Newcastle Disease Virus-Vectored Vaccines Expressing the Hemagglutinin or Neuraminidase Protein of H5N1 Highly Pathogenic Avian Influenza Virus Protect against Virus Challenge in Monkeys

H5N1 highly pathogenic avian influenza virus (HPAIV) causes periodic outbreaks in humans, resulting in severe infections with a high (60%) incidence of mortality. The circulating strains have low human-to-human transmissibility; however, widespread concerns exist that enhanced transmission due to mutations could lead to a global pandemic. We previously engineered Newcastle disease virus (NDV), an avian paramyxovirus, as a vector to express the HPAIV hemagglutinin (HA) protein, and we showed that this vaccine (NDV/HA) induced a high level of HPAIV-specific mucosal and serum antibodies in primates when administered through the respiratory tract. Here we developed additional NDV-vectored vaccines expressing either HPAIV HA in which the polybasic cleavage site was replaced with that from a low-pathogenicity strain of influenza virus [HA(RV)], in order to address concerns of enhanced vector replication or genetic exchange, or HPAIV neuraminidase (NA). The three vaccine viruses [NDV/HA, NDV/HA(RV), and NDV/NA] were administered separately to groups of African green monkeys by the intranasal/intratracheal route. An additional group of animals received NDV/HA by aerosol administration. Each of the vaccine constructs was highly restricted for replication, with only low levels of virus shedding detected in respiratory secretions. All groups developed high levels of neutralizing antibodies against homologous and heterologous strains of HPAIV and were protected against challenge with 2 × 10⁷ PFU of homologous HPAIV. Thus, needle-free, highly attenuated NDV-vectored vaccines expressing either HPAIV HA, HA(RV), or NA have been developed and demonstrated to be individually immunogenic and protective in a primate model of HPAIV infection. The finding that HA(RV) was protective indicates that it would be preferred for inclusion in a vaccine. The study also identified NA as an independent protective HPAIV antigen in primates. Furthermore, we demonstrated the feasibility of aerosol delivery of NDV-vectored vaccines.H5N1 highly pathogenic avian influenza virus (HPAIV) was first detected in human infections in 1997; previously, it had been found only in birds (11, 50). To date, this virus has been identified in 436 confirmed cases of human infection in 15 countries, 262 (60%) of which were fatal (75). The currently circulating H5N1 strains are characterized by low human-to-human transmissibility. This has been attributed, in part, to a preference for binding to α-2,3-linked sialic acids that are present in high concentrations throughout the avian respiratory tract but were thought to be found primarily in the lower human respiratory tract (57), although this explanation has been questioned (48, 49). It has also been observed that mutations in the PB2 subunit of the viral polymerase are necessary to confer the ability for the virus to be spread by aerosolized nasal droplets in ferrets (72). Whatever factors may be involved, there is widespread concern that the avian virus could mutate to enhance its transmissibility among humans, possibly resulting in a global pandemic (28, 50). For the avian H9N2 virus, which also has pandemic potential, it has been demonstrated that only five amino acid changes were sufficient for the virus to gain the ability to be spread by aerosolized nasal droplets in a ferret model (60). Thus, there is an urgent need for vaccines against HPAIV.Several vaccine strategies for HPAIV have been evaluated (reviewed in references 32 and 41), including inactivated and live attenuated vaccines. These efforts have been hampered by several factors. HPAIV strains are highly virulent for embryonated chicken eggs, the most widely used substrate for vaccine manufacture, and their rapid death following inoculation renders eggs unsuitable for efficient virus propagation. In addition, the major protective antigen, hemagglutinin (HA), administered either as a purified protein or in inactivated HPAIV virions, appears to be poorly immunogenic (69, 70). An additional factor complicating the development of HPAIV vaccines based on inactivated virus is the high cost and biohazard associated with HPAIV propagation, which must be done under enhanced biosafety level 3 (BSL-3) containment, although this problem might be addressed by the use of live attenuated reassortant influenza virus vaccines that contain the HPAIV glycoproteins on the background of an avirulent human influenza virus strain (24, 37). In addition, such reassortant strains might serve directly as live attenuated vaccines. Unfortunately, the latter approach may be limited by subtle and unpredictable incompatibility between the avian-origin glycoproteins and human-origin vaccine backgrounds acceptable for human use, which can result in overattenuation in vivo (24). There are also lingering concerns about the significant potential, with a live HPAIV vaccine, for reassortment between gene segments of the vaccine virus and