Astragalus polysaccharide enhances immunity and inhibits H9N2 avian influenza virus in vitro and in vivo

This study investigated the humoral immunization of Astragalus polysaccharide （APS） against HgN2 avian influenza virus （H9N2 AIV） infection in chickens. The effects of APS treatment on H9N2 infection was evaluated by an Mqq- [3（4, 5-dimethylthiazol-2-yl）-2, 3-diphenyl tetrazolium bromide] assay and analysis of MFIC and cytokine mRNA expression. The effect on lymphocyte and serum antibody titers in vivo was also investigated. IL-4, IL-6, IL-10, LITAF, IL-12 and antibody titers to H9N2 AIV wet enhanced in the first week after APS treatment. The results indicated that APS treatment reduces H9N2 AIV replication and promotes early humoral immune responses in young chickens.This study investigated the humoral immunization of Astragalus polysaccharide （APS） against HgN2 avian influenza virus （H9N2 AIV） infection in chickens. The effects of APS treatment on HgN2 infection was evaluated by an M]q- [3（4, 5-dimethylthiazol-2-yl）-2, 3-diphenyl tetrazolium bromide] assay and analysis of MHC and cytokine mRNA expression. The effect on lymphocyte and serum antibody titers in vivo was also investigated. IL-4, IL-6, IL-10, LITAF, IL-12 and antibody titers to PIgN2 AIV were enhanced in the first week after APS treatment. The results indicated that APS treatment reduces HgN2 AIV replication and promotes early humoral immune responses in young chickens.

Genetic Variation Analysis on the Whole Genomic Sequence of a H9N2 Subtype Avian Influenza Virus Isolate

A Objective3 This study was to understand the genetic variation characters of the H9N2 subtype avian influenza virus isolate （A/Chicken/ Hebei/WD/98, abbreviated as WD98） by comparing with other reference strains. I-Method3 Eight complete genes were amplified by RT-PCR and sequenced. The homology and genetic evolution relationship were analyzed between these sequences and that of the seven reference strains. [Result] The whole genomic sequence of WD98 strain was 91.1% -95.8% homologous to that of seven reference strains tested. This isolate shared the highest homology （95.8%） to D/HK/Y280/97 and the lowest homology （91.1% ） to C/Pak/2/99. The HA cleavage site of the WD98 strain was R-S-S-R G, and the 226th amino acid at receptor-binding site was Gin. [ Condmion] WD98 strain belongs to mildly pathogenic avian in- fluenza virus and may not infect human. The genetic relationship is the closest between A/Chicken/Hebei/wD/98 and A/duck/HongKong/Y280/ 97, both of which belong to the sub-line of A/Chicken/Beijing/1/94 in Eurasian line. And A/Chicken/Hebei/WD/98 and A/Chicken/Beijing/1/94 are genetically distant within the same sub-line.

Subtype Identification of Avian Influenza Virus on DNA Microarray

We have developed a rapid microarray-based assay for the reliable detection of H5, H7 and H9 subtypes of avian influenza virus （AIV）. The strains used in the experiment were A/Goose/Guangdong/1/96 （H5N1）, A/African starling/983/79 （H7N1） and A/Turkey/Wiscosin/1/66 （H9N2）. The capture DNAs clones which encoding approximate 500-bp avian influenza virus gene fragments obtained by RT-PCR, were spotted on a slide-bound microarray. Cy5-labeled fluorescent cDNAs, which generated from virus RNA during reverse transcription were hybridized to these capture DNAs. These capture DNAs contained multiple fragments of the hemagglutinin and matrix protein genes of AIV respectively, for subtyping and typing AIV. The arrays were scanned to determine the probe binding sites. The hybridization pattern agreed approximately with the known grid location of each target. The results show that DNA microarray technology provides a useful diagnostic method for AIV.

