Quantitative Characterization of Glycan-Receptor Binding of H9N2 Influenza A Virus Hemagglutinin

Avian influenza subtypes such as H5, H7 and H9 are yet to adapt to the human host so as to establish airborne transmission between humans. However, lab-generated reassorted viruses possessing hemagglutinin (HA) and neuraminidase (NA) genes from an avian H9 isolate and other genes from a human-adapted (H3 or H1) subtype acquired two amino acid changes in HA and a single amino acid change in NA that confer respiratory droplet transmission in ferrets. We previously demonstrated for human-adapted H1, H2 and H3 subtypes that quantitative binding affinity of their HA to α2→6 sialylated glycan receptors correlates with respiratory droplet transmissibility of the virus in ferrets. Such a relationship remains to be established for H9 HA. In this study, we performed a quantitative biochemical characterization of glycan receptor binding properties of wild-type and mutant forms of representative H9 HAs that were previously used in context of reassorted viruses in ferret transmission studies. We demonstrate here that distinct molecular interactions in the glycan receptor-binding site of different H9 HAs affect the glycan-binding specificity and affinity. Further we show that α2→6 glycan receptor-binding affinity of a mutant H9 HA carrying Thr-189→Ala amino acid change correlates with the respiratory droplet transmission in ferrets conferred by this change. Our findings contribute to a framework for monitoring the evolution of H9 HA by understanding effects of molecular changes in HA on glycan receptor-binding properties.     

Amino Acid Substitutions That Affect Receptor Binding and Stability of the Hemagglutinin of Influenza A/H7N9 Virus

Receptor-binding preference and stability of hemagglutinin have been implicated as crucial determinants of airborne transmission of influenza viruses. Here, amino acid substitutions previously identified to affect these traits were tested in the context of an A/H7N9 virus. Some combinations of substitutions, most notably G219S and K58I, resulted in relatively high affinity for α2,6-linked sialic acid receptor and acid and temperature stability. Thus, the hemagglutinin of the A/H7N9 virus may adopt traits associated with airborne transmission.     

Recombinant Parainfluenza Virus 5 Expressing Hemagglutinin of Influenza A Virus H5N1 Protected Mice against Lethal Highly Pathogenic Avian Influenza Virus H5N1 Challenge

A safe and effective vaccine is the best way to prevent large-scale highly pathogenic avian influenza virus (HPAI) H5N1 outbreaks in the human population. The current FDA-approved H5N1 vaccine has serious limitations. A more efficacious H5N1 vaccine is urgently needed. Parainfluenza virus 5 (PIV5), a paramyxovirus, is not known to cause any illness in humans. PIV5 is an attractive vaccine vector. In our studies, a single dose of a live recombinant PIV5 expressing a hemagglutinin (HA) gene of H5N1 (rPIV5-H5) from the H5N1 subtype provided sterilizing immunity against lethal doses of HPAI H5N1 infection in mice. Furthermore, we have examined the effect of insertion of H5N1 HA at different locations within the PIV5 genome on the efficacy of a PIV5-based vaccine. Interestingly, insertion of H5N1 HA between the leader sequence, the de facto promoter of PIV5, and the first viral gene, nucleoprotein (NP), did not lead to a viable virus. Insertion of H5N1 HA between NP and the next gene, V/phosphorprotein (V/P), led to a virus that was defective in growth. We have found that insertion of H5N1 HA at the junction between the small hydrophobic (SH) gene and the hemagglutinin-neuraminidase (HN) gene gave the best immunity against HPAI H5N1 challenge: a dose as low as 1,000 PFU was sufficient to protect against lethal HPAI H5N1 challenge in mice. The work suggests that recombinant PIV5 expressing H5N1 HA has great potential as an HPAI H5N1 vaccine.     

