NS1: A Key Protein in the "Game" Between Influenza A Virus and Host in Innate Immunity.

Since the influenza pandemic occurred in 1918, people have recognized the perniciousness of this virus. It can cause mild to severe infections in animals and humans worldwide, with extremely high morbidity and mortality. Since the first day of human discovery of it, the "game" between the influenza virus and the host has never stopped. NS1 protein is the key protein of the influenza virus against host innate immunity. The interaction between viruses and organisms is a complex and dynamic process, in which they restrict each other, but retain their own advantages. In this review, we start by introducing the structure and biological characteristics of NS1, and then investigate the factors that affect pathogenicity of influenza which determined by NS1. In order to uncover the importance of NS1, we analyze the interaction of NS1 protein with interferon system in innate immunity and the molecular mechanism of host antagonism to NS1 protein, highlight the unique biological function of NS1 protein in cell cycle.

Intranasal immunization with chitosan/pCAGGS-flaA nanoparticles inhibits Campylobacter jejuni in a White Leghorn model.

Campylobacter jejuni is the most common zoonotic bacterium associated with human diarrhea, and chickens are considered to be one of the most important sources for human infection, with no effective prophylactic treatment available. We describe here a prophylactic strategy using chitosan-DNA intranasal immunization to induce specific immune responses. The chitosan used for intranasal administration is a natural mucus absorption enhancer, which results in transgenic DNA expression in chicken nasopharynx. Chickens immunized with chitosan-DNA nanoparticles, which carried a gene for the major structural protein FlaA, produced significantly increased levels of serum anti-Campylobacter jejuni IgG and intestinal mucosal antibody (IgA), compared to those treated with chitosan-DNA (pCAGGS). Chitosan-pCAGGS-flaA intranasal immunization induced reductions of bacterial expellation by 2-3 log(10) and 2 log(10) in large intestine and cecum of chickens, respectively, when administered with the isolated C. jejuni strain. This study demonstrated that intranasal delivery of chitosan-DNA vaccine successfully induced effective immune response and might be a promising vaccine candidate against C. jejuni infection.

A reverse transcription-PCR for subtyping of the neuraminidase of avian influenza viruses.

To date, nine neuraminidase (NA) subtypes of avian influenza viruses have been identified. In order to differentiate the NA of avian influenza viruses rapidly, a reverse transcription PCR (RT-PCR) was developed. Nine pairs of NA-specific primers for the RT-PCR were designed based on the analysis of 509 complete NA sequences in GenBank. The primers were designed to amplify partial NA genes and each pair is unique to a single NA subtype (N1-N9). By nine RT-PCRs simultaneously in a set of separate tubes, the subtype of NA was determined by subsequent agarose gel electrophoresis and ethidium bromide staining, since only one of the nine RT-PCRs would give a product of expected size for each virus strain. In comparison with the established method of sequence analysis of 101 reference strains or isolates of avian influenza viruses, the RT-PCR method had a sensitivity of 97.3% and a specificity of 91.1% in subtyping avian influenza viruses. These results indicate that the RT-PCR method described below provides a specific and sensitive alternative to conventional NA-subtyping methods.

Comparison of virulence-associated traits between a UPEC strain HEC4 and a APEC strain E058.

Since avian pathogenic Escherichia coli (APEC) and human uropathogenic Escherichia coli (UPEC) may encounter similar challenges when establishing infection in the extra-intestinal locations of the hosts, they may share a similar content of virulence genes and capacity to cause disease. One APEC and one UPEC isolates were compared by their content of virulence genes and other traits. The two strains showed overlap in terms of their virulence genotypes, including their possession of certain genes associated with a large transmissible plasmid of APEC, and also shared some biochemical activities. Study of the pathogenicity of UPEC in chicks showed the similar symptoms and lesions compare to those caused by APEC. Based on these results, the potential whether APEC might serve as a reservoir of plasmid-linked and virulence genes for UPEC should be considered.

[Attenuation of a genotype VIId Newcastle disease virus ZJI strain of goose origin by reverse genetics].

Based on the complete genome sequence of Newcastle disease virus (NDV) ZJI strain isolated from an outbreak in the goose, seven pairs of primers were designed to amplify cDNA fragment for constructing the plasmid pNDV/ZJI, which contained the full-length cDNA of NDV ZJI strain. The pNDV/ZJI with three helper plasmids, pCI-NP, pCI-P and pCI-L, were then cotransfected into BSR-T7/5 cells expressing T7 RNA polymerase. After inoculation of the transfected cell culture supernatant into embryonated chicken eggs from specific-pathogen-free (SPF) flock, infectious NDV ZJI strain was successfully rescued. The recombinant plasmid pNDV/ZJIFM was generated by converting the multi-basic amino acid sequence of the F0 protein cleavage region in pNDV/ZJI to the non-basic amino acid sequence characteristic of avirulent NDV strain. After cotransfection of the resultant plasmid and the three helper plasmids into BSR-T7/5 cells, the recombinant NDV, NDV/ZJIFM, was generated. The mean death time (MDT) of NDV/ZJIFM was more than 120h and the intrancerebral pathogenicity index (ICPI) was 0.16, indicating that the rescued virus was highly attenuated. This attenuated genotype VIId NDV of goose origin could be a desirable vaccine in controlling the current epidemic of ND.

