These results indicate that dormant spores contain mRNA species present in both log-phase cells and stage IV cells of sporulation. The RNA polymerase in the developing forespore must be able to recognize promotor sites for both log-phase and sporulation genes.     

Synchronous replication of poliovirus RNA: initiation of negative-strand RNA synthesis requires the guanidine-inhibited activity of protein 2C.

We report that protein 2C, the putative nucleoside triphosphatase/helicase protein of poliovirus, is required for the initiation of negative-strand RNA synthesis. Preinitiation RNA replication complexes formed upon the translation of poliovirion RNA in HeLa S10 extracts containing 2 mM guanidine HCI, a reversible inhibitor of viral protein 2C. Upon incubation in reactions lacking guanidine, preinitiation RNA replication complexes synchronously initiated and elongated negative-strand RNA molecules, followed by the synchronous initiation and elongation of positive-strand RNA molecules. The immediate and exclusive synthesis of negative-strand RNA upon the removal of guanidine demonstrates that guanidine specifically blocks the initiation of negative-strand RNA synthesis. Readdition of guanidine HCl to reactions synchronously elongating nascent negative-strand RNA molecules did not prevent their continued elongation and completion. In fact, readdition of guanidine HCl to reactions containing preinitiation complexes elongating nascent negative-strand RNA molecules had no effect on subsequent positive-strand RNA synthesis initiation or elongation. Thus, the guanidine-inhibited function of viral protein 2C was not required for the elongation of negative-strand RNA molecules, the initiation of positive-strand RNA molecules, or the elongation of positive-strand RNA molecules. The guanidine-inhibited function of viral protein 2C is required only immediately before or during the initiation of negative-strand RNA synthesis. We suggest that guanidine may block an irreversible structural maturation of protein 2C and/or RNA replication complexes necessary for the initiation of RNA replication.     

RNA模式分析进展

研究表明,R N A模式在基因表达调控方面起着重要作用.由于RN A模式不仅与初级序列有关,更多的表现为高级结构(一般为二级结构)的保守性,所以R N A模式的识别比D N A模式的识别要复杂的多.近十几年里,对R N A模式分析作了大量的计算方面的研究,包括:R N A结构的预测、识别和已知的类型相似的R N A模式、在一组功能或进化相关的基因中找出共同的R N A模式.这里对上述3个方面的计算方法的发展和研究进行了综述.     

Analysis of ribonucleoproteins of influenza virus containing genomic and complementary RNA

The density and sedimentation characteristics of ribonucleoproteins (RNP) containing genomic RNA from influenza virus and RNA complementary have been studied. Radioactive RNA from infected cells has been used for analysis. RNA classes of interest were isolated by reannealing with abundant nonradioactive genomic and complementary RNA and separation of resulting duplexes in electrophoresis. The RNP containing antigenomic virus-specific RNA are practically identical to "genomic" RNP for their sedimentation and density characteristics. The "plus" RNP is characterized by the stoichiometric mode of RNA protein interaction.     

Utilization of a mammalian cell-based RNA binding assay to characterize the RNA binding properties of picornavirus 3C proteinases.

Using an assay capable of detecting sequence-specific RNA/protein interactions in mammalian cells, we demonstrate that the poliovirus and rhinovirus 3C proteinases are able to bind structured target RNA sequences derived from their respective 5' noncoding regions in vivo. Specific RNA binding by poliovirus 3C was found to be dependent on the integrity of stem-loop d of the RNA cloverleaf structure located at the 5' end of poliovirus genomic RNA. In contrast, mutation of stem-loop b did not prevent this in vivo interaction. However, mutation of stem-loop b, which serves as the RNA binding site for a cellular co-factor important for efficient poliovirus replication, did significantly attenuate the efficiency of 3C RNA binding in vivo and 3CD RNA binding in vitro. This in vivo protein:RNA binding assay was also used to identify several residues in 3C that are critical for RNA binding, but dispensable for 3C proteinase activity. The mammalian cell-based RNA binding assay described in this study may have considerable potential utility in the future detection or analysis of in vivo RNA/protein interactions unrelated to the 3C/RNA interaction described here.