甲型H1N1流感病毒HA蛋白抗原表位及受体结合位点突变特性的对比研究

人群中流行的H1N1病毒按其来源可分为两类:人感染的猪H1N1病毒与人类季节性H1N1流感病毒。这两类病毒在流行频率、易感性和致病性等方面存在明显差异。文章收集了1918～2009年间17株人感染的猪甲型H1N1毒株以及21株季节性H1N1毒株,通过序列比对、氨基酸残基保守性分析及3D结构对比等生物信息学方法,揭示造成这两类病毒流行病学和感染性差异的机制。研究发现这两类病毒HA蛋白的进化路径并不相同,且两者具有不同的突变特征,人感染的猪H1N1病毒中,Ca1、Ca2、Sa和Sb四个位点均较为保守,仅Cb位点的突变较快;季节性H1N1病毒仅有Ca1位点较为保守,其他四个抗原性位点均具有较快的突变速率,且较多的突变为新类型的氨基酸。另外,对受体结合位点的研究也显示,这两类病毒的该区域存在5个氨基酸水平的差异(ALA138SER、GLN192LYS、GLN196HIS、ALA198GLU和ALA227GLU),这些位点的差异使得人感染的猪H1N1流感病毒比人类季节性H1N1病毒的易感性更强。这些研究结果可为阐明两类H1N1流感病毒感染性及致病性差异提供更多的信息,并有助于进一步认识H1N1流感病毒的进化机制。     

Quantitative Description of Glycan-Receptor Binding of Influenza A Virus H7 Hemagglutinin

In the context of recently emerged novel influenza strains through reassortment, avian influenza subtypes such as H5N1, H7N7, H7N2, H7N3 and H9N2 pose a constant threat in terms of their adaptation to the human host. Among these subtypes, it was recently demonstrated that mutations in H5 and H9 hemagglutinin (HA) in the context of lab-generated reassorted viruses conferred aerosol transmissibility in ferrets (a property shared by human adapted viruses). We previously demonstrated that the quantitative binding affinity of HA to α2→6 sialylated glycans (human receptors) is one of the important factors governing human adaptation of HA. Although the H7 subtype has infected humans causing varied clinical outcomes from mild conjunctivitis to severe respiratory illnesses, it is not clear where the HA of these subtypes stand in regard to human adaptation since its binding affinity to glycan receptors has not yet been quantified. In this study, we have quantitatively characterized the glycan receptor-binding specificity of HAs from representative strains of Eurasian (H7N7) and North American (H7N2) lineages that have caused human infection. Furthermore, we have demonstrated for the first time that two specific mutations; Gln226→Leu and Gly228→Ser in glycan receptor-binding site of H7 HA substantially increase its binding affinity to human receptor. Our findings contribute to a framework for monitoring the evolution of H7 HA to be able to adapt to human host.     

H5N1亚型禽流感病毒血凝素蛋白单链抗体基因的克隆及表达

构建并表达H5N1亚型禽流感病毒血凝素蛋白单链抗体,为禽流感靶向治疗药物的研制制备靶向载体。从分泌血凝素单克隆抗体的杂交瘤细胞株中提取mRNA,采用RT-PCR法扩增出重链和轻链可变区基因,通过SOE-PCR法将重链和轻链通过Linker连接起来构建单链抗体基因,将获得的单链抗体基因装入原核表达载体pET28a(+)中,构建重组质粒并表达,以Western blot鉴定单链抗体的特异性。结果成功构建了单链抗体基因,全长714bp,经原核表达,所构建的单链抗体可与H5亚型禽流感病毒HA蛋白特异结合,为禽流感的靶向治疗奠定了基础。     

Structure,Receptor Binding,and Antigenicity of Influenza Virus Hemagglutinins from the 1957 H2N2 Pandemic

