The Special Neuraminidase Stalk-Motif Responsible for Increased Virulence and Pathogenesis of H5N1 Influenza A Virus

The variation of highly pathogenic avian influenza H5N1 virus results in gradually increased virulence in poultry, and human cases continue to accumulate. The neuraminidase (NA) stalk region of influenza virus varies considerably and may associate with its virulence. The NA stalk region of all N1 subtype influenza A viruses can be divided into six different stalk-motifs, H5N1/2004-like (NA-wt), WSN-like, H5N1/97-like, PR/8-like, H7N1/99-like and H5N1/96-like. The NA-wt is a special NA stalk-motif which was first observed in H5N1 influenza virus in 2000, with a 20-amino acid deletion in the 49^th to 68^th positions of the stalk region. Here we show that there is a gradual increase of the special NA stalk-motif in H5N1 isolates from 2000 to 2007, and notably, the special stalk-motif is observed in all 173 H5N1 human isolates from 2004 to 2007. The recombinant H5N1 virus with the special stalk-motif possesses the highest virulence and pathogenicity in chicken and mice, while the recombinant viruses with the other stalk-motifs display attenuated phenotype. This indicates that the special stalk-motif has contributed to the high virulence and pathogenicity of H5N1 isolates since 2000. The gradually increasing emergence of the special NA stalk-motif in H5N1 isolates, especially in human isolates, deserves attention by all.     

A 20-Amino-Acid Deletion in the Neuraminidase Stalk and a Five-Amino-Acid Deletion in the NS1 Protein Both Contribute to the Pathogenicity of H5N1 Avian Influenza Viruses in Mallard Ducks

Since 2003, H5N1-subtype avian influenza viruses (AIVs) with both a deletion of 20 amino acids in the stalk of the neuraminidase (NA) glycoprotein (A−) and a deletion of five amino acids at positions 80 to 84 in the non-structural protein NS1 (S−) have become predominant. To understand the influence of these double deletions in the NA and NS1 proteins on the pathogenicity of H5N1-subtype AIVs, we selected A/mallard/Huadong/S/2005 as a parental strain to generate rescued wild-type A−S− and three variants (A−S+ with a five-amino-acid insertion in the NS1 protein, A+S− with a 20-amino-acid insertion in the NA stalk, and A+S+ with insertions in both NA and NS1 proteins) and evaluated their biological characteristics and virulence. The titers of the AIVs with A− and/or S− replicated in DEF cells were higher than that of A+S+, and the A−S− virus exhibited a replication predominance when co-infected with the other variants in DEF cells. In addition, A−S− induced a more significant increase in the expression of immune-related genes in peripheral blood mononuclear cells of mallard ducks in vitro compared with the other variants. Furthermore, an insertion in the NA and/or NS1 proteins of AIVs resulted in a notable decrease in virulence in ducks, as determined by intravenous pathogenicity index, and the two insertions exerted a synergistic effect on the attenuation of pathogenicity in ducks. In addition, compared with A+S+ and A+S−, the A−S+ and A−S− viruses that were introduced via the intranasal inoculation route exhibited a faster replication ability in the lungs of ducks. These data indicate that both the deletions in the NA stalk and the NS1 protein contribute to the high pathogenicity of H5N1 AIVs in ducks.     

Length variations in the NA stalk of an H7N1 influenza virus have opposite effects on viral excretion in chickens and ducks

A deletion of ～20 amino acids in the stalk of neuraminidase is frequently observed upon transmission of influenza A viruses from waterfowl to domestic poultry. A pair of recombinant H7N1 viruses bearing either a short- or long-stalk neuraminidase was genetically engineered. Inoculation of the long-stalk-neuraminidase virus resulted in a higher cloacal excretion in ducks and led conversely to lower-level oropharyngeal excretion in chickens, associated with a higher-level local immune response and better survival. Therefore, a short-stalk neuraminidase is a determinant of viral adaptation and virulence in chickens but is detrimental to virus replication and shedding in ducks.     

Characterization of the Influenza A Virus Gene Pool in Avian Species in Southern China: Was H6N1 a Derivative or a Precursor of H5N1?

In 1997, an H5N1 influenza virus outbreak occurred in chickens in Hong Kong, and the virus was transmitted directly to humans. Because there is limited information about the avian influenza virus reservoir in that region, we genetically characterized virus strains isolated in Hong Kong during the 1997 outbreak. We sequenced the gene segments of a heterogeneous group of viruses of seven different serotypes (H3N8, H4N8, H6N1, H6N9, H11N1, H11N9, and H11N8) isolated from various bird species. The phylogenetic relationships divided these viruses into several subgroups. An H6N1 virus isolated from teal (A/teal/Hong Kong/W312/97 [H6N1]) showed very high (>98%) nucleotide homology to the human influenza virus A/Hong Kong/156/97 (H5N1) in the six internal genes. The N1 neuraminidase sequence showed 97% nucleotide homology to that of the human H5N1 virus, and the N1 protein of both viruses had the same 19-amino-acid deletion in the stalk region. The deduced hemagglutinin amino acid sequence of the H6N1 virus was most similar to that of A/shearwater/Australia/1/72 (H6N5). The H6N1 virus is the first known isolate with seven H5N1-like segments and may have been the donor of the neuraminidase and the internal genes of the H5N1 viruses. The high homology between the internal genes of H9N2, H6N1, and the H5N1 isolates indicates that these subtypes are able to exchange their internal genes and are therefore a potential source of new pathogenic influenza virus strains. Our analysis suggests that surveillance for influenza A viruses should be conducted for wild aquatic birds as well as for poultry, pigs, and humans and that H6 isolates should be further characterized.     

