Influenza A Virus PB1-F2 Protein Expression Is Regulated in a Strain-Specific Manner by Sequences Located Downstream of the PB1-F2 Initiation Codon

Translation of influenza A virus PB1-F2 occurs in a second open reading frame (ORF) of the PB1 gene segment. PB1-F2 has been implicated in regulation of polymerase activity, immunopathology, susceptibility to secondary bacterial infection, and induction of apoptosis. Experimental evidence of PB1-F2 molecular function during infection has been collected primarily from human and avian viral isolates. As the 2009 H1N1 (H1N1pdm09) strain highlighted, some swine-derived influenza viruses have the capacity to infect human hosts and emerge as a pandemic. Understanding the impact that virulence factors from swine isolates have on both human and swine health could aid in early identification of viruses with pandemic potential. Studies examining PB1-F2 from swine isolates have focused primarily on H1N1pdm09, which does not encode PB1-F2 but was engineered to carry a full-length PB1-F2 ORF to assess the impact on viral replication and pathogenicity. However, experimental evidence of PB1-F2 protein expression from swine lineage viruses has not been demonstrated. Here, we reveal that during infection, PB1-F2 expression levels are substantially different in swine and human influenza viruses. We provide evidence that PB1-F2 expression is regulated at the translational level, with very low levels of PB1-F2 expression from swine lineage viruses relative to a human isolate PB1-F2. Translational regulation of PB1-F2 expression was partially mapped to two independent regions within the PB1 mRNA, located downstream of the PB1-F2 start site. Our data suggest that carrying a full-length PB1-F2 ORF may not be predictive of PB1-F2 expression in infected cells for all influenza A viruses.     

Virulence Determinants in the PB2 Gene of a Mouse-Adapted H9N2 Virus

The molecular bases of adaptation and pathogenicity of H9N2 influenza virus in mammals are largely unknown. Here, we show that a mouse-adapted PB2 gene with a phenylalanine-to-leucine mutation (F404L) mainly contributes to enhanced polymerase activity, replication, and pathogenicity of H9N2 in mice and also increases the virulence of the H5N1 and 2009 pandemic H1N1 influenza viruses. Therefore, we defined a novel pathogenic determinant, providing further insights into the pathogenesis of influenza viruses in mammals.     

A single mutation in the PB1-F2 of H5N1 (HK/97) and 1918 influenza A viruses contributes to increased virulence

The proapoptotic PB1-F2 protein of influenza A viruses has been shown to contribute to pathogenesis in the mouse model. Expression of full-length PB1-F2 increases the pathogenesis of the influenza A virus, causing weight loss, slower viral clearance, and increased viral titers in the lungs. After comparing viruses from the Hong Kong 1997 H5N1 outbreak, one amino acid change (N66S) was found in the PB1-F2 sequence at position 66 that correlated with pathogenicity. This same amino acid change (N66S) was also found in the PB1-F2 protein of the 1918 pandemic A/Brevig Mission/18 virus. Two isogenic recombinant chimeric viruses were created with an influenza A/WSN/33 virus background containing the PB1 segment from the HK/156/97: WH and WH N66S. In mice infected with WH N66S virus there was increased pathogenicity as measured by weight loss and decreased survival, and a 100-fold increase in virus replication when compared to mice infected with the WH virus. The 1918 pandemic strain A/Brevig Mission/18 was reconstructed with a pathogenicity-reducing mutation in PB1-F2 (S66N). The resultant 1918 S66N virus was attenuated in mice having a 3-log lower 50% lethal dose and caused less morbidity and mortality in mice than the wild-type virus. Viral lung titers were also decreased in 1918 S66N-infected mice compared with wild-type 1918 virus-infected mice. In addition, both viruses with an S at position 66 (WH N66S and wt 1918) induced elevated levels of cytokines in the lungs of infected mice. Together, these data show that a single amino acid substitution in PB1-F2 can result in increased viral pathogenicity and could be one of the factors contributing to the high lethality seen with the 1918 pandemic virus.     

