In vivo oligo(A) insertions in phage MS2: role of Escherichia coli poly(A) polymerase.

Previously we introduced an RNase III site into the genome of RNA phage MS2 by extending a hairpin with a perfect 18 bp long stem. One way in which the phage escaped from being killed by RNase III cleavage was to incorporate uncoded A residues on either side of the stem. This oligo(A) stretch interrupts the perfect stem that forms the RNase III site and thus confers resistance. In this paper we have analyzed the origin of these uncoded adenosines. The data strongly suggest that they are added by the host enzyme poly(A) polymerase. Apparently the 3'-OH created by RNase III cleavage becomes a substrate for poly(A) polymerase. Subsequently, MS2 replicase makes one contiguous copy from the two parts of the genome RNA. The evolutionary conversion from RNase III sensitivity to resistance provides a large spectrum of solutions that could be an important tool to understand what essentially constitutes an RNase III site in vivo.     

Stable hairpin structure within the 5''-terminal 85 nucleotides of poliovirus RNA.

The primary sequence of a 5'-terminal fragment of poliovirus type 1 RNA, generated by digestion with RNase III, has been determined. This sequence reveals the presence of a stable hairpin structure beginning nine nucleotides from the terminally linked protein VPg. The sequence does not contain (i) the initiation codons AUG or GUG or (ii) the putative ribosome-binding sequence complementary to the 3' end of eucaryotic ribosomal 18S RNA. The stem-and-loop structure identified can be drawn in either plus or minus RNA strands. It is unclear to which strand functional significance (if any) can be assigned. It is possible that the hairpin structure is involved in ribosomal recognition and translation or in RNA synthesis by interacting with replicase molecules.     

Interaction of turnip yellow mosaic virus Val-RNA with eukaryotic elongation factor EF-1 [alpha]. Search for a function

The 3'-terminal tRNA-like structure in turnip yellow mosaic virus (TYMV) RNA can be adenylated by tRNA nucleotidyltransferase and subsequently aminoacylated by valyl-tRNA synthetase.Here we present evidence that TYMV Val-RNA can form a stable complex with eukaryotic wheat germ elongation factor EF-1alpha and GTP: the Val-RNA is protected by EF-1alpha.. GTP against digestion by RNase A. By affinity chromatography of TYMV Val-RNA fragments on immobilized EF-1alpha . GTP, it has been established that the valylated aminoacyl RNA domain, which in TYMV RNA is formed by the 3' half of the tRNA-like region, is sufficient for complex formation with EF-1alpha . GTP. The aminoacyl RNA domain is equivalent in tRNAs to the continuous helix formed by the acceptor stem and the T stem and loop. In line with these results, the aminoacyl RNA domain in TYMV Val-RNA complexed to EF-1 alpha . GTP is resistant to digestion by RNase A. It is also shown that the TYMV RNA replicase (RNA-dependent RNA polymerase) isolated from TYMV-infected Chinese cabbage leaves does not contain tRNA nucleotidyltransferase, valyl-tRNA synthetase or EF-1alpha. This suggests that interaction of TYMV RNA with EF-1alpha is not mandatory for replicase activity.     

Mutational analysis of the sequence and structural requirements in brome mosaic virus RNA for minus strand promoter activity

An RNA-dependent RNA polymerase (replicase) activity that specifically copies brome mosaic virus (BMV) RNAs in vitro can be prepared from BMV-infected barley leaves. The signals directing complementary (minus) strand synthesis reside within the 3' 134-nucleotide-long tRNA-like structure that is common to each of the virion RNAs. By studying the influence of minus strand synthesis of numerous mutations introduced throughout this region of the RNA, we have mapped in detail the sequence and structural elements necessary for minus strand promoter activity. Sequence alterations (either substitutions or small, structurally discrete deletions) in most parts of the tRNA-like structure resulted in decreased minus strand synthesis. This suggests that BMV replicase is a large enzyme, possibly composed of several subunits. The lowest activities, 5 to 8% of wild type, were observed for mutants with substitutions at three separate loci, identifying one structural and two sequence-specific elements essential for optimal promoter activity. (1) Destabilization of the pseudoknot structure in the aminoacyl acceptor stem resulted in low promoter activity, demonstrating the importance of a tRNA-like conformation. (2) Substitution of the C residue adjacent to the 3' terminus resulted in low promoter activity, probably by interfering with strand initiation. (3) The low activities resulting from substitutions and a small deletion in arm C suggest this region of the RNA to be a major feature involved in replicase binding. In particular, nucleotides within the loop of arm C appear to be involved in a sequence-specific interaction with the replicase.     

