The Structure of the RNA-Dependent RNA Polymerase of a Permutotetravirus Suggests a Link between Primer-Dependent and Primer-Independent Polymerases

Thosea asigna virus (TaV), an insect virus belonging to the Permutatetraviridae family, has a positive-sense single-stranded RNA (ssRNA) genome with two overlapping open reading frames, encoding for the replicase and capsid proteins. The particular TaV replicase includes a structurally unique RNA-dependent RNA polymerase (RdRP) with a sequence permutation in the palm sub-domain, where the active site is anchored. This non-canonical arrangement of the RdRP palm is also found in double-stranded RNA viruses of the Birnaviridae family. Both virus families also share a conserved VPg sequence motif at the polymerase N-terminus which in birnaviruses appears to be used to covalently link a fraction of the replicase molecules to the 5’-end of the genomic segments. Birnavirus VPgs are presumed to be used as primers for replication initiation. Here we have solved the crystal structure of the TaV RdRP, the first non-canonical RdRP of a ssRNA virus, in its apo- form and bound to different substrates. The enzyme arranges as a stable dimer maintained by mutual interactions between the active site cleft of one molecule and the flexible N-terminal tail of the symmetrically related RdRP. The latter, partially mimicking the RNA template backbone, is involved in regulating the polymerization activity. As expected from previous sequence-based bioinformatics predictions, the overall architecture of the TaV enzyme shows important resemblances with birnavirus polymerases. In addition, structural comparisons and biochemical analyses reveal unexpected similarities between the TaV RdRP and those of Flaviviruses. In particular, a long loop protruding from the thumb domain towards the central enzyme cavity appears to act as a platform for de novo initiation of RNA replication. Our findings strongly suggest an unexpected evolutionary relationship between the RdRPs encoded by these distant ssRNA virus groups.     

Initiation of Genomic Plus-Strand RNA Synthesis from DNA and RNA Templates by a Viral RNA-Dependent RNA Polymerase

In contrast to the synthesis of minus-strand genomic and plus-strand subgenomic RNAs, the requirements for brome mosaic virus (BMV) genomic plus-strand RNA synthesis in vitro have not been previously reported. Therefore, little is known about the biochemical requirements for directing genomic plus-strand synthesis. Using DNA templates to characterize the requirements for RNA-dependent RNA polymerase template recognition, we found that initiation from the 3' end of a template requires one nucleotide 3' of the initiation nucleotide. The addition of a nontemplated nucleotide at the 3' end of minus-strand BMV RNAs led to initiation of genomic plus-strand RNA in vitro. Genomic plus-strand initiation was specific since cucumber mosaic virus minus-strand RNA templates were unable to direct efficient synthesis under the same conditions. In addition, mutational analysis of the minus-strand template revealed that the -1 nontemplated nucleotide, along with the +1 cytidylate and +2 adenylate, is important for RNA-dependent RNA polymerase interaction. Furthermore, genomic plus-strand RNA synthesis is affected by sequences 5' of the initiation site.     

Arabidopsis RNA-Dependent RNA Polymerases and Dicer-Like Proteins in Antiviral Defense and Small Interfering RNA Biogenesis during Turnip Mosaic Virus Infection

Plants respond to virus infections by activation of RNA-based silencing, which limits infection at both the single-cell and system levels. Viruses encode RNA silencing suppressor proteins that interfere with this response. Wild-type Arabidopsis thaliana is immune to silencing suppressor (HC-Pro)-deficient Turnip mosaic virus, but immunity was lost in the absence of DICER-LIKE proteins DCL4 and DCL2. Systematic analysis of susceptibility and small RNA formation in Arabidopsis mutants lacking combinations of RNA-dependent RNA polymerase (RDR) and DCL proteins revealed that the vast majority of virus-derived small interfering RNAs (siRNAs) were dependent on DCL4 and RDR1, although full antiviral defense also required DCL2 and RDR6. Among the DCLs, DCL4 was sufficient for antiviral silencing in inoculated leaves, but DCL2 and DCL4 were both involved in silencing in systemic tissues (inflorescences). Basal levels of antiviral RNA silencing and siRNA biogenesis were detected in mutants lacking RDR1, RDR2, and RDR6, indicating an alternate route to form double-stranded RNA that does not depend on the three previously characterized RDR proteins.     