Restored PB1-F2 in the 2009 pandemic H1N1 influenza virus has minimal effects in swine

PB1-F2 is an 87- to 90-amino-acid-long protein expressed by certain influenza A viruses. Previous studies have shown that PB1-F2 contributes to virulence in the mouse model; however, its role in natural hosts-pigs, humans, or birds-remains largely unknown. Outbreaks of domestic pigs infected with the 2009 pandemic H1N1 influenza virus (pH1N1) have been detected worldwide. Unlike previous pandemic strains, pH1N1 viruses do not encode a functional PB1-F2 due to the presence of three stop codons resulting in premature truncation after codon 11. However, pH1N1s have the potential to acquire the full-length form of PB1-F2 through mutation or reassortment. In this study, we assessed whether restoring the full-length PB1-F2 open reading frame (ORF) in the pH1N1 background would have an effect on virus replication and virulence in pigs. Restoring the PB1-F2 ORF resulted in upregulation of viral polymerase activity at early time points in vitro and enhanced virus yields in porcine respiratory explants and in the lungs of infected pigs. There was an increase in the severity of pneumonia in pigs infected with isogenic virus expressing PB1-F2 compared to the wild-type (WT) pH1N1. The extent of microscopic pneumonia correlated with increased pulmonary levels of alpha interferon and interleukin-1β in pigs infected with pH1N1 encoding a functional PB1-F2 but only early in the infection. Together, our results indicate that PB1-F2 in the context of pH1N1 moderately modulates viral replication, lung histopathology, and local cytokine response in pigs.     

Virulence and genetic compatibility of polymerase reassortant viruses derived from the pandemic (H1N1) 2009 influenza virus and circulating influenza A viruses

Gene mutations and reassortment are key mechanisms by which influenza A virus acquires virulence factors. To evaluate the role of the viral polymerase replication machinery in producing virulent pandemic (H1N1) 2009 influenza viruses, we generated various polymerase point mutants (PB2, 627K/701N; PB1, expression of PB1-F2 protein; and PA, 97I) and reassortant viruses with various sources of influenza viruses by reverse genetics. Although the point mutations produced no significant change in pathogenicity, reassortment between the pandemic A/California/04/09 (CA04, H1N1) and current human and animal influenza viruses produced variants possessing a broad spectrum of pathogenicity in the mouse model. Although most polymerase reassortants had attenuated pathogenicity (including those containing seasonal human H3N2 and high-pathogenicity H5N1 virus segments) compared to that of the parental CA04 (H1N1) virus, some recombinants had significantly enhanced virulence. Unexpectedly, one of the five highly virulent reassortants contained a A/Swine/Korea/JNS06/04(H3N2)-like PB2 gene with no known virulence factors; the other four had mammalian-passaged avian-like genes encoding PB2 featuring 627K, PA featuring 97I, or both. Overall, the reassorted polymerase complexes were only moderately compatible for virus rescue, probably because of disrupted molecular interactions involving viral or host proteins. Although we observed close cooperation between PB2 and PB1 from similar virus origins, we found that PA appears to be crucial in maintaining viral gene functions in the context of the CA04 (H1N1) virus. These observations provide helpful insights into the pathogenic potential of reassortant influenza viruses composed of the pandemic (H1N1) 2009 influenza virus and prevailing human or animal influenza viruses that could emerge in the future.     

PB2-588I Enhances 2009 H1N1 Pandemic Influenza Virus Virulence by Increasing Viral Replication and Exacerbating PB2 Inhibition of Beta Interferon Expression

