Distinct regions of influenza virus PB1 polymerase subunit recognize vRNA and cRNA templates.

The influenza virus RNA polymerase is a heterotrimer comprising the PB1, PB2 and PA subunits. PB1 is the core of the complex and accounts for the polymerase activity. We have studied the interaction of PB1 with model cRNA template by in vitro binding and Northwestern analyses. The binding to model cRNA was specific and showed an apparent Kd of approximately 7x10(-8) M. In contrast to the interaction with vRNA, PB1 was able to bind equally the 5' and 3' arm of the cRNA panhandle. The N-terminal 139 amino acids of PB1 and sequences between positions 267 and 493 proved positive for binding to cRNA, whereas the interaction with vRNA template previously was mapped to the N- and C-terminal regions. Competition experiments using the 5' and 3' arms of either the vRNA or cRNA panhandle indicated that the N-terminal binding site is shared by both templates. The data indicate that the PB1 RNA-binding sites are constituted by: (i) residues located at the N-terminus (probably common for vRNA and cRNA binding) and, either (ii) residues from the central part of PB1 (for cRNA) or (iii) residues from the C-terminal region of PB1 (for vRNA), and suggest that PB1 undergoes a conformational change upon binding to cRNA versus vRNA templates.     

Solution structure of the influenza A virus cRNA promoter: implications for differential recognition of viral promoter structures by RNA-dependent RNA polymerase

Influenza A virus replication requires the interaction of viral RNA-dependent RNA polymerase (RdRp) with promoters in both the RNA genome (vRNA) and the full-length complementary RNA (cRNA) which serve as templates for the generation of new vRNAs. Although RdRp binds both promoters effectively, it must also discriminate between them because they serve different functional roles in the viral life cycle. Even though the inherent asymmetry between two RNA promoters is considered as a cause of the differential recognition by the RdRp, the structural basis for the ability of the RdRp to recognize the RNA promoters and discriminate effectively between them remains unsolved. Here we report the structure of the cRNA promoter of influenza A virus as determined by heteronuclear magnetic resonance spectroscopy. The terminal region is extremely unstable and does not have a rigid structure. The major groove of the internal loop is widened by the displacement of a novel A*(UU) motif toward the minor groove. These internal loop residues show distinguishable dynamic characters, with differing motional timescales for each residue. Comparison of the cRNA promoter structure with that of the vRNA promoter reveals common structural and dynamic elements in the internal loop, but also differences that provide insight into how the viral RdRp differentially recognizes the cRNA and vRNA promoters.     

Mutational analysis of the influenza virus cRNA promoter and identification of nucleotides critical for replication

Replication of the influenza A virus virion RNA (vRNA) requires the synthesis of full-length cRNA, which in turn is used as a template for the synthesis of more vRNA. A "corkscrew" secondary-structure model of the cRNA promoter has been proposed recently. However the data in support of that model were indirect, since they were derived from measurement, by use of a chloramphenicol acetyltransferase (CAT) reporter in 293T cells, of mRNA levels from a modified cRNA promoter rather than the authentic cRNA promoter found in influenza A viruses. Here we measured steady-state cRNA and vRNA levels from a CAT reporter in 293T cells, directly measuring the replication of the authentic influenza A virus wild-type cRNA promoter. We found that (i) base pairing between the 5' and 3' ends and (ii) base pairing in the stems of both the 5' and 3' hairpin loops of the cRNA promoter were required for in vivo replication. Moreover, nucleotides in the tetraloop at positions 4, 5, and 7 and nucleotides forming the 2-9 base pair of the 3' hairpin loop were crucial for promoter activity in vivo. However, the 3' hairpin loop was not required for polymerase binding in vitro. Overall, our results suggest that the corkscrew secondary-structure model is required for authentic cRNA promoter activity in vivo, although the precise role of the 3' hairpin loop remains unknown.     

Sequence-specific binding of the influenza virus RNA polymerase to sequences located at the 5' ends of the viral RNAs.

The enzymatic activity of recombinant influenza virus RNA polymerase is strictly dependent on the addition of a template RNA containing 5' and 3' viral sequences. Here we report the analysis of the binding specificity and physical characterization of the complex by using gel shift, modification interference, and density gradient techniques. The 13S complex binds specifically to short synthetic RNAs that mimic the partially double stranded panhandle structures found at the termini of both viral RNA and cRNA. The polymerase will also bind independently to the single-stranded 5' or 3' ends of viral RNA. It binds most strongly to specific sequences within the 5' end but is unable to bind these sequences in the context of a completely double stranded structure. Modification interference analysis identified the short sequence motifs at the 5' ends of the viral RNA and cRNA templates that are critical for binding.     