The Surface Glycoproteins of H5 Influenza Viruses Isolated from Humans, Chickens, and Wild Aquatic Birds Have Distinguishable Properties

In 1997, 18 confirmed cases of human influenza arising from multiple independent transmissions of H5N1 viruses from infected chickens were reported from Hong Kong. To identify possible phenotypic changes in the hemagglutinin (HA) and neuraminidase (NA) of the H5 viruses during interspecies transfer, we compared the receptor-binding properties and NA activities of the human and chicken H5N1 isolates from Hong Kong and of H5N3 and H5N1 viruses from wild aquatic birds. All H5N1 viruses, including the human isolate bound to Sia2-3Gal-containing receptors but not to Sia2-6Gal-containing receptors. This finding formally demonstrates for the first time that receptor specificity of avian influenza viruses may not restrict initial avian-to-human transmission. The H5N1 chicken viruses differed from H5 viruses of wild aquatic birds by a 19-amino-acid deletion in the stalk of the NA and the presence of a carbohydrate at the globular head of the HA. We found that a deletion in the NA decreased its ability to release the virus from cells, whereas carbohydrate at the HA head decreased the affinity of the virus for cell receptors. Comparison of amino acid sequences from GenBank of the HAs and NAs from different avian species revealed that additional glycosylation of the HA and a shortened NA stalk are characteristic features of the H5 and H7 chicken viruses. This finding indicates that changes in both HA and NA may be required for the adaptation of influenza viruses from wild aquatic birds to domestic chickens and raises the possibility that chickens may be a possible intermediate host in zoonotic transmission.     

In Silico Structural Homology Modelling and Docking for Assessment of Pandemic Potential of a Novel H7N9 Influenza Virus and Its Ability to Be Neutralized by Existing Anti-Hemagglutinin Antibodies

The unpredictable nature of pandemic influenza and difficulties in early prediction of pandemic potential of new isolates present a major challenge for health planners. Vaccine manufacturers, in particular, are reluctant to commit resources to development of a new vaccine until after a pandemic is declared. We hypothesized that a structural bioinformatics approach utilising homology-based molecular modelling and docking approaches would assist prediction of pandemic potential of new influenza strains alongside more traditional laboratory and sequence-based methods. The newly emerged Chinese A/Hangzhou/1/2013 (H7N9) influenza virus provided a real-life opportunity to test this hypothesis. We used sequence data and a homology-based approach to construct a 3D-structural model of H7-Hangzhou hemagglutinin (HA) protein. This model was then used to perform docking to human and avian sialic acid receptors to assess respective binding affinities. The model was also used to perform docking simulations with known neutralizing antibodies to assess their ability to neutralize the newly emerged virus. The model predicted H7N9 could bind to human sialic acid receptors thereby indicating pandemic potential. The model also confirmed that existing antibodies against the HA head region are unable to neutralise H7N9 whereas antibodies, e.g. Cr9114, targeting the HA stalk region should bind with high affinity to H7N9. This indicates that existing stalk antibodies initially raised against H5N1 or other influenza A viruses could be therapeutically beneficial in prevention and/or treatment of H7N9 infections. The subsequent publication of the H7N9 HA crystal structure confirmed the accuracy of our in-silico structural model. Antibody docking studies performed using the H7N9 HA crystal structure supported the model''s prediction that existing stalk antibodies could cross-neutralise the H7N9 virus. This study demonstrates the value of using in-silico structural modelling approaches to complement physical studies in characterization of new influenza viruses.     

Novel Genotypes of H9N2 Influenza A Viruses Isolated from Poultry in Pakistan Containing NS Genes Similar to Highly Pathogenic H7N3 and H5N1 Viruses

The impact of avian influenza caused by H9N2 viruses in Pakistan is now significantly more severe than in previous years. Since all gene segments contribute towards the virulence of avian influenza virus, it was imperative to investigate the molecular features and genetic relationships of H9N2 viruses prevalent in this region. Analysis of the gene sequences of all eight RNA segments from 12 viruses isolated between 2005 and 2008 was undertaken. The hemagglutinin (HA) sequences of all isolates were closely related to H9N2 viruses isolated from Iran between 2004 and 2007 and contained leucine instead of glutamine at position 226 in the receptor binding pocket, a recognised marker for the recognition of sialic acids linked α2–6 to galactose. The neuraminidase (NA) of two isolates contained a unique five residue deletion in the stalk (from residues 80 to 84), a possible indication of greater adaptation of these viruses to the chicken host. The HA, NA, nucleoprotein (NP), and matrix (M) genes showed close identity with H9N2 viruses isolated during 1999 in Pakistan and clustered in the A/Quail/Hong Kong/G1/97 virus lineage. In contrast, the polymerase genes clustered with H9N2 viruses from India, Iran and Dubai. The NS gene segment showed greater genetic diversity and shared a high level of similarity with NS genes from either H5 or H7 subtypes rather than with established H9N2 Eurasian lineages. These results indicate that during recent years the H9N2 viruses have undergone extensive genetic reassortment which has led to the generation of H9N2 viruses of novel genotypes in the Indian sub-continent. The novel genotypes of H9N2 viruses may play a role in the increased problems observed by H9N2 to poultry and reinforce the continued need to monitor H9N2 infections for their zoonotic potential.     