Strengthened Monitoring of H5 Avian Influenza Viruses in External Environment in Hubei, 2018

The contamination status of H5 avian influenza viruses and distribution of subtypes of H5N1 and H5N6 in poultry-related environment of Hubei areas were investigated.Urban and rural live poultry markets,poultry farms,intensive livestock farms and other monitoring types of 103 counties in 17 cities were selected in Hubei.Wiping samples from cage surface,wiping samples from chopping board,fecal specimens and other environmental samples were collected and tested by real-time RT-PCR using primers and probes of influenza A,avian influenza of H5,N1 and N6 from December 2017 to March 2018.The avian influenza virus positive rate was compared among different monitoring sites,samples,time and regions.Totally,7132 environmental samples were collected in 1634 monitoring points with a positive rate of 2.24%.The positive rate of H5 avian influenza virus was the highest in urban and rural live poultry markets(3.44%,x^2=61.329,P<0.05)in 6 monitoring sites and wiping samples from chopping board(5.46%,x^2=67.072,P<0.05)in 6 sample types.H5N6 avian influenza viruses were detected more in eastern than western Hubei,and H5N6 avian influenza viruses were detected only in Xiangyang city of western Hubei.There were important high-risk places of human infection with H5 avian influenza virus in urban and rural live poultry markets and the poultry slaughtering plants.H5N6 has been the predominant subtype of H5 avian influenza viruses in the eastern and western Hubei and H5N6 avian influenza viruses were still present in a few areas of Hubei.Outbreaks of human H5N1 and H5N6 avian influenza remain at risk in Hubei province.

The Protection Efficacity of DNA Vaccine Encoding Hemagglutinin of H5 Subtype Avian Influenza Virus

The DNA vaccine pCIHA5 encoding hemagglutinin can protect SPF chicken against lethal H5N1 avian influenza virus challenge. The more characters about its protection efficacity were studied. The protective rates in 10, 40, 70, 100 and 150 μg groups immunized with pCIHA5 were 12.5 (1/8), 58.3 (7/12), 72.7 (8/11), 50.0 (6/12) and 66.7% (8/12), respectively. The protective rates in 5, 20, 35 and 50 μg groups were 145.5 (5/11), 58.3 (7/12), 58.3 (7/12) and 91.7% (11/12), respectively. The 70, 100 and 5 μg groups have virus shedding of 1/8, 2/6 and 1/5. Though the inactived oil-emulsion vaccine has high HI antibody titers and 100% protective rate, the AGP antibody could be detected after vaccination. Results show that the pCIHA5 is fit to boost by intramuscular injection. This would be useful to the study on gene engineering vaccine of avian influenza virus.

HA Gene Variation Analysis of H9N2 Sub-type Avian Influenza Virus from Three Strains in Different Times

HA Gene of H9N2. sub-type avian influenza virus from three strains in different times was amplified, purified and then sequenced. The results of its sequence analysis showed that the whole length of the amplified HA Gene was 1 683 bp, encoding 560 amino acids. The amino acid sequence of three virulent strains at cleavage site was R-S-S-R, which was low-pathogenicity strain. According to the amino acid sequence of the isolated strains, there were 7 potential glycosylation sites, and the receptor-binding site was the specific sequence of the avian-derived influenza virus. Amino acids on the left edge of receptor-binding site were all NGQQG, while amino acids on the right edge of receptor-binding site were GTSKA. From the comparative sequence analysis of HA Gene from some referenced strains, the results indicated that nucleotide and amino acid homology between isolated strains and referenced strains was higher. Evolutionary tree analysis showed that three strains were all Eurasian species, and there was a close relationship with the representative strains of A / duck / Hong Kong/Y280/97.

Phylogenetic and Molecular Analysis of an H7N7 Avian Influenza Virus Isolated in East Dongting Lake in 2012