The hemagglutinin (HA) envelope protein of influenza viruses mediates essential viral functions, including receptor binding and membrane fusion, and is the major viral antigen for antibody neutralization. The 1957 H2N2 subtype (Asian flu) was one of the three great influenza pandemics of the last century and caused 1 million deaths globally from 1957 to 1968. Three crystal structures of 1957 H2 HAs have been determined at 1.60 to 1.75 Å resolutions to investigate the structural basis for their antigenicity and evolution from avian to human binding specificity that contributed to its introduction into the human population. These structures, which represent the highest resolutions yet recorded for a complete ectodomain of a glycosylated viral surface antigen, along with the results of glycan microarray binding analysis, suggest that a hydrophobicity switch at residue 226 and elongation of receptor-binding sites were both critical for avian H2 HA to acquire human receptor specificity. H2 influenza viruses continue to circulate in birds and pigs and, therefore, remain a substantial threat for transmission to humans. The H2 HA structure also reveals a highly conserved epitope that could be harnessed in the design of a broader and more universal influenza A virus vaccine.Influenza (flu) is an infection of the respiratory tract that affects millions of people every year. In addition to the seasonal toll, three flu pandemics in the past century caused millions of deaths worldwide in relatively short time periods (27). In April 2009, a novel strain of influenza A virus H1N1 (S-OIV) with swine origin emerged in North America and has become the first influenza pandemic in 4 decades. To date, this new H1N1 pandemic has spread globally and caused at least 7,800 deaths (World Health Organization, http://www.who.int).Hemagglutinin (HA) is the major surface envelope glycoprotein on influenza virus, and responsible for essential viral functions, such as binding to host receptors, viral entry, and membrane fusion (31). A key factor that determines the host range, restriction, and transmission of influenza virus is the specificity of HA for binding glycan receptors comprising terminal sialic acids linked to a vicinal galactose residue. HAs in avian viruses are specific for sialic acids with an α2,3-linkage, whereas in humans, the specificity is for sialic acids with an α2,6-linkage (Fig. ​(Fig.1a).1a). This simple linkage difference likely contributes to the inability of most avian influenza viruses to become established and transmit in the human population (26). Influenza pandemics in humans are generally associated with nonhuman viruses of novel antigenicity acquiring specificity for human receptors. HA is also the principal antigen of influenza viruses and the main target for neutralizing antibodies.Open in a separate windowFIG. 1.Crystal structure of H2 HA. (a) Chemical structures of α2,3- and α2,6-linked glycans, with the terminal sialic acid and galactose shown here. (b) Overview of the 1957 H2 trimer. One of the monomers is highlighted in green (HA1) and blue (HA2), respectively. Five potential glycosylation sites are found on each monomer (as labeled). Glycans in the density map are shown in orange. (c) Receptor binding site of H2. Residues involved in receptor binding, as suggested by the H3 structures, are shown in sticks. Aromatic residues comprising the base of the binding site are absolutely conserved in various HA subtypes. Residues from the 220 loop and position 190 are critical for the receptor specificity switch in H1, H2, and H3.Although future influenza pandemics seem inevitable, predicting the potential HA subtypes that will emerge remains a daunting task (41). To date, 16 HA subtypes have been identified and classified based on their antigenic properties (1). Theoretically, all influenza viruses new to the immune system of the human population today possess the potential to initiate a flu pandemic if their ability to enter human cells and transmit efficiently evolves. Historically, however, only viruses of three HA subtypes have acquired the ability to efficiently transmit from human to human, and these were responsible for the influenza pandemics of the last century: 1918 (H1N1), 1957 (H2N2), 1968 (H3N2), and 2009 (H1N1). In recent years, viruses of other HA subtypes (H5, H7, and H9) of avian origin have infected humans in sporadic cases and occasionally with very high mortality, such as H5N1 (2, 4, 10). A key barrier to avian flu becoming a human pandemic is its inefficient human-to-human transmission, which requires a switch of receptor specificity from α2,3- to α2,6-linked receptors. Although the H2 subtype has disappeared from the human population since 1968, it has reemerged in swine in the United States (19). Preparedness for future pandemics can be best addressed by rigorous characterization of the HA subtypes that have already caused pandemics, as well as development of therapeutic reagents that broadly target multiple influenza subtypes.Here, we present three crystal structures of human H2 HA from the 1957 pandemic at resolutions of 1.60, 1.73, and 1.75 Å. These structures, which differ only by one or two residues in the receptor-binding site, represent the evolution of binding specificity for human-like receptors of avian origin during the 1957 H2N2 pandemic. Structural comparisons among the structures, along with glycan array binding studies, have shed new light on the requirements for avian H2 HA to adapt for human transmission.     

