Characterization of a new avian-like influenza A virus from horses in China.

In March 1989 a severe outbreak of respiratory disease occurred in horses in the Jilin and Heilongjiang provinces of Northeast China that caused up to 20% mortality in some herds. An influenza virus of the H3N8 subtype was isolated from the infected animals and was antigenically and molecularly distinguishable from the equine 2 (H3N8) viruses currently circulating in the world. The reference strain A/Equine/Jilin/1/89 (H3N8) was most closely related to avian H3N8 influenza viruses. Sequence comparisons of the entire hemagglutinin (HA), nucleoprotein (NP), neuraminidase (NA), matrix (M), and NS genes along with partial sequences of the three polymerase (PB1, PB2, PA) genes suggest that six of the eight gene segments (PA, HA, NP, NA, M, NS) are closely related to avian influenza viruses. Since direct sequence analysis can only provide a crude measure of relationship, phylogenetic analysis was done on the sequence information. Phylogenetic analyses of the entire HA, NP, M, and NS genes and of partial sequences of PB1, PB2, and PA indicated that these genes are of recent avian origin. The NP gene segment is closely related to the gene segment found in the newly described H14 subtype isolated from ducks in the USSR. The A/Equine/Jilin/1/89 (H3N8) influenza virus failed to replicate in ducks, but did replicate and cause disease in mice on initial inoculation and on subsequent passaging caused 100% mortality. In ferrets, the virus caused severe influenza symptoms. A second outbreak of influenza in horses in Northeast China occurred in April 1990 in the Heilongjiang province with 48% morbidity and no mortality. The viruses isolated from this outbreak were antigenically indistinguishable from those in the 1989 outbreak and it is probable that the reduced mortality was due to the immune status of of the horses in the region. No influenza was detected in horses in Northern China in the spring, summer, or fall of 1991 and no influenza has been detected in horses in adjacent areas. Our analysis suggests that this new equine influenza virus in horses in Northeast China is the latest influenza virus in mammals to emerge from the avian gene pool in nature and that it may have spread to horses without reassortment. The appearance of this new equine virus in China emphasizes the potential for whole avian influenza viruses to successfully enter mammalian hosts and serves as a model and a warning for the appearance of new pandemic influenza viruses in humans.(ABSTRACT TRUNCATED AT 250 WORDS)     

Phylogenetic analysis of H1N2 isolates of influenza A virus from pigs in the United States

Twenty-four H1N2 influenza A viruses were newly isolated from pigs in the United States. These isolates originated from 19 farms in 9 different swine producing states between 1999 and 2001. All farms had clinical histories of respiratory problem and/or abortion. The viral isolates were characterized genetically to determine the origin of all eight gene segments. The results showed that all H1N2 isolates were reassortants of classical swine H1N1 and triple reassortant H3N2 viruses. The neuraminidase (NA) and PB1 genes of the H1N2 isolates were of human origin, while the hemagglutinin (HA), nucleoprotein (NP), matrix (M), non-structural (NS), PA and PB2 polymerase genes were of avian or swine origin. Fifteen of the 24 H1N2 isolates were shown to have a close phylogenic relationship and high amino acid homology with the first US isolate of H1N2 (A/SW/IN/9K035/99). The remaining nine isolates had a close phylogenic relationship with classical swine influenza H1N1 in the HA gene. All other genes including NA, M, NP, NS, PA, PB1 and PB2 showed a close phylogenic relationship with the H1N2 (A/SW/IN/9K035/99) strain and triple reassortant H3N2 viruses. However, PB1 genes of two isolates (A/SW/KS/13481-S/00, A/SW/KS/13481-T/00) were originated from avian influenza A virus lineage. These results suggest that although there are some variations in the HA genes, the H1N2 viruses prevalent in the US swine population are of a similar genetic lineage.     