神经氨酸酶茎部氨基酸缺失对H5N1亚型禽流感病毒生物学特性的影响

近年来H5N1亚型禽流感病毒(AIV)神经氨酸酶(NA)茎部15~20个氨基酸的自发缺失时有报道,突变对于AIV生物学特性的影响还没有得到系统研究。应用反向遗传操作技术,拯救获得5株具有不同NA茎部长度的H5N1/PR8重组AIV。重组病毒的内部基因和血凝素(HA)基因来源相同,NA基因来源不同,并在NA茎部进行20个氨基酸的删除或添加突变。通过研究其生物学特性发现,5株重组病毒在SPF鸡胚中繁殖良好,其EID50、MDT和平均病毒滴度相似;NA茎部长短影响病毒的解凝能力,长茎病毒红细胞解脱能力比短茎病毒强;NA茎部15或20个氨基酸删除突变提高了重组病毒在MDCK细胞上的繁殖能力,短茎病毒释放出的病毒粒子数量是长茎病毒的10~100倍,释放时间提前6~10h,短茎病毒在MDCK细胞上形成的空斑也明显比长茎病毒的空斑大。实验结果揭示了AIV NA茎部氨基酸缺失突变的生物学意义,NA茎部15或20个氨基酸删除突变增强了AIV的细胞适应性,可能与现阶段H5N1亚型AIV宿主范围进一步扩大有关。利用反向遗传技术成功拯救了5株H5N1/PR8重组流感病毒,为流感病毒基因功能研究和重组疫苗研究建立了技术平台。通过对AIV NA茎部氨基酸的删除突变提高了病毒在MDCK细胞上的繁殖产量,为流感病毒细胞苗的生产提供了新的思路。     

Characterization of neuraminidases from the highly pathogenic avian H5N1 and 2009 pandemic H1N1 influenza A viruses

To study the precise role of the neuraminidase (NA), and its stalk region in particular, in the assembly, release, and entry of influenza virus, we deleted the 20-aa stalk segment from 2009 pandemic H1N1 NA (09N1) and inserted this segment, now designated 09s60, into the stalk region of a highly pathogenic avian influenza (HPAI) virus H5N1 NA (AH N1). The biological characterization of these wild-type and mutant NAs was analyzed by pseudotyped particles (pseudoparticles) system. Compared with the wild-type AH N1, the wild-type 09N1 exhibited higher NA activity and released more pseudoparticles. Deletion/insertion of the 09s60 segment did not alter this relationship. The infectivity of pseudoparticles harboring NA in combination with the hemagglutinin from HPAI H5N1 (AH H5) was decreased by insertion of 09s60 into AH N1 and was increased by deletion of 09s60 from 09N1. When isolated from the wild-type 2009H1N1 virus, 09N1 existed in the forms (in order of abundance) dimer>tetramer>monomer, but when isolated from pseudoparticles, 09N1 existed in the forms dimer>monomer>tetramer. After deletion of 09s60, 09N1 existed in the forms monomer>dimer. AH N1 from pseudoparticles existed in the forms monomer>dimer, but after insertion of 09s60, it existed in the forms dimer>monomer. Deletion/insertion of 09s60 did not alter the NA glycosylation pattern of 09N1 or AH N1. The 09N1 was more sensitive than the AH N1 to the NA inhibitor oseltamivir, suggesting that the infectivity-enhancing effect of oseltamivir correlates with robust NA activity.     

A 27-Amino-Acid Deletion in the Neuraminidase Stalk Supports Replication of an Avian H2N2 Influenza A Virus in the Respiratory Tract of Chickens

The events and mechanisms that lead to interspecies transmission of, and host adaptation to, influenza A virus are unknown; however, both surface and internal proteins have been implicated. Our previous report highlighted the role that Japanese quail play as an intermediate host, expanding the host range of a mallard H2N2 virus, A/mallard/Potsdam/178-4/83 (H2N2), through viral adaptation. This quail-adapted virus supported transmission in quail and increased its host range to replicate and be transmitted efficiently in chickens. Here we report that of the six amino acid changes in the quail-adapted virus, a single change in the hemagglutinin (HA) was crucial for transmission in quail, while the changes in the polymerase genes favored replication at lower temperatures than those for the wild-type mallard virus. Reverse genetic analysis indicated that all adaptive mutations were necessary for transmission in chickens, further implicating quail in extending this virus to terrestrial poultry. Adaptation of the quail-adapted virus in chickens resulted in the alteration of viral tropism from intestinal shedding to shedding and transmission via the respiratory tract. Sequence analysis indicated that this chicken-adapted virus maintained all quail-adaptive mutations, as well as an additional change in the HA and, most notably, a 27-amino-acid deletion in the stalk region of neuraminidase (NA), a genotypic marker of influenza virus adaptation to chickens. This stalk deletion was shown to be responsible for the change in virus tropism from the intestine to the respiratory tract.Of the 16 known hemagglutinin (HA) subtypes, only 3 (H1, H2, and H3) have established stable lineages in humans. The H2N2 virus caused a pandemic in 1957 and circulated in the human population until reassortment of the H2N2 virus with an avian H3 virus resulted in the H3N2 pandemic of 1968 (36). Since then, H2N2 viruses have been absent from the human population; however, the H2 subtype has been repeatedly isolated in wild-bird surveillance, and its HA has been found to be antigenically similar to the H2 pandemic virus HA (23, 25, 36). An H2 influenza virus containing human-like receptor specificity was recently isolated as an H2N3 avian-swine reassortant. This virus caused disease and was transmitted in swine and ferrets (24), indicating that this subtype continues to circulate and mutate and can cross the species barrier to mammals. The repeat introduction of a novel H1N1 pandemic this past year (12, 37) highlights the need to understand the mechanisms of introduction, adaptation, and transmission of avian H2N2 influenza viruses in terrestrial birds and potentially mammalian species.Our previous study built on reports that Japanese quail (Coturnix coturnix) play an important role as an intermediate host in the adaptation of avian influenza viruses to land-based birds (38). Japanese quail are typically more susceptible to aquatic influenza viruses than other terrestrial poultry. These viruses establish infection in the respiratory tract, and shedding occurs via aerosol (2, 19, 26, 34, 38, 43). Quail have been implicated in the transmission of avian influenza viruses, such as H5N1 and H9N2 viruses, which have crossed the species barrier to infect humans (9, 14, 15, 22, 28). The susceptibility of quail to multiple subtypes and their role in interspecies transmission led to their removal from live-bird markets in Hong Kong in 2000; however, they continue to be an integral part of live-bird markets throughout the world. Their role as potential intermediate hosts requires further study to identify important molecular markers in the adaptation via quail of avian viruses to other terrestrial poultry, and possibly to humans.The molecular determinants of the host range and pathogenesis of influenza A viruses have been linked to multiple regions of the 11 genes, most notably those encoding the viral surface glycoproteins (HA and neuraminidase [NA]) and the polymerase proteins (PB2, PB1, PA, and NP). However, a comprehensive map of the various determinants remains incomplete, and the molecular mechanisms involved are unclear. In our previous report, we demonstrated that through the use of quail as an intermediate host, a mallard H2N2 influenza virus, A/mallard/Potsdam/178-4/83 (mall/178), which in its wild-type (wt) form was unable to be transmitted in quail or to establish an efficient infection in chickens, was able, in its adapted form (qa-mall/178), not only to be transmitted to sentinel quail but also to replicate to efficient levels in the chicken intestinal tract and to be transmitted to sentinel cagemates via the fecal-oral route. This adaptation was the result of six serial passages of lung homogenates in quail that led to six amino acid changes in four genes (38). Here we present data confirming the role that Japanese quail play in the transmission of this mall/178 H2N2 virus in land-based birds. Reverse genetics studies confirmed that the amino acid changes produced during the adaptation in quail were necessary for the infection of chickens with this virus and for its transmission in chickens. Further adaptation of the qa-mall/178 H2N2 virus in chickens, aimed at establishing replication in the respiratory tract, resulted in a deletion in the stalk region of the NA, which supported replication in the chicken trachea and lung. This 27-amino-acid deletion in the stalk region of the N2 NA is characteristic of the adaptation of aquatic influenza viruses to domestic poultry, particularly chickens (3, 5, 29). Our work indicates that through the use of quail as an intermediate host, this mallard H2N2 virus is able to further adapt within an additional terrestrial poultry species, potentially improving its chances of expanding its host range further.     