Objective In March 2012, an H7N7 subtype avian influenza virus （AIV） named A/wild goose/Dongting/PC0360/2022 （H7N7） （DT/PC0360） was recovered from a wild goose in East Dongting Lake. We performed whole-genome sequencing of the isolate, and analyzed the phylogenetic and molecular characterization. Methods RNA was extracted from environment samples （including fecal samples from wild bird or domestic ducks, and water samples） for detecting the presence of Influenza A Virus targeting Matrix gene, using realtime RT-PCR assay. The positive samples were performed virus isolation with embryonated eggs. The subtype of the isolates were identified by RT-PCR assay with the HI-HI6 and N1-N9 primer set. The whole-genome sequencing of isolates were performed. Phylogenetic and molecular characterizations of the eight genes of the isolates were analyzed. Results Our results suggested that all the eight gene segments of DT/PC0360 belonged to the Eurasian gene pool, and the HA gene were belonged to distinct sublineage with H7N9 AIV which caused outbreaks in China's Mainland in 2013. The hemagglutinin cleavage site of HA of DT/PC0360 showed characterization of low pathogenic avian influenza virus. Conclusion Strengthening the surveillance of AlVs of wild waterfowl and poultry in this region is vita for our knowledge of the ecology and mechanism of transmission to prevent an influenza pandemic.

Distribution of Avian Influenza A Viruses in Poultry-Related Environment and Its Association with Human Infection in Henan, 2016 to 2017

Objective To survey avian influenza A viruses(AIVs) in the environment and explore the reasons for the surge in human H7 N9 cases.Methods A total of 1,045 samples were collected from routine surveillance on poultry-related environments and 307 samples from human H7 N9 cases-exposed environments in Henan from 2016 to2017. The nucleic acids of influenza A(Flu A), H5, H7, and H9 subtypes were detected by real-time polymerase chain reaction.Results A total of 27 H7 N9 cases were confirmed in Henan from 2016 to 2017, 24 had a history of live poultry exposure, and 15 had H7 N9 virus detected in the related live poultry markets(LPMs). About 96%(264/275) Flu A positive-environmental samples were from LPMs. H9 was the main AIV subtype(10.05%) from routine surveillance sites with only 1 H7-positive sample, whereas 21.17% samples were H7-positive in H7 N9 cases-exposed environments. Samples from H7 N9 cases-exposed LPMs(47.56%)had much higher AIVs positive rates than those from routine surveillance sites(12.34%). The H7+H9 combination of mixed infection was 78.18%(43/55) of H7-positive samples and 41.34%(43/104) of H9-positive samples.Conclusion The contamination status of AIVs in poultry-related environments is closely associated with the incidence of human infection caused by AIVs. Therefore, systematic surveillance of AIVs in LPMs in China is essential for the detection of novel reassortant viruses and their potential for interspecies transmission.

A duplex RT-PCR assay for detection of H9 subtype avian influenza viruses and infectious bronchitis viruses

H9 s ubtype avian influenza virus（AIV） and infectious bronchitis virus（IBV） are major pathogens circulating in poultry and have resulted in great economic losses due to respiratory disease and reduced egg production. As similar symptoms are elicited by the two pathogens, it is difficult for their differential diagnosis. So far, no reverse transcription-polymerase chain reaction（RT-PCR） assay has been found to differentiate between H9 AIV and IBV in one reaction. Therefore, developing a sensitive and specific method is of importance to simultaneously detect and differentiate H9 AIV and IBV. In this study, a duplex RT-PCR（d RT-PCR） was established. Two primer sets target the hemagglutinin（HA） gene of H9 AIV and the nucleocapsid（N） gene of IBV, respectively. Spec ific PCR products were obtained from all tested H9 AIVs and IBVs belonging to the major clades circulating in China, but not from AIVs of other subtypes or other infectious avian viruses. The sensitivity of the d RT-PCR assay corresponding to H9 AIV, IBV and mixture of H9 AIV and IBV were at a concentration of 1×10^1, 1.5×10^1 and 1.5×10^1 50% egg infective doses（EID_（50）） m L^–1, respectively. The concordance rates between the d RT-PCR and virus isolation were 99.1 and 98.2%, respectively, for detection of samples from H9N2 AIV or IBV infected chickens, while the concordance rate was 99.1% for detection of samples from H9N2 AIV and IBV co-infected chickens. Thus, the d RT-PCR assay reported herein is specific and sensitive, and suitable for the differential diagnosis of clinical infections and survei llance of H9 AIVs and IBVs.