Genetic characterization of low pathogenic H5N1 and co-circulating avian influenza viruses in wild mallards (Anas platyrhynchos) in Belgium, 2008

As part of a long-term wild bird monitoring programme, five different low pathogenic (LP) avian influenza viruses (AIVs) were isolated from wild mallards (subtypes H1N1, H4N6, H5N1, H5N3, and H10N7). A LP H5N1 and two co-circulating (same location, same time period) viruses were selected for full genome sequencing. An H1N1 (A/Anas platyrhynchos/Belgium/09-762/2008) and an H5N1 virus (A/Anas platyrhynchos/Belgium/09-762-P1/2008) were isolated on the same day in November 2008, then an H5N3 virus (A/Anas platyrhynchos/09-884/2008) 5 days later in December 2008. All genes of these co-circulating viruses shared common ancestors with recent (2001 to 2007) European wild waterfowl influenza viruses. The H5N1 virus shares genome segments with both the H1N1 (PB1, NA, M) and the H5N3 (PB2, HA) viruses, and all three viruses share the same NS sequence. A double infection with two different PA segments from H5N1 and from H5N3 could be observed for the H1N1 sample. The observed gene constellations resulted from multiple reassortment events between viruses circulating in wild birds in Eurasia. Several internal gene segments from these 2008 viruses and the N3 sequence from the H5N3 show homology with sequences from 2003 H7 outbreaks in Italy (LP) and the Netherlands (highly pathogenic). These data contribute to the growing sequence evidence of the dynamic nature of the avian influenza natural reservoir in Eurasia, and underline the importance of monitoring AIV in wild birds. Genetic information of potential hazard to commercial poultry continues to circulate in this reservoir, including H5 and H7 subtype viruses and genes related to previous AIV outbreaks.     

Influenza A virus-induced apoptosis is a multifactorial process: exploiting reverse genetics to elucidate the role of influenza A virus proteins in virus-induced apoptosis

Three influenza viruses, A/Puerto Rico/8/34-A/England/939/69 clone 7a (H3N2), A/Fiji/15899/83 (H1N1), and A/Victoria/3/75 (H3N2), induce different levels of apoptosis in vitro at equal moi; Clone 7a > A/Victoria > A/Fiji. Previous studies have shown that several viral proteins from clone 7a and A/Fiji, including PB2, NA, NS1, M1, and M2, induce apoptosis when expressed individually fused to the herpes simplex virus tegument protein, VP22. However, this did not reflect viral protein-protein-RNA interactions known to occur within infected cells. To explore the role of viral proteins in apoptosis under infection conditions, recombinant viruses with single or triple gene exchanges were generated using A/Victoria or clone 7a as the background virus. Inserting the A/Fiji NS or PB2 gene into A/Victoria or clone 7a significantly reduced the level of apoptosis compared to the parent virus while clone 7a PA or NP genes increased apoptosis. Inserting A/Fiji NA or HA or clone 7a NS, M, NA, or HA genes individually into A/Victoria had no significant effect on apoptosis. Surprisingly, inserting the M, NA, and HA genes of A/Fiji together into clone 7a reduced apoptosis, whereas inserting clone 7a M, NA, and HA together into A/Fiji increased apoptosis. These results suggest that no single virus protein induces apoptosis and that the combination of genes required may be strain specific, highlighting the difficulty of predicting the virulence of new strains that arise in nature. No support for the view that apoptosis is essential for high virus yields was obtained as high virus yields were obtained with viruses that induced both high and low levels of apoptosis.     

Molecular and phylogenetic analysis of haemagglutinin and neuraminidase sequences from recent human influenza type A (H3N2) viral isolates in Southern Greece

Summary.  Eighteen haemagglutinin (HA1) gene segments and eleven neuraminidase (NA) genes of human influenza type A (H3N2) viruses isolated from non-vaccinated individuals presenting severe influenza-like illness at peak influenza activity in Southern Greece during the surveillance period 1996–1999, were subjected to sequence and phylogenetic analyses following propagation in embryonated hen’s eggs. The HA1 gene segment of the clinical isolates differed from the recent reference influenza type A (H3N2) vaccine strains in an Ile at residue 186, a Val at residue 194 and a Val at residue 226 for one, two and thirteen isolates of the 1996–1997 and 1996–1999 periods, respectively. The analogous differences in the NA gene were confined in an Asp to Asn substitution at residue 198 in one A/Wuhan/359/95 (H3N2)-like isolate of the 1996–1997 period, primarily. In addition, phylogenetic analysis revealed that an isolate of the 1997–1998 period was a recombinant with its HA1 gene segment being closely related to that of A/Wuhan/359/95-like viruses and its NA to viruses of the A/Sydney/5/97 (H3N2) lineage. These findings confirmed the profound genetic instability of influenza type A (H3N2) viruses and underscored the importance for periodic molecular surveys of HA and NA in the effective prevention and management of viral outbreaks. Most importantly, however, they contributed the first complete epidemiological material for influenza in Southern Greece, the archival nature of which constitutes valuable reference for future surveys. Accepted April 21, 2001 Received     