A Genetically Engineered Waterfowl Influenza Virus with a Deletion in the Stalk of the Neuraminidase Has Increased Virulence for Chickens

A deletion of about 20 amino acids in the stalk of the neuraminidase (NA) is frequently detected upon transmission of influenza A viruses from waterfowl to domestic poultry. Using reverse genetics, a recombinant virus derived from a wild duck influenza virus isolate, A/Mallard/Marquenterre/Z237/83 (MZ), and an NA stalk deletion variant (MZ-delNA) were produced. Compared to the wild type, the MZ-delNA virus showed a moderate growth advantage on avian cultured cells. In 4-week-old chickens inoculated intratracheally with the MZ-delNA virus, viral replication in the lungs, liver, and kidneys was enhanced and interstitial pneumonia lesions were more severe than with the wild-type virus. The MZ-delNA-inoculated chickens showed significantly increased levels of mRNAs encoding interleukin-6 (IL-6), transforming growth factor-β4 (TGF-β4), and CCL5 in the lungs and a higher frequency of apoptotic cells in the liver than did their MZ-inoculated counterparts. Molecular mechanisms possibly underlying the growth advantage of the MZ-delNA virus were explored. The measured enzymatic activities toward a small substrate were similar for the wild-type and deleted NA, but the MZ-delNA virus eluted from chicken erythrocytes at reduced rates. Pseudoviral particles expressing the MZ hemagglutinin in combination with the MZ-NA or MZ-delNA protein were produced from avian cultured cells with similar efficiencies, suggesting that the deletion in the NA stalk does not enhance the release of progeny virions and probably affects an earlier step of the viral cycle. Overall, our data indicate that a shortened NA stalk is a strong determinant of adaptation and virulence of waterfowl influenza viruses in chickens.In the waterfowl reservoir, influenza A viruses are enzootic and infections are usually asymptomatic. The viruses replicate preferentially in the intestinal tract and are transmitted by the fecal-oral route. Phylogenetic analyses of amino acid changes show that influenza viruses in wild aquatic birds have low evolution rates, suggesting that they are in evolutionary stasis. Upon transmission to domestic poultry, rapid evolution occurs (63, 79). The replication of influenza viruses of duck origin in chickens is generally limited to the respiratory and gastrointestinal tracts and causes mild or no symptoms. However, sustained replication of viruses of the H5 or H7 subtype may lead to the emergence of highly pathogenic influenza viruses, which cause devastating epizootics (for a review, see reference 5). Mutations acquired upon replication in domestic poultry might also increase the potential for adaptation of avian influenza viruses to other species, including humans (20, 21, 50), which raises public health concerns.The viral surface glycoproteins hemagglutinin (HA) and neuraminidase (NA) are major determinants in the interspecies transmission and adaptation of influenza A viruses to a new host (for a review, see reference 46). The HA binds to the sialic acids (SA) linked to cellular membrane glycoproteins or glycolipids, whereas the sialidase activity of the NA facilitates the release and diffusion of progeny virions. SA are usually attached to a galactose moiety via an α2,3 or α2,6 glycosidic linkage. Avian viruses bind preferentially to SA-α2,3-galactose, whereas human viruses bind preferentially to SA-α2,6-galactose (13, 37, 56). This receptor binding specificity correlates with the relative predominance of SA-α2,3-galactose and SA-α2,6-galactose at the sites of viral multiplication in ducks and in humans, respectively (14, 28), and involves specific residues in the receptor binding site of the HA (37, 70). Viruses isolated from terrestrial poultry bind preferentially to SA-α2,3-galactose, but they differ from duck viruses by an enhanced binding to receptors in which the penultimate saccharide is sulfated and/or fucosylated (22, 23). Changes in the receptor binding site or at potential glycosylation sites of the HA that could modulate the binding of the HA to the receptors have been associated with the adaptation of duck viruses to poultry (3, 21, 36). A deletion of about 20 amino acids in the stalk region of the NA has also been frequently detected concomitant with the adaptation of duck viruses to poultry (3, 4, 25, 36, 62). In particular, it is a feature of the highly pathogenic H5N1 viruses that have become endemic in poultry in southern Asia since 2003 and have been causing sporadic human cases (26). The stalk is a flexible region which separates the globular, enzymatically active head of the tetrameric NA from the hydrophobic transmembrane domain (Fig. ​(Fig.1A).1A). The biological significance of the selection of variants with a shorter NA stalk is still unclear. Shortening of the stalk was found to decrease the ability of the NA to release the virus from cells (2, 6, 17, 25, 36, 39), and it was suggested that such a decreased activity of the NA could counterbalance a reduced binding of the HA to sialic acids expressed in poultry (2, 40, 71). The NA stalk length was found to have little effect on the efficiency of replication of a highly pathogenic H5N1 virus in poultry (39). However, it is possible that the presence of a multibasic site on the H5, a strong determinant of virulence, might be masking the effect, if any, of a shortened NA stalk.Open in a separate windowFIG. 1.Wild-type and deleted variants of the MZ-NA protein. (A) Schematic representation of the wild-type MZ-NA protein (470 amino acids [aa]). The domain corresponding to the stalk (amino acids 36 to 90) is represented in gray. The region of the stalk which is deleted in the MZ-delNA variant (amino acids 54 to 72) is represented by a hatched box. TM, transmembrane domain. (B) Amino acid sequence alignment of the NAs from MZ (H1N1), MZ-delNA (H1N1), A/Goose/Guandong/1/96 (H5N1), and A/Hong Kong/156/97 (H5N1) viruses. The domain corresponding to the stalk is highlighted in gray. The residues that are deleted in the NAs of MZ-delNA and A/Hong Kong/156/97 are represented by dashes.In the present study, we used a low-pathogenic duck influenza A(H1N1) virus isolate to investigate possible mechanisms involved in the selection of influenza viruses with a deletion in the stalk of the NA upon transmission from the waterfowl reservoir to chickens. Reverse genetics was used to produce a wild-type (wt) virus and a variant with a 19-amino-acid deletion in the stalk of the NA. The rationale for using an H1N1 virus was that a slight increase in viral fitness of the deleted variant, if any, would be more readily detected if the wild-type virus showed a low replication potential in chickens. In vitro and in vivo approaches were developed to examine the effect of the deletion in the stalk of the NA on the biological properties of the enzyme, on viral infectivity in avian cultured cells, and on viral infectivity and pathogenicity in chickens.     

