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.     

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.     

Brome mosaic virus Protein 1a recruits viral RNA2 to RNA replication through a 5' proximal RNA2 signal

Brome mosaic virus (BMV), a positive-strand RNA virus in the alphavirus-like superfamily, encodes two RNA replication factors. Membrane-associated 1a protein contains a helicase-like domain and RNA capping functions. 2a, which is targeted to membranes by 1a, contains a central polymerase-like domain. In the absence of 2a and RNA replication, 1a acts through an intergenic replication signal in BMV genomic RNA3 to stabilize RNA3 and induce RNA3 to associate with cellular membrane. Multiple results imply that 1a-induced RNA3 stabilization reflects interactions involved in recruiting RNA3 templates into replication. To determine if 1a had similar effects on another BMV RNA replication template, we constructed a plasmid expressing BMV genomic RNA2 in vivo. In vivo-expressed RNA2 templates were replicated upon expression of 1a and 2a. In the absence of 2a, 1a stabilized RNA2 and induced RNA2 to associate with membrane. Deletion analysis demonstrated that 1a-induced membrane association of RNA2 was mediated by sequences in the 5'-proximal third of RNA2. The RNA2 5' untranslated region was sufficient to confer 1a-induced membrane association on a nonviral RNA. However, sequences in the N-terminal region of the 2a open reading frame enhanced 1a responsiveness of RNA2 and a chimeric RNA. A 5'-terminal RNA2 stem-loop important for RNA2 replication was essential for 1a-induced membrane association of RNA2 and, like the 1a-responsive RNA3 intergenic region, contained a required box B motif corresponding to the TPsiC stem-loop of host tRNAs. The level of 1a-induced membrane association of various RNA2 mutants correlated well with their abilities to serve as replication templates. These results support and expand the conclusion that 1a-induced BMV RNA stabilization and membrane association reflect early, 1a-mediated steps in viral RNA replication.     

Small RNA species in maize tissue

The low molecular weight RNA components of maize have been analyzed after labeling callus and leaf tissue with [³H]uridine in vitro. Electrophoresis of the isolated RNA on acrylamide slab gels reveals, apart from 5S and transfer RNA, three major and about five minor RNA species with chain lengths between 140 and 280 nucleotides. These RNA molecules are labeled as rapidly as 5S, transfer RNA, and do not represent degradation products of large ribosomal RNA molecules. Furthermore, like 5S and transfer RNA, these small RNA species are stable and show no detectable turnover within forty-eight hours. Fractionation of the tissue into crude subcellular fractions indicates a preferential association of some of the small stable RNA species with the nucleus, while others appear to be located in the cytoplasm. The low molecular weight RNA spectrum from the leaf is similar to that observed in callus, with the major small RNA species equally present in both tissues.Abbreviations tRNA transfer RNA - hnRNA heterogenous nuclear RNA - mRNA messenger RNA - scRNA small cytoplasmic RNA - snRNA small nuclear RNA     

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.     

Characterization of the Low-Molecular-Weight RNAs Associated with the 70S RNA of Rous Sarcoma Virus

Two low-molecular-weight RNAs are associated with the 70S RNA complex of Rous sarcoma virus: a previously described 4S RNA and a newly identified 5S RNA. The 4S RNA constitutes 3 to 4% of the 70S RNA complex or the equivalent of 12 to 20 molecules per 70S RNA. It exhibits a number of structural properties characteristic of transfer RNA as revealed by two-dimensional electrophoresis of oligonucleotides obtained from a T1 ribonuclease digest of the 4S RNA species. The 5S RNA is approximately 120 nucleotides in length, constitutes 1% of the 70S RNA complex or the equivalent of 3 to 4 molecules per molecules of 70S RNA, and is identical in nucleotide composition and structure to 5S RNA from uninfected chicken embryo fibroblasts. Melting studies indicate that the 5S RNA is released from the 70S RNA complex at the same temperature required to dissociate 70S RNA into its constituent 35S subunits. In contrast, greater than 80% of the 4S RNA is released from 70S RNA prior to its conversion into subunits. The possible biological significance of these 70S-associated RNAs is discussed.     

Nodamura virus RNA replication in Saccharomyces cerevisiae: heterologous gene expression allows replication-dependent colony formation

