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.

Recognition of small interfering RNA by a viral suppressor of RNA silencing

Abstract: RNA silencing (also known as RNA interference) is a conserved biological response to double-stranded RNA that regulates gene expression, and has evolved in plants as a defence against viruses1,2,3 The response is mediated by small interfering RNAs (siRNAs), which guide the sequence-specific degradation of cognate messenger RNAs As a counter-defence, many viruses encode proteins that specifically inhibit the silencing machinery3,4 The p19 protein from the tombusvirus is such a viral suppressor of RNA silencing5 and has been shown to bind specifically to siRNA6 Here, we report the 185-A crystal structure of p19 bound to a 21-nucleotide siRNA, where the 19-base-pair RNA duplex is cradled within the concave face of a continuous eight-stranded β-sheet, formed across the p19 homodimer interface Direct and water-mediated intermolecular contacts are restricted to the backbone phosphates and sugar 2′-OH groups, consistent with sequence-independent p19-siRNA recognition Two α-helical ‘reading heads’ project from opposite ends of the p19 homodimer and position pairs of tryptophans for stacking over the terminal base pairs, thereby measuring and bracketing both ends of the siRNA duplex Our structure provides an illustration of siRNA sequestering by a viral protein

RNA-Directed DNA Synthesis and RNA Tumor Viruses

Abstract: Publisher Summary The discovery of RNA-directed DNA synthesis in disrupted virions of RNA tumor viruses added strong support to the hypothesis that information transfer from RNA to DNA exists in biological system. The chapter discusses the properties of the endogenous reaction carried out by the virion DNA polymerase. To study the endogenous reaction disrupted, virions are incubated with substrates in the absence of any added template and synthesis of DNA is observed using the RNA present in the virions as template. The chapter also discusses the general implications of RNA-directed DNA synthesis in relation to tumor viruses, neoplastic cells, and normal cells. It is hypothesized that the leukovirus RNA-directed DNA polymerase activity is an integral part of the ribonucleoprotein core of the virions. The cores are synthesized in cells as precursor particles and then are incorporated into complete virions when the virions are assembled by budding at the cell surface. This core enzyme system contains not only the template-primer RNA, a DNA polymerase that can transfer information from RNA to double-stranded DNA, but ancillary enzymes, such as polynucleotide ligase and nucleases, which may aid in integrating the viral information with cellular DNA. This suggests that the virion enzyme activity is related to normal cellular DNA polymerases, and that there are homologies between the amino acid sequences of the viral enzyme and normal cellular enzymes. The relationship of RNA-directed DNA synthesis to neoplasia depends upon the relationship of RNA tumor viruses to neoplasia, which is supported by three general hypotheses: the provirus model, the oncogene model, and the protovirus model.

Structure of influenza A polymerase bound to the viral RNA promoter

Abstract: The influenza virus polymerase transcribes or replicates the segmented RNA genome (viral RNA) into viral messenger RNA or full-length copies. To initiate RNA synthesis, the polymerase binds to the conserved 3′ and 5′ extremities of the viral RNA. Here we present the crystal structure of the heterotrimeric bat influenza A polymerase, comprising subunits PA, PB1 and PB2, bound to its viral RNA promoter. PB1 contains a canonical RNA polymerase fold that is stabilized by large interfaces with PA and PB2. The PA endonuclease and the PB2 cap-binding domain, involved in transcription by cap-snatching, form protrusions facing each other across a solvent channel. The 5′ extremity of the promoter folds into a compact hook that is bound in a pocket formed by PB1 and PA close to the polymerase active site. This structure lays the basis for an atomic-level mechanistic understanding of the many functions of influenza polymerase, and opens new opportunities for anti-influenza drug design. The crystal structure of the bat-specific influenza A polymerase in complex with the viral RNA promoter is presented, revealing how binding of the 5′ end of the viral RNA is required to activate or enhance the polymerase allosterically. Stephen Cusack and colleagues have solved the crystal structure of the complete influenza polymerase, comprising subunits PA, PB1 and PB2, bound to its viral RNA promoter. In the first of two papers they present the structure of the polymerase from a bat-specific influenza A virus, which is evolutionarily close to human/avian influenza A strains. The second paper presents the structure of the polymerase from a human isolate of influenza B. Together, the structures provide a wealth of information about how the influenza polymerase functions and how the different subunits interact with each other.