Biologic importance of neuraminidase stalk length in influenza A virus.

To investigate the biologic importance of the neuraminidase (NA) stalk of influenza A virus, we generated mutant viruses of A/WSN/33 (H1N1) with stalks of various lengths (0 to 52 amino acids), by using the recently developed reverse genetics system. These mutant viruses, including one that lacked the entire stalk, replicated in tissue culture to the level of the parent virus, whose NA stalk contains 24 amino acid residues. In eggs, however, the length of the stalk was correlated with the efficiency of virus replication: the longer the stalk, the better the replication. This finding indicates that the length of the NA stalk affects the host range of influenza A viruses. The NA stalkless mutant was highly attenuated in mice; none of the animals died even after intranasal inoculation of 10(6) PFU of the virus (the dose of the parent virus required to kill 50% of mice was 10(2.5) PFU). Moreover, the stalkless mutant replicated only in the respiratory organs, whereas the parent virus caused systemic infection in mice. Thus, attenuation of the virus with the deletion of the entire NA stalk raises the possibility of its use as live vaccines.     

Reassortment between Avian H5N1 and Human Influenza Viruses Is Mainly Restricted to the Matrix and Neuraminidase Gene Segments

Highly pathogenic avian influenza H5N1 viruses have devastated the poultry industry in many countries of the eastern hemisphere. Occasionally H5N1 viruses cross the species barrier and infect humans, sometimes with a severe clinical outcome. When this happens, there is a chance of reassortment between H5N1 and human influenza viruses. To assess the potential of H5N1 viruses to reassort with contemporary human influenza viruses (H1N1, H3N2 and pandemic H1N1), we used an in vitro selection method to generate reassortant viruses, that contained the H5 hemagglutinin gene, and that have a replication advantage in vitro. We found that the neuraminidase and matrix gene segments of human influenza viruses were preferentially selected by H5 viruses. However, these H5 reassortant viruses did not show a marked increase in replication in MDCK cells and human bronchial epithelial cells. In ferrets, inoculation with a mixture of H5N1-pandemic H1N1 reassortant viruses resulted in outgrowth of reassortant H5 viruses that had incorporated the neuraminidase and matrix gene segment of pandemic 2009 H1N1. This virus was not transmitted via aerosols or respiratory droplets to naïve recipient ferrets. Altogether, these data emphasize the potential of avian H5N1 viruses to reassort with contemporary human influenza viruses. The neuraminidase and matrix gene segments of human influenza viruses showed the highest genetic compatibility with HPAI H5N1 virus.     

