Mapping of the influenza virus genome. III. Identification of genes coding for nucleoprotein, membrane protein, and nonstructural protein.

In previous communications we reported that the eight RNA segments of influenza A/PR/8/34 (HON1) virus could be distinguished from corresponding segments of influenza A/Hong Kong/8/68 (H3N2) virus by migration on polyacrylamide-urea gels. Examination of the RNA patterns of the two parent viruses and recombinants derived from them in concert with serological identification of surface proteins and analysis of the other proteins on sodium dodecyl sulfate gradient gels permitted the identification of the genes coding for hemagglutinin, neuraminidase, and the P1, P2, and P3 proteins (Palese and Schulman, 1976; P. Palese et al., Virology, in press). In the present report we have extended these observations using similar techniques to examine other recombinants and have identified the genes coding for the remaining virus-specific moving RNA segment as 1) and segment 6 of Hong Kong virus coding for the respective nucleoproteins, and that segment 7 of both viruses codes for the membtane protein and RNA segment 8 codes for the nonstructural protein. This completes the mapping of the influenza A virus genome.     

RNAs of influenza A, B, and C viruses.

The nucleic acids of influenza A, B, and C viruses were compared. Susceptibility to nucleases demonstrates that influenza C virus, just as influenza A and B viruses, possesses single-stranded RNA as its genome. The base compositions of the RNAs of influenza A, B, and influenza C virus are almost identical and comparative analysis on polyacrylamide gels shows that the genome of influenza C/GL/1167/54 virus, like that of the RNAs of influenza A and B viruses, is segmented. Eight distinct RNA bands were found for influenza A/PR/8/34 virus and for influenza B/Lee/40 virus. The RNA of influenza C/GL/1167/54 virus separated into at least four segments. The total molecular weights of the RNA of influenza A/PR/8/34 and B/Lee/40 virus were calculated to be 5.29 X 10(6) and 6.43 X 10(6), respectively. A minimum value of 4.67 X 10(6) daltons was obtained for influenza C/GL/1167/54 virus RNA. The data suggest that influenza C viruses are true members of the influenza virus group.     

Transfection-mediated recombination of influenza A virus.

Several mechanisms, including a high mutation rate and reassortment of genes, have been found to be responsible for the variability of influenza A viruses. RNA recombination would be another mechanism leading to genetic variation; however, recombination has only rarely been reported to occur in influenza viruses. During ribonucleoprotein transfection experiments designed to generate viable influenza viruses from in vitro-synthesized RNA, we discovered several viruses which must have originated from recombination events. The ribonucleoprotein transfection system may enhance the formation of viruses which result from jumping of the viral polymerase between RNAs or from ligation of different viral RNAs. Five different recombinant viruses are described. Two of these, REC1 and REC2, contain a neuraminidase (NA) gene whose defective polyadenylation signal has been repaired via intergenic recombination; 124 and 95 nucleotides have been added, respectively. Another virus, REC5, must have originated by multiple recombination events since it contains a mosaic gene with sequences derived from the NA gene of influenza A/WSN/33 virus and the matrix, polymerase protein PB1, and NA genes of influenza A/PR/8/34 virus.     

Characterization of virulent and avirulent A/chicken/Pennsylvania/83 influenza A viruses: potential role of defective interfering RNAs in nature.