The Mode of Inhibition of TMV- and PVX-Induced RNA-Dependent RNA Polymerases by some Antiphytoviral Drugs

Six nucleobase and nucleoside analogues (6-aminouracil [6-AU], 6-aminothymin [6-AT], 6-fluorothymin [6-FT], 2,4-dioxohexahydro-1,3,5-triazine [DHT], 9-(2,3-dihydroxypropyl) adenine [DHPA] and 1-β-D-ribofuranosyl-1,2,4-triazol-3-carboxamid [ribavirin]) with potential antiphytoviral activity were tested in an in vitro replication system for their effect on tobacco mosaic virus (TMV)-and potato virus X(PVX)-induced RNA dependent RNA polymerase. 6-AU, 6-AT, 6-FT, and DHPA inhibited both polymerases which may be a target of these compounds. A Putative noncompetitive mode of inhibition is discussed. Whereas ribavirin did not affect the in vitr RNA synthesis in the established systems, the uracil-derivative DHT inhibited only the PVX-specific enzyme.     

Enzymatic Synthesis of Bacteriophage f1 DNA: RNA Hybrid and Double Stranded RNA

A double stranded RNA and an RNA-DNA hybrid of the same nucleotide sequence have been constructed from phage f1.     

Motif D of Viral RNA-Dependent RNA Polymerases Determines Efficiency and Fidelity of Nucleotide Addition

Fast, accurate nucleotide incorporation by polymerases facilitates expression and maintenance of genomes. Many polymerases use conformational dynamics of a conserved α helix to permit efficient nucleotide addition only when the correct nucleotide substrate is bound. This α helix is missing in structures of RNA-dependent RNA polymerases (RdRps) and RTs. Here, we use solution-state nuclear magnetic resonance to demonstrate that the conformation of conserved structural motif D of an RdRp is?linked to the nature (correct versus incorrect) of the bound nucleotide and the protonation state of a conserved, motif-D lysine. Structural data also reveal the inability of motif D to achieve its optimal conformation after incorporation of an incorrect nucleotide. Functional data are consistent with the conformational change of motif D becoming rate limiting during and after nucleotide misincorporation. We conclude that motif D of RdRps and, by inference, RTs is the functional equivalent to the fidelity helix of other polymerases.     

Endotoxin and Double Stranded RNA render Macrophages Cytotoxic

The cytotoxicities of double stranded RNA and endotoxin have striking similarities. Both seem to render mouse macrophages cytotoxic to other mouse cells.     

Viral RNA Synthesis and Levels of DNA-Dependent RNA Polymerases During Replication of Adenovirus 2

The rates of RNA synthesis in cultured human KB cells infected by adenovirus 2 were estimated by measuring the endogenous RNA polymerase activities in isolated nuclei. The fungal toxin α-amanitin was used to determine the relative and absolute levels of RNA synthesis by RNA polymerases I, II, and III in nuclei isolated during the course of infection. Whereas the level of endogenous RNA polymerase I activity in nuclei from infected cells remained constant relative to the level in nuclei from mock-infected cells, the endogenous RNA polymerase II and III activities each increased about 10-fold. These increases in endogenous RNA polymerase activities were accompanied by concomitant increases in the rates of synthesis in isolated nuclei of viral mRNA precursor, which was monitored by hybridization to viral DNA, and of viral 5.5S RNA, which was quantitated by electrophoretic analysis on polyacrylamide gels. The cellular RNA polymerase levels were measured with exogenous templates after solubilization and chromatographic resolution of the enzymes on DEAE-Sephadex, using procedures in which no losses of activity were apparent. In contrast to the endogenous RNA polymerase activities in isolated nuclei, the cellular levels of the solubilized class I, II, and III RNA polymerases remained constant throughout the course of the infection. Furthermore, no differences were detected in the chromatographic properties of the RNA polymerases obtained from infected or control mock-infected cells. These observations suggest that the increases in endogenous RNA polymerase activities in isolated nuclei are not due to variations in the cellular concentrations of the enzymes. Instead, it is likely that the increased endogenous enzyme activities result from either the large amounts of viral DNA template available as a consequence of viral replication or from functional modifications of the RNA polymerases or from a combination of these effects.     