The 2009 pandemic H1N1 influenza virus (pdm/09) is typically mildly virulent in mice. In a previous study, we identified four novel swine isolates of pdm/09 viruses that exhibited high lethality in mice. Comparing the consensus sequences of the PB2 subunit of human isolates of pdm/09 viruses with those of the four swine isolate viruses revealed one consensus mutation: T588I. In this study, we determined that 588T is an amino acid mutation conserved in pdm/09 viruses that was exceedingly rare in previous human influenza isolates. To investigate whether the PB2 with the T5581 mutation (PB2-T558I) has an effect on the increased pathogenicity, we rescued a variant containing PB2-588I (Mex_PB2-588I) in the pdm/09 virus, A/Mexico/4486/2009(H1N1), referred to as Mex_WT (where WT is wild type), and characterized the variant in vitro and in vivo. The results indicated that the mutation significantly enhanced polymerase activity in mammalian cells, and the variant exhibited increased growth properties and induced significant weight loss in a mouse model compared to the wild type. We determined that the mutation exacerbated PB2 inhibition of mitochondrial antiviral signaling protein (MAVS)-mediated beta interferon (IFN-β) expression, and PB2-588I was observed to bind to MAVS more efficiently than PB2-588T. The variant induced lower levels of host IFN-β expression than the WT strain during infection. These findings indicate that the pdm/09 influenza virus has increased pathogenicity upon the acquisition of the PB2-T588I mutation and highlight the need for the continued surveillance of the genetic variation of molecular markers in influenza viruses because of their potential effects on pathogenicity and threats to human health.     

Differential contribution of PB1-F2 to the virulence of highly pathogenic H5N1 influenza A virus in mammalian and avian species

Highly pathogenic avian influenza A viruses (HPAIV) of the H5N1 subtype occasionally transmit from birds to humans and can cause severe systemic infections in both hosts. PB1-F2 is an alternative translation product of the viral PB1 segment that was initially characterized as a pro-apoptotic mitochondrial viral pathogenicity factor. A full-length PB1-F2 has been present in all human influenza pandemic virus isolates of the 20(th) century, but appears to be lost evolutionarily over time as the new virus establishes itself and circulates in the human host. In contrast, the open reading frame (ORF) for PB1-F2 is exceptionally well-conserved in avian influenza virus isolates. Here we perform a comparative study to show for the first time that PB1-F2 is a pathogenicity determinant for HPAIV (A/Viet Nam/1203/2004, VN1203 (H5N1)) in both mammals and birds. In a mammalian host, the rare N66S polymorphism in PB1-F2 that was previously described to be associated with high lethality of the 1918 influenza A virus showed increased replication and virulence of a recombinant VN1203 H5N1 virus, while deletion of the entire PB1-F2 ORF had negligible effects. Interestingly, the N66S substituted virus efficiently invades the CNS and replicates in the brain of Mx+/+ mice. In ducks deletion of PB1-F2 clearly resulted in delayed onset of clinical symptoms and systemic spreading of virus, while variations at position 66 played only a minor role in pathogenesis. These data implicate PB1-F2 as an important pathogenicity factor in ducks independent of sequence variations at position 66. Our data could explain why PB1-F2 is conserved in avian influenza virus isolates and only impacts pathogenicity in mammals when containing certain amino acid motifs such as the rare N66S polymorphism.     

Influenza A virus PB1-F2 protein contributes to viral pathogenesis in mice

The influenza virus PB1-F2 protein is a novel protein previously shown to be involved in induction of cell death. Here we characterize the expression and the function of the protein within the context of influenza viral infection in tissue culture and a mouse model. We show that the C-terminal region of the protein can be expressed from a downstream initiation codon and is capable of interaction with the full-length protein. Using this knowledge, we generated influenza viruses knocked out for the expression of PB1-F2 protein and its downstream truncation products. Knocking out the PB1-F2 protein had no effect on viral replication in tissue culture but diminished virus pathogenicity and mortality in mice. The viruses replicated to similar levels in mouse lungs by day 3 postinfection, suggesting that the knockout did not impair viral replication. However, while the PB1-F2 knockout viruses were cleared after day 5, the wild-type viruses were detectable in mouse lungs until day 7, implying that expression of PB1-F2 resulted in delayed clearance of the viruses by the host immune system. Based on our findings and on the fact that the PB1 genomic segment was always newly introduced into some pandemic influenza viruses of the last century, we speculate that the PB1-F2 protein plays an important role in pathogenesis of influenza virus infection and may be an important contributor to pathogenicity of pandemic influenza viruses.     