Genetic stability and linkage analysis of the 2009 influenza A(H1N1) virus based on sequence homology

The 2009 swine-origin Influenza A virus subtype H1N1 (S-OIV) is generally believed to be a mixture of human, bird and swine viruses, resulting from multiple reassortments. The evolutionary origin of the S-OIV is of high interest but still remains obscure. In order to understand the evolution of the new virus, we performed sequence homology, segment stability and segment linkage analysis, as well as analysis of the host and geographic distribution of the evolutionarily related viruses. Stability analysis demonstrated that segment 6 (NA) was the most unstable one, followed by segment 4 (HA), while the other 6 segments were relatively stable. Host and geographic distribution analysis indicated that all 8 segments of the new virus were closely related to those of swine influenza viruses circulating either in North America or in Eurasia. Segment linkage analysis showed that segments 1 (PB2), 2 (PB1), 3 (PA), 4 (HA), 5 (NP), and 8 (NS) are in linkage disequilibrium exclusively with North American swine influenza viruses, and segments 6 (NA) and 7 (M) are evolutionarily linked solely with Eurasian swine influenza viruses. Two North American swine strains and 2 Eurasian swine strains were identified as possible ancestors of S-OIV 2009. Based on the most recent linkage analysis with the updated influenza sequences, South Dakota avian strains were found to be the closest known relatives of S-OIV 2009.     

The genome sequence analysis of H5N1 avian influenza A virus isolated from the outbreak among poultry populations in Thailand

In this report, the genome of the Thai avian influenza virus A (H5N1); A/Chicken/Nakorn-Pathom/Thailand/CU-K2/04, isolated from the Thai avian influenza A (AI) epidemic during the early of 2004 was sequenced. Phylogenetic analyses were performed in comparison to AI viruses from Hong Kong 1997 outbreaks and other AI (H5N1) isolates reported during 2001-2004. Molecular characterization of the Thai AI (H5N1) HA gene revealed a common characteristic of a highly pathogenic AI (HPAI), a 20-codon deletion in the neuraminidase gene, a 5-codon deletion in the NS gene and polymorphisms of the M2 and PB2 genes. Moreover, the HA and NA genes of the Thai AI displayed high similarity to those of the AI viruses isolated from human cases during the same epidemic. Finally, our results demonstrated that the Thai AI emerged as a member of 2000's AI lineage with most of the genetic sequences closely related to the Influenza A/Duck/China/E319.2/03 (H5N1).     

一株鹅H5N1亚型流感病毒基因特性的分析

目的 弄清了Ａ／鹅／广东／２／９６（Ｈ５Ｎ１）毒株对鹅致病的分子生物学基础 ，研究香港区人群中发生的禽（Ｈ５Ｎ１）流感的病因，方法 病毒ＲＮＡ经逆转录合成ｃＤＮＡ经聚合酶链反应（ＰＣＲ）扩增，产物纯化，采用双脱链末端终止法测定核苷酸序列，结果 Ａ／鹅／广东／２／９６（Ｈ５Ｎ１）与Ａ／ＨＫ／１５６／９７（Ｈ５Ｎ１）毒株ＲＮＡ４核苷酸序列有２２个位点不同（同源性为９８．８％）无任何掉失或插入。它与人和     

Characterization of H9N2 influenza viruses isolated from Dongting Lake wetland in 2007

In 2007, a total of eight H9N2 influenza viruses were isolated from the water and fowl feces in Dongting Lake wetland, China. The genomes of the eight viruses were sequenced, and all eight gene segments were subjected to phylogenetic analysis. The results showed that all the isolates belonged to the same genotype, in which the HA, NA and NS gene segments were Chicken/Beijing/94-like; the PB2, PB1, PA and NP gene segments were Chicken/Shanghai/F/98-like; and the M gene was Quail/Hong Kong/G1/97-like. Animal experiments showed low pathogenicity of the selected viruses for chickens, although some chickens died after inoculation. The viruses showed no overt clinical signs in mice, but they could replicate in murine lungs prior to adaptation.     