In April 1983, an influenza virus of low virulence appeared in chickens in Pennsylvania. Subsequently, in October 1983, the virus became virulent and caused high mortality in poultry. The causative agent has been identified as an influenza virus of the H5N2 serotype. The hemagglutinin is antigenically closely related to tern/South Africa/61 (H5N3) and the neuraminidase is similar to that from human H2N2 strains (e.g., A/Japan/305/57) and from some avian influenza virus strains (e.g., A/turkey/Mass/66 [H6N2]). Comparison of the genome RNAs of chicken/Penn with other influenza virus isolates by RNA-RNA hybridization indicated that all of the genes of this virus were closely related to those of various other influenza virus isolates from wild birds. Chickens infected with the virulent strain shed high concentrations of virus in their feces (10(7) 50% egg infective dose per g), and the virus was isolated from the albumin and yolk of eggs layed just before death. Virus was also isolated from house flies in chicken houses. Serological and virological studies showed that humans are not susceptible to infection with the virus, but can serve as short-term mechanical carriers. Analysis of the RNA of the viruses isolated in April and October by gel migration and RNA-RNA hybridization suggested that these strains were very closely related. Oligonucleotide mapping of the individual genes of virulent and avirulent strains showed a limited number of changes in the genome RNAs, but no consistent differences between the virulent and avirulent strains that could be correlated with pathogenicity were found. Polyacrylamide gel analysis of the early (avirulent) isolates demonstrated the presence of low-molecular-weight RNA bands which is indicative of defective-interfering particles. These RNAs were not present in the virulent isolates. Experimental infection of chickens with mixtures of the avirulent and virulent strains demonstrated that the avirulent virus interferes with the pathogenicity of the virulent virus. The results suggest that the original avirulent virus was probably derived from influenza viruses from wild birds and that the virulent strain was derived from the avirulent strain by selective adaptation rather than by recombination or the introduction of a new virus into the population. This adaptation may have involved the loss of defective RNAs, as well as mutations, and thus provides a possible model for a role of defective-interfering particles in nature.     

The sequence of RNA segment 1 of influenza virus A/NT/60/68 and its comparison with the corresponding segment of strains A/PR/8/34 and A/WSN/33.

The complete nucleotide sequence of RNA segment 1 of influenza virus A/NT/60/68, corresponding to the PB2 protein, has been determined. It is 2341 nucleotides long, encoding a predicted product of 759 amino acids with a net charge of +27 1/2 at neutral pH. The predicted amino acid sequence has been compared to the equivalent sequences in influenza viruses A/PR/8/34 and A/WSN/33. Evolutionary divergence, assuming a direct lineage from A/PR/8/34 and allowing for "laboratory drift", is 0.08% per year. The alignment of RNA segment 10 of A/NT/60/68 with segments 1 and 3 is completed, confirming that it is a mosaic of regions from these two segments.     

携带TAP标签的重组甲型流感病毒的构建与鉴定

【目的】将TAP标签构建到WSN病毒基因组上,得到含有TAP标签的重组流感病毒,以便进行后续的病毒追踪。【方法】利用反向遗传学技术,对甲型流感病毒A/WSN/33(H1N1)的PA片段进行改造来插入TAP(tandemaffinitypurification)标签序列。通过病毒拯救得到表达外源标签TAP的重组流感病毒WSNPA-TAP,并对拯救出的重组病毒进行生物学鉴定。【结果】成功拯救出重组流感病毒并命名为WSN PA-TAP。重组病毒基因组测序表明重组病毒的序列正确,利用RNA银染技术观察到重组病毒的全基因组片段。重组流感病毒WSN PA-TAP在MDCK细胞上测定生长曲线,发现该重组病毒的复制能力比野生型WSN弱;Westernblotting检测到PA-TAP融合蛋白的表达,其分子质量为96 kDa。【结论】成功拯救出能够表达外源标签TAP的重组流感病毒WSN PA-TAP,为筛选与甲型流感病毒聚合酶有关的宿主蛋白的研究提供了新思路,同时也为以甲型流感病毒为载体携带外源基因的探索提供了重要依据。     

Role of hemagglutinin cleavage and expression of M1 protein in replication of A/WS/33, A/PR/8/34, and WSN influenza viruses in mouse brain.