Genomic polymorphism of the pandemic A (H1N1) influenza viruses correlates with viral replication, virulence, and pathogenicity in vitro and in vivo

The novel pandemic A (H1N1) virus was first identified in Mexico in April 2009 and quickly spread worldwide. Like all influenzas, the H1N1 strain-specific properties of replication, virulence, and pathogenicity are a result of the particular genomic sequence and concerted expression of multiple genes. Thus, specific mutations may support increased virulence and may be useful as biomarkers of potential threat to human health. We performed comparative genomic analysis of ten strains of the 2009 pandemic A (H1N1) influenza viruses to determine whether genotypes associated with clinical phenotypes, which ranged from mild to severe illness and up to lethal. Virus replication capacity was tested for each strain in vitro using cultured epithelial cells, while virulence and pathogenicity were investigated in vivo using the BALB/c mouse model. The results indicated that A/Sichuan/1/2009 strain had significantly higher replication ability and virulence than the other strains, and five unique non-synonymous mutations were identified in important gene-encoding sequences. These mutations led to amino acid substitutions in HA (L32I), PA (A343T), PB1 (K353R and T566A), and PB2 (T471M), and may be critical molecular determinants for replication, virulence, and pathogenicity. Our results suggested that the replication capacity in vitro and virulence in vivo of the 2009 pandemic A (H1N1) viruses were not associated with the clinical phenotypes. This study offers new insights into the transmission and evolution of the 2009 pandemic A (H1N1) virus.     

Non-Avian Animal Reservoirs Present a Source of Influenza A PB1-F2 Proteins with Novel Virulence-Enhancing Markers

PB1-F2 protein, expressed from an alternative reading frame of most influenza A virus (IAV) PB1 segments, may possess specific residues associated with enhanced inflammation (L62, R75, R79, and L82) and cytotoxicity (I68, L69, and V70). These residues were shown to increase the pathogenicity of primary viral and secondary bacterial infections in a mouse model. In contrast to human seasonal influenza strains, virulence-associated residues are present in PB1-F2 proteins from pandemic H1N1 1918, H2N2 1957, and H3N2 1968, and highly pathogenic H5N1 strains, suggesting their contribution to viruses'' pathogenic phenotypes. Non-human influenza strains may act as donors of virulent PB1-F2 proteins. Previously, avian influenza strains were identified as a potential source of inflammatory, but not cytotoxic, PB1-F2 residues. Here, we analyze the frequency of virulence-associated residues in PB1-F2 sequences from IAVs circulating in mammalian species in close contact with humans: pigs, horses, and dogs. All four inflammatory residues were found in PB1-F2 proteins from these viruses. Among cytotoxic residues, I68 was the most common and was especially prevalent in equine and canine IAVs. Historically, PB1-F2 from equine (about 75%) and canine (about 20%) IAVs were most likely to have combinations of the highest numbers of residues associated with inflammation and cytotoxicity, compared to about 7% of swine IAVs. Our analyses show that, in addition to birds, pigs, horses, and dogs are potentially important sources of pathogenic PB1-F2 variants. There is a need for surveillance of IAVs with genetic markers of virulence that may be emerging from these reservoirs in order to improve pandemic preparedness and response.     

The influenza virus protein PB1-F2 inhibits the induction of type I interferon at the level of the MAVS adaptor protein

PB1-F2 is a 90 amino acid protein that is expressed from the +1 open reading frame in the PB1 gene of some influenza A viruses and has been shown to contribute to viral pathogenicity. Notably, a serine at position 66 (66S) in PB1-F2 is known to increase virulence compared to an isogenic virus with an asparagine (66N) at this position. Recently, we found that an influenza virus expressing PB1-F2 N66S suppresses interferon (IFN)-stimulated genes in mice. To characterize this phenomenon, we employed several in vitro assays. Overexpression of the A/Puerto Rico/8/1934 (PR8) PB1-F2 protein in 293T cells decreased RIG-I mediated activation of an IFN-β reporter and secretion of IFN as determined by bioassay. Of note, the PB1-F2 N66S protein showed enhanced IFN antagonism activity compared to PB1-F2 wildtype. Similar observations were found in the context of viral infection with a PR8 PB1-F2 N66S virus. To understand the relationship between NS1, a previously described influenza virus protein involved in suppression of IFN synthesis, and PB1-F2, we investigated the induction of IFN when NS1 and PB1-F2 were co-expressed in an in vitro transfection system. In this assay we found that PB1-F2 N66S further reduced IFN induction in the presence of NS1. By inducing the IFN-β reporter at different levels in the signaling cascade, we found that PB1-F2 inhibited IFN production at the level of the mitochondrial antiviral signaling protein (MAVS). Furthermore, immunofluorescence studies revealed that PB1-F2 co-localizes with MAVS. In summary, we have characterized the anti-interferon function of PB1-F2 and we suggest that this activity contributes to the enhanced pathogenicity seen with PB1-F2 N66S- expressing influenza viruses.     

