RNA-dependent RNA polymerase

About: RNA-dependent RNA polymerase is a research topic. Over the lifetime, 13904 publications have been published within this topic receiving 767954 citations. The topic is also known as: RdRp & RNA replicase.

Role of the DIS hairpin in replication of human immunodeficiency virus type 1.

Abstract: The virion-associated genome of human immunodeficiency virus type 1 consists of a noncovalently linked dimer of two identical, unspliced RNA molecules. A hairpin structure within the untranslated leader transcript is postulated to play a role in RNA dimerization through base pairing of the autocomplementary loop sequences. This hairpin motif with the palindromic loop sequence is referred to as the dimer initiation site (DIS), and the type of interaction is termed loop-loop kissing. Detailed phylogenetic analysis of the DIS motifs in different human and simian immunodeficiency viruses revealed conservation of the hairpin structure with a 6-mer palindrome in the loop, despite considerable sequence divergence. This finding supports the loop-loop kissing mechanism. To test this possibility, proviral genomes with mutations in the DIS palindrome were constructed. The appearance of infectious virus upon transfection into SupT1 T cells was delayed for the DIS mutants compared with that obtained by transfection of the wild-type provirus (pLAI), confirming that this RNA motif plays an important role in virus replication. Surprisingly, the RNA genome extracted from mutant virions was found to be fully dimeric and to have a normal thermal stability. These results indicate that the DIS motif is not essential for human immunodeficiency virus type 1 RNA dimerization and suggest that DIS base pairing does not contribute to the stability of the mature RNA dimer. Instead, we measured a reduction in the amount of viral RNA encapsidated in the mutant virions, suggesting a role of the DIS motif in RNA packaging. This result correlates with the idea that the processes of RNA dimerization and packaging are intrinsically linked, and we propose that DIS pairing is a prerequisite for RNA packaging.

Recombination between nonsegmented RNA genomes of murine coronaviruses.

Abstract: We have isolated a recombinant virus between the A59 and JHM strains of mouse hepatitis virus, which contain a single species of nonsegmented RNA genome. This recombinant was derived by mixed infection of DBT cells with temperature-sensitive mutants of A59 and JHM at nonpermissive temperature. Viruses recovered at this temperature were screened by oligonucleotide fingerprinting of their genomic RNAs. One recombinant virus, B1, was found to contain mostly A59-derived sequences, but the 3 kilobases at the 5' end of the genomic RNA was derived from JHM. Thus, the crossover point in the B1 genome is located within gene A, which codes for the viral RNA polymerases. The study of the intracellular RNA species of B1 virus revealed that probably all of the virus-specific subgenomic mRNA species contained the body sequences of strain A59 but the leader sequences of JHM. This result indicates that the JHM leader RNA, which differs from the A59 leader RNA, could be fused to the mRNAs of a different virus strain during RNA transcription. Furthermore, B1 virus-infected cells contain an additional subgenomic mRNA species which is transcribed from a new initiation site within gene C, suggesting that the leader RNA could determine the site of initiation for coronavirus mRNAs. These data represent a first report of RNA recombination between viruses, other than picornaviruses, which contain nonsegmented RNA genomes.

Use of Bacteriophage MS2 as an Internal Control in Viral Reverse Transcription-PCR Assays

Abstract: Diagnostic systems based on reverse transcription (RT)-PCR are widely used for the detection of viral genomes in different human specimens. The application of internal controls (IC) to monitor each step of nucleic acid amplification is necessary to prevent false-negative results due to inhibition or human error. In this study, we designed various real-time RT-PCRs utilizing the coliphage MS2 replicase gene, which differ in detection format, amplicon size, and efficiency of amplification. These noncompetitive IC assays, using TaqMan, hybridization probe, or duplex scorpion probe techniques, were tested on the LightCycler and Rotorgene systems. In our approach, clinical specimens were spiked with the control virus to monitor the efficiency of extraction, reverse transcription, and amplification steps. The MS2 RT-PCR assays were applied for internal control when using a second target hepatitis C virus RNA in duplex PCR in blood donor screening. The 95% detection limit was calculated by probit analysis to 44.9 copies per PCR (range, 38.4 to 73.4). As demonstrated routinely, application of MS2 IC assays exhibits low variability and can be applied in various RT-PCR assays. MS2 phage lysates were obtained under standard laboratory conditions. The quantification of phage and template RNA was performed by plating assays to determine PFU or via real-time RT-PCR. High stability of the MS2 phage preparations stored at −20°C, 4°C, and room temperature was demonstrated.

In vivo interactions of RNA polymerase II with genes of Drosophila melanogaster.

Abstract: We describe a method for examining the in vivo distribution of a protein on specific eucaryotic DNA sequences. In this method, proteins are cross-linked to DNA in intact cells, and the protein-DNA adducts are isolated by immunoprecipitation with antiserum against the protein. Characterization of the DNA cross-linked to the precipitated protein identifies the sequences with which the protein is associated in vivo. Here, we applied these methods to detect RNA polymerase II-DNA interactions in heat-shocked and untreated Drosophila melanogaster Schneider line 2 cells. The level of RNA polymerase II associated with several heat shock genes increased dramatically in response to heat shock, whereas the level associated with the copia genes decreased, indicating that both induction of heat shock gene expression and repression of the copia gene expression by heat shock occur at the transcriptional level. Low levels of RNA polymerase II were present on DNA outside of the transcription units, and for at least two genes, hsp83 and hsp26, RNA polymerase II initiated binding near the transcription start site. Moreover, for hsp70, the density of RNA polymerase II on sequences downstream of the polyadenylate addition site was much lower than that observed on the gene internal sequences. Examination of the amount of specific restriction fragments cross-linked to RNA polymerase II provides a means of detecting RNA polymerase II on individual members of multigene families. This analysis shows that RNA polymerase II is associated with only one of the two cytoplasmic actin genes.

Association of the Influenza A Virus RNA-Dependent RNA Polymerase with Cellular RNA Polymerase II

Abstract: Transcription by the influenza virus RNA-dependent RNA polymerase is dependent on cellular RNA processing activities that are known to be associated with cellular RNA polymerase II (Pol II) transcription, namely, capping and splicing. Therefore, it had been hypothesized that transcription by the viral RNA polymerase and Pol II might be functionally linked. Here, we demonstrate for the first time that the influenza virus RNA polymerase complex interacts with the large subunit of Pol II via its C-terminal domain. The viral polymerase binds hyperphosphorylated forms of Pol II, indicating that it targets actively transcribing Pol II. In addition, immunofluorescence analysis is consistent with a new model showing that influenza virus polymerase accumulates at Pol II transcription sites. The present findings provide a framework for further studies to elucidate the mechanistic principles of transcription by a viral RNA polymerase and have implications for the regulation of Pol II activities in infected cells.