The combined presence of WSN gene segments 6 (neuraminidase), 7 (M1 and M2), and 8 (NS1 and NS2) in reassortants of WSN with A/Aichi/2/68 (H3N2) has been found by others to be necessary for full expression of neurovirulence in mice. We are examining the expression of the analogous three gene segments in brains of mice after intracerebral infection with non-neuroadapted strains A/WS/33 (WS) (from which WSN was derived) and A/PR/8/34 (PR8). Our aim is to determine possible mechanisms by which one or more of the five gene products may restrict replication of these strains in mouse brain cells to a single cycle, yielding noninfectious hemagglutinating particles (incomplete growth cycle). We found that minority subsets of such particles did produce plaques, provided they were activated by trypsin (analogous to other abortive systems producing virions with uncleaved HA), a step obviated for some WSN virions by indirect promotion of hemagglutinin cleavage by the neuraminidase of that strain. The percentage of such potentially infectious virions, relative to total hemagglutinating particles, was significantly lower in WS- or PR8-infected than in WSN-infected brains, suggesting possible defects in synthesis or function of M1 protein in the former. Cells in immunostained sections and appropriate bands in Western blots (immunoblots) of viral proteins electrophoretically separated from lysates of PR8-infected brains reacted with antibody to nucleoprotein but not to M1 protein. Either method revealed the presence of both proteins in WSN-infected brains. In contrast, Western blot analyses of particles concentrated from PR8-, WS-, or WSN-infected brains by hemadsorption, elution, and pelleting did reveal NP and M1 bands with comparable relative peroxidase-antiperoxidase staining intensities. The findings suggest that availability of M1 protein is a factor influencing the extent or rate of assembly of potentially infectious (i.e., trypsin-activated) progeny virions in mouse brains and that in this respect the two non-neurovirulent strains differ from WSN quantitatively rather than qualitatively.     

Nucleotide sequences of influenza virus segments 1 and 3 reveal mosaic structure of a small viral RNA segment

Defective interfering RNAs of influenza virus are small segments derived from viral segments 1, 2 and 3. We present here the complete nucleotide sequences of segments 1 and 3 from the human influenza strain A/PR/8/34 and deduce that the sequence of a small RNA segment from A/NT/60/68, apparently a defective interfering RNA, is derived from five separate regions in segment 3 and from one region in segment 1. These regions, which are located near the termini of the two parental segments, are arranged in the small RNA segment in an alternating fashion: thus a region derived from near a 5′ terminus is adjacent to a region derived from near a 3′ terminus. We propose that the small segment is generated during positive strand synthesis as a result of the viral polymerase pausing at uridine-rich sequences in the template and reinitiating synthesis at another site.     

Origin of small RNA in von Magnus particles of influenza virus.

A clone of recombinant virus obtained from the cross between WSN and Hong Kong strains of influenza virus gave rise to progeny containing predominantly von Magnus particles. In the electropherogram of virus RNA, the P3 gene was markedly diminished, and a new species of RNA (extra RNA) was present in addition to eight gene segments. The origin of the extra RNA was studied by two-dimensional gel electrophoresis of T1 RNase-generated oligonucleotides. Four out of five large oligonucleotide spots present in the extra RNA matched to those contained by the P3 gene. It was concluded that the extra RNA was derived from the P3 gene probably by deletion. The possible origin of the spot which was present in the extra RNA but not in eight gene segments including P3 was discussed.     

Nonspecificity of the phenomenon of influenza virus phagocytosis by murine macrophages

Peritoneal macrophage cultures from intact mice and those immune to influenza virus A/PR/8/34 (HON1) were infected with homologous virus or influenza virus A/England/42/72 (H3N2) whereupon virus was isolated from chick embryos. It was established that in intact macrophages, both viruses duplicated similarly. Macrophages immune to virus HON1 equally disintegrated both in homologous virus and heterologous influenza virus H3N2.     

P1 and P3 proteins of influenza virus are required for complementary RNA synthesis.

Members of two temperature-sensitive (ts) mutant groups of influenza A/WSN virus defective in complementary RNA synthesis were analyzed with respect to the identity of their defective genes. RNA analysis of recombinants having a ts+ phenotype derived from the mutants and HK virus permitted the identification of RNA 1 and RNA 2 as the single defective gene in mutant groups I and III, respectively. Based on knowledge obtained by mapping the WSN virus genome, it then was possible to determine that biologically functional P3 protein (coded for by RNA 1) and P1 protein (RNA 2) are required for complementary RNA synthesis of influenza virus.     