广州地区新型H1N1流感病毒PB1-F2基因进化和变异分析

比较和分析2009～2011年广州地区分离到的甲型H1N1流感病毒PB1-F2基因和世界各地甲型H1N1流感病毒PB1-F2基因的变异情况,为该蛋白的功能和作用机制奠定基础。对分离自中国广州地区2009～2011年人类感染的17株新型H1N1和1株季节性H1N1流感病毒进行了PB1-F2基因克隆和序列测定,通过与GenBank数据库中68株人类新型H1N1和季节性H1N1流感病毒参考株的PB1-F2基因进行比对。结果表明,甲型流感病毒的PB1-F2基因进化树形成了2个不同的进化分支。全部2009～2011年新型H1N1流感病毒为一分支。广州地区PB1-F2基因与其它地区分离到的新型H1N1流感病毒具有高度的同源性,均为截短型变异。本实验室分离的1株季节性H1N1流感病毒也发生了第12位氨基酸截短突变。广州地区新型H1N1流感病毒PB1-F2截短蛋白与其它地区病毒相比未发生氨基酸变异,季节性H1N1流感病毒发现类似新型H1N1流感病毒PB1-F2的截短变异,提示新型H1N1流感病毒和季节性H1N1流感病毒PB1-F2可能发生早期重组。     

Influenza A virus protein PB1-F2 from different strains shows distinct structural signatures

The proapoptotic influenza A virus PB1-F2 protein contributes to viral pathogenicity and is present in most human and avian influenza isolates. The structures of full-length PB1-F2 of the influenza strains Pandemic flu 2009 H1N1, 1918 Spanish flu H1N1, Bird flu H5N1 and H1N1 PR8, have been characterized by NMR and CD spectroscopy. The study was conducted using chemically synthesized full-length PB1-F2 protein and fragments thereof. The amino acid residues 30–70 of PR8 PB1-F2 were found to be responsible for amyloid formation of the protein, which could be assigned to formation of β-sheet structures, although α-helices were the only structural features detected under conditions that mimic a membranous environment. At membranous conditions, in which the proteins are found in their most structured state, significant differences become apparent between the PB1-F2 variants investigated. In contrast to Pandemic flu 2009 H1N1 and PR8 PB1-F2, which exhibit a continuous extensive C-terminal α-helix, both Spanish flu H1N1 and Bird flu H5N1 PB1-F2 contain a loop region with residues 66–71 that divides the C-terminus into two shorter helices. The observed structural differences are located to the C-terminal ends of the proteins to which most of the known functions of these proteins have been assigned. A C-terminal helix–loop–helix motif might be a structural signature for PB1-F2 of the highly pathogenic influenza viruses as observed for 1918 Spanish flu H1N1 and Bird flu H5N1 PB1-F2. This signature could indicate the pathological nature of viruses emerging in the future and thus aid in the recognition of these viruses.     

Asparagine Substitution at PB2 Residue 701 Enhances the Replication,Pathogenicity, and Transmission of the 2009 Pandemic H1N1 Influenza A Virus

The 2009/2010 pandemic influenza virus (H1N1pdm) contains an avian-lineage PB2 gene that lacks E627K and D701N substitutions important in the pathogenesis and transmission of avian-origin viruses in humans or other mammals. Previous studies have shown that PB2-627K is not necessary because of a compensatory Q591R substitution. The role that PB2-701N plays in the H1N1pdm phenotype is not well understood. Therefore, PB2-D701N was introduced into an H1N1pdm virus (A/New York/1682/2009 (NY1682)) and analyzed in vitro and in vivo. Mini-genome replication assay, in vitro replication characteristics in cell lines, and analysis in the mouse and ferret models demonstrated that PB2-D701N increased virus replication rates and resulted in more severe pathogenicity in mice and more efficient transmission in ferrets. In addition, compared to the NY1682-WT virus, the NY1682-D701N mutant virus induced less IFN-λ and replicated to a higher titer in primary human alveolar epithelial cells. These findings suggest that the acquisition of the PB2-701N substitution by H1N1pdm viruses may result in more severe disease or increase transmission in humans.     