Geographical Spread of Highly Pathogenic Avian Influenza Virus H5N1 during the 2006 Outbreak in Austria

In spring 2006, highly pathogenic avian influenza virus (HPAIV) of subtype H5N1 was detected in Austria in 119 dead wild birds. The hemagglutinin cleavage site showed that the amino acid sequence motif was identical to that of the Qinghai lineage. For detailed analysis, the hemagglutinin (HA) and neuraminidase (NA) genes of 27 selected Austrian H5N1 viruses originating from different regions and wild bird species were analyzed phylogenetically, which revealed two clearly separated Austrian subclusters, both belonging to European cluster EMA-1. Subcluster South (SCS) contains virus isolates from the south of Austria as well as from Slovenia, Turkey, Egypt, and Nigeria. The second subcluster, Northwest (SCN), covered a larger group of viruses originating from different locations and wild bird species in the northern and very western parts of Austria, as well as from Bavaria and Switzerland. Surprisingly, virus isolates originating from two mute swans and one wild duck found on the north side of the Alps did not cluster with SCN but with SCS. Together with isolates from Bavarian, the Czech Republic, Italy, and Slovakia, they form a genuine subgroup, named subgroup Bavaria (SGB). This subgroup forms a link to SCN, indicating a spread of the virus from south to north. There has been a general assumption that the generic HPAI introduction route into Europe was from Russia to north Germany, introducing cluster EMA-2 into Europe. Interestingly, our findings support the assumption of an alternative introduction of the HPAI H5N1 virus from Turkey to central Europe, where it spread as cluster EMA-1 during the outbreak of 2006.Highly pathogenic H5N1 viruses have been recognized in Asia since 1996, when the first Asian H5N1 virus (A/Goose/Guandgdong/1/96) was isolated from sick geese in southern China (25). Since then, this virus has caused endemic infections in poultry in many southeast Asian countries (13, 18). Although influenza viruses in wild aquatic birds occasionally are transmitted to chickens and turkeys, where they may produce outbreaks of severe disease, they do not appear to have entered the wild bird populations to a substantial extent until late April to June 2005, when a large outbreak of H5N1 infection occurred at Qinghai Lake in western China, a major breeding site of migratory birds (2). Subsequently to the outbreak at Qinghai Lake from April to June 2005, H5N1 viruses have continued to cause outbreaks in Asia and Europe (http://www.who.int).A major molecular determinant for the pathogenicity of H5 and H7 viruses is the amino acid sequence specifying the proteolytic cleavage site of hemagglutinin (HA). In lowly pathogenic avian influenza virus (LPAIV), single basic residues at the cleavage site restrict the proteolytic activation of HA to the respiratory and intestinal tracts. In contrast, insertional mutations at the genomic locus encoding the endoproteolytic cleavage site resulting in the presence of a polybasic site render it accessible for ubiquitous protease, resulting in severe, systemic infections (17). All analyzed viruses originating from Qinghai Lake showed the series of basic amino acids at the HA cleavage site PQGERRRKKRGLF, which is characteristic of high pathogenicity in chickens. They also exhibited a 20-amino-acid deletion of the neuraminidase (NA) stalk (residues 49 to 68) that is characteristic of the NA of the A/Goose/Guandgdong/1/96 virus (2).Salzberg et al. analyzed 36 isolates of highly pathogenic avian influenza (HPAI) H5N1 viruses collected from Europe, northern Africa, the Middle East, and Asia and described the genetic relationships among these isolates, which affect birds and humans (16). He grouped the isolates into three distinct lineages, one encompassing all known non-Asian isolates, and hypothesized that this Europe-African lineage has been introduced into the European-African region at least three times and has split into three distinct, independently evolving sublineages: EMA-1, EMA-2, and EMA-3. These three clades possibly represent either separate introductions or a single introduction from Asia via Russia into Europe or any other western site, which then has subsequently evolved into three sublineages, EMA-1, EMA-2, and EMA-3 (16). EMA-2 contains the first German H5N1-positive swan found at the beginning of February 2006 on the Baltic island Ruegen (A/Cygnus cygnus/Germany/R65/06). This suggests a single introduction route for this cluster, because a phylogenetic analysis of the HA and the NA nucleotide sequences revealed that the closest genetic relative was an isolate from Astrakhan (A/Cygnus olor/Astrakhan/Ast05-2-3/2005). From Astrakhan, located in southern Russia, a westward movement of wild birds to central Europe in late January/early February 2006 is suggested (24).The aim of this study was to perform a phylogenetic analysis of Austrian HPAI H5N1 isolates from the outbreak of 2006 to determine their linkage to the European clusters EMA-1, EMA-2, and EMA-3 and to identify possible implications for H5N1 introduction routes into Austria.     

The Short Stalk Length of Highly Pathogenic Avian Influenza H5N1 Virus Neuraminidase Limits Transmission of Pandemic H1N1 Virus in Ferrets

H5N1 influenza viruses pose a pandemic threat but have not acquired the ability to support sustained transmission between mammals in nature. The restrictions to transmissibility of avian influenza viruses in mammals are multigenic, and overcoming them requires adaptations in hemagglutinin (HA) and PB2 genes. Here we propose that a further restriction to mammalian transmission of the majority of highly pathogenic avian influenza (HPAI) H5N1 viruses may be the short stalk length of the neuraminidase (NA) protein. This genetic feature is selected for when influenza viruses adapt to chickens. In our study, a recombinant virus with seven gene segments from a human isolate of the 2009 H1N1 pandemic combined with the NA gene from a typical chicken-adapted H5N1 virus with a short stalk did not support transmission by respiratory droplet between ferrets. This virus was also compromised in multicycle replication in cultures of human airway epithelial cells at 32°C. These defects correlated with a reduction in the ability of virus with a short-stalk NA to penetrate mucus and deaggregate virions. The deficiency in transmission and in cleavage of tethered substrates was overcome by increasing the stalk length of the NA protein. These observations suggest that H5N1 viruses that acquire a long-stalk NA through reassortment might be more likely to support transmission between humans. Phylogenetic analysis showed that reassortment with long-stalk NA occurred sporadically and as recently as 2011. However, all identified H5N1 viruses with a long-stalk NA lacked other mammalian adapting features and were thus several genetic steps away from becoming transmissible between humans.     