M protein (M1) of influenza virus: antigenic analysis and intracellular localization with monoclonal antibodies.

A panel of 16 monoclonal antibodies recognizing M protein (M1) of influenza virus was generated. Competition analyses resulted in localization of 14 monoclonal antibodies to three antigenic sites. Three monoclonal antibodies localized to site 1B recognized a peptide synthesized to M1 (residues 220 to 236) with enzyme-linked immunosorbent assay titers equivalent to or greater than that seen with purified M1; therefore, site 1B is located near the C terminus of M1. Sites 2 and 3 localize to the N-terminal half of M1. Antigenic variation of M proteins was seen when the monoclonal antibodies were tested against 14 strains of type A influenza viruses. Several monoclonal antibodies showed specific recognition of A/PR/8/34 and A/USSR/90/77 M proteins and little or no reactivity for all other strains tested. Immunofluorescence analysis with the monoclonal antibodies showed migration of M protein to the nucleus during the replicative cycle and demonstrated association of M protein with actin filaments in the cytoplasm. Use of a vaccinia virus recombinant containing the M-protein gene demonstrated migration of M protein to the nucleus in the absence of synthesis of gene products from other influenza virus RNA segments.     

A Nine-Segment Influenza A Virus Carrying Subtype H1 and H3 Hemagglutinins

Influenza virus genomic RNAs possess segment-specific packaging signals that include both noncoding regions (NCRs) and adjacent terminal coding region sequences. Using reverse genetics, an A/Puerto Rico/8/34 (A/PR/8/34) virus was rescued that contained a modified PB1 gene such that the PB1 packaging sequences were exchanged for those of the neuraminidase (NA) gene segment. To accomplish this, the PB1 open reading frame, in which the terminal packaging signals were inactivated by serial synonymous mutations, was flanked by the NA segment-specific packaging sequences including the NCRs and the coding region packaging signals. Next, the ATGs located on the 3′ end of the NA packaging sequences of the resulting PB1 chimeric segment were mutated to allow for correct translation of the full-length PB1 protein. The virus containing this chimeric PB1 segment was viable and able to stably carry a ninth, green fluorescent protein (GFP), segment flanked by PB1 packaging signals. Utilizing this method, we successfully generated an influenza virus that contained the genes coding for both the H1 hemagglutinin (HA) from A/PR/8/34 and the H3 HA from A/Hong Kong/1/68 (A/HK/1/68); both subtypes of HA protein were also incorporated into the viral envelope. Immunization of mice with this recombinant virus conferred complete protection from lethal challenge with recombinant A/PR/8/34 virus and with X31 virus that expresses the A/HK/1/68 HA and NA. Using the described methodology, we show that a ninth segment can also be incorporated by manipulation of the PB2 or PA segment-specific packaging signals. This approach offers a means of generating a bivalent influenza virus vaccine.Influenza viruses possess segmented, negative-sense RNA genomes and belong to the family of Orthomyxoviridae. Three types of influenza viruses have been identified: A, B, and C (24). Based on the two surface glycoproteins hemagglutinin (HA) and neuraminidase (NA), type A viruses are further divided into different subtypes; there are now 16 HA subtypes (H1 to H16) and 9 NA subtypes (N1 to N9) of influenza A viruses (24). Current influenza A viruses circulating in humans include the H1N1 and H3N2 subtypes.The genomes of influenza A and B viruses consist of eight RNAs, while C viruses have only seven segments. Influenza virus genomic RNAs associate with nucleoprotein (NP) and three viral polymerase subunits (PB2, PB1, and PA), to form the ribonucleoprotein (RNP) complexes within virions (24). Previous data indicated that each segment of the influenza A/WSN/33 (H1N1) virus possesses segment-specific RNA packaging signals that include both the 3′ and 5′ noncoding regions (NCRs), as well as coding sequences at the two ends of each open reading frame (ORF) (4, 5, 10, 11, 13, 15, 22, 23, 28; and see Fig. 47.23 in reference 24). In addition, an electron microscopy study showed that the wild-type influenza A virus contains exactly eight RNPs within the virions, with seven RNPs surrounding a central one (19). These results suggest that influenza virus genome packaging is a specific process, with each particle containing eight unique RNA segments. Additional evidence supporting a specific packaging theory came from studies of defective interfering (DI) RNAs which contain internal deletions in the coding sequences. These short RNAs can be incorporated into the virus particles despite the fact that they do not encode full-length functional proteins. The finding that incorporation of DI RNAs interferes with the parent full-length RNAs in a segment-specific manner (1, 16, 17) also suggests that influenza virus genome packaging is a specific process.However, there are also data arguing that influenza virus RNA packaging can be nonspecific. First, studies showed that the two different RNA segments of influenza virus can be engineered to share the same set of 3′ and 5′ NCRs, which are important components of the influenza virus RNA packaging signals (18, 31). In addition, under specific circumstances, influenza virus is able to contain nine RNA segments, in which two of them share identical NCRs and partially identical coding region sequences (2, 29). Titrations of the nine-segment virus revealed a linear relationship between dilutions and plaque numbers, suggesting an influenza virus virion can incorporate more than eight segments (2).Herein, we describe a novel approach for the generation of nine-segment influenza viruses based on the manipulation of the segment-specific packaging signals. When the packaging sequences of the PB1 (or PB2 or PA) segment were replaced by those of the NA segment, influenza A/PR/8/34 virus was able to stably incorporate a ninth segment flanked by the PB1 (or PB2 or PA) packaging signals. Using this property, we successfully generated influenza viruses encoding two full-length HA glycoproteins: a subtype H1 A/PR/8/34 HA and a subtype H3 A/HK/1/68 HA. Immunization of mice with the virus carrying two HAs protected them from the lethal challenge with either A/PR/8/34 or X31 virus, the latter of which carries the HA and NA genes of A/HK/1/68. This approach can be used to construct live attenuated influenza vaccine viruses targeting two heterologous strains.     

