The replication activity of influenza virus polymerase is linked to the capacity of the PA subunit to induce proteolysis

The PA subunit of the influenza virus polymerase complex is a phosphorylated protein that induces a proteolytic process that decreases its own accumulation levels and those of coexpressed proteins. The amino-terminal third of the protein is responsible for the induction of proteolysis. We mutated five potential casein kinase II phosphorylation sites located in the amino-terminal third of the protein. Mutations affecting position 157 almost completely abrogated proteolysis induction, whereas a mutation at position 162 produced a moderate decrease and mutations at positions 151, 200, and 224 did not affect proteolysis induction. Reconstitution of the influenza virus polymerase in vivo with viral model RNA containing the chloramphenicol acetyltransferase (CAT) gene indicated that the CAT activity obtained correlated with the capacity of each PA mutant to induce proteolysis. RNA protection assays of the products obtained with viral polymerase, reconstituted in vivo with model RNAs, indicated that mutations at position 157 led to a selective loss of the ability to synthesize cRNA from the viral RNA template but not to transcribe viral RNA, while a mutation affecting position 162 showed an intermediate phenotype. Collectively, these data provide a link between PA-mediated induction of proteolysis and the replication activity of the polymerase.     

Mutational analysis identifies functional domains in the influenza A virus PB2 polymerase subunit.

A collection of influenza virus PB2 mutant genes was prepared, including N-terminal deletions, C-terminal deletions, and single-amino-acid insertions. These mutant genes, driven by a T7 promoter, were expressed by transfection into COS-1 cells infected with a vaccinia virus encoding T7 RNA polymerase. Mutant proteins accumulated to levels similar to that of wild-type PB2. Immunofluorescence analyses showed that the C-terminal region of the protein is essential for nuclear transport and that internal sequences affect nuclear localization, confirming previous results (J. Mukaijawa and D. P. Nayak, J. Virol. 65:245-253, 1991). The biological activity of these mutants was tested by determining their capacity to (i) reconstitute RNA polymerase activity in vivo by cotransfection with proteins NP, PB1, and PA and a virion-like RNA encoding the cat gene into vaccinia virus T7-infected COS-1 cells and (ii) complete with the wild-type PB2 activity. In addition, when tested at different temperatures in vivo, two mutant PB2 proteins showed a temperature-sensitive phenotype. The lack of interference shown by some N-terminal deletion mutants and the complete interference obtained with a C-terminal deletion mutant encoding only 124 amino acids indicated that this protein domain is responsible for interaction with another component of the polymerase, probably PB1. To further characterize the mutants, their ability to induce in vitro synthesis of viral cRNA or mRNA was tested by using ApG or beta-globin mRNA as a primer. One of the mutants, 1299, containing an isoleucine insertion at position 299, was able to induce cRNA and mRNA synthesis in ApG-primed reactions but required a higher beta-globin mRNA concentration than wild-type PB2 for detection of in vitro synthesis. This result suggested that mutant I299 has diminished cap-binding activity.     

Mutational analyses of the influenza A virus polymerase subunit PA reveal distinct functions related and unrelated to RNA polymerase activity

Influenza A viral polymerase is a heterotrimeric complex that consists of PA, PB1, and PB2 subunits. We previously reported that a di-codon substitution mutation (G507A-R508A), denoted J10, in the C-terminal half of PA had no apparent effect on viral RNA synthesis but prevented infectious virus production, indicating that PA may have a novel role independent of its polymerase activity. To further examine the roles of PA in the viral life cycle, we have now generated and characterized additional mutations in regions flanking the J10 site from residues 497 to 518. All tested di-codon mutations completely abolished or significantly reduced viral infectivity, but they did so through disparate mechanisms. Several showed effects resembling those of J10, in that the mutant polymerase supported normal levels of viral RNA synthesis but nonetheless failed to generate infectious viral particles. Others eliminated polymerase activity, in most cases by perturbing the normal nuclear localization of PA protein in cells. We also engineered single-codon mutations that were predicted to pack near the J10 site in the crystal structure of PA, and found that altering residues K378 or D478 each produced a J10-like phenotype. In further studies of J10 itself, we found that this mutation does not affect the formation and release of virion-like particles per se, but instead impairs the ability of those particles to incorporate each of the eight essential RNA segments (vRNAs) that make up the viral genome. Taken together, our analysis identifies mutations in the C-terminal region of PA that differentially affect at least three distinct activities: protein nuclear localization, viral RNA synthesis, and a trans-acting function that is required for efficient packaging of all eight vRNAs.     

Two nuclear location signals in the influenza virus NS1 nonstructural protein.