Immune Efficacy of a Recombinant Fowlpox Virus Co-Expressing HA and NA Genes of Avian Influenza Virus in SPF Chickens

A recombinant fowlpox virus co-expressing Haemagglutinin (HA) and Neuraminidase (NA)named as rFPV-HA-NA was produced by HA and NA gene of A/Goose/Guangdong/3/96(H5N1)isolate of avian influenza virus recombined into the genome of fowlpox virus. In thisstudy, to evaluate its ability of protecting chickens against challenge with a lethaldose of highly pathogenic isolates of avian influenza virus, eight-week-old specific-pathogenic-free (SPF) chickens were vaccinated with recombinant virus or the wildtypefowlpox virus by wing-web puncture. After challenge 4 weeks with 10 LD50 highly pathogenicavian influenza virus H5N1 and H7N1 isolate, all chickens vaccinated with recombinantvirus were protected, while the chickens vaccinated with the wildtype fowlpox virus orunvaccinated controls experienced 100% mortality respectively following challenge. Thiscomplete protection was accompanied by the high levels of specific antibody response tothe respective components of the recombinant virus.

Localization of Avian Influenza Virus in Formalin-Fixed, Paraffin-Embedded Chicken Tissues by In Situ Hybridization

In this study, in situ hybridization （ISH） was developed to detect avian influenza＇virus （AIV） in Madin-Darby canine kidney （MDCK） cells and formalin-fixed, paraffin-embedded chicken tissues. A cDNA probe corresponding to a region of AIV nucleoprotein （NP） gene was synthesized and labeled with digoxigenin. Probe specificity was determined by AIV infected MDCK cells in vitro and the results showed that strong cytoplasmic staining was only detected in AIV-infected cells. Various tissues were collected from 12 h to 35 days post-infection （PI） following inoculation with the H9N2 subtype A1V. AIV was localized in the epithelial cells of the duodenum and cartilage of the throat and trachea at 12 h PI. Tissues from uninfected chickens were negative. The finding of this study indicated ISH was a sensitive and specific technique to detect and localize AIV as well as to study AIV pathogenesis.

Preparation of Monoclonal Antibodies against Hemagglutinin of Avian Influenza Virus H9 Subtype by Plasmid Immunization

Avian influenza has caused enormous economic losses to poultry industry. To develop kits for rapid diagnosis of avian influenza virus （AIV） H9 subtype, 8-week-old Balb/c mice were administered with pcDNA3.1 （ ＋ ） carrying hemagglutinin （HA） gene of AIV H9 subtype. After cell fusion, one positive hybridoma cell strain was screened out by hemagglutination inhibition assay （ HI ）, and another positive hybddoma call strain was screened out by ELISA. After subcloning 3 times, the two cell strains could still secret antibodies against the HA of AIV H9 subtype. The mono- clonal antibodies did not react with Newcastle disease virus, AIV H5 subtype and duck adenovirus A. Their subtypes were IgG2b with kappa light chain. These two hybridoma cell strains may play an important role in rapid diagnosis and early-warning surveillance of AIV H9 subtype.

Genetic Analysis of the Entire Genome of a A/duck/Shanghai/Y20/2006 (H4N6) Avian Influenza Virus

[ Objective] This paper aimed to investigate the origin, characteristics and molecular evolution of duck derived H4N6 subtype avian influ- enza virus （DK/SH/Y20/06） and enrich the epidemiologic data of the waterfowl origin AIV. [Method] The entire genome of DK/SH/Y20/06 was amplified and subjected to genome sequencing. The molecular software was used for sequence analysis and phylogenetic tree construction of DK/ SH/Y20/06 with some other reference sequences in GenBank. [Result] The results indicated that the amino acid sequence adjacent to HA cleav- age site was PEKASR ↓ GLF, which was the typical characteristics of the LPAIV. The phylogenetic analysis indicated that the HA gene of the isolate was derived from the Eurasian lineage in the eastern hemisphere. The NA gene was at the same branch with A/rnallard/Yan chen/2005（ H4N6）, sharing 98.3% sequence identity. The PB2, PB1, NP and PA gene of this isolate had genetically close relationships with H6 subtype AIV which is epidemic in China at present. The M gene fell into the same branch with A/environment/Korea/CSM05/2004（ H3N1 ）. The NS segment had the highest similarity with A/wild duck/Korea/YS44/2004（H1N2）. The eight genes were not at the same branch and shared a low similarity with other H4N6 subtype avian influenza viruses isolated in North America. [Condusion] These data showed that DK/SH/Y20/06（H4N6） was possibly a re- combinant virus derived from H4N6 subtype, H6N2, H6N5, H3N1 and H1 N2 subtype AIV by complex gene recombination in duck.