Selection and identification of influenza virus recombinants of defined genetic composition.

The RNAs of influenza virus recombinants were analyzed on polyacrylamide gels under conditions in which the derivation of specific RNA segments (including those coding for hemagglutinin and neuraminidase) could be determined. Analysis of the RNAs of recombinant viruses with identical hemagglutinin and neuramindase revealed that the derivation of the remaining genes could be influenced by UV irradiation of one of the parent viruses. In five of seven such recombinants all of the remaining identifiable genes were derived from the nonirradiated parent, whereas in two others only the three largest RNA segments were derived from the nonirradiated parent. Analysis of the RNA pattern of a recombinant isolated from mixed infection in which neither parent was irradiated demonstrated a random mixture of RNA segments derived from the two parent viruses.     

流行性感冒病毒重组株京生75-29 R2 T1及冷适应株31-广的基因分析

用聚丙烯酰胺凝胶电泳方法分析了流行性感冒病毒重组株京生75-29R2 T1(H3N2)及冷适应株31-广(H3N2)的RNA及多肽。重组株京生75-29R2 T1的HA及M基因系来自流行病毒亲本株/甲/北京/29/75(H3N2),而P_2、NA、NP及NS基因则来自温度敏感母株福R3(H2N2)。流行病毒株甲/穗/03/68(H3N2)在低温条件下经鸡胚尿囊腔传递24代而获得的冷适应疫苗毒株31-广(H3N2)其基因型与野毒株一致。     

The M segment of the 2009 new pandemic H1N1 influenza virus is critical for its high transmission efficiency in the guinea pig model

A remarkable feature of the 2009 pandemic H1N1 influenza virus is its efficient transmissibility in humans compared to that of precursor strains from the triple-reassortant swine influenza virus lineage, which cause only sporadic infections in humans. The viral components essential for this phenotype have not been fully elucidated. In this study, we aimed to determine the viral factors critical for aerosol transmission of the 2009 pandemic virus. Single or multiple segment reassortments were made between the pandemic A/California/04/09 (H1N1) (Cal/09) virus and another H1N1 strain, A/Puerto Rico/8/34 (H1N1) (PR8). These viruses were then tested in the guinea pig model to understand which segment of Cal/09 virus conferred transmissibility to the poorly transmissible PR8 virus. We confirmed our findings by generating recombinant A/swine/Texas/1998 (H3N2) (sw/Tx/98) virus, a representative triple-reassortant swine virus, containing segments of the Cal/09 virus. The data showed that the M segment of the Cal/09 virus promoted aerosol transmissibility to recombinant viruses with PR8 and sw/Tx/98 virus backgrounds, suggesting that the M segment is a critical factor supporting the transmission of the 2009 pandemic virus.     