禽流感病毒H5N1血凝素基因适应性进化过程中的关键位点突变规律研究

目的:寻找导致禽流感病毒H5N1血凝素(HA)适应性进化的关键突变,建立氨基酸突变评价体系,对突变作用进行评估,印证它们与病毒适应性进化的关联性。方法:计算株频率和枝频率,寻找标记分枝,向根结点回溯寻找HA进化路径上的氨基酸突变。计算各突变位点氨基酸的频率变化、有效变换及高频次突变,基于以上几个因素建立突变评价体系。结果:建立了大规模自动化寻找突变的方法,计算得到HA进化过程中的氨基酸突变435个,通过氨基酸频率图表分析这些突变可以很好地反映病毒适应性进化过程,其中79个突变是有效变换,发生的位点为正选择位点,且多数位点落在HA抗原表位上;29个突变是高频次突变,其中多数也为有效变换,因而与病毒适应性进化密切相关。结论:大规模自动化寻找突变的方法可靠,建立的突变评价体系准确性高,找到的关键突变及位点对实验有很好的指导意义。     

Virulence-Associated Substitution D222G in the Hemagglutinin of 2009 Pandemic Influenza A(H1N1) Virus Affects Receptor Binding

The clinical impact of the 2009 pandemic influenza A(H1N1) virus (pdmH1N1) has been relatively low. However, amino acid substitution D222G in the hemagglutinin of pdmH1N1 has been associated with cases of severe disease and fatalities. D222G was introduced in a prototype pdmH1N1 by reverse genetics, and the effect on virus receptor binding, replication, antigenic properties, and pathogenesis and transmission in animal models was investigated. pdmH1N1 with D222G caused ocular disease in mice without further indications of enhanced virulence in mice and ferrets. pdmH1N1 with D222G retained transmissibility via aerosols or respiratory droplets in ferrets and guinea pigs. The virus displayed changes in attachment to human respiratory tissues in vitro, in particular increased binding to macrophages and type II pneumocytes in the alveoli and to tracheal and bronchial submucosal glands. Virus attachment studies further indicated that pdmH1N1 with D222G acquired dual receptor specificity for complex α2,3- and α2,6-linked sialic acids. Molecular dynamics modeling of the hemagglutinin structure provided an explanation for the retention of α2,6 binding. Altered receptor specificity of the virus with D222G thus affected interaction with cells of the human lower respiratory tract, possibly explaining the observed association with enhanced disease in humans.In April 2009, the H1N1 influenza A virus of swine origin was detected in humans in North America (9, 12, 42). Evidence for its origin came from analyses of the viral genome, with six gene segments displaying the closest resemblance to American “triple-reassortant” swine viruses and two to “Eurasian-lineage” swine viruses (13, 42). After this first detection in humans, the virus spread rapidly around the globe, starting the first influenza pandemic of the 21st century. The 2009 pandemic influenza A(H1N1) virus (pdmH1N1) has been relatively mild, with a spectrum of disease ranging from subclinical infections or mild upper respiratory tract illness to sporadic cases of severe pneumonia and acute respiratory distress syndrome (3, 11, 27, 29, 30, 37). Overall, the case-fatality rate during the start of the pandemic was not significantly higher than in seasonal epidemics in most countries. However, a marked difference was observed in the case-fatality rate in specific age groups, with seasonal influenza generally causing highest mortality in elderly and immunocompromised individuals, and the pdmH1N1 affecting a relatively large proportion of (previously healthy) young individuals (3, 11, 27, 29, 30, 37).Determinants of influenza A virus virulence have been mapped for a wide variety of zoonotic and pandemic influenza viruses to the polymerase genes, hemagglutinin (HA), neuraminidase (NA), and nonstructural protein 1 (NS1). Such virulence-associated substitutions generally facilitate more efficient replication in humans via improved interactions with host cell factors. Since most of these virulence-associated substitutions were absent in the earliest pdmH1N1s, it has been speculated that the virus could acquire some of these mutations, potentially resulting in the emergence of more pathogenic viruses. Such virulence markers could be acquired by gene reassortment with cocirculating influenza A viruses, or by mutation. The influenza virus polymerase genes, in particular PB2, have been shown to be important determinants of the virulence of the highly pathogenic avian influenza (HPAI) H5N1 and H7N7 viruses and the transmission of the 1918 H1N1 Spanish influenza virus (17, 26, 34, 51). One of the most commonly identified virulence markers to date is E627K in PB2. The glutamic acid (E) residue is generally found