In vitro replication of tobacco mosaic virus RNA in tobacco callus cultures: solubilization of membrane-bound replicase and partial purification.

A fraction containing membrane-bound tobacco mosaic virus RNA replicase was isolated form tobacco mosaic virus-infected tobacco callus cultures. The replicase activity reached a maximum 60 h after inoculation and then declined. The enzyme activity was insensitive to actinomycin D and DNase. The corresponding fraction from healthy callus contained essentially no activity. The viral RNA synthesis in vitro proceeded linearly for 30 min and required the four nucleotide triphosphates and Mg2+ ions. Mn2+ was a poor substitute for Mg2+. During RNA synthesis the product was at least 70% resistant to RNase in 2X SSC (0.15 M NaCl plus 0.015 M sodium citrate), but completely digested by RNase in 0.1X SSC. Analysis of the product by polns) that appeared to be replicative form and a partially RNase-resistant structure similar to replicative intermediate form. Washing the membrane-bound replicase with Mg2+-deficient buffer solubilized enzyme. The solubulized enzyme was further purified by DEAE-Sephadex column chromatography. The DEAE-purified enzyme was nearly completely dependent upon tobacco mosaic virus RNA for activity. Analysis of the product on a sucrose gradient revealed a double-stranded RNA with sedimentation of 16S and smaller heterogeneous RNase-sensitive products.     

特异切割马铃薯卷叶病毒复制酶基因负链的核酶研究

根据锤头状核酶的作用模式,设计、合成并克隆了特异性切割马铃薯地病毒中国分离株（ＰＬＲＶ－Ｃｈ）复制酶基因负链ＲＮＡ的核酶序列,以体外转录的ＰＬＲＶ－Ｃｈ复制酶基因负链ＲＮＡ作为底物,与转录的核酶ＲＮＡ共同保温,以检测核酶对底和的体外切割作用。实验结果表明,核酸疼 ＲＮＡ对ＰＬＲＶ－Ｃｈ复制酶基因负锭ＲＮＡ具有特异切割作用。     

Specificity of cleavage by ribonuclease III

The specificity of RNase III for various synthetic homopolymeric doublestranded RNA substrates have been examined. Although RNase III appears to cleave all homopolymeric RNA duplex structures, with Poly (U)·Poly (A) as the substrate, the enzyme cleaves the Poly (U) strand much faster than it cleaves the Poly (A) strand. Under conditions where the Poly (U) strand is quantitatively cleaved into acid-soluble fragments ranging in size between 5–8 nucleotides in length, the poly (A) strand is cleaved into large fragments 40–60 nucleotides in length. These results indicate that RNase III recognizes duplex RNA structures for binding, and makes single-stranded scissions and suggests that the enzyme has a preference for cleaving adjacent to UMP residues over AMP residues in polynucleotide chains.     

Long-range translational coupling in single-stranded RNA bacteriophages: an evolutionary analysis.

In coliphage MS2 RNA a long-distance interaction (LDI) between an internal segment of the upstream coat gene and the start region of the replicase gene prevents initiation of replicase synthesis in the absence of coat gene translation. Elongating ribosomes break up the repressor LDI and thus activate the hidden initiation site. Expression studies on partial MS2 cDNA clones identified base pairing between 1427-1433 and 1738-1744, the so-called Min Jou (MJ) interaction, as the molecular basis for the long-range coupling mechanism. Here, we examine the biological significance of this interaction for the control of replicase gene translation. The LDI was disrupted by mutations in the 3'-side and the evolutionary adaptation was monitored upon phage passaging. Two categories of pseudorevertants emerged. The first type had restored the MJ interaction but not necessarily the native sequence. The pseudorevertants of the second type acquired a compensatory substitution some 80 nt downstream of the MJ interaction that stabilizes an adjacent LDI. In one examined case we confirmed that the second site mutations had restored coat-replicase translational coupling. Our results show the importance of translational control for fitness of the phage. They also reveal that the structure that buries the replicase start extends to structure elements bordering the MJ interaction.     