Atomic Force Microscopy Imaging of Double Stranded DNA and RNA

Abstract

A procedure for imaging long DNA and double stranded RNA (dsRNA) molecules using Atomic Force Microscopy (AFM) is described. Stable binding of double stranded DNA molecules to the flat mica surface is achieved by chemical modification of freshly cleaved mica under mild conditions with 3-aminopropyltriethoxy silane. We have obtained striking images of intact lambda DNA, Hind III restriction fragments of lambda DNA and dsRNA from reovirus. These images are stable under repeated scanning and measured contour lengths are accurate to within a few percent. This procedure leads to strong DNA attachment, allowing imaging under water. The widths of the DNA images lie in the range of 20 to 80nm for data obtained in air with commercially available probes. The work demonstrates that AFM is now a routine tool for simple measurements such as a length distribution. Improvement of substrate and sample preparation methods are needed to achieve yet higher resolution.     

A Rapid Method for Isolation of Double Stranded RNA

A rapid and simple method for the isolation and purification of dsRNA is presented. The crucial step of this method is the extraction of proteins and DNA with acid phenol. After the extraction, only RNA is left in the aquaeous phase. ssRNA contamination of the RNA preparation can be greatly reduced when ammonium sulfate is present during the extraction.     

错位双链核糖核酸的热原反应

由于错位dsRNA的毒副作用得到降低,因此是一类很有潜力的抗病毒、抗肿瘤物质。研究中利用家兔实验评价了PolyI:C和PolyI:C12U引起的热原反应。在10mgml、1mgml、005mgml剂量水平PolyI:C12U均未产生发热和其他毒副作用,而PolyI:C实验组均有发热现象,甚至有家兔死亡。     

Regulation of De Novo-Initiated RNA Synthesis in Hepatitis C Virus RNA-Dependent RNA Polymerase by Intermolecular Interactions

The hepatitis C virus (HCV) RNA-dependent RNA polymerase (RdRp) has been proposed to change conformations in association with RNA synthesis and to interact with cellular proteins. In vitro, the RdRp can initiate de novo from the ends of single-stranded RNA or extend a primed RNA template. The interactions between the Δ1 loop and thumb domain in NS5B are required for de novo initiation, although it is unclear whether these interactions are within an NS5B monomer or are part of a higher-order NS5B oligomeric complex. This work seeks to address how polymerase conformation and/or oligomerization affects de novo initiation. We have shown that an increasing enzyme concentration increases de novo initiation by the genotype 1b and 2a RdRps while primer extension reactions are not affected or inhibited under similar conditions. Initiation-defective mutants of the HCV polymerase can increase de novo initiation by the wild-type (WT) polymerase. GTP was also found to stimulate de novo initiation. Our results support a model in which the de novo initiation-competent conformation of the RdRp is stimulated by oligomeric contacts between individual subunits. Using electron microscopy and single-molecule reconstruction, we attempted to visualize the low-resolution conformations of a dimer of a de novo initiation-competent HCV RdRp.Polymerases undergo a series of conformational changes at different stages of nucleic acid synthesis (14). Of the template-dependent polymerases, the RNA-dependent RNA polymerases (RdRps) are the least understood in terms of their mechanism of action. RdRps are of increasing interest since cellular RdRps play important roles in the defense against nonself RNAs (44). In addition, virus-encoded RdRps are important targets for the development of antivirals. A better understanding of RNA-dependent RNA polymerases is thus important for both basic and applied science.Several model systems for biochemical study of viral RNA-dependent RNA synthesis exist (4, 19, 20, 25, 37, 42). Well-characterized RdRps include those from the hepatitis C virus (HCV) and poliovirus (5, 17). In the host, the RdRps are complexed with other viral and/or cellular proteins that are usually associated with membranous intracellular structures. The replicases are usually difficult to study biochemically, but the catalytic RdRp subunits of several viruses can be purified for functional and structural analyses (53). These recombinant proteins can reproduce some of the activities of the replicases, including the ability to initiate RNA synthesis by a de novo mechanism (22, 47-49). Furthermore, recombinant RdRps can affect the activities of other replicase subunits in vitro, suggesting that the recombinant RdRp is useful for an in-depth understanding of RNA synthesis by HCV (45, 60).RdRps form a right-hand-like structure with thumb, finger, and palm subdomains. The metal-coordinating residues important for nucleotide binding are positioned within the palm subdomain (26). An interesting feature of viral RdRps is that they tend to exist in a closed conformation, even in the absence of template, in contrast to DNA-dependent RNA polymerases, which transition from open to closed complexes upon template recognition (13). The closed form of the phage φ6 RdRp has been proposed to allow specific recognition of the single-stranded viral RNA (7). The template channel formed by the closed structure, however, is too narrow to accommodate the partially duplexed RNA that forms during RNA synthesis, and hence, the closed conformation needs to undergo significant rearrangements in the ternary complex. Biswal et al. (3) have captured an X-ray crystallographic structure of a partially open conformation of the HCV RdRp. Bovine viral diarrhea virus (BVDV) RdRp was also shown to exist in a partially open conformation (11). Ranjith-Kumar and Kao (49) demonstrated that the HCV RdRp could initiate RNA synthesis from a circular RNA template, and thus, the threading of a single-stranded RNA into the template channel is not required for de novo-initiated RNA synthesis. Altogether, these results raise the possibility that the HCV RdRp can undergo rearrangements from the closed conformation seen in the crystal structure prior to de novo initiation.A secondary structure that extends from the finger to the thumb subdomains, named the Δ1 loop, has been proposed to serve as a gate to cover the template channel and regulate the switch from de novo initiation to elongation (5, 10). Mutations that affect the interaction between the Δ1 loop and the mostly hydrophobic residues that it contacts have resulted in polymerases that are defective for de novo initiation but can bind to partially duplexed RNA and can extend from the 3′ terminus of an RNA primer (10).Two general models for RNA synthesis by the HCV RdRp can be proposed (Fig. ​(Fig.1).1). The first posits that the HCV RdRp functions as a monomer at least during de novo initiation because the closed template channel is needed for specific recognition of the template (5, 7, 10). It was presumed that the Δ1 loop and thumb domain interaction in the HCV RdRp is stable and mutations that disrupted this interaction would render the enzyme catalytically inactive (5, 24). However, a deletion of five residues in the tip of the Δ1 loop did not prevent RNA synthesis from a primed template by the polymerase (10). Furthermore, a genotype 2a RdRp was crystallized in a form with altered interaction between the Δ1 loop and thumb domain in comparison to the 1b RdRp (3). Interestingly, a low-affinity GTP binding site exists on the thumb domain close to the base of the Δ1 loop binding pocket. GTP binding at this site has been proposed to stabilize the Δ1 loop and thumb domain interactions, favoring the closed monomer model (6). A second model is based on the reports that HCV RdRp can oligomerize and that oligomerization increases its activity (12, 16, 46, 54). The dimer could be active due to either the second subunit increasing the stability of the Δ1 loop and thumb interactions in the first subunit to increase de novo initiation or the two subunits forming a common template-binding domain (Fig. ​(Fig.1).1). Here we have attempted to determine whether monomers or oligomers of the HCV RdRp can better perform de novo initiation using biochemical and biophysical analyses.Open in a separate windowFIG. 1.Models for RNA synthesis by the HCV RdRp. The monomer model is based on the central tenet that intramolecular interactions within an RdRp molecule regulate the modes of RNA synthesis. The curved arrow represents the possible orientation of the template RNA. The oligomer model is an adaptation from the dimer model of the norovirus RdRp (18). T, P, and F represent the thumb, palm, and finger domains, respectively, in different shades of gray, and the thick black line connecting the thumb and finger domains represents the Δ1 loop.     