Genetic analysis of influenza A/H3N2 and A/H1N1 viruses circulating in Vietnam from 2001 to 2006

Influenza A virus has the ability to overcome immunity from previous infections through the acquisition of genetic changes. Thus, understanding the evolution of the viruses in humans is important for the surveillance and the selection of vaccine strains. A total of 30 influenza A/H3N2 viruses and 35 influenza A/H1N1 viruses that were collected in Vietnam from 2001 to 2006 were used to analyze the evolution of the hemagglutinin (HA), neuraminidase (NA), and matrix protein (M) genes. Phylogenetic analysis of individual gene segments revealed that the HA and the NA genes of the influenza A viruses evolved in a sequential way. However, the evolutionary pattern of the M gene proved to be nonlinear and was not linked with that of the HA and NA genes. Genetic drift in HA1 segments, especially in the antigenic sites of A/H3N2 viruses, occurred more frequently in A/H3N2 viruses than it did in A/H1N1 viruses. Two reassortants, one influenza A/H3N2 strain and one A/H1N1 strain, were found on the basis of the phylogenetic analysis of the three genes. While both genetic mutation and reassortment contributed to their evolution, the frequency of genetic changes and reassortment events differs between the two subtypes. As influenza viruses circulate throughout the year, we emphasize the importance of surveillance in tropical and subtropical zones, where the emergence of new strains may be detected earlier than it is in temperate zones.     

Phylogenetic analysis of an H1N2 influenza A virus isolated from a pig in Korea

Summary. An influenza H1N2 virus was isolated from a pig during an severe outbreak of respiratory disease in a Korean herd. The neuraminidase (NA) and PB1 genes of the H1N2 isolate were of human origin, while the hemagglutinin (HA), matrix (M), nucleoprotein (NP), and non-structural (NS) genes were of swine origin and PA and PB2 gene were of avain origin. Phylogenetic results indicate that the Korean H1N2 isolate was closely related to H1N2 viruses isolated recently from pigs in the United States.     

Epidemiology and full genome sequence analysis of H1N1pdm09 from Northeast China

Pandemic influenza A (H1N1) 2009 virus (H1N1pdm09) was a novel tri-assortment virus that emerged in Mexico and North America in 2009 and caused the first influenza pandemic in the 21st century. This study investigated the prevalence pattern and molecular characteristics of H1N1pdm09 in three continuous years from April 2009 to March 2012 in populations of Tianjin, Northeast China. Totally, 3,068 influenza viruses (25.4 %) were detected from 12,089 respiratory specimens. Among them, 41.4 % (1,269/3,068) were H1N1pdm09 positive. 15.1 % (192/1,269) severe respiratory infection cases were H1N1pdm09 positive. H1N1pdm09 was the predominant prevalence subtype in October 2009–March 2010 (69.1 %, 930/1,346) and October 2010–March 2011 (42.1 %, 220/523). Eight isolated H1N1pdm09 viruses from severe infection/death cases in three different years were selected to sequence the whole genome through splicing the sequences following 46 PCRs. HA sequences of seven H1N1pdm09 isolates from mild infection cases were detected. Phylogenetic analysis showed that HA, NA, M, NP and NS genes of H1N1pdm09 viruses gathered together with swine influenza A (H1N1), whereas PB2 and PA genes originated from avian influenza virus, and PB1 gene originated from human seasonal influenza virus. Identity analysis indicated that all the genes were highly conserved. Compared with vaccine strain A/California/07/2009(H1N1), the maximal mutation gene was HA (0.7–2.6 %), then NA (0.6–1.7 %), last one was M (mutation rate 0–0.6 %). More site substitutions were observed in 2011 isolates than in 2009 and 2010 isolates of HA (p = 0.002), NA (p = 0.003) and PA (p = 0.001) proteins. The amino acid substitution rates were varied among eight gene segments, ranging from 7.39 × 10^?4 for PB2 to 7.40 × 10^?3 for NA. The higher d _N / d _S rates were observed in HA, PA and NS segments in H1N1pdm09 in Tianjin. Three HA amino acid site substitutions occurred at the HA receptor-binding sites and antigenic determinant, including S179N and K180T (located at antigenic site Sa) in A/Tianjinhedong/SWL44/2011(H1) and A/Tianjinjinnan/SWL41/2011(H1), and D239N (located at antigenic site Ca) in A/Tianjinninghe/SWL49/2009(H1). Antigenic drift may have occurred in H1N1pdm09 with time. No oseltamivir-resistance site substitution was observed at 275 and 295 sites. Amino acid residue site at 31 in M2 protein was N in all 8 isolates, which suggested that H1N1pdm09 was resistant to amantadine.     