Monitoring Report of Maternal Antibody of Broiler Avian Influenza Virus H5 Subtype Re-8 Strain

[ Objective ] The paper was to prevent the occurrence of broiler avian influenza virus HS subtype Re-8 strain effectively in the breeding process of broilers. [Method] The maternal antibodies of broilers in Beijing Baochen Hongwang farm were monitored. According to the disappearance law of maternal antibody, the optimal immune time of broiler avian influenza virus H5 subtype Re-8 strain was determined. [ Result] The maternal antibody level of 2-day-old broilers was relatively high, concentrated at 6 log2 -9 log2, and the antibody positive rate was 100%. The maternal antibody level of 8-day-old broilers concentrated at 4 log2 -6 log2, and the antibody positive rate was 100%. The maternal antibody level of 17-day-old broilers concentrated at 0 log2 -3 log2 , and the antibody positive rate was 0. The average maternal antibody level of 24 - 37 days old broilers was 〈 1 log2, and the antibody positive rate was 0. [ Conclusion ] Although the av- erage maternal antibody level of 8-day-old broilers was higher than 5 log2 , 20% of chickens was 4 log2, and maternal antibody could not protect the flock completely. Therefore, the best primary immunization day age of chicks against avian influenza virus was 8 - 10 days of age.

Effects of Trypsin on Proliferation of Avian Influenza Virus H9N2 Subtype in MDCK Cells

[Objective] The study aims to determine the optimal concentration of trypsin for the proliferation of avian influenza virus （AIV） H9N2 subtype in Madin- Darby canine kidney （MDCK） cells. [Method] Three AIV H9 subtype isolates were inoculated on MDCK cells respectively. Then, DMEM containing different concentrations of trypsin as maintenance media were added to MDCK monolayer cells. The cytopathic effect （CPE） was observed once every 24 h, and the HA titer of the supematant was measured by HA assay. [Result] When the trypsin concentration was 10 -20 μg/ml in DMEM, the HA titer of virus culture reached 7 log2 （1：128）. Almost all cells were cytopathic after 96 h post inoculation with 1：1 000 or 1：10 000 dilution of AIV culture, and the virus titer reached a peak after 72 -96 h. [ Conclusion] The optimal concentration of trypsin is 10 -20 pg/ml for proliferation of AIV H9N2 subtype in MDCK cells.

Development of Neural Network for BLSOM Clustering of HA Genes of Avian Influenza Viruses Isolated in Guangdong Province

A neural network classification method,and a batch-learning self-organizing map(BLSOM),was established using trinucleotide and tetranucleotide in the hemagglutinin gene sequences of 25 avian influenza viruses isolated in Guangdong Province. Statistical analysis and normalization of the fragment number were done and MATLAB function was used to simulate the human brain thinking for self-organizing learning. When the number of training steps was 100 and above,the strains could be successfully clustered. H_1,H_3,H_5,H_7 and H_9 subtype strains fell within different classes,respectively,and the HA gene cluster map of H_3N_2 and H_7N_9strains was quite similar,suggesting that these strains shared the same origin; H_5N_1 strain was quite different in different years; H_1N_1 and H_9N_2 strains could be clustered into one group,indicating the natural recombinant variation in the two kinds of viruses,thereby providing a reference for high-risk strain screening and traceability.

