Localisation of the temperature-sensitive defect in the nucleoprotein of an influenza A/FPV/Rostock/34 virus

Influenza viral neuraminidase: the forgotten antigen

Influenza is the most common cause of vaccine-preventable morbidity and mortality despite the availability of the conventional trivalent inactivated vaccine and the live-attenuated influenza vaccine. These vaccines induce an immunity dominated by the response to hemagglutinin (HA) and are most effective when there is sufficient antigenic relatedness between the vaccine strain and the HA of the circulating wild-type virus. Vaccine strategies against influenza may benefit from inclusion of other viral antigens in addition to HA. Epidemiologic evidence and studies in animals and humans indicate that anti-neuraminidase (NA) immunity will provide protection against severe illness or death in the event of a significant antigenic change in the HA component of the vaccine. However, there is little NA immunity induced by trivalent inactivated vaccine and live-attenuated influenza vaccine. The quantity of NA in influenza vaccines is not standardized and varies significantly among manufacturers, production lots and tested strains. The activity and stability of the NA enzyme is influenced by concentration of divalent cations. If immunity against NA is desirable, a better understanding of how the enzymatic properties affect the immunogenicity is needed.

Studies of an influenza A virus temperature-sensitive mutant identify a late role for NP in the formation of infectious virions

The influenza A virus nucleoprotein (NP) is a single-stranded RNA-binding protein that encapsidates the virus genome and has essential functions in viral-RNA synthesis. Here, we report the characterization of a temperature-sensitive (ts) NP mutant (US3) originally generated in fowl plague virus (A/chicken/Rostock/34). Sequence analysis revealed a single mutation, M239L, in NP, consistent with earlier mapping studies assigning the ts lesion to segment 5. Introduction of this mutation into A/PR/8/34 virus by reverse genetics produced a ts phenotype, confirming the identity of the lesion. Despite an approximately 100-fold drop in the viral titer at the nonpermissive temperature, the mutant US3 polypeptide supported wild-type (WT) levels of genome transcription, replication, and protein synthesis, indicating a late-stage defect in function of the NP polypeptide. Nucleocytoplasmic trafficking of the US3 NP was also normal, and the virus actually assembled and released around sixfold more virus particles than the WT virus, with normal viral-RNA content. However, the particle/PFU ratio of these virions was 50-fold higher than that of WT virus, and many particles exhibited an abnormal morphology. Reverse-genetics studies in which A/PR/8/34 segment 7 was swapped with sequences from other strains of virus revealed a profound incompatibility between the M239L mutation and the A/Udorn/72 M1 gene, suggesting that the ts mutation affects M1-NP interactions. Thus, we have identified a late-acting defect in NP that, separate from its function in RNA synthesis, indicates a role for the polypeptide in virion assembly, most likely involving M1 as a partner.

Human influenza a viral genes responsible for the restriction of its replication in duck intestine

Although influenza A viruses are occasionally transmitted from one animal species to another, their host range tends to be restricted. Currently circulating human influenza A viruses are thought to have originated from avian viruses, yet none of these strains replicate in duck intestine, a major site of avian virus replication. Although the hemagglutinin (HA) and neuraminidase (NA) genes are known to restrict human virus replication in ducks, the contribution of the other viral genes remains unknown. To determine the genetic basis for host range restriction of the replication of human influenza A virus in duck intestine, we first established a reverse genetics system for generating A/Memphis/8/88 (H3N2) (Mem/88) and A/mallard/New York/6750/78 (H2N2) (Mal/NY) viruses from cloned cDNAs. Using this system, we then attempted to generate reassortant viruses with various combinations of candidate genes. We were able to generate single-gene reassortants, which possessed PB2, NP, M, or NS from Mem/88, with the remainder from Mal/NY. Despite unsuccessful production of other single-gene reassortants from Mem/88, we did generate reassortant viruses comprised of both the HA and the NA, all three polymerase genes (PB2, PB1, and PA), or all polymerase genes and the NP gene from Mem/88, with the rest derived from Mal/NY. Among these reassortants, only those possessing the M or NS gene from Mem/88 and the remainder from Mal/NY replicated in duck intestine. These results indicate incompatibility between the genes of avian and human influenza A viruses and indicate that all genes other than the M and NS restrict replication of human influenza A virus in duck intestine.