Amplification of four genes of influenza A viruses using a degenerate primer set in a one step RT-PCR method

We designed a degenerate primer set that yielded full-length amplification of hemagglutinin (HA), neuraminidase (NA), matrix (M), and non-structural protein (NSP) genes of influenza A viruses in a single reaction mixture. These four genes were amplified from 15 HA (1–15) and 9 NA (1–9) subtypes of influenza A viruses of avian (n = 16) origin. In addition, 272 field isolates of avian origin were tested by this method. Full-length amplification of HA, NA, M, and NSP genes was obtained in 242 (88.9%), 254 (93.4%), 268 (98.5%), and 268 (98.5%) isolates, respectively. No gene was amplified in four isolates. Of these four isolates, two were subtyped as H4N6, one as H7N7, and one as H10N7. Amplification was successful for all 4 genes of H1N1, H2N3, and H3N2 isolates of swine influenza. Also, all four genes were amplified in one equine influenza (H3N8) isolate and seven isolates of human origin (H1N1 and H3N2). This appears to be the first study using degenerate primer set for full-length amplification of four genes of influenza A viruses in a single reaction. Further studies are needed to determine if this primer set can be used for subtyping of influenza virus isolates.     

Genetic characterization of the pathogenic influenza A/Goose/Guangdong/1/96 (H5N1) virus: similarity of its hemagglutinin gene to those of H5N1 viruses from the 1997 outbreaks in Hong Kong.

Analysis of the sequences of all eight RNA segments of the influenza A/G oose/Guangdong/1/96 (H5N1) virus, isolated from a sick goose during an outbreak in Guangdong province, China, in 1996, revealed that the hemagglutinin (HA) gene of the virus was genetically similar to those of the H5N1 viruses isolated in Hong Kong in 1997. However, the remaining genes showed greater similarity to other avian influenza viruses. Notably, the neuraminidase gene did no have the 19-amino-acid deletion in the stalk region seen in the H5N1 Hong Kong viruses and the NS gene belonged to allele B, while that of the H5N1 Hong Kong viruses belonged to allele A. These data suggest that the H5N1 viruses isolated from the Hong Kong outbreaks derived their HA genes from a virus similar to the A/Goose/Guangdong/1/96 virus or shared a progenitor with this goose pathogen.     

Genetic analysis of H3 subtype influenza viruses isolated from domestic ducks in northern China during 2004–2005

The broad distribution and prevalence of H3 subtype influenza viruses in avian and mammalian hosts constitutes a global threat to both human and veterinary health. In this present study, six H3N8 influenza viruses isolated from domestic ducks during 2004–2005 in northern China were genetically and phylogenetically characterized. Sequence analysis showed that HA, NA, and M genes of all the six H3N8 isolates had a close relationship with those of Equine/Jilin/1/89 (H3N8) virus, which once caused outbreak in equine populations in northern China. The PB2 and PA genes of the viruses possessed the highest similarities with highly pathogenic avian H5N1 influenza viruses currently circulating in this region. These findings emphasize the importance of avian influenza virus surveillance in this region for understanding the genesis and emergency of novel reassortants with pandemic potential.     

Polygenic virulence factors involved in pathogenesis of 1997 Hong Kong H5N1 influenza viruses in mice

Virulence factors of influenza A (H5N1) viruses collected in 1997 from mammalian hosts were examined using a BALB/c mouse model. Fifteen amino acid (aa) residues in four influenza virus genes which correlated with high- and low-pathogenic phenotypes in mice were identified by analyzing sequence alignments. In addition to these specific residues, the effects of aa residue 627 of the PB2 gene, and the hemagglutinin (HA) and neuraminidase (NA) genes were also investigated using a reverse genetics system established with representative viruses of low (A/Hong Kong/486/97) and high (A/Hong Kong/483/97) pathogenicity for mice. None of 15 aa residues alone had any effect on virulence. The HA and NA genes had a synergistic effect on virulence and the absence of a glycosylation site at aa154 in the HA gene also increased virulence of virus. Multiple genes are involved in virulence of Hong Kong H5N1 influenza A viruses for mice with the presence of lysine at aa627 in the PB2 gene exhibiting a significantly larger effect than the HA and NA genes.     