circulating influenza virus strains, which might result in novel strains with unpredictable biological properties (63).We and others have been evaluating Newcastle disease virus (NDV) as a general human vaccine vector for emerging pathogens, including H5N1 HPAIV (7, 18-20, 29). NDV is an avian paramyxovirus that is antigenically unrelated to common human pathogens; hence, its use in humans should not be affected by host immunity to common pathogens. The many naturally occurring strains of NDV can be categorized into three pathotypes based on virulence in chickens: velogenic strains, causing severe disease with high mortality; mesogenic strains, causing disease of intermediate severity with low mortality; and lentogenic strains, causing mild or inapparent infections (reviewed in reference 2). Lentogenic, and sometimes mesogenic, strains of NDV are in wide use as live attenuated vaccines against velogenic NDV in poultry (2). When mesogenic or lentogenic NDV was administered to the respiratory tracts of nonhuman primates as a model for the immunization of humans, the virus was highly attenuated for replication, was shed only at low titers, appeared to remain restricted to the respiratory tract, and was highly immunogenic for the expressed foreign antigen (7). We recently demonstrated that a mesogenic strain of NDV expressing the HA protein of H5N1 HPAIV (NDV/HA) elicited high titers of neutralizing antibodies in serum following combined intranasal (i.n.) and intratracheal (i.t.) delivery in a nonhuman primate model (20). Vaccination of mice with a similar NDV-vectored vaccine protected them from HPAIV challenge (29). However, results obtained with mice do not reliably predict the efficacy of an influenza virus vaccine for human use, due to the pathophysiological and phylogenetic differences between mice and humans (71). In particular, mice may produce a potent immune response to HPAIV vaccines (64) that may not be reproduced in clinical trials (38). These considerations are especially important for a vaccine based on a live viral vector platform, since its immunogenicity, and therefore its protective efficacy, is directly linked to replication, which can differ greatly in various experimental animals versus humans (reviewed in references 6 and 9). Therefore, the protective efficacy of NDV-based vaccines against HPAIV challenge in nonhuman primate models—the closest model to humans—has remained unknown.The protease recognition sequence of the HA protein is one of the major determinants of avian influenza virus pathogenicity (62). HPAIV strains have a “polybasic” cleavage site, containing multiple basic amino acids, that is readily cleaved by ubiquitous intracellular subtilisin-like proteases, facilitating the replication and spread of the virus. In contrast, the HA cleavage site of low-pathogenicity strains contains fewer basic amino acids and depends on secretory trypsin-like proteases found in the respiratory and enteric tracts, resulting in more-localized infections (30, 62). The presence of a polybasic cleavage site in the H5 HA of any live vaccine raises some concern about the possibility of genetic exchange with circulating strains of influenza virus. It should be noted that genetic exchange involving paramyxoviruses is a rare event (14) that has been documented only once (61). However, elimination of the polybasic HA cleavage site would mitigate the effects of even this rare possibility of genetic exchange. Another concern was based on our previous finding that the HPAIV H5 HA protein is incorporated into the NDV envelope as a trimer (20), consistent with its presence in a functional form. While we previously showed that this did not enhance the pathogenicity of the NDV/HA recombinant in chickens (20), we could not rule out the possibility that it might confer an altered tropism on the NDV/HA virus in other systems. For example, a recombinant parainfluenza virus type 3 expressing the Ebola virus glycoprotein incorporated the foreign protein into its envelope, allowing cellular attachment and fusion of the vaccine virus independently of the vector''s own envelope glycoproteins (10).In addition to the HA protein, the neuraminidase (NA) protein is also present on the surfaces of influenza virus-infected cells and virions. Antibodies specific for NA are not thought to interfere with the initial viral attachment and penetration of host cells (36, 40, 54). However, NA-specific antibodies prevent the release of virus from infected cells, thereby decreasing viral spread (35), and they increase resistance to viral infection in humans (40, 47, 54). They also provide at least some protection against viruses bearing homologous or heterologous NA proteins of the same subtype in a mouse model (12, 56). NA also appears to evolve at a lower rate than HA, suggesting that NA-specific antibodies may provide broader protection than a vaccine utilizing HA alone (39). Therefore, it was important to assess the immunogenicity and protective efficacy of the HPAIV NA independently of those of HA, which has not previously been done in a human or nonhuman primate model.     