in avian influenza viruses, while human viruses have a lysine (K), and this mutation was described as a determinant of host range in vitro (48). Given that all human and many zoonotic influenza viruses of the last century contained 627K, it was surprising that the pdmH1N1 had 627E. In addition, an aspartate (D)-to-asparagine (N) substitution at position 701 (D701N) of PB2 has previously been shown to expand the host range of avian H5N1 virus to mice and humans and to increase virus transmission in guinea pigs (26, 46). Like E627K, D701N was absent in the genome of pdmH1N1. Thus, the pdmH1N1 was the first known human pandemic virus with 627E and 701D, and it has been speculated that pdmH1N1 could mutate into a more virulent form by acquiring one of these mutations or both. Recently, it was shown that neither E627K nor D701N in PB2 of pdmH1N1 increased its virulence in ferrets and mice (18). The PB1-F2 protein has previously also been associated with high pathogenicity of the 1918 H1N1 and HPAI H5N1 viruses (8). The PB1-F2 protein of the pdmH1N1 is truncated due to premature stop codons. However, restoration of the PB1-F2 reading frame did not result in viruses with increased virulence (15). The NS1 protein of pdmH1N1 is also truncated due to a stop codon and, as a result, does not contain a PDZ ligand domain that is involved in cell-signaling pathways and has been implicated in the pathogenicity of 1918 H1N1 and HPAI H5N1 viruses (5, 8, 21). Surprisingly, restoration of a full-length version of the NS1 gene did not result in increased virulence in animal models (16). Mutations affecting virulence and host range have further frequently been mapped to hemagglutinin (HA) and neuraminidase (NA) in relation to their interaction with α2,3- or α2,6-linked sialic acids (SAs), the virus receptors on host cells (17, 32, 35, 50). The HA gene of previous pandemic viruses incorporated substitutions that allow efficient attachment to α2,6-SAs—the virus receptor on human cells—compared to ancestral avian viruses that attach more efficiently to α2,3-SAs (35, 47, 50).To search for mutations of potential importance to public health, numerous laboratories performed genome sequencing of pdmH1N1s, resulting in the real-time accumulation of information on emergence of potential virulence markers. Of specific interest were reports on amino acid substitutions from aspartic acid (D) to glycine (G) at position 222 (position 225 in H3) in HA of pdmH1N1. This substitution was observed in a fatal case of pdmH1N1 infection in June 2009 in the Netherlands (M. Jonges et al., unpublished data). Between July and December 2009, viruses from 11 (18%) of 61 cases with severe disease outcome in Norway have also been reported to harbor the D222G substitution upon direct sequencing of HA in clinical specimens. Such mutant viruses were not observed in any of 205 mild cases investigated, and the frequency of detection of this mutation was significantly higher in severe cases than in mild cases (23). In Hong Kong, the D222G substitution was detected in 12.5% (6) and 4.1% (31) of patients with severe disease and in 0% of patients with mild disease, in two different studies without prior propagation in embryonated chicken eggs. In addition to Norway and Hong Kong, the mutation has been detected in Brazil, Japan, Mexico, Ukraine, and the United States (56). Thus, D222G in HA could be the first identified “virulence marker” of pdmH1N1. pdmH1N1 with D222G in HA have not become widespread in the population, although they were detected in several countries. However, D222G in HA is of special interest, since it has also been described as the single change in HA between two strains of the “Spanish” 1918 H1N1 virus that differed in receptor specificity (47). Furthermore, upon propagation in embryonated chicken eggs, pdmH1N1 can acquire the mutation rapidly, presumably because it results in virus adaptation to avian (α2,3-SAs) receptors (49). The presence of the substitution in pdmH1N1s in the human population and its potential association with more severe disease prompted us to test its effect on pdmH1N1 receptor binding, replication, antigenic properties, and pathogenesis and transmission in animal models.     