The NS1 protein of influenza A virus has been shown to enter and accumulate in the nuclei of virus-infected cells independently of any other influenza viral protein. Therefore, the NS1 protein contains within its polypeptide sequence the information that codes for its nuclear localization. To define the nuclear signal of the NS1 protein, a series of recombinant simian virus 40 vectors that express deletion mutants or fusion proteins was constructed. Analysis of the proteins expressed resulted in identification of two regions of the NS1 protein which affect its cellular location. Nuclear localization signal 1 (NLS1) contains the stretch of basic amino acids Asp-Arg-Leu-Arg-Arg (codons 34 to 38). This sequence is conserved in all NS1 proteins of influenza A viruses, as well as in that of influenza B viruses. NLS2 is defined within the region between amino acids 203 and 237. This domain is present in the NS1 proteins of most influenza A virus strains. NLS1 and NLS2 contain basic amino acids and are similar to previously defined nuclear signal sequences of other proteins.     

Intracellular localization of the viral polymerase proteins in cells infected with influenza virus and cells expressing PB1 protein from cloned cDNA.

The biosynthesis, nuclear transport, and formation of a complex among the influenza polymerase proteins were studied in influenza virus-infected MDBK cells by using monospecific antisera. To obtain these monospecific antisera, portions of cloned cDNAs encoding the individual polymerase proteins (PB1, PB2, or PA) of A/WSN/33 influenza virus were expressed as fusion proteins in Escherichia coli, and the purified fusion proteins were injected into rabbits. Studies using indirect immunofluorescence showed that early in the infectious cycle (4 h postinfection) of influenza virus, PB1 and PB2 are present mainly in the nucleus, whereas PA is predominantly present in the cytoplasm of the virus-infected cells. Later, at 6 to 8 h postinfection, all three polymerase proteins are apparent both in the cytoplasm as well as the nucleus. Radiolabeling and immunoprecipitation analyses showed that the three polymerase proteins remain physically associated as a complex in either the presence or the absence of ribonucleoproteins. In the cytoplasm, the majority of the polymerase proteins remain unassociated, whereas in the nucleus they are present as a complex of three polymerase proteins. To determine whether a polymerase protein is transported into the nucleus individually, PB1 was expressed from the cloned cDNA by using the simian virus 40 late promoter expression vector. PB1 alone, in the absence of the other polymerase proteins or the nucleoprotein, accumulates in the nucleus. This suggests that the formation of a complex with other viral protein(s) is not required for either nuclear transport or nuclear accumulation of PB1 protein and that the PB1 protein may contain an intrinsic signal(s) for nuclear transport.     

Resistance to Virus Infection Conferred by the Interferon-Induced Promyelocytic Leukemia Protein

The interferon (IFN)-induced promyelocytic leukemia (PML) protein is specifically associated with nuclear bodies (NBs) whose functions are yet unknown. Two of the NB-associated proteins, PML and Sp100, are induced by IFN. Here we show that overexpression of PML and not Sp100 induces resistance to infections by vesicular stomatitis virus (VSV) (a rhabdovirus) and influenza A virus (an orthomyxovirus) but not by encephalomyocarditis virus (a picornavirus). Inhibition of viral multiplication was dependent on both the level of PML expression and the multiplicity of infection and reached 100-fold. PML was shown to interfere with VSV mRNA and protein synthesis. Compared to the IFN mediator MxA protein, PML had less powerful antiviral activity. While nuclear body localization of PML did not seem to be required for the antiviral effect, deletion of the PML coiled-coil domain completely abolished it. Taken together, these results suggest that PML can contribute to the antiviral state induced in IFN-treated cells.     

YRKL sequence of influenza virus M1 functions as the L domain motif and interacts with VPS28 and Cdc42

Earlier studies have shown that the C-terminal half of helix 6 (H6) of the influenza A virus matrix protein (M1) containing the YRKL sequence is involved in virus budding (E. K.-W. Hui, S. Barman, T. Y. Yang, and D. P. Nayak, J. Virol. 77:7078-7092, 2003). In this report, we show that the YRKL sequence is the L domain motif of influenza virus. Like other L domains, YRKL can be inserted at different locations on the mutant M1 protein and can restore virus budding in a position-independent manner. Although YRKL is a part of the nuclear localization signal (NLS), the function of YRKL was independent of the NLS activity and the NLS function of M1 was not required for influenza virus replication. Some mutations in YRKL and the adjacent region caused a reduction in the virus titer by blocking virus release, and some affected virus morphology, producing elongated particles. Coimmunoprecipitation and Western blotting analyses showed that VPS28, a component of the ESCRT-I complex, and Cdc42, a member of the Rho family GTP-binding proteins, interacted with the M1 protein via the YRKL motif. In addition, depletion of VPS28 and Cdc42 by small interfering RNA resulted in reduction of influenza virus production. Moreover, overexpression of dominant-negative Cdc42 inhibited influenza virus replication, whereas a constitutively active Cdc42 mutant enhanced virus production in infected cells. These results indicated that VPS28, a component of ESCRT-I, and Cdc42, a small G protein, are associated with the M1 protein and involved in the influenza virus life cycle.     