Chimeric Newcastle Disease Virus-like Particles Containing DC-Binding Peptide-Fused Haemagglutinin Protect Chickens from Virulent Newcastle Disease Virus and H9N2 Avian Influenza Virus Challenge

Newcastle disease virus(NDV) and H9N2 subtype Avian influenza virus(AIV) are two notorious avian respiratory pathogens that cause great losses in the poultry industry. Current inactivated commercial vaccines against NDV and AIV have the disadvantages of inadequate mucosal responses, while an attenuated live vaccine bears the risk of mutation.Dendritic cell(DC) targeting strategies are attractive for their potent mucosal and adaptive immune-stimulating ability against respiratory pathogens. In this study, DC-binding peptide(DCpep)-decorated chimeric virus-like particles(cVLPs),containing NDV haemagglutinin–neuraminidase(HN) and AIV haemagglutinin(HA), were developed as a DC-targeting mucosal vaccine candidate. DCpep-decorated cVLPs activated DCs in vitro, and induced potent immune stimulation in chickens, with enhanced secretory immunoglobulin A(sIgA) secretion and splenic T cell differentiation. 40 μg cVLPs can provide full protection against the challenge with homologous, heterologous NDV strains, and AIV H9N2. In addition,DCpep-decorated cVLPs could induce a better immune response when administered intranasally than intramuscularly, as indicated by robust s IgA secretion and a reduced virus shedding period. Taken together, this chimericVLPs are a promising vaccine candidate to control NDV and AIV H9N2 and a useful platform bearing multivalent antigens.     

Immunization of Chickens with Newcastle Disease Virus Expressing H5 Hemagglutinin Protects against Highly Pathogenic H5N1 Avian Influenza Viruses

Background

Highly-pathogenic avian influenza virus (HPAIV) and Newcastle disease virus (NDV) are the two most important poultry viruses in the world. Natural low-virulence NDV strains have been used as vaccines over the past 70 years with proven track records. We have previously developed a reverse genetics system to produce low-virulent NDV vaccine strain LaSota from cloned cDNA. This system allows us to use NDV as a vaccine vector for other avian pathogens.

Methodology/Principal Finding

Here, we constructed two recombinant NDVs (rNDVs) each of which expresses the hemagglutinin (HA) gene of HPAIV H5N1strain A/Vietnam/1203/2004 from an added gene. In one, rNDV (rNDV-HA), the open reading frame (ORF) of HA gene was expressed without modification. In the second, rNDV (rNDV-HAF), the ORF was modified so that the transmembrane and cytoplasmic domains of the encoded HA gene were replaced with those of the NDV F protein. The insertion of either version of the HA ORF did not increase the virulence of the rNDV vector. The HA protein was found to be incorporated into the envelopes of both rNDV-HA and rNDV-HAF. However, there was an enhanced incorporation of the HA protein in rNDV-HAF. Chickens immunized with a single dose of either rNDV-HA or rNDV-HAF induced a high titer of HPAIV H5-specific antibodies and were completely protected against challenge with NDV as well as lethal challenges of both homologous and heterologous HPAIV H5N1.

Conclusion and Significance

Our results suggest that these chimeric viruses have potential as safe and effective bivalent vaccines against NDV and. HPAIV. These vaccines will be convenient and affordable, which will be highly beneficial to the poultry industry. Furthermore, immunization with these vaccines will permit serological differentiation of vaccinated and avian influenza field virus infected animals.     

H3 Stalk-Based Chimeric Hemagglutinin Influenza Virus Constructs Protect Mice from H7N9 Challenge

The recent outbreak of H7N9 influenza virus infections in humans in China has raised concerns about the pandemic potential of this strain. Here, we test the efficacy of H3 stalk-based chimeric hemagglutinin universal influenza virus vaccine constructs to protect against H7N9 challenge in mice. Chimeric hemagglutinin constructs protected from viral challenge in the context of different administration routes as well as with a generic oil-in-water adjuvant similar to formulations licensed for use in humans.     