PB1-F2 Proteins from H5N1 and 20th Century Pandemic Influenza Viruses Cause Immunopathology

With the recent emergence of a novel pandemic strain, there is presently intense interest in understanding the molecular signatures of virulence of influenza viruses. PB1-F2 proteins from epidemiologically important influenza A virus strains were studied to determine their function and contribution to virulence. Using 27-mer peptides derived from the C-terminal sequence of PB1-F2 and chimeric viruses engineered on a common background, we demonstrated that induction of cell death through PB1-F2 is dependent upon BAK/BAX mediated cytochrome c release from mitochondria. This function was specific for the PB1-F2 protein of A/Puerto Rico/8/34 and was not seen using PB1-F2 peptides derived from past pandemic strains. However, PB1-F2 proteins from the three pandemic strains of the 20^th century and a highly pathogenic strain of the H5N1 subtype were shown to enhance the lung inflammatory response resulting in increased pathology. Recently circulating seasonal influenza A strains were not capable of this pro-inflammatory function, having lost the PB1-F2 protein''s immunostimulatory activity through truncation or mutation during adaptation in humans. These data suggest that the PB1-F2 protein contributes to the virulence of pandemic strains when the PB1 gene segment is recently derived from the avian reservoir.     

The Effects of Influenza A Virus PB1-F2 Protein on Polymerase Activity Are Strain Specific and Do Not Impact Pathogenesis