Identification of amino acid residues of influenza virus nucleoprotein essential for RNA binding

The influenza virus nucleoprotein (NP) is a single-strand-RNA-binding protein associated with genome and antigenome RNA and is one of the four virus proteins necessary for transcription and replication of viral RNA. To better characterize the mechanism by which NP binds RNA, we undertook a physical and mutational analysis of the polypeptide, with the strategy of identifying first the regions in direct contact with RNA, then the classes of amino acids involved, and finally the crucial residues by mutagenesis. Chemical fragmentation and amino acid sequencing of NP that had been UV cross linked to radiolabelled RNA showed that protein-RNA contacts occur throughout the length of the polypeptide. Chemical modification experiments implicated arginine but not lysine residues as important for RNA binding, while RNA-dependent changes in the intrinsic fluorescence spectrum of NP suggested the involvement of tryptophan residues. Supporting these observations, single-codon mutagenesis identified five tryptophan, one phenylalanine, and two arginine residues as essential for high-affinity RNA binding at physiological temperature. In addition, mutants unable to bind RNA in vitro were unable to support virus gene expression in vivo. The mutationally sensitive residues are not localized to any particular region of NP but instead are distributed throughout the protein. Overall, these data are inconsistent with previous models suggesting that the NP-RNA interaction is mediated by a discrete N-terminal domain. Instead, we propose that high-affinity binding of RNA by NP requires the concerted interaction of multiple regions of the protein with RNA and that the individual protein-RNA contacts are mediated by a combination of electrostatic interactions between positively charged residues and the phosphate backbone and planar interactions between aromatic side chains and bases.

Temperature-sensitive lesions in two influenza A viruses defective for replicative transcription disrupt RNA binding by the nucleoprotein

The negative-sense segmented RNA genome of influenza virus is transcribed into capped and polyadenylated mRNAs, as well as full-length replicative intermediates (cRNAs). The mechanism that regulates the two forms of transcription remains unclear, although several lines of evidence imply a role for the viral nucleoprotein (NP). In particular, temperature-shift and biochemical analyses of the temperature-sensitive viruses A/WSN/33 ts56 and A/FPV/Rostock/34/Giessen tsG81 containing point mutations within the NP coding region have indicated specific defects in replicative transcription at the nonpermissive temperature. To identify the functional defect, we introduced the relevant mutations into the NP of influenza virus strain A/PR/8/34. Both mutants were temperature sensitive for influenza virus gene expression in transient-transfection experiments but localized and accumulated normally in transfected cells. Similarly, the mutants retained the ability to self-associate and interact with the virus polymerase complex whether synthesized at the permissive or the nonpermissive temperatures. In contrast, the mutant NPs were defective for RNA binding when expressed at the nonpermissive temperature but not when expressed at 30 degrees C. This suggests that the RNA-binding activity of NP is required for replicative transcription.

Mutational analysis of influenza A virus nucleoprotein: identification of mutations that affect RNA replication

The influenza A virus nucleoprotein (NP) is a multifunctional polypeptide which plays a pivotal role in virus replication. To get information on the domains and specific residues involved in the different NP activities, we describe here the preparation and characterization of 20 influenza A virus mutant NPs. The mutations, mostly single-amino-acid substitutions, were introduced in a cDNA copy of the A/Victoria/3/75 NP gene and, in most cases, affected residues located in regions that were highly conserved across the NPs of influenza A, B, and C viruses. The mutant NPs were characterized (i) in vivo (cell culture) by analyzing their intracellular localization and their functionality in replication, transcription, and expression of model RNA templates; and (ii) in vitro by analyzing their RNA-binding and sedimentation properties. The results obtained allowed us to identify both a mutant protein that accumulated in the cytoplasm and mutations that altered the functionality and/or the oligomerization state of the NP polypeptide. Among the mutations that reduced the NP capability to express chloramphenicol acetyltransferase protein from a model viral RNA (vRNA) template, some displayed a temperature-sensitive phenotype. Interestingly, four mutant NPs, which showed a reduced functionality in synthesizing cRNA molecules from a vRNA template, were fully competent to reconstitute complementary ribonucleoproteins (cRNPs) capable of synthesizing vRNAs, which in turn yielded mRNA molecules. Based on the phenotype of these mutants and on previously published observations, it is proposed that these mutant NPs have a reduced capability to interact with the polymerase complex and that this NP-polymerase interaction is responsible for making vRNPs switch from mRNA to cRNA synthesis.