Design of fluorinated sialic acid analog inhibitor to H5 hemagglutinin of H5N1 influenza virus through molecular dynamics simulation study

Abstract

Influenza epidemics and pandemics are caused by influenza A virus. The cell surface protein of hemagglutinin and neuraminidase is responsible for viral infection and release of progeny virus on the host cell membrane. Now 18 hemagglutinin and 11 neuraminidase subtypes are identified. The avian influenza virus of H5N1 is an emergent threat to public health issues. To control the influenza viral infection it is necessary to develop antiviral inhibitors and vaccination. In the present investigation we carried out 50 ns Molecular Dynamics simulation on H5 hemagglutinin of Influenza A virus H5N1 complexed with fluorinated sialic acid by substituting fluorine atoms at any two hydroxyls of sialic acid by considering combinatorial combination. The binding affinity between the protein–ligand complex system is investigated by calculating pair interaction energy and MM-PBSA binding free energy. All the complex structures are stabilized by hydrogen bonding interactions between the H5 protein and the ligand fluorinated sialic acid. It is concluded from all the analyses that the fluorinated complexes enhance the inhibiting potency against H5 hemagglutinin and the order of inhibiting potency is SIA-F9 ? SIA-F2 ≈ SIA-F7 ≈ SIA-F2F4 ≈ SIA-F2F9 ≈ SIA-F7F9 > SIA-F7F8 ≈ SIA-F2F8 ≈ SIA-F8F9 > SIA-F4 ≈ SIA-F4F7 ≈ SIA-F4F8 ≈ SIA-F8 ≈ SIA-F2F7 ≈ SIA > SIA-F4F9. This study suggests that one can design the inhibitor by using the mono fluorinated models SIA-F9, SIA-F2 and SIA-F7 and difluorinated models SIA-F2F4, SIA-F2F9 and SIA-F7F9 to inhibit H5 of H5N1 to avoid Influenza A viral infection.

Communicated by Ramaswamy H. Sarma     

A Live Attenuated H7N7 Candidate Vaccine Virus Induces Neutralizing Antibody That Confers Protection from Challenge in Mice,Ferrets, and Monkeys

A live attenuated H7N7 candidate vaccine virus was generated by reverse genetics using the modified hemagglutinin (HA) and neuraminidase (NA) genes of highly pathogenic (HP) A/Netherlands/219/03 (NL/03) (H7N7) wild-type (wt) virus and the six internal protein genes of the cold-adapted (ca) A/Ann Arbor/6/60 ca (AA ca) (H2N2) virus. The reassortant H7N7 NL/03 ca vaccine virus was temperature sensitive and attenuated in mice, ferrets, and African green monkeys (AGMs). Intranasal (i.n.) administration of a single dose of the H7N7 NL/03 ca vaccine virus fully protected mice from lethal challenge with homologous and heterologous H7 viruses from Eurasian and North American lineages. Two doses of the H7N7 NL/03 ca vaccine induced neutralizing antibodies in serum and provided complete protection from pulmonary replication of homologous and heterologous wild-type H7 challenge viruses in mice and ferrets. One dose of the H7N7 NL/03 ca vaccine elicited an antibody response in one of three AGMs that was completely protected from pulmonary replication of the homologous wild-type H7 challenge virus. The contribution of CD8⁺ and/or CD4⁺ T cells to the vaccine-induced protection of mice was evaluated by T-cell depletion; T lymphocytes were not essential for the vaccine-induced protection from lethal challenge with H7 wt viruses. Additionally, passively transferred neutralizing antibody induced by the H7N7 NL/03 ca virus protected mice from lethality following challenge with H7 wt viruses. The safety, immunogenicity, and efficacy of the H7N7 NL/03 ca vaccine virus in mice, ferrets, and AGMs support the evaluation of this vaccine virus in phase I clinical trials.Highly pathogenic avian influenza (HPAI) is a disease of poultry that is caused by H5 or H7 avian influenza viruses and is associated with up to 100% mortality (2). Influenza A H7 subtype viruses from both Eurasian and North American lineages have resulted in more than 100 cases of human infection since 2002 in the Netherlands, Italy, Canada, the United Kingdom, and the United States. These cases include outbreaks of HPAI H7N7 virus in the Netherlands in 2003 that resulted in more than 80 cases of human infection and one fatality; HPAI H7N3 virus in British Columbia, Canada, in 2004 that resulted in two cases of conjunctivitis; a cluster of human infections of low-pathogenicity avian influenza (LPAI) H7N2 virus in the United Kingdom in 2007 that resulted in several cases of influenza-like illness and conjunctivitis; and a single case of respiratory infection in New York in 2003 (3-6, 17, 27).Due to an unprecedented geographic spread of H5 subtype viruses since 2003 and the continued occurrence of sporadic cases of H5N1 infections in humans, much emphasis has been placed on the pandemic threat posed by H5 subtype viruses. However, H7 subtype viruses also have significant pandemic potential. Humans are immunologically naïve to the H7 avian influenza viruses (16), and LPAI H7 subtype viruses circulating in domestic poultry and wild birds in Eurasia and North America have the potential to evolve and acquire an HP phenotype either by accumulating mutations or by recombination at the hemagglutinin (HA) cleavage site resulting in a highly cleavable HA that is a virulence motif in poultry (30, 33, 34). Recent work also suggests that contemporary North American lineage H7 subtype viruses, isolated in 2002 to 2003, are partially adapted to recognize α2-6-linked sialic acids, which are the receptors preferred by human influenza viruses and are preferentially found in the human upper respiratory tract (7). Moreover, coinfection and genetic reassortment of RNA genomes between H7 avian influenza viruses and human influenza viruses, including the seasonal H1N1 and H3N2 and pandemic H1N1 viruses, could result in the generation of reassortant viruses with the capacity to efficiently transmit among people and result in a pandemic. Domesticated birds may serve as important intermediate hosts for the transmission of wild-bird influenza viruses to humans, as may pigs, as evidenced by human infections with swine-origin 2009 pandemic H1N1 influenza virus throughout the world.Vaccination is the most effective method for the prevention of influenza. However, technical limitations result in delays in the rapid generation and availability of a strain-specific vaccine against an emerging pandemic virus. The emergence of antigenically distinct virus clades poses a substantial challenge for the design of vaccines against H5N1 viruses because of the possible need for clade-specific vaccines (1). Similar challenges are present for the generation of H7 subtype vaccine candidates, because antigenically distinct H7 subtype viruses, including North American lineage H7N2 and H7N3 and Eurasian lineage H7N7 and H7N3 viruses, have caused human disease. The successful control of H7 influenza virus in poultry has been achieved by stamping out and by vaccination of poultry (9). Vaccines for human use against both lineages of H7 influenza virus are under development, and candidate vaccines have been evaluated in preclinical and clinical studies (14, 23, 29, 42).We have previously analyzed the antigenic relatedness among H7 viruses from Eurasian and North American lineages using postinfection mouse and ferret sera (22). Among 10 H7 viruses tested, A/Netherlands/219/03 (H7N7) virus induced the most broadly cross-neutralizing antibodies (Abs) (22). Based on the phylogenetic relationships and its ability to induce broadly cross-neutralizing antibodies in mice and ferrets, we selected the A/Netherlands/219/03 (NL/03) (H7N7) virus from the Eurasian lineage for vaccine development. We used reverse genetics to generate a live attenuated cold-adapted (ca) H7N7 candidate vaccine virus bearing a modified HA, a wild-type (wt) neuraminidase (NA) gene from the NL/03 wt virus, and the six internal protein gene segments from the cold-adapted (ca) influenza A virus vaccine donor strain, A/Ann Arbor/6/60 ca (AA ca) (H2N2). The immunogenicity and protective efficacy against challenge with HP and LP H7 viruses from the Eurasian and North American lineages of the reassortant H7N7 NL03/AA ca vaccine virus were evaluated in mice, ferrets, and African green monkeys (AGMs).     