The influenza A virus PB1-F2 protein has been implicated as a virulence factor, but the mechanism by which it enhances pathogenicity is not understood. The PB1 gene segment of the H1N1 swine-origin influenza virus pandemic strain codes for a truncated PB1-F2 protein which terminates after 11 amino acids but could acquire the full-length form by mutation or reassortment. It is therefore important to understand the function and impact of this protein. We systematically assessed the effect that PB1-F2 expression has on viral polymerase activity, accumulation and localization of PB1, and replication in vitro and in mice. We used both the laboratory strain PR8 and a set of viruses engineered to study clinically relevant PB1-F2 proteins. PB1-F2 expression had modest effects on polymerase activity, PB1 accumulation, and replication that were cell type and virus strain dependent. Disruption of the PB1-F2 reading frame in a recent, seasonal H3N2 influenza virus strain did not affect these parameters, suggesting that this is not a universal function of the protein. Disruption of PB1-F2 expression in several backgrounds or expression of PB1-F2 from the 1918 pandemic strain or a 1956 H1N1 strain had no effect on viral lung loads in mice. Alternate mechanisms besides alterations to replication are likely responsible for the enhanced virulence in mammalian hosts attributed to PB1-F2 in previous studies.Seasonal influenza is responsible for significant morbidity and mortality worldwide. In the 1990s, it was estimated to kill 36,000 persons annually in the United States alone and 250,000 to 500,000 persons in the developed world, although hospitalization rates and mortality figures varied considerably from season to season based on the circulating strains (19, 20). Influenza A viruses also have the capability to cause a pandemic if they are sufficiently novel. Strains may emerge whole or in part from animal reservoirs and establish long-term (years to decades) zoonotic lineages in humans (23). The most striking example of this phenomenon occurred in 1918, when an avian virus of the H1N1 subtype crossed the species barrier and established related lineages in two mammalian hosts, swine and humans (16). This pandemic is thought to have killed more than 40 million persons worldwide. In 2009, a novel H1N1 influenza virus of swine origin (H1N1 S-OIV) emerged and is now causing the first pandemic the world has seen in more than 40 years (14). Because of the history of pandemic influenza and the current circulation of a novel pandemic strain, there is intense interest and urgency in understanding viral factors that allow expression of disease in humans.One such virulence factor is the influenza A virus protein PB1-F2 (8). This small (87 to 90 amino acids), 11th gene product was discovered in 2001 in a search for CD8⁺ epitopes in alternative reading frames of influenza A virus genes (2). It is encoded in the +1 reading frame of the PB1 gene segment and is translated from an AUG codon downstream of the PB1 start site, probably accessed through leaky ribosomal scanning. It has been shown to contribute to virulence both directly and indirectly, through modulation of responses to bacteria (3, 11). The exact mechanism(s) through which virulence is increased by PB1-F2 expression, however, is not yet understood. Three effects of PB1-F2 expression have been suggested so far. It has been demonstrated to cause cell death in some cell types (2, 5), it has been shown to induce inflammation by recruitment of inflammatory cells in mice (11), and it has been determined to bind PB1 and to increase the activity of the influenza virus polymerase in vitro (10).The function of the PB1-F2 protein in the life cycle of influenza virus is as unclear as its precise role in virulence. Given that almost all avian influenza virus strains express a full-length PB1-F2 protein (27), it is likely to contribute to survival or transmission in the natural avian host. After introduction of viruses into mammalian hosts such as humans or swine, however, the protein often becomes truncated during adaptation, implying that any effects it might induce are not necessary for virus viability and transmission in these hosts. The 1918 H1N1 virus had a full-length PB1-F2 protein, which has been demonstrated to contribute to virulence in mice (3, 11). During the evolution of H1N1 viruses in humans over time, a stop codon at position 58 in the PB1-F2 amino acid sequence appeared around 1950 and has been retained in the human H1N1 lineage since its reemergence in 1977. Similarly, multiple swine lineages of influenza A virus have had truncations appear at different positions, including position 58, such that 25% of swine PB1-F2 sequences in GenBank lack the C-terminal portion of the protein (27). The H3N2 lineage of viruses in humans has retained a full-length PB1-F2 protein since the introduction of a new PB1 gene segment during the 1968 pandemic, although considerable variation in sequence has occurred during evolution since that time. It is tempting to map these differences in PB1-F2 expression onto patterns of human excess mortality over time, since higher mortality was associated with H1N1 epidemics in the 1930s and 1940s than has been seen since and more excess mortality occurred in recent years with H3N2 viruses than with either H1N1 or influenza B viruses (reviewed in reference 12). Differences in primary virulence or the association with bacteria mediated by PB1-F2 expression could be at least partly responsible for these observed epidemiologic trends.A recent paper from Wise et al. has shown that a 12th influenza A virus gene product, N40, is also expressed from the PB1 gene segment (24). A delicate balance between PB1, PB1-F2, and N40 appears to be in place. Polymerase activity measured by an in vitro assay was affected by changes in this balance, suggesting a potential importance for replication. If these differences translate to differences in replication, then this could be a key factor in virulence in the host. However, to this point, most studies have utilized a single laboratory variant of influenza A virus, A/Puerto Rico/8/34 (H1N1; PR8), in a limited set of cell types, in assays performed in vitro. We undertook this study to determine the relevance of potential changes in replication mediated by PB1-F2 expression, utilizing several different epidemiologically important virus strains. We found that the effects on polymerase activity and in vitro replication efficiency were virus and cell type specific and did not mediate changes in viral lung load in animals.     

NP, PB1, and PB2 viral genes contribute to altered replication of H5N1 avian influenza viruses in chickens