Influenza virus nucleoprotein interacts with influenza virus polymerase proteins

Influenza virus nucleoprotein (NP) is a critical factor in the viral infectious cycle in switching influenza virus RNA synthesis from transcription mode to replication mode. In this study, we investigated the interaction of NP with the viral polymerase protein complex. Using coimmunoprecipitation with monospecific or monoclonal antibodies, we observed that NP interacted with the RNP-free polymerase protein complex in influenza virus-infected cells. In addition, coexpression of the components of the polymerase protein complex (PB1, PB2, or PA) with NP either together or pairwise revealed that NP interacts with PB1 and PB2 but not PA. Interaction of NP with PB1 and PB2 was confirmed by both coimmunoprecipitation and histidine tagging of the NP-PB1 and NP-PB2 complexes. Further, it was observed that NP-PB2 interaction was rather labile and sensitive to dissociation in 0.1% sodium dodecyl sulfate and that the stability of NP-PB2 interaction was regulated by the sequences present at the COOH terminus of NP. Analysis of NP deletion mutants revealed that at least three regions of NP interacted independently with PB2. A detailed analysis of the COOH terminus of NP by mutation of serine-to-alanine (SA) residues either individually or together demonstrated that SA mutations in this region did not affect the binding of NP to PB2. However, some SA mutations at the COOH terminus drastically affected the functional activity of NP in an in vivo transcription-replication assay, whereas others exhibited a temperature-sensitive phenotype and still others had no effect on the transcription and replication of the viral RNA. These results suggest that a direct interaction of NP with polymerase proteins may be involved in regulating the switch of viral RNA synthesis from transcription to replication.

Molecular dissection of influenza virus nucleoprotein: deletion mapping of the RNA binding domain

Influenza virus nucleoprotein (NP) is associated with the genome RNA, forming ribonucleoprotein cores. To identify the amino acid sequence involved in RNA binding, we performed Northwestern blot analysis with a set of N- and C-terminal deletion mutants of NP produced in Escherichia coli. The RNA binding region has been mapped between amino acid residues 91 and 188, a stretch of residues that contains a sequence that is not only highly conserved among NPs from A-, B-, and C-type influenza viruses but also similar to the RNA binding domain of a plant virus movement protein.

Influenza A virus NP protein expressed in insect cells by a recombinant baculovirus is associated with a protein kinase activity and possesses single-stranded RNA binding activity

Influenza A virus NP protein, the phosphoprotein associated with viral RNA in ribonucleoprotein (RNP) complexes, has been expressed at high levels (approximately 100 mg/liter cells) in insect (Sf9) cells by a baculovirus recombinant, and was localized almost entirely in the nuclei of these cells. NP was purified by immuno-affinity chromatography, and purified NP was shown to autophosphorylate and to phosphorylate casein in a cAMP-independent reaction. Furthermore, purified NP was able to bind to ssRNA as demonstrated by a mobility shift of ssRNA in non-denaturing gels. The binding of NP to ssRNA caused a diminution of its kinase activity in proportion to binding.