Phylogenetic and genetic characterization of a 2017 clinical isolate of H7N9 virus in Guangzhou,China during the fifth epidemic wave

Pathogenic H7N9 influenza viruses continue to pose a public health concern. The H7N9 virus has caused five outbreak waves of human infections in China since 2013. In the present study, a novel H7N9 strain (A/Guangdong/8H324/2017) was isolated from a female patient with severe respiratory illness during the fifth wave of the 2017 H7N9 epidemic. Phylogenetic analysis showed that the H7N9 viruses collected during the fifth wave belong to two different lineages: the Pearl River Delta lineage and the Yangtze River Delta lineage. The novel isolate is closely related to the Pearl River Delta H7N9 viruses, which were isolated from patients in Guangdong Province. The novel H7N9 isolate has an insertion of three basic amino acids in the cleavage site of hemagglutinin (HA), which may enhance virulence in poultry. The 2017 isolate also possesses an R292K substitution in the neuraminidase (NA) protein, which confers oseltamivir resistance. This study highlights the pandemic potential of the novel H7N9 virus in mammals; thus, future characterization and surveillance is warranted.     

一株人感染高致病性禽流感(H5N1)病毒基因组分子特征分析

【背景】H5N1禽流感病毒可以感染人类导致重症呼吸道感染,致死率高。【目的】研究我中心确认的一例人感染高致病性禽流感H5N1病毒A/Nanjing/1/2015的可能起源及基因组分子特征。【方法】对病人痰液样本中的H5N1病毒进行全基因组测序,使用CLC Genomics Workbench 9.0对序列进行拼接,使用BLAST和MEGA 5.22软件进行同源性比对和各片段分子特征分析。【结果】该株禽流感病毒属于H5亚型的2.3.2.1c家系,其8个片段均与江浙地区禽类中分离的病毒高度同源,未发现有明显的重配。分子特征显示,该病毒血凝素(Hemagglutinin,HA)蛋白裂解位点为PQRERRRR/G,受体结合位点呈现禽类受体特点,但出现D94N、S133A和T188I氨基酸置换增强了病毒对人类受体的亲和性。神经氨酸酶(Neuraminidase,NA)蛋白颈部在49-68位缺失20个氨基酸,非结构蛋白1 (Non-structure protein,NS1)存在P42S置换和80-84位氨基酸的缺失。其他蛋白中也存在多个增强病毒致病力和对人类细胞亲和力的氨基酸突变。对耐药位点分析发现存在对奥司他韦的耐药突变H_274Y,病毒对金刚烷胺仍旧敏感。【结论】人感染高致病性禽流感H5N1病毒A/Nanjing/1/2015属于2.3.2.1c家系,禽类来源,关键位点较保守,但仍出现了多个氨基酸的进化与变异使其更利于感染人类。H5N1禽流感病毒进化活跃,持续动态监测不能放松。