Characterization of An Avian Influenza Virus of Subtype H7N2 Isolated from Chickens in Northern China

An H7N2 avian influenza virus was isolated from chickens during routine surveillance in northern China in 2002. To understand the origin of this virus, we completely sequenced its genome. The PB1, PA, HA, and M genes of this virus were highly homologous with those of the wild bird virus A/Africa starling/Eng-Q/983/79 (H7N1). The NP and NS genes were closely related to those of two other wild bird viruses isolated 30 years ago. The closest relatives of the PB2 and NA genes of the virus were those of the A/swine/Germany/2/81 (H1NI) and A/Leningrad/134/57 (H2N2), respectively. Animal inoculation tests showed that the virus cannot replicate efficiently in chickens. However, after intranasal inoculation, the virus induced 20% weight loss and replicated well in the lungs of mice. The virus was also recovered from the hearts and brains of the mice. These results suggest that the influenza virus isolated in chickens in northern China in 2002 originated in wild birds and may pose a threat for both avian species and mammalian hosts.     

Human influenza a viral genes responsible for the restriction of its replication in duck intestine

Although influenza A viruses are occasionally transmitted from one animal species to another, their host range tends to be restricted. Currently circulating human influenza A viruses are thought to have originated from avian viruses, yet none of these strains replicate in duck intestine, a major site of avian virus replication. Although the hemagglutinin (HA) and neuraminidase (NA) genes are known to restrict human virus replication in ducks, the contribution of the other viral genes remains unknown. To determine the genetic basis for host range restriction of the replication of human influenza A virus in duck intestine, we first established a reverse genetics system for generating A/Memphis/8/88 (H3N2) (Mem/88) and A/mallard/New York/6750/78 (H2N2) (Mal/NY) viruses from cloned cDNAs. Using this system, we then attempted to generate reassortant viruses with various combinations of candidate genes. We were able to generate single-gene reassortants, which possessed PB2, NP, M, or NS from Mem/88, with the remainder from Mal/NY. Despite unsuccessful production of other single-gene reassortants from Mem/88, we did generate reassortant viruses comprised of both the HA and the NA, all three polymerase genes (PB2, PB1, and PA), or all polymerase genes and the NP gene from Mem/88, with the rest derived from Mal/NY. Among these reassortants, only those possessing the M or NS gene from Mem/88 and the remainder from Mal/NY replicated in duck intestine. These results indicate incompatibility between the genes of avian and human influenza A viruses and indicate that all genes other than the M and NS restrict replication of human influenza A virus in duck intestine.     

Molecular epizootiology of recurrent low pathogenic avian influenza by H9N2 subtype virus in Korea.

The first outbreak of low pathogenic avian influenza (LPAI), H9N2 virus subtype, in 1996 prompted an eradication response, but LPAI returned to Korea in 1999. The relationship between the first and the recurrent viruses is unclear. To determine the molecular epizootiology of recurrent LPAI, we performed phylogenetic analysis with partial nucleotide sequences of four gene segments (HA, NA, NP and PB2) from eight chicken-origin H9N2 viruses. The recurrent H9N2 viruses showed higher nucleotide similarity in haemagglutinin and neuraminidase genes to the 1996 Korean isolates than other Eurasian viruses, and formed a distinct cluster with the early Korean isolates and some isolates from migratory and domestic ducks in Japan and China. Phylogenetic analysis with internal genes showed that some Korean isolates formed a cluster with other subtypes, such as H5N1, H6N1, and H6N2 in China and Taiwan. These results suggest that the recurrent viruses are progeny of the early Korean H9N2 isolates, but further studies are required to explain their phylogenetic relatedness to viruses in China.     

流感病毒A/广州/333/99(H9N2)毒株基因组特性的研究

目的 了解一株再次从流感患儿中分离出禽H9N2流感毒株的基因组特性，并弄清它的来源。方法 病毒在鸡胚中传代，从收获的尿囊液中提取RNA，通过逆转录合成cDNA，cDNA用PCR扩增。PCR产物用纯化试剂盒纯化，接着做核苷酸序列测定，然后用Meg Align(Version 1.03)和Editseg(Version 3.69)软件进行基因进化树分析。结果 A／广州／333／99（H9N2）毒株的基因组属于禽流感病毒，但它明显不同于A／Duck/Hong Kong/Y439/97毒株。同时不含有任何人流感病毒基因节段，其基因组中有4个基因节段（分别编码HA、NA、NP和NS蛋白）来自G9毒株基因系，而其余4个基因节段（分别编码PB2、PB1、PA和M蛋白）来自G1毒株基因系。结论 A／广州／333／99（H9N2）病毒是G9和G1毒株通过基因重配而来的重配株，它最大可能性直接来自禽。进一步证实了禽H9N2毒株能感染人，同时首次证实了H9N2不同基因系毒株间，在自然界中也能发生基因重配。