Crystal structure of RNase H3–substrate complex reveals parallel evolution of RNA/DNA hybrid recognition

RNases H participate in the replication and maintenance of genomic DNA. RNase H1 cleaves the RNA strand of RNA/DNA hybrids, and RNase H2 in addition hydrolyzes the RNA residue of RNA–DNA junctions. RNase H3 is structurally closely related to RNases H2, but its biochemical properties are similar to type 1 enzymes. Its unique N-terminal substrate-binding domain (N-domain) is related to TATA-binding protein. Here, we report the first crystal structure of RNase H3 in complex with its RNA/DNA substrate. Just like RNases H1, type 3 enzyme recognizes the 2′-OH groups of the RNA strand and detects the DNA strand by binding a phosphate group and inducing B-form conformation. Moreover, the N-domain recognizes RNA and DNA in a manner that is highly similar to the hybrid-binding domain of RNases H1. Our structure demonstrates a remarkable example of parallel evolution of the elements used in the specific recognition of RNA and DNA.     

Secondary structure of the central region of bacteriophage MS2 RNA. Conservation and biological significance

The RNA of the Escherichia coli RNA phages is highly structured with 75% of the nucleotides estimated to take part in base-pairing. We have used enzymatic and chemical sensitivity of nucleotides, phylogenetic sequence comparison and the phenotypes of constructed mutants to develop a secondary structure model for the central region (900 nucleotides) of the group I phage MS2. The RNA folds into a number of, mostly irregular, helices and is further condensed by several long-distance interactions. There is substantial conservation of helices between the related groups I and II, attesting to the relevance of discrete RNA folding. In general, the secondary structure is thought to be needed to prevent annealing of plus and minus strand and to confer protection against RNase. Superimposed, however, are features required to regulate translation and replication. The MS2 RNA section studied here contains three translational start sites, as well as the binding sites for the coat protein and the replicase enzyme. Considering the density of helices along the RNA, it is not unexpected to find that all these sites lie in helical regions. This fact, however, does not mean that these sites are recognized as secondary structure elements by their interaction partners. This holds true only for the coat protein binding site. The other four sites function in the unfolded state and the stability of the helix in which they are contained serves to negatively control their accessibility. Mutations that stabilize helices containing ribosomal binding sites reduce their efficiency and vice versa. Comparison of homologous helices in different phage RNAs indicates that base substitutions have occurred in such a way that the thermodynamic stability of the helix is maintained. The evolution of individual helices shows several distinct size-reduction patterns. We have observed codon deletions from loop areas and shortening of hairpins by base-pair deletions from either the bottom, the middle or the top of stem structures. Evidence for the coaxial stacking of some helical segments is discussed.     

RNase III cleaves vesicular stomatitis virus genome-length RNAs but fails to cleave viral mRNA''s.

The procaryotic RNA processing enzyme RNase III (endoribonuclease III [EC 3.1.4.24]) was used to probe vesicular stomatitis virus (VSV) RNAs for specific sites that could be recognized and cleaved. The effect of the enzyme on the RNAs was monitored by measuring their subsequent migration in denaturing agarose-urea gels. VSV virion RNA (negative strand; Mr, 4 X 10(6)) was cleaved by the enzyme to yield a set of discrete fragments which ranged on size from 3.5 X 10(6) to 0.2 X 10(6) daltons. The cleavage was a function of enzyme concentration, salt concentration, and time. A maximum of 20 to 22 fragments was generated under conditions of low enzyme concentration or short times of incubation. VSV genome-length intracellular RNA of both + and - polarity was also cleaved by RNase III. In contrast to the findings with virion-length RNA, however, the migration rates of VSV mRNA's purified by chromatography on polyuridylic acid-Sepharose were unaffected by treatment with RNase III. These results show that specific sites in the virion RNA and its full-length complement can be recognized by RNase III. Sites of this type are not present in the polyadenylic acid-containing mRNA, however.     