H9与H5亚型禽流感病毒血凝素基因的快速鉴别

建立一步法RT-PCR检测方法,对禽流感病毒(Avian influenza virus,AIV)的血凝素(Hemagglutinin,HA)分型进行了研究。参照AIV的HA基因序列设计1对引物,对H9和H5亚型AIV进行了扩增,产物大小分别为579bp和177bp。经测试,该引物不与新城疫病毒等鸡的其它传染性病原及鸡肌肉组织的核酸发生交叉反应。敏感性分析发现,从50pg的AIV总RNA中亦能扩增到目的条带。结果表明,此次利用1对引物建立的一步法RT-PCR方法简便适用,可以在一次反应中同时将H9和H5亚型AIV进行快速检测和分型。另外,两个亚型的扩增产物均包含了HA裂解位点在内的基因序列,可通过测序推导氨基酸顺序以预测H5或H9亚型禽流感病毒的潜在毒力。     

H9与H5亚型禽流感病毒血凝素基因的快速鉴别

建立一步法RT-PCR检测方法,对禽流感病毒(Avian influenza virus,AIV)的血凝素(Hemagglutinin,HA)分型进行了研究.参照AIV的HA基因序列设计1对引物,对H9和H5亚型AIV进行了扩增,产物大小分别为579bp和177bp.经测试,该引物不与新城疫病毒等鸡的其它传染性病原及鸡肌肉组织的核酸发生交叉反应.敏感性分析发现,从50pg的AIV总RNA中亦能扩增到目的条带.结果表明,此次利用1对引物建立的一步法RT-PCR方法简便适用,可以在一次反应中同时将H9和H5亚型AIV进行快速检测和分型.另外,两个亚型的扩增产物均包含了HA裂解位点在内的基因序列,可通过测序推导氨基酸顺序以预测H5或H9亚型禽流感病毒的潜在毒力.     

Altered Receptor Specificity and Cell Tropism of D222G Hemagglutinin Mutants Isolated from Fatal Cases of Pandemic A(H1N1) 2009 Influenza Virus

Mutations in the receptor-binding site of the hemagglutinin of pandemic influenza A(H1N1) 2009 viruses have been detected sporadically. An Asp222Gly (D222G) substitution has been associated with severe or fatal disease. Here we show that 222G variants infected a higher proportion of ciliated cells in cultures of human airway epithelium than did viruses with 222D or 222E, which targeted mainly nonciliated cells. Carbohydrate microarray analyses showed that 222G variants bind a broader range of α2-3-linked sialyl receptor sequences of a type expressed on ciliated bronchial epithelial cells and on epithelia within the lung. These features of 222G mutants may contribute to exacerbation of disease.Although the majority of disease cases have been mild, the pandemic influenza A(H1N1) 2009 (H1N1pdm) virus has caused a substantial number of severe and fatal infections (2). Mutants with a D222G or D222E substitution (D225G or D225E in the H3 numbering system) in the receptor-binding site of the virus hemagglutinin (HA) have been detected sporadically (1), and the D222G substitution has been observed to correlate with cases of severe or fatal disease (1, 3, 9, 14). Cell surface receptors for influenza viruses are sialyl glycans (α2-3 Sia or α2-6 Sia) with terminal sialic acid linked α2-3 or α2-6, respectively, to a penultimate galactose. These differ in distribution in the tissues and cells of different species. The sialyl glycans are differentially recognized by the HAs of human and animal influenza viruses and are critical determinants of host range and tissue tropism (16). Using an experimental system of differentiated cultures of human tracheobronchial epithelial cells (HTBE) for studying influenza virus cell tropism, we and others have established that in the initial stages of infection, seasonal human influenza viruses which recognize α2-6 Sia receptors infect mainly nonciliated cells, whereas avian viruses which recognize α2-3 Sia receptors predominantly infect ciliated cells (8, 17, 22).Previous analyses of human and swine influenza H1N1 viruses (5, 15, 21) and preliminary studies of H1N1pdm viruses (24) have indicated that amino acid substitutions in the HA at position 222 may affect the specificity of receptor binding. This, in turn, would be predicted to determine the range of cell types in human respiratory tissues infected by the viruses (17, 20, 22, 23). We have therefore examined the influence of the D222G and D222E substitutions on the cell tropism of H1N1pdm viruses in HTBE cultures (Table ​(Table1).1). Five viruses were isolated from clinical material in MDCK cells and passaged solely in these cells. Two of these, A/Hamburg/5/2009 (Ham) (4) isolated from a case of mild infection and A/Moldova/G186/2009 (Mol) from a serious but nonfatal infection, had 222D. A/Dakar/37/2009 (Dak) isolated from a mild case of the disease had 222E. Two isolates from fatal cases, A/Lviv/N6/2009 (Lvi) and A/Norway/3206-3/2009 (Nor), had 222G. A sixth virus tested, A/Hamburg/5/2009-e (Ham-e), was derived from Ham by egg passage and plaque purification in MDCK cells and differed by a single substitution, D222G.