Nodamura virus (NoV) and Flock House virus (FHV) are members of the family Nodaviridae. The nodavirus genome is composed of two positive-sense RNA segments: RNA1 encodes the viral RNA-dependent RNA polymerase and RNA2 encodes the capsid protein precursor. A small subgenomic RNA3, which encodes nonstructural proteins B1 and B2, is transcribed from RNA1 during RNA replication. Previously, FHV was shown to replicate both of its genomic RNAs and to transcribe RNA3 in transiently transfected yeast cells. FHV RNAs and their derivatives could also be expressed from plasmids containing RNA polymerase II promoters. Here we show that all of these features can be recapitulated for NoV, the only nodavirus that productively infects mammals. Inducible plasmid-based systems were used to characterize the RNA replication requirements for NoV RNA1 and RNA2 in Saccharomyces cerevisiae. Induced NoV RNA1 replication was robust. Three previously described NoV RNA1 mutants behaved in yeast as they had in mammalian cells. Yeast colonies were selected from cells expressing NoV RNA1, and RNA2 replicons that encoded yeast nutritional markers, from plasmids. Unexpectedly, these NoV RNA replication-dependent yeast colonies were recovered at frequencies 10(4)-fold lower than in the analogous FHV system. Molecular analysis revealed that some of the NoV RNA replication-dependent colonies contained mutations in the NoV B2 open reading frame in the replicating viral RNA. In addition, we found that NoV RNA1 could support limited replication of a deletion derivative of the heterologous FHV RNA2 that expressed the yeast HIS3 selectable marker, resulting in formation of HIS+ colonies.     

卫星RNA对黄瓜花叶病毒基因组RNA体外合成的影响

卫星ＲＮＡ对黄瓜花叶病毒基因组ＲＮＡ体外合成的影响杨海花,康良仪,赵大健,田波（中国科学院微生物研究所,北京１０００８０）关键词卫星ＲＮＡ,黄瓜花叶病毒,依赖ＲＮＡ的ＲＮＡ聚合酶,体外合成利用卫星ＲＮＡ生防制剂控制田间的番茄、青椒、烟草等由黄瓜花叶病...     

野田村病毒RNA的复制机制

野田村病毒科Nodaviradae分为2个属,分别为主要感染昆虫的α野田村病毒属(Alphanodavirus)和主要感染鱼类的β野田村病毒属(Betanodavirus)。野田村病毒的基因组由2条单链正义RNA分子(RNA1和RNA2)所组成,RNA1编码蛋白A,即病毒负责复制病毒两条基因组的依赖RNA的RNA聚合酶催化亚基。RNA2编码衣壳前体蛋白α,此前体蛋白α先组装成原病毒粒子,再经历一次自我催化的成熟切割成2个病毒的衣壳蛋白β和γ,就成了成熟的有感染性的病毒粒子。在RNA复制过程中,从RNA1的3′末端会合成一个不被包装进病毒粒子的亚基因组RNA3。RNA1能在无RNA2的情况下自我复制,并持续地产生亚基因组RNA3,RNA3的合成采取的是提前终止机制。本文还介绍了野田村病毒复制的调节、非结构蛋白的功能和病毒复制在细胞内的定位。     

细菌RNA稳定性调控相关元件的研究进展

RNA降解体（细菌RNA降解的主要执行者）是一种多亚基的蛋白质复合物,主要由RNA解螺旋酶、聚核苷酸磷酸化酶（polynucleotide phosphorylase,PNPase）、内切核酸酶（ribonuclease E,RNase E）以及糖酵解途径中的烯醇化酶、磷酸果糖激酶等组成,参与核糖体RNA（ribosome RNA,rRNA）的加工以及信使RNA（messenger RNA,mRNA）的降解。此外,RNA分子伴侣Hfq和调控小RNA（small RNA,sRNA）在RNA稳定性调控中也发挥着重要作用。综述了细菌RNA稳定性调控相关功能元件,特别是降解体蛋白及RNA分子伴侣Hfq的最新进展,以期为研究细菌RNA稳定性及其参与的代谢调控提供理论参考。     

DNA-Directed expression of functional flock house virus RNA1 derivatives in Saccharomyces cerevisiae, heterologous gene expression, and selective effects on subgenomic mRNA synthesis

Flock house virus (FHV), a positive-strand RNA animal virus, is the only higher eukaryotic virus shown to undergo complete replication in yeast, culminating in production of infectious virions. To facilitate studies of viral and host functions in FHV replication in Saccharomyces cerevisiae, yeast DNA plasmids were constructed to inducibly express wild-type FHV RNA1 in vivo. Subsequent translation of FHV replicase protein A initiated robust RNA1 replication, amplifying RNA1 to levels approaching those of rRNA, as in FHV-infected animal cells. The RNA1-derived subgenomic mRNA, RNA3, accumulated to even higher levels of >100,000 copies per yeast cell, compared to 10 copies or less per cell for 95% of yeast mRNAs. The time course of RNA1 replication and RNA3 synthesis in induced yeast paralleled that in yeast transfected with natural FHV virion RNA. As in animal cells, RNA1 replication and RNA3 synthesis depended on FHV RNA replicase protein A and 3'-terminal RNA1 sequences but not viral protein B2. Additional plasmids were engineered to inducibly express RNA1 derivatives with insertions of the green fluorescent protein (GFP) gene in subgenomic RNA3. These RNA1 derivatives were replicated, synthesized RNA3, and expressed GFP when provided FHV polymerase in either cis or trans, providing the first demonstration of reporter gene expression from FHV subgenomic RNA. Unexpectedly, fusing GFP to the protein A C terminus selectively inhibited production of positive- and negative-strand subgenomic RNA3 but not genomic RNA1 replication. Moreover, changing the first nucleotide of the subgenomic mRNA from G to T selectively inhibited production of positive-strand but not negative-strand RNA3, suggesting that synthesis of negative-strand subgenomic RNA3 may precede synthesis of positive-strand RNA3.     