Influenza A virus NEP (NS2 protein) downregulates RNA synthesis of model template RNAs

The influenza A virus NEP (NS2) protein is an structural component of the viral particle. To investigate whether this protein has an effect on viral RNA synthesis, we examined the expression of an influenza A virus-like chloramphenicol acetyltransferase (CAT) RNA in cells synthesizing the four influenza A virus core proteins (nucleoprotein, PB1, PB2, and PA) and NEP from recombinant plasmids. Influenza A virus NEP inhibited drastically, and in a dose-dependent manner, the level of CAT expression mediated by the recombinant influenza A virus polymerase. This inhibitory effect was not observed in an analogous artificial system in which expression of a synthetic CAT RNA is mediated by the core proteins of an influenza B virus. This result ruled out the possibility that inhibition of reporter gene expression was due to a general toxic effect induced by NEP. Analysis of the virus-specific RNA species that accumulated in cells expressing the type A recombinant core proteins and NEP showed that there was an important reduction in the levels of minireplicon-derived vRNA, cRNA, and mRNA molecules. Taken together, the results obtained suggest a regulatory role for NEP during virus-specific RNA synthesis, and this finding is discussed regarding the biological implications for the virus life cycle.     

Defective assembly of influenza A virus due to a mutation in the polymerase subunit PA

The RNA-dependent RNA polymerase of influenza A virus is composed of three subunits that together synthesize all viral mRNAs and also replicate the viral genomic RNA segments (vRNAs) through intermediates known as cRNAs. Here we describe functional characterization of 16 site-directed mutants of one polymerase subunit, termed PA. In accord with earlier studies, these mutants exhibited diverse, mainly quantitative impairments in expressing one or more classes of viral RNA, with associated infectivity defects of varying severity. One PA mutant, however, targeting residues 507 and 508, caused only modest perturbations of RNA expression yet completely eliminated the formation of plaque-forming virus. Polymerases incorporating this mutant, designated J10, proved capable of synthesizing translationally active mRNAs and of replicating diverse cRNA or vRNA templates at levels compatible with viral infectivity. Both the mutant protein and its RNA products were appropriately localized in the cytoplasm, where influenza virus assembly occurs. Nevertheless, J10 failed to generate infectious particles from cells in a plasmid-based influenza virus assembly assay, and hemagglutinating material from the supernatants of such cells contained little or no nuclease-resistant genomic RNA. These findings suggest that PA has a previously unrecognized role in assembly or release of influenza virus virions, perhaps influencing core structure or the packaging of vRNAs or other essential components into nascent influenza virus particles.     

Nuclear location of all three influenza polymerase proteins and a nuclear signal in polymerase PB2.

In order to re-examine the sub-cellular location of the three influenza A/NT/60/68 polymerase proteins PB1, PB2 and PA in infected cells, specific antisera for each polymerase component have been prepared by immunizing rabbits with polymerase-beta-galactosidase fusion proteins synthesized in Escherichia coli. We show that polymerase PB1, PB2, and PA are predominantly associated with the nucleus of influenza-infected MDCK cells by immunocytochemical techniques. In the case of polymerase PB2 we investigate the possibility that nuclear accumulation is an intrinsic property of the PB2 protein. Using a vaccinia-PB2 recombinant virus, we show that PB2 accumulates intra-nuclearly in monkey CV-1 cells in the absence of any other influenza protein, suggesting it contains an intrinsic nuclear signal.     

The N- and C-terminal domains of the NS1 protein of influenza B virus can independently inhibit IRF-3 and beta interferon promoter activation

The NS1 proteins of influenza A and B viruses (A/NS1 and B/NS1 proteins) have only approximately 20% amino acid sequence identity. Nevertheless, these proteins show several functional similarities, such as their ability to bind to the same RNA targets and to inhibit the activation of protein kinase R in vitro. A critical function of the A/NS1 protein is the inhibition of synthesis of alpha/beta interferon (IFN-alpha/beta) during viral infection. Recently, it was also found that the B/NS1 protein inhibits IFN-alpha/beta synthesis in virus-infected cells. We have now found that the expression of the B/NS1 protein complements the growth of an influenza A virus with A/NS1 deleted. Expression of the full-length B/NS1 protein (281 amino acids), as well as either its N-terminal RNA-binding domain (amino acids 1 to 93) or C-terminal domain (amino acids 94 to 281), in the absence of any other influenza B virus proteins resulted in the inhibition of IRF-3 nuclear translocation and IFN-beta promoter activation. A mutational analysis of the truncated B/NS1(1-93) protein showed that RNA-binding activity correlated with IFN-beta promoter inhibition. In addition, a recombinant influenza B virus with NS1 deleted induces higher levels of IRF-3 activation, as determined by its nuclear translocation, and of IFN-alpha/beta synthesis than wild-type influenza B virus. Our results support the hypothesis that the NS1 protein of influenza B virus plays an important role in antagonizing the IRF-3- and IFN-induced antiviral host responses to virus infection.