Construction and characterization of a bacterial clone containing the hemagglutinin gene of the WSN strain (HON1) of influenza virus

A synthetic dodecadeoxynucleotide primer has been used to prepare a double-stranded DNA form of the hemagglutinin (HA) gene of a human influenza virus (WSN strain, HON1). This DNA has been inserted in plasmid pBR322 and cloned in bacterial cells. The insert contains nearly the complete hemagglutinin gene. A restriction map of this insert has been determined and structurally important areas of the HA gene have been sequenced. Amino acid sequences of several regions of the HA protein were deduced from the DNA sequences and compared to the known amino acid sequences of other influenza A viruses. WSN HA shows extensive homology to all influenza A viruses in a few regions, namely the first 17 amino acids of the N-terminus of HA1 (N-terminal polypeptide of HA) and the first 24 amino acids of the N-terminus of HA2 (C-terminal polypeptide of HA). The sequence diverges extensively from other influenza A viruses in most other areas. The sequence of WSN virus HA is similar to that of other HON1 viruses with the exception of the C-terminus of the HA1 peptide. The change in this area may contribute to some of the unique properties of WSN virus among the HON1 viruses. In addition, WSN HA contains a 17-amino-acid precursor before the N-terminus of HA1 and a single amino acid, arginine, connecting HA1 and HA2.     

Chimeric influenza A viruses with a functional influenza B virus neuraminidase or hemagglutinin

Reassortment of influenza A and B viruses has never been observed in vivo or in vitro. Using reverse genetics techniques, we generated recombinant influenza A/WSN/33 (WSN) viruses carrying the neuraminidase (NA) of influenza B virus. Chimeric viruses expressing the full-length influenza B/Yamagata/16/88 virus NA grew to titers similar to that of wild-type influenza WSN virus. Recombinant viruses in which the cytoplasmic tail or the cytoplasmic tail and the transmembrane domain of the type B NA were replaced with those of the type A NA were impaired in tissue culture. This finding correlates with reduced NA content in virions. We also generated a recombinant influenza A virus expressing a chimeric hemagglutinin (HA) protein in which the ectodomain is derived from type B/Yamagata/16/88 virus HA, whereas both the cytoplasmic and the transmembrane domains are derived from type A/WSN virus HA. This A/B chimeric HA virus did not grow efficiently in MDCK cells. However, after serial passage we obtained a virus population that grew to titers as high as wild-type influenza A virus in MDCK cells. One amino acid change in position 545 (H545Y) was found to be responsible for the enhanced growth characteristics of the passaged virus. Taken together, we show here that the absence of reassortment between influenza viruses belonging to different A and B types is not due to spike glycoprotein incompatibility at the level of the full-length NA or of the HA ectodomain.     

The structure of two subgenomic RNAs from human influenza virus A/PR/8/34.

The nucleotide sequences of two subgenomic RNA segments from influenza virus A/PR/8/34 have been determined by cloning viral cDNA into the vector M13mp7. Sequence analysis was facilitated by a re-cloning strategy which takes advantage of both wild-type and amber derivatives of the M13 vector. The RNA species (444 and 480 nucleotides) contain the 5' and 3' termini of segment 1 and therefore derive by simple internal deletions of this segment. However, these species are not exact copies of the terminal regions of the progenitor segment but contain a few base changes. These differences suggest that after these RNAs have arisen, their sequences can drift, presumably reflecting a lower selective pressure than on the standard RNA segments.