Evolution of influenza A virus nucleoprotein genes: implications for the origins of H1N1 human and classical swine viruses

A phylogenetic analysis of 52 published and 37 new nucleoprotein (NP) gene sequences addressed the evolution and origin of human and swine influenza A viruses. H1N1 human and classical swine viruses (i.e., those related to Swine/Iowa/15/30) share a single common ancestor, which was estimated to have occurred in 1912 to 1913. From this common ancestor, human and classical swine virus NP genes have evolved at similar rates that are higher than in avian virus NP genes (3.31 to 3.41 versus 1.90 nucleotide changes per year). At the protein level, human virus NPs have evolved twice as fast as classical swine virus NPs (0.66 versus 0.34 amino acid change per year). Despite evidence of frequent interspecies transmission of human and classical swine viruses, our analysis indicates that these viruses have evolved independently since well before the first isolates in the early 1930s. Although our analysis cannot reveal the original host, the ancestor virus was avianlike, showing only five amino acid differences from the root of the avian virus NP lineage. The common pattern of relationship and origin for the NP and other genes of H1N1 human and classical swine viruses suggests that the common ancestor was an avian virus and not a reassortant derived from previous human or swine influenza A viruses. The new avianlike H1N1 swine viruses in Europe may provide a model for the evolution of newly introduced avian viruses into the swine host reservoir. The NPs of these viruses are evolving more rapidly than those of human or classical swine viruses (4.50 nucleotide changes and 0.74 amino acid change per year), and when these rates are applied to pre-1930s human and classical swine virus NPs, the predicted date of a common ancestor is 1918 rather than 1912 to 1913. Thus, our NP phylogeny is consistent with historical records and the proposal that a short time before 1918, a new H1N1 avianlike virus entered human or swine hosts (O. T. Gorman, R. O. Donis, Y. Kawaoka, and R. G. Webster, J. Virol. 64:4893-4902, 1990). This virus provided the ancestors of all known human influenza A virus genes, except for HA, NA, and PB1, which have since been reassorted from avian viruses. We propose that during 1918 a virulent strain of this new avianlike virus caused a severe human influenza pandemic and that the pandemic virus was introduced into North American swine populations, constituting the origin of classical swine virus.

A single nucleotide substitution in the 5'-untranslated region of the vaccinia N2L gene is responsible for both alpha-amanitin-resistant and temperature-sensitive phenotypes

The locus responsible for encoding resistance to alpha-amanitin was previously mapped to the vaccinia virus (VV) HindIII N fragment by using cloned wild-type VV DNA fragments to rescue the ability of an alpha-amanitin-resistant/temperature-sensitive VV mutant (alpha rts7) to replicate under nonpermissive conditions. DNA sequencing and transcriptional analyses of this region identified two leftward-reading open reading frames (ORFs), N2L and M1L, as candidates to encode the protein responsible for eliciting both phenotypes. In the present study, high-resolution marker rescue mapping and genomic sequencing techniques have been applied to identify the nature of the mutation within the HindIII N region of the alpha rts7 genome. Interestingly, a single G to T transversion mutation was noted at position -10 relative to the initiator ATG of the N2L ORF. Since transcription of the N2L gene starts at position -12/-13, this places the alpha rts7 mutation within the 5'-untranslated leader of the N2L transcript expressed early in infection and suggests that the transcriptional efficiency, mRNA stability, or translational efficiency must be altered in the mutant RNA. These results identify the N2L ORF as the gene responsible for conferring resistance to alpha-amanitin in the alpha rts7 mutant and suggest that the N2L gene product is the viral function that interacts with the host cell nucleus during VV infection.

Mutants and revertants of an avian influenza A virus with temperature-sensitive defects in the nucleoprotein and PB2

ts19 is a temperature-sensitive (ts) mutant of the influenza A fowl plague virus with a defect in the nucleoprotein (NP). In ts19-infected chicken embryo cells all viral components are synthesized in normal yields at the nonpermissive temperature, but infectious virus is not formed. Under these conditions the migration of the NP and M of ts19 from the cell nucleus to the cytoplasm is affected. This ts defect is due to a single amino acid replacement (R162K) in a completely conserved region of the NP. Another mutant with a different defect in the NP is ts81. After infection with ts81 at 40 degrees no vRNA is being synthesized. By backcross of a revertant derived from ts81 many isolates with a ts defect in the PB2 protein were obtained. This ts defect seems to extragenically suppress the ts defect in the NP gene and to be dominant in a wild-type background.