Studies of newly synthesized ribosomal ribonucleic acid of Escherichia coli

1. RNA synthesized by Escherichia coli during one-hundredth of the generation time contains two fractions distinguishable by hybridization with homologous DNA. One fraction, approximately 30% of the newly synthesized RNA, did not compete with ribosomal RNA, being apparently messenger RNA. The other fraction, approximately 70% of the newly made RNA, hybridized as ribosomal RNA. These values are comparable with previous estimates (McCarthy & Bolton, 1964; Pigott & Midgley, 1968). 2. Hybridization-competition experiments showed that the newly made RNA associated with 70s ribosomes and larger ribosome aggregates was a mixture of ribosomal RNA and messenger RNA, whereas that associated with nascent ribosomal subunits consisted exclusively of ribosomal RNA. This observation provides means by which newly synthesized ribosomal RNA can be isolated free from messenger RNA. 3. Newly made ribosomal RNA in nascent ribosomal subunits was sensitive to shear under conditions where ribosomal RNA in mature ribosomes was shear-resistant. Thus, when RNA was extracted from cells of E. coli disrupted by mechanical means, newly made ribosomal RNA appeared heterogeneous in size, sedimenting as a broad peak extending from 8s to 16s. 4. Newly synthesized ribosomal RNA in nascent ribosomal subunits was rapidly degraded in the presence of actinomycin D and during glucose starvation. 5. Newly synthesized ribosomal RNA stimulated amino acid incorporation in a system synthesizing protein in vitro to the same extent as the RNA which contained the messenger RNA fraction.     

Electrophoretic Characterization of Foot-and-Mouth Disease Virus-Specific Ribonucleic Acid

Foot-and-mouth disease virus (FMDV)-specific ribonucleic acid (RNA) was analyzed by electrophoresis on 0.5% agarose gels. Four classes of RNA were resolved as a function of mobility in agarose: two classes of slowly migrating multistranded RNA, the infectious viral RNA with intermediate mobility, and a minor fast-moving class of lower-molecular-weight single-stranded RNA. The major RNA species were infectious viral RNA and the slowest migrating class of multistranded RNA. The latter RNA was polydisperse when analyzed by sucrose gradient centrifugation, it was partially ribonuclease resistant, and it was the predominant RNA species labeled during the initial period of (3)H-uridine triphosphate incorporation in the cell-free system. Heat treatment studies indicated that part of the slowest-moving RNA was degraded at 60 C and almost complete degradation was detected at 100 C. It was concluded that this RNA is the replicative intermediate in viral RNA synthesis. The second class of multistranded RNA contained both a ribonuclease-resistant RNA and a second RNA peak which was detected only after heat treatment at temperatures above 75 C. Fractions of FMDV-specific RNA isolated by sucrose gradient centrifugation were analyzed by agarose-gel electrophoresis. Infectious viral RNA was detected only in the 37S zone and was the major species of RNA in this part of the gradient. The ribonuclease-resistant RNA (the 20S zone) contained about equal amounts of multistranded RNA (both classes) and the low-molecular-weight single-stranded RNA. All sucrose gradient fractions between 20 and 40S were found to contain the replicative intermediate, although the major portion was detected in the 20 to 25S region.     

The red clover necrotic mosaic virus RNA2 trans-activator is also a cis-acting RNA2 replication element

The expression of the coat protein gene requires RNA-mediated trans-activation of subgenomic RNA synthesis in Red clover necrotic mosaic virus (RCNMV), the genome of which consists of two positive-strand RNAs, RNA1 and RNA2. The trans-acting RNA element required for subgenomic RNA synthesis from RNA1 has been mapped previously to the protein-coding region of RNA2, whereas RNA2 is not required for the replication of RNA1. In this study, we investigated the roles of the protein-coding region in RNA2 replication by analyzing the replication competence of RNA2 mutants containing deletions or nucleotide substitutions. Our results indicate that the same stem-loop structure (SL2) that functions as a trans-activator for RNA-mediated coat protein expression is critically required for the replication of RNA2 itself. Interestingly, however, disruption of the RNA-RNA interaction by nucleotide substitutions in the region of RNA1 corresponding to the SL2 loop of RNA2 does not affect RNA2 replication, indicating that the RNA-RNA interaction is not required for RNA2 replication. Further mutational analysis showed that, in addition to the stem-loop structure itself, nucleotide sequences in the stem and in the loop of SL2 are important for the replication of RNA2. These findings suggest that the structure and nucleotide sequence of SL2 in RNA2 play multiple roles in the virus life cycle.