Live Attenuated Influenza Viruses Containing NS1 Truncations as Vaccine Candidates against H5N1 Highly Pathogenic Avian Influenza

Due to the high mortality associated with recent, widely circulating strains of H5N1 influenza virus in poultry, the recurring introduction of H5N1 viruses from birds to humans, and the difficulties in H5N1 eradication by elimination of affected flocks, an effective vaccine against HPAI (highly pathogenic avian influenza) is highly desirable. Using reverse genetics, a set of experimental live attenuated vaccine strains based on recombinant H5N1 influenza virus A/Viet Nam/1203/04 was generated. Each virus was attenuated through expression of a hemagglutinin protein in which the polybasic cleavage site had been removed. Viruses were generated which possessed a full-length NS1 or a C-terminally truncated NS1 protein of 73, 99, or 126 amino acids. Viruses with each NS genotype were combined with a PB2 polymerase gene which carried either a lysine or a glutamic acid at position 627. We predicted that glutamic acid at position 627 of PB2 would attenuate the virus in mammalian hosts, thus increasing the safety of the vaccine. All recombinant viruses grew to high titers in 10-day-old embryonated chicken eggs but were attenuated in mammalian cell culture. Induction of high levels of beta interferon by all viruses possessing truncations in the NS1 protein was demonstrated by interferon bioassay. The viruses were each found to be highly attenuated in a mouse model. Vaccination with a single dose of any virus conferred complete protection from death upon challenge with a mouse lethal virus expressing H5N1 hemagglutinin and neuraminidase proteins. In a chicken model, vaccination with a single dose of a selected virus encoding the NS1 1-99 protein completely protected chickens from lethal challenge with homologous HPAI virus A/Viet Nam/1203/04 (H5N1) and provided a high level of protection from a heterologous virus, A/egret/Egypt/01/06 (H5N1). Thus, recombinant influenza A/Viet Nam/1203/04 viruses attenuated through the introduction of mutations in the hemagglutinin, NS1, and PB2 coding regions display characteristics desirable for live attenuated vaccines and hold potential as vaccine candidates in poultry as well as in mammalian hosts.     

Prior Infection of Chickens with H1N1 or H1N2 Avian Influenza Elicits Partial Heterologous Protection against Highly Pathogenic H5N1

There is a critical need to have vaccines that can protect against emerging pandemic influenza viruses. Commonly used influenza vaccines are killed whole virus that protect against homologous and not heterologous virus. Using chickens we have explored the possibility of using live low pathogenic avian influenza (LPAI) A/goose/AB/223/2005 H1N1 or A/WBS/MB/325/2006 H1N2 to induce immunity against heterologous highly pathogenic avian influenza (HPAI) A/chicken/Vietnam/14/2005 H5N1. H1N1 and H1N2 replicated in chickens but did not cause clinical disease. Following infection, chickens developed nucleoprotein and H1 specific antibodies, and reduced H5N1 plaque size in vitro in the absence of H5 neutralizing antibodies at 21 days post infection (DPI). In addition, heterologous cell mediated immunity (CMI) was demonstrated by antigen-specific proliferation and IFN-γ secretion in PBMCs re-stimulated with H5N1 antigen. Following H5N1 challenge of both pre-infected and naïve controls chickens housed together, all naïve chickens developed acute disease and died while H1N1 or H1N2 pre-infected chickens had reduced clinical disease and 70–80% survived. H1N1 or H1N2 pre-infected chickens were also challenged with H5N1 and naïve chickens placed in the same room one day later. All pre-infected birds were protected from H5N1 challenge but shed infectious virus to naïve contact chickens. However, disease onset, severity and mortality was reduced and delayed in the naïve contacts compared to directly inoculated naïve controls. These results indicate that prior infection with LPAI virus can generate heterologous protection against HPAI H5N1 in the absence of specific H5 antibody.     

Immunization with a Live Attenuated H7N9 Influenza Vaccine Protects Mice against Lethal Challenge