Single-molecule FRET reveals the pre-initiation and initiation conformations of influenza virus promoter RNA

Influenza viruses have a segmented viral RNA (vRNA) genome, which is replicated by the viral RNA-dependent RNA polymerase (RNAP). Replication initiates on the vRNA 3′ terminus, producing a complementary RNA (cRNA) intermediate, which serves as a template for the synthesis of new vRNA. RNAP structures show the 3′ terminus of the vRNA template in a pre-initiation state, bound on the surface of the RNAP rather than in the active site; no information is available on 3′ cRNA binding. Here, we have used single-molecule Förster resonance energy transfer (smFRET) to probe the viral RNA conformations that occur during RNAP binding and initial replication. We show that even in the absence of nucleotides, the RNAP-bound 3′ termini of both vRNA and cRNA exist in two conformations, corresponding to the pre-initiation state and an initiation conformation in which the 3′ terminus of the viral RNA is in the RNAP active site. Nucleotide addition stabilises the 3′ vRNA in the active site and results in unwinding of the duplexed region of the promoter. Our data provide insights into the dynamic motions of RNA that occur during initial influenza replication and has implications for our understanding of the replication mechanisms of similar pathogenic viruses.     

蛋白激酶抑制剂Flavopiridol对流感病毒复制的体外抑制作用

【目的】在细胞水平上研究黄酮类化合物flavopiridol的抗流感病毒效果,初步探索了其抗流感病毒的机制。【方法】首先用Western blot初步检测了在蛋白激酶抑制剂flavopiridol处理下流感病毒NP和M1蛋白的水平,然后通过免疫荧光实验观察了宿主细胞中流感病毒vRNP的合成,又利用噬斑实验检测了flavopiridol对病毒复制的影响,最后通过检测flavopiridol处理的宿主细胞内RNA聚合酶Ⅱ的磷酸化状态和病毒各种RNA的合成量,探究了flavopiridol抑制流感病毒复制的机理。【结果】结果表明,flavopiridol在细胞水平上可以显著抑制流感病毒蛋白质和vRNP的合成及病毒的复制,同时flavopiridol也可以抑制宿主RNA聚合酶Ⅱ大亚基CTD结构域七肽重复序列中的2位丝氨酸的磷酸化来抑制聚合酶的转录延伸活性,显著地减少病毒vRNA的合成。【结论】Flavopiridol可以通过抑制宿主细胞RNA聚合酶Ⅱ的转录延伸活性有效地抑制流感病毒的复制。     

Mutagenic analysis of the 5' arm of the influenza A virus virion RNA promoter defines the sequence requirements for endonuclease activity

Short synthetic influenza virus-like RNAs derived from influenza virus promoter sequences were examined for their ability to stimulate the endonuclease activity of recombinant influenza virus polymerase complexes in vitro, an activity that is required for the cap-snatching activity of primers from host pre-mRNA. An extensive set of point mutants of the 5' arm of the influenza A virus viral RNA (vRNA) was constructed to determine the cis-acting elements which influenced endonuclease activity. Activity was found to be dependent on three features of the conserved vRNA termini: (i) the presence of the 5' hairpin loop structure, (ii) the identity of residues at positions 5 and 10 bases from the 5' terminus, and (iii) the presence of base pair interactions between the 5' and 3' segment ends. Further experiments discounted a role for the vRNA U track in endonuclease activation. This study represents the first mutagenic analysis of the influenza virus promoter with regard to endonuclease activity.     

The packaging signal of influenza viral RNA molecules.

The packaging signal present in influenza viral RNA molecules is shown not to constitute a separate structural element, but to reside within the 5'-bulged promoter structure, as caused by the central unpaired residue A10 in its 5' branch. Upon insertion of two uridine residues in the 3' branch opposite A10, the minus-strand viral RNA (vRNA) promoter is converted into a 3'-bulged structure, whereas the plus-strand cRNA promoter instead adopts the 5'-bulged conformation. In this promoter variant it is exclusively the cRNA that is found packaged in the progeny virions. Upon insertion of only a single uridine nucleotide opposite 5'A10, the two debulged structures of the vRNA and cRNA promoters are rendered identical, and both vRNA and cRNA molecules are packaged indiscriminately, in a 1:1 ratio, but at lower rates. We propose that the binding interactions of viral polymerase with either of the two differently bulged vRNA and cRNA promoter structures result in two different conformations of the enzyme protein. Only the 5' bulged RNA-associated polymerase conformation appears to be recognized for nuclear export, which depends on nuclear matrix protein M1 and nonstructural protein NS2. And the respective wild-type vRNP- or insertion mutant cRNP complex is observed to enter the cytoplasm and hence is included in the viral encapsidation process, which takes place at the plasma membrane.