TABLE 1.

Differences in amino acid sequence of the HAs of the H1N1pdm viruses and cell tropism in HTBE cultures

Avian Influenza Virus H3 Hemagglutinin May Enable High Fitness of Novel Human Virus Reassortants

Reassortment of influenza A virus genes enables antigenic shift resulting in the emergence of pandemic viruses with novel hemagglutinins (HA) acquired from avian strains. Here, we investigated whether historic and contemporary avian strains with different replication capacity in human cells can donate their hemagglutinin to a pandemic human virus. We performed double-infections with two avian H3 strains as HA donors and a human acceptor strain, and determined gene compositions and replication of HA reassortants in mammalian cells. To enforce selection for the avian virus HA, we generated a strictly elastase-dependent HA cleavage site mutant from A/Hong Kong/1/68 (H3N2) (Hk68-Ela). This mutant was used for co-infections of human cells with A/Duck/Ukraine/1/63 (H3N8) (DkUkr63) or the more recent A/Mallard/Germany/Wv64-67/05 (H3N2) (MallGer05) in the absence of elastase but presence of trypsin. Among 21 plaques analyzed from each assay, we found 12 HA reassortants with DkUkr63 (4 genotypes) and 14 with MallGer05 (10 genotypes) that replicated in human cells comparable to the parental human virus. Although DkUkr63 replicated in mammalian cells at a reduced level compared to MallGer05 and Hk68, it transmitted its HA to the human virus, indicating that lower replication efficiency of an avian virus in a mammalian host may not constrain the emergence of viable HA reassortants. The finding that HA and HA/NA reassortants replicated efficiently like the human virus suggests that further HA adaptation remains a relevant barrier for emergence of novel HA reassortants.     

The Role of Influenza A Virus Hemagglutinin Residues 226 and 228 in Receptor Specificity and Host Range Restriction

Influenza A viruses can be isolated from a variety of animals, but their range of hosts is restricted. For example, human influenza viruses do not replicate in duck intestine, the major replication site of avian viruses in ducks. Although amino acids at positions 226 and 228 of hemagglutinin (HA) of the H3 subtype are known to be important for this host range restriction, the contributions of specific amino acids at these positions to restriction were not known. Here, we address this issue by generating HAs with site-specific mutations of a human virus that contain different amino acid residues at these positions. We also let ducks select replication-competent viruses from a replication-incompetent virus containing a human virus HA by inoculating animals with 10^10.5 50% egg infectious dose of the latter virus and identified a mutation in the HA. Our results showed that the Ser-to-Gly mutation at position 228, in addition to the Leu-to-Gln mutation at position 226 of the HA of the H3 subtype, is critical for human virus HA to support virus replication in duck intestine.     

Evolution of the Hemagglutinin Protein of the New Pandemic H1N1 Influenza Virus: Maintaining Optimal Receptor Binding by Compensatory Substitutions

Pandemic influenza A H1N1 (pH1N1) virus emerged in 2009. In the subsequent 4 years, it acquired several genetic changes in its hemagglutinin (HA). Mutations may be expected while virus is adapting to the human host or upon evasion from adaptive immune responses. However, pH1N1 has not displayed any major antigenic changes so far. We examined the effect of the amino acid substitutions found to be most frequently occurring in the pH1N1 HA protein before 1 April 2012 on the receptor-binding properties of the virus by using recombinant soluble HA trimers. Two changes (S186P and S188T) were shown to increase the receptor-binding avidity of HA, whereas two others (A137T and A200T) decreased binding avidity. Construction of an HA protein tree revealed the worldwide emergence of several HA variants during the past few influenza seasons. Strikingly, two major variants harbor combinations of substitutions (S186P/A137T and S188T/A200T, respectively) with opposite individual effects on binding. Stepwise reconstruction of the HA proteins of these variants demonstrated that the mutations that increase receptor-binding avidity are compensated for by the acquisition of subsequent mutations. The combination of these substitutions restored the receptor-binding properties (avidity and specificity) of these HA variants to those of the parental virus. The results strongly suggest that the HA of pH1N1 was already optimally adapted to the human host upon its emergence in April 2009. Moreover, these results are in agreement with a recent model for antigenic drift, in which influenza A virus mutants with high and low receptor-binding avidity alternate.