The emergence of severe cases of human influenza A (H7N9) viral infection in China in the spring of 2003 resulted in a global effort to rapidly develop an effective candidate vaccine. In this study, a cold-adapted (ca), live attenuated monovalent reassortant influenza H7N9 virus (Ah01/AA ca) was generated using reverse genetics that contained hemagglutinin (HA) and neuraminidase (NA) genes from a 2013 pandemic A H7N9 isolate, A/Anhui/01/2013 virus (Ah01/H7N9); the remaining six backbone genes derived from the cold-adapted influenza H2N2 A/Ann Arbor/6/60 virus (AA virus). Ah01/AA ca virus exhibited temperature sensitivity (ts), ca, and attenuation (att) phenotypes. Intranasal immunization of female BALB/c mice with Ah01/AA ca twice at a 2-week interval induced robust humoral, mucosal, and cell-mediated immune responses in a dose-dependent manner. Furthermore, the candidate Ah01/AA ca virus was immunogenic and offered partial or complete protection of mice against a lethal challenge by the live 2013 influenza A H7N9 (A/Anhui/01/2013). Protection was demonstrated by the inhibition of viral replication and the attenuation of histopathological changes in the challenged mouse lung. Taken together, these data support the further evaluation of this Ah01/AA ca candidate vaccine in primates.     

Intranasal H5N1 Vaccines,Adjuvanted with Chitosan Derivatives,Protect Ferrets against Highly Pathogenic Influenza Intranasal and Intratracheal Challenge

We investigated the protective efficacy of two intranasal chitosan (CSN and TM-CSN) adjuvanted H5N1 Influenza vaccines against highly pathogenic avian Influenza (HPAI) intratracheal and intranasal challenge in a ferret model.Six groups of 6 ferrets were intranasally vaccinated twice, 21 days apart, with either placebo, antigen alone, CSN adjuvanted antigen, or TM-CSN adjuvanted antigen. Homologous and intra-subtypic antibody cross-reacting responses were assessed. Ferrets were inoculated intratracheally (all treatments) or intranasally (CSN adjuvanted and placebo treatments only) with clade 1 HPAI A/Vietnam/1194/2004 (H5N1) virus 28 days after the second vaccination and subsequently monitored for morbidity and mortality outcomes. Clinical signs were assessed and nasal as well as throat swabs were taken daily for virology. Samples of lung tissue, nasal turbinates, brain, and olfactory bulb were analysed for the presence of virus and examined for histolopathological findings.In contrast to animals vaccinated with antigen alone, the CSN and TM-CSN adjuvanted vaccines induced high levels of antibodies, protected ferrets from death, reduced viral replication and abrogated disease after intratracheal challenge, and in the case of CSN after intranasal challenge. In particular, the TM-CSN adjuvanted vaccine was highly effective at eliciting protective immunity from intratracheal challenge; serologically, protective titres were demonstrable after one vaccination. The 2-dose schedule with TM-CSN vaccine also induced cross-reactive antibodies to clade 2.1 and 2.2 H5N1 viruses. Furthermore ferrets immunised with TM-CSN had no detectable virus in the respiratory tract or brain, whereas there were signs of virus in the throat and lungs, albeit at significantly reduced levels, in CSN vaccinated animals.This study demonstrated for the first time that CSN and in particular TM-CSN adjuvanted intranasal vaccines have the potential to protect against significant mortality and morbidity arising from infection with HPAI H5N1 virus.     

Estimation of Transmission Parameters of H5N1 Avian Influenza Virus in Chickens

Despite considerable research efforts, little is yet known about key epidemiological parameters of H5N1 highly pathogenic influenza viruses in their avian hosts. Here we show how these parameters can be estimated using a limited number of birds in experimental transmission studies. Our quantitative estimates, based on Bayesian methods of inference, reveal that (i) the period of latency of H5N1 influenza virus in unvaccinated chickens is short (mean: 0.24 days; 95% credible interval: 0.099–0.48 days); (ii) the infectious period of H5N1 virus in unvaccinated chickens is approximately 2 days (mean: 2.1 days; 95%CI: 1.8–2.3 days); (iii) the reproduction number of H5N1 virus in unvaccinated chickens need not be high (mean: 1.6; 95%CI: 0.90–2.5), although the virus is expected to spread rapidly because it has a short generation interval in unvaccinated chickens (mean: 1.3 days; 95%CI: 1.0–1.5 days); and (iv) vaccination with genetically and antigenically distant H5N2 vaccines can effectively halt transmission. Simulations based on the estimated parameters indicate that herd immunity may be obtained if at least 80% of chickens in a flock are vaccinated. We discuss the implications for the control of H5N1 avian influenza virus in areas where it is endemic.     