Multiplication of the Recombinant Strain Re-7 of Avian Influenza Virus Subtype H5 in MDCK Cells

This study was conducted to explore the multiplication pattern of the recombinant strain Re-7 of avian influenza virus subtype H5 in Madin Darby Canine Kidney （MDCK） cells and to determine the optimal multiplicity of infection （MOI） and the optimal time for virus harvest. The recombinant strain Re-7 was inoculated at different MOIs into MDCK cells grown in serum-free medium in 100 L bioreactors for replication. Then, the hemagglutination（HA） titer, 50% tissue culture infectious dose （TCID50） and 50% embryo infectious dose （EID50） of culture medium were measured once every 12 h from 24 h after virus inoculation to determine the optimal MOI. After that, virus was inoculated at the optimal MOI determined above into MDCK cells for large-scale virus replication to determine the optimal time for virus harvest. The results showed that the optimal MOI was 10 2, and the optimal time for virus harvest was 60 h after inoculation. Under these conditions, the HA titer, TCIDso per 1 mL and EIDso per 0.1 mL were increased to 1：102 4, 10^7.33 and 10^6.83, respectively. This study provides relatively stable parameters for large-scale production of the recombinant strain Re-7 of avian influenza virus subtype H5.

Effect of Different Culture Media on the Proliferation of Avian Influenza Virus H9 Subtypes in MDCK Cells

[Objective] To screen the best culture media for the proliferation of avian influenza virus （AIV） H9 subtypes in MDCK cells. [Method] The DMEM containing 10% （V/V） newborn calf serum, low-serum containing medium （ MEM-MD-611 ） and serum-free medium （SFE4Mega） were used to culture the MDCK monolayer ceils, which were then inoculated with different dilutions of AIV H9 subtypes, and the 3 kinds of media were al- so used as the maintenance solution to culture the virus. The cytopathic changes were observed at every 24 h, and the HA titers of the culture su- pernatants were also determined. [ Result] After culturing for 72 -96 h, the HA titers of the serum-free media were higher than that of low-serum culture media, while the HA titers were higher in the low-serum media than in the serum containing media. [ Conclusion] The 3 kinds of media can all used for the proliferation of AIV_ but the low-serum culture medium （MEM-MD-611 ） and serum-free medium （SFE4Meaa3 are preferred.

Development and Assessment of Two Highly Pathogenic Avian Influenza(HPAI) H5N6 Candidate Vaccine Viruses for Pandemic Preparedness

Objective In China, 24 cases of human infection with highly pathogenic avian influenza(HPAI) H5 N6 virus have been confirmed since the first confirmed case in 2014. Therefore, we developed and assessed two H5 N6 candidate vaccine viruses(CVVs).Methods In accordance with the World Health Organization(WHO) recommendations, we constructed two reassortant viruses using reverse genetics(RG) technology to match the two different epidemic H5 N6 viruses. We performed complete genome sequencing to determine the genetic stability. We assessed the growth ability of the studied viruses in MDCK cells and conducted a hemagglutination inhibition assay to analyze their antigenicity. Pathogenicity attenuation was also evaluated in vitro and in vivo.Results The results showed that no mutations occurred in hemagglutinin or neuraminidase, and both CVVs retained their original antigenicity. The replication capacity of the two CVVs reached a level similar to that of A/Puerto Rico/8/34 in MDCK cells. The two CVVs showed low pathogenicity in vitro and in vivo, which are in line with the WHO requirements for CVVs.Conclusion We obtained two genetically stable CVVs of HPAI H5N6 with high growth characteristics,which may aid in our preparedness for a potential H5N6 pandemic.

Multiple RT-PCR Detection of H5,H7,and H9 Subtype Avian Influenza Viruses and Newcastle Disease Virus

Objective:This paper focuses on the multiple detection RT-PCR technology of H5,H7,AND H9 subtype avian influenza viruses and Newcastle disease virus,and points out the specific detection methods and detection procedures of avian influenza and Newcastle disease virus.Methods:The genes of Newcastle disease virus carrying out the HA gene sequence of H5,H7 and H9 subtype AIV in GenBank were used to establish a strategy for simultaneous detection of three subtypes of avian influenza virus and Newcastle disease virus.Results:The results showed that the program can detect and distinguish H5,H7 and H9 subtype avian influenza viruses and Newcastle disease virus at one time.Conclusion:Multiple RT-PCR detection method has high detection sensitivity and can detect and determine different subtypes of avian influenza virus and Newcastle disease virus quickly and accurately,therefore,it has a crucial role in the detection and control of avian influenza H5,H7 and H9 subtypes and Newcastle disease.