Evolution of the nucleoprotein gene of influenza A virus

Nucleotide sequences of 24 nucleoprotein (NP) genes isolated from a wide range of hosts, geographic regions, and influenza A virus serotypes and 18 published NP gene sequences were analyzed to determine evolutionary relationships. The phylogeny of NP genes was determined by a maximum-parsimony analysis of nucleotide sequences. Phylogenetic analysis showed that NP genes have evolved into five host-specific lineages, including (i) Equine/Prague/56 (EQPR56), (ii) recent equine strains, (iii) classic swine (H1N1 swine, e.g., A/Swine/Iowa/15/30) and human strains, (iv) gull H13 viruses, and (v) avian strains (including North American, Australian, and Old World subgroups). These NP lineages match the five RNA hybridization groups identified by W. J. Bean (Virology 133:438-442, 1984). Maximum nucleotide differences among the NPs was 18.5%, but maximum amino acid differences reached only 10.8%, reflecting the conservative nature of the NP protein. Evolutionary rates varied among lineages; the human lineage showed the highest rate (2.54 nucleotide changes per year), followed by the Old World avian lineage (2.17 changes per year) and the recent equine lineage (1.22 changes per year). The per-nucleotide rates of human and avian NP gene evolution (1.62 x 10(-3) to 1.39 x 10(-3) changes per year) are lower than that reported for human NS genes (2.0 x 10(-3) changes per year; D. A. Buonagurio, S. Nakada, J. D. Parvin, M. Krystal, P. Palese, and W. M. Fitch, Science 232:980-982, 1986). Of the five NP lineages, the human lineage showed the greatest evolution at the amino acid level; over a period of 50 years, human NPs have accumulated 39 amino acid changes. In contrast, the avian lineage showed remarkable conservatism; over the same period, avian NP proteins changed by 0 to 10 amino acids. The specificity of the H13 NP in gulls and its distinct evolutionary separation from the classic avian lineage suggests that H13 NPs may have a large degree of adaptation to gulls. The presence of avian and human NPs in some swine isolates demonstrates the susceptibility of swine to different virus strains and supports the hypothesis that swine may serve as intermediates for the introduction of avian influenza virus genes into the human virus gene pool. EQPR56 is relatively distantly related to all other NP lineages, which suggests that this NP is rooted closest to the ancestor of all contemporary NPs. On the basis of estimation of evolutionary rates from nucleotide branch distances, current NP lineages are at least 100 years old, and the EQPR56 NP is much older.(ABSTRACT TRUNCATED AT 400 WORDS)

Immunogenic properties of ISCOM prepared with influenza virus nucleoprotein

After covalent attachment of bacterial lipopolysaccharide to the nucleoprotein of influenza A virus, this water-soluble antigen could be incorporated firmly into ISCOM. This potent "immunostimulating complex" induced the production of high antibody titers in mice and could partially protect the animals from a lethal challenge infection. After immunization with ISCOM preparations NP-specific cytotoxic T cell activity could not be demonstrated.

Two subtypes of nucleoproteins (NP) of influenza A viruses

The nucleoprotein (NP) genes of nine influenza A virus strains isolated from different species have been sequenced and the deduced amino acid sequences have been compared to published NP sequences and sequences in press. Two "subtypes" of NPs can clearly be defined, one "subtype" comprises the NPs found with all tested human and one porcine strain, and another "subtype" comprises the NPs found with all tested avian and equine, and some porcine strains and a mink virus. There are no significant differences between these two groups concerning secondary structure predictions. Pig viruses were the only ones whose NP can belong to the one or the other "subtype." Therefore, pigs can be regarded as "mixing vessels," where the two independently evolving reservoirs of influenza A viruses can meet for the creation of new pandemic strains by reassortment.