Detection and Genetic Characteristics of H9N2 Avian Influenza Viruses from Live Poultry Markets in Hunan Province,China

H9N2 avian influenza viruses (AIVs) are highly prevalent and of low pathogenicity in domestic poultry. These viruses show a high genetic compatibility with other subtypes of AIVs and have been involved in the genesis of H5N1, H7N9 and H10N8 viruses causing severe infection in humans. The first case of human infection with H9N2 viruses in Hunan province of China have been confirmed in November 2013 and identified that H9N2 viruses from live poultry markets (LPMs) near the patient’s house could be the source of infection. However, the prevalence, distribution and genetic characteristics of H9N2 viruses in LPMs all over the province are not clear. We collected and tested 3943 environmental samples from 380 LPMs covering all 122 counties/districts of Hunan province from February to April, 2014. A total of 618 (15.7%) samples were H9 subtype positive and 200 (52.6%) markets in 98 (80.3%) counties/districts were contaminated with H9 subtype AIVs. We sequenced the entire coding sequences of the genomes of eleven H9N2 isolates from environmental samples. Phylogenetic analysis showed that the gene sequences of the H9N2 AIVs exhibited high homology (94.3%-100%). All eleven viruses were in a same branch in the phylogenetic trees and belonged to a same genotype. No gene reassortment had been found. Molecular analysis demonstrated that all the viruses had typical molecular characteristics of contemporary avian H9N2 influenza viruses. Continued surveillance of AIVs in LPMs is warranted for identification of further viral evolution and novel reassortants with pandemic potential.     

Vaccination with Recombinant RNA Replicon Particles Protects Chickens from H5N1 Highly Pathogenic Avian Influenza Virus

Highly pathogenic avian influenza viruses (HPAIV) of subtype H5N1 not only cause a devastating disease in domestic chickens and turkeys but also pose a continuous threat to public health. In some countries, H5N1 viruses continue to circulate and evolve into new clades and subclades. The rapid evolution of these viruses represents a problem for virus diagnosis and control. In this work, recombinant vesicular stomatitis virus (VSV) vectors expressing HA of subtype H5 were generated. To comply with biosafety issues the G gene was deleted from the VSV genome. The resulting vaccine vector VSV*ΔG(HA) was propagated on helper cells providing the VSV G protein in trans. Vaccination of chickens with a single intramuscular dose of 2×10⁸ infectious replicon particles without adjuvant conferred complete protection from lethal H5N1 infection. Subsequent application of the same vaccine strongly boosted the humoral immune response and completely prevented shedding of challenge virus and transmission to sentinel birds. The vaccine allowed serological differentiation of infected from vaccinated animals (DIVA) by employing a commercially available ELISA. Immunized chickens produced antibodies with neutralizing activity against multiple H5 viruses representing clades 1, 2.2, 2.5, and low-pathogenic avian influenza viruses (classical clade). Studies using chimeric H1/H5 hemagglutinins showed that the neutralizing activity was predominantly directed against the globular head domain. In summary, these results suggest that VSV replicon particles are safe and potent DIVA vaccines that may help to control avian influenza viruses in domestic poultry.     

鸡源H9N2亚型流行性感冒病毒神经氨酸酶基因序列分析

对1996～2001年间自中国部分养鸡场发病鸡或死亡鸡分离鉴定的8株H9N2亚型禽流感病毒的神经氨酸酶基因(NA),进行了扩增和序列测定,并分析和比较了其核苷酸和氨基酸的同源性.结果表明,NA基因核苷酸和氨基酸同源性分别为97.1%～99.8%和95.7%～99.7%,说明NA基因稳定遗传,高度保守.与A/chicken/HongKong/G9/97相比较,发现中国大陆鸡源H9N2分离株的神经氨酸酶蛋白在其茎部的第63、64、65位点上都有3个氨基酸的丢失,而与中国邻近的韩国、巴基斯坦鸡源H9N2分离株的神经氨酸酶没有氨基酸的丢失,因此这些部位的氨基酸丢失可初步认为是中国大陆H9N2流感病毒分离株的一个标记.系统进化树分析表明,该8株病毒的NA基因属于相同的进化分支,即A/duck/HongKong/Y280/97-like分支,尚未发现NA基因属于A/quail/HongKong/G1/97-like分支的分离株.中国的H9N2分离株与韩国、巴基斯坦等地的H9N2分离株隶属于不同的进化亚分支,说明H9N2亚型禽流感的发生与流行和地域有一定的相关性.