Host-Cell Repair of Vaccinia Virus and of Double Stranded RNA of Encephalomyocarditis Virus

IN normal human cells DNA which has been damaged by ultraviolet radiation is repaired by excision of thymidine dimers and by repair replication. Patients suffering from xeroderma pigmentosum have a hereditary defect of the excision step and therefore their cells repair ultraviolet-induced lesions in their DNA less efficiently than do normal cells^1–4. An analogous situation has been well characterized in bacteria⁵.     

Regulation of RNA Synthesis by DNA-Dependent RNA Polymerases and RNases during Cold Acclimation in Winter and Spring Wheat

Chromatin DNA-dependent RNA polymerases and RNases activities were measured in winter and spring varieties to understand the overall regulation of RNA synthesis during cold acclimation. We found that total RNA polymerase activities were significantly higher in chromatin isolated from winter wheat compared to the spring wheat during the acclimation period. This increase was parallel to the increase in protein and RNA contents during hardening. The ratio of RNA polymerase I to RNA polymerase II activity was higher than 2 in winter wheat after 30 days of hardening compared, to a ratio of 0.90 under the nonhardening conditions. The increase in activity and the ratio of polymerase I to polymerase II was maintained after the separation of the enzymes from the template, suggesting that RNA synthesis is regulated in part at the enzyme level. On the other hand, the chromatin associated RNase activity decreased in both varieties during acclimation, indicating a nonspecific inhibition caused by low temperature rather than a selective genetic response associated with cold acclimation.