The virulence determinants for highly pathogenic avian influenza viruses (AIVs) are considered multigenic, although the best characterized virulence factor is the hemagglutinin (HA) cleavage site. The capability of influenza viruses to reassort gene segments is one potential way for new viruses to emerge with different virulence characteristics. To evaluate the role of other gene segments in virulence, we used reverse genetics to generate two H5N1 recombinant viruses with differing pathogenicity in chickens. Single-gene reassortants were used to determine which viral genes contribute to the altered virulence. Exchange of the PB1, PB2, and NP genes impacted replication of the reassortant viruses while also affecting the expression of specific host genes. Disruption of the parental virus' functional polymerase complexes by exchanging PB1 or PB2 genes decreased viral replication in tissues and consequently the pathogenicity of the viruses. In contrast, exchanging the NP gene greatly increased viral replication and expanded tissue tropism, thus resulting in decreased mean death times. Infection with the NP reassortant virus also resulted in the upregulation of gamma interferon and inducible nitric oxide synthase gene expression. In addition to the impact of PB1, PB2, and NP on viral replication, the HA, NS, and M genes also contributed to the pathogenesis of the reassortant viruses. While the pathogenesis of AIVs in chickens is clearly dependent on the interaction of multiple gene products, we have shown that single-gene reassortment events are sufficient to alter the virulence of AIVs in chickens.     

Immunopathogenic and antibacterial effects of H3N2 influenza A virus PB1-F2 map to amino acid residues 62, 75, 79, and 82

The influenza A virus protein PB1-F2 has been linked to the pathogenesis of both primary viral and secondary bacterial infections. H3N2 viruses have historically expressed full-length PB1-F2 proteins with either proinflammatory (e.g., from influenza A/Hong Kong/1/1968 virus) or noninflammatory (e.g., from influenza A/Wuhan/359/1995 virus) properties. Using synthetic peptides derived from the active C-terminal portion of the PB1-F2 protein from those two viruses, we mapped the proinflammatory domain to amino acid residues L62, R75, R79, and L82 and then determined the role of that domain in H3N2 influenza virus pathogenicity. PB1-F2-derived peptides containing that proinflammatory motif caused significant morbidity, mortality, and pulmonary inflammation in mice, manifesting as increased acute lung injury and the presence of proinflammatory cytokines and inflammatory cells in the lungs compared to peptides lacking this motif, and better supported bacterial infection with Streptococcus pneumoniae. Infections of mice with an otherwise isogenic virus engineered to contain this proinflammatory sequence in PB1-F2 demonstrated increased morbidity resulting from primary viral infections and enhanced development of secondary bacterial pneumonia. The presence of the PB1-F2 noninflammatory (P62, H75, Q79, and S82) sequence in the wild-type virus mediated an antibacterial effect. These data suggest that loss of the inflammatory PB1-F2 phenotype that supports bacterial superinfection during adaptation of H3N2 viruses to humans, coupled with acquisition of antibacterial activity, contributes to the relatively diminished frequency of severe infections seen with seasonal H3N2 influenza viruses in recent decades compared to their first 2 decades of circulation.     

Enhanced pathogenicity and transmissibility of H9N2 avian influenza virus in mammals by hemagglutinin mutations combined with PB2-627K

H9N2 avian influenza viruses (AIVs) circulate globally in poultry and have become the dominant AIV subtype in China in recent years. Previously, we demonstrated that the H9N2 virus (A/chicken/Eastern China/SDKD1/2015) naturally harbors a mammalian-adaptive molecular factor (627K) in the PB2 protein and is weakly pathogenic in mice. Here, we focused on new markers for virulence in mammals. A mouse-adapted H9N2 virus was serially passaged in mice by infecting their lungs. As expected, infected mice showed clinical symptoms and died at passage six. A comparison between the wild-type and mouse-adapted virus sequences identified amino acid substitutions in the hemagglutinin (HA) protein. H9N2 viruses with the T187P ?+ ?M227L double mutation exhibited an increased affinity to human-type (SAα2,6Gal) receptors and significantly enhanced viral attachment to mouse lung tissues, which contributed to enhancing viral replication and virulence in mice. Additionally, HA with the T187P ?+ ?M227L mutation enabled H9N2 viral transmission in guinea pigs via direct contact. AIV pathogenicity in mice is a polygenic trait. Our results demonstrated that these HA mutations might be combined with PB2-627K to significantly increase H9N2 virulence in mice, and this enhanced virulence was achieved in other H9N2 AIVs by generating the same combination of mutations. In summary, our study identified novel key elements in the HA protein that are required for H9N2 pathogenicity in mice and provided valuable insights into pandemic preparedness against emerging H9N2 strains.