Structural insight into the mechanism of double-stranded RNA processing by ribonuclease III

Members of the ribonuclease III (RNase III) family are double-stranded RNA (dsRNA) specific endoribonucleases characterized by a signature motif in their active centers and a two-base 3' overhang in their products. While Dicer, which produces small interfering RNAs, is currently the focus of intense interest, the structurally simpler bacterial RNase III serves as a paradigm for the entire family. Here, we present the crystal structure of an RNase III-product complex, the first catalytic complex observed for the family. A 7 residue linker within the protein facilitates induced fit in protein-RNA recognition. A pattern of protein-RNA interactions, defined by four RNA binding motifs in RNase III and three protein-interacting boxes in dsRNA, is responsible for substrate specificity, while conserved amino acid residues and divalent cations are responsible for scissile-bond cleavage. The structure reveals a wealth of information about the mechanism of RNA hydrolysis that can be extrapolated to other RNase III family members.     

MS2噬菌体衣壳蛋白与包装位点结合特异性及其生物学应用进展

MS2噬菌体为正义单链RNA噬菌体,基因组含有3569个核苷酸,编码成熟酶蛋白、衣壳蛋白、复制酶蛋白和裂解蛋白。MS2噬菌体复制酶编码基因5'端一个由19个碱基组成的茎环结构(又称包装位点)是衣壳蛋白二聚体与RNA相互作用的部位,二者相互作用形成的复合物是启动噬菌体自我包装的信号。MS2噬菌体衣壳蛋白与包装位点结合的特异性已被应用于RNA病毒核酸检测的标准物质、校准品和质控品的研究,实时动态监测活细胞内RNA的运动,以及RNA体内递送载体的研究等领域。     

Emergence of distinct brome mosaic virus recombinants is determined by the polarity of the inoculum RNA

Despite overwhelming interest in the impact exerted by recombination during evolution of RNA viruses, the relative contribution of the polarity of inoculum templates remains poorly understood. Here, by agroinfiltrating Nicotiana benthamiana leaves, we show that brome mosaic virus (BMV) replicase is competent to initiate positive-strand [(+)-strand] synthesis on an ectopically expressed RNA3 negative strand [(-) strand] and faithfully complete the replication cycle. Consequently, we sought to examine the role of RNA polarity in BMV recombination by expressing a series of replication-defective mutants of BMV RNA3 in (+) or (-) polarity. Temporal analysis of progeny sequences revealed that the genetic makeup of the primary recombinant pool is determined by the polarity of the inoculum template. When the polarity of the inoculum template was (+), the recombinant pool that accumulated during early phases of replication was a mixture of nonhomologous recombinants. These are longer than the inoculum template length, and a nascent 3' untranslated region (UTR) of wild-type (WT) RNA1 or RNA2 was added to the input mutant RNA3 3' UTR due to end-to-end template switching by BMV replicase during (-)-strand synthesis. In contrast, when the polarity of the inoculum was (-), the progeny contained a pool of native-length homologous recombinants generated by template switching of BMV replicase with a nascent UTR from WT RNA1 or RNA2 during (+)-strand synthesis. Repair of a point mutation caused by polymerase error occurred only when the polarity of the inoculum template was (+). These results contribute to the explanation of the functional role of RNA polarity in recombination mediated by copy choice mechanisms.     

In Vitro Replication of Cowpea Mosaic Virus RNA I. Isolation and Properties of the Membrane-Bound Replicase

A fraction which contained the membrane-bound cowpea mosaic virus RNA replicase was isolated from cowpea mosaic virus-infected cowpea leaves. The replicase activity appeared on day 1 after inoculation, then increased to reach a maximal on day 4. The increase in enzyme activity preceded the most-rapid virus multiplication. The membrane-bound replicase activity was almost completely insensitive to actinomycin D and DNase. The corresponding fraction from healthy leaves had no RNA-dependent RNA polymerase activity. The viral RNA synthesis in vitro proceeded linearly for 20 min and required all four ribonucleoside triphosphates and Mg(2+) ions. Mn(2+) was a poor substitute for Mg(2+). The reaction was optimal at pH 8.2. During the whole period of RNA synthesis the in vitro synthesized RNA was at least 70% resistant against RNase in 2 x SSC (0.15 M NaCl plus 0.015 M sodium citrate), but completely digestable by RNase in 0.1 x SSC. Analysis of the products by sucrose gradient centrifugation followed by treatment of separate fractions with RNase demonstrated that both single-and double-stranded RNA were present. Double-stranded RNA sedimented at about 20S, with a shoulder at 16S to 17S. A minor part of the double-stranded RNA sedimented below 10S. Single-stranded RNA sedimented with the same rate as the two viral RNAs, 26S and 34S.