[Identification of APEC genes expressed in vivo by selective capture of transcribed sequences].

Direct screening of bacterial genes expressed during infection in the host is limited, because isolation of bacterial transcripts from host tissues necessitates separation from the abundance of host RNA. Selective capture of transcribed sequences (SCOTS) allows the selective capture of bacterial cDNA derived from infected tissues using hybridization to biotinylated bacterial genomic DNA. Avian pathogenic E. coli strain E037 (serogroup O78) was used in a chicken infection model to identify bacterial genes that are expressed in infected tissues. Three-week-old white leghorn specific-pathogen-free chickens were inoculated into the right thoracic air sac with a 0.1 mL suspension containing 10(7) CFU of APEC strain E037. Total RNA was isolated from infected tissues (pericardium and air sacs) 6 or 24h postinfection and converted to cDNAs. By using the cDNA selection method of selective capture of transcribed sequences and enrichment for the isolation of pathogen-specific (non-pathogenic E. coli K-12 strain ) transcripts, pathogen-specific cDNAs were identified. Randomly chosen cDNA clones derived from transcripts in the air sacs or pericardium were selected and sequenced. The clones, termed aec, contained numerous APEC-specific sequences. Among the distinct 31 aec clones, pathogen-specific clones contained sequences homologous to known and novel putative bacterial virulence gene products involved in adherence, iron transport, lipopolysaccharide (LPS) synthesis, plasmid replication and conjugation, putative phage encoded products, and gene products of unknown function. Overall, the current study provided a means to identify novel pathogen-specific genes expressed in vivo and insight regarding the global gene expression of a pathogenic E. coli strain in a natural animal host during the infectious process.

[Molecular mechanism affecting route of transmission for H9N2 subtype AIV].

The available evidence suggests that H9 subtype avian influenza virus (AIV) did not circulate in Chicken flocks in China until the early 1990s. However, the pandemic of H9 subtype AI, which started in summer of 1998, spread very rapidly to more than 20 provinces within several months. Obviously, the virus responsible for the 1998 pandemic was quite different from the virus isolated in early 1990s. In order to investigate the molecular mechanism affecting the route of transmission for H9N2 AIVs, strains of A/Chicken/Guangdong/SS/94 (H9N2) (SS) and A/Chicken/ Shanghai/F/98 (H9N2) (F) were compared in their route of transmission. SS strain representing the earlier strain was isolated in chickens in Guangdong province in 1994, whereas F strain was isolated in Shanghai during 1998 pandemic. The findings suggested that F strain could transmitted in chickens by direct contact and by aerosol route. Whereas SS strain only by direct contact, and neither of two viruses by fecal contact. The cDNAs derived from the HA and NA genes of SS strain were cloned into vector pHW2000 to construct two transcription/expression plasmids respectively, and the cDNAs derived from 8 genes of F strain was done in the same way. Three recombinants were generated by reverse genetics: RF7/SSHA with the HA gene from SS strain and the remaining seven genes from F strain, RF7/SSNA with the NA gene from SS strain and the remaining seven genes from F strain, and RF7/SSHA/SSNA with the HA and NA genes of SS strain and the remaining six genes from F strain. In order to identify three recombinants, a total of seven genes from them were amplified by using PCR with universal primer pairs of H9N2 influenza virus and sequenced. In addition, three recombinants were characterized by HA and HI tests and sequence analysis. The results indicated that three recombinants were successfully rescued by reverse genetics. To determine the genes associated with the ability to transmit by aerosol route in chickens, a set of transmission experiments were designed. Groups of three chickens were inoculated with equal dose of virus by oral, intratracheal and intranasal routes. Each group was placed in direct, aerosol or fecal contact with three uninoculated chickens. Virus isolation and identification showed that only the RF7/SSHA recombinant was transmitted from inoculated to uninoculated chickens by aerosol route, whereas three recombinants were transmitted by direct contact, but not by fecal contact. The results were further confirmed by HI test of serum samples from uninoculated chickens. The data suggest that the NA gene might be the major determinant of the ability of aerosol transmission for H9N2 subtype AIVs in chickens.

[The deletion of nucleotides of NS gene from 263 to 277 of H5N1 increases viral virulence in chicken].

Since 2000, more and more NS fragment of H5N1 subtype influenza A virus had a unique deletion of nuleotides from 263 to 277. In order to investigate the biological significance of the mutation, four recombinants, RWSN-848, RWSN-m848, RWSN-248 and RWSN-m248, were generated via eight-plasmid reverse genetic system. These reassortants had the same inner gene and outer gene derived from A/WSN/33(H1N1) and A/D/SD/04(H5N1), respectively. But their NS genes were different. RWSN-m248 and RWSN-848 were isogenic with RWSN-248 and RWSN-m848 respectively, except for the NS gene, the formers encoded a mutant NS with a deletion from 263 - 277 nucleotides. All of the four recombinants could grow well in embryonated chicken eggs and had the similar viral titer, EID50 and MDT. Infections were done with the same Multiplicity of infection (MOI, 0.001), and the viruses in supernatants from infected cells were titrated at 12, 24, 36, and 48 h post-infection by plaque assay in fresh MDCK. The results show that four viruses grown well and had the same viral title in Vero cell, a non-IFN-responsive cell system. But in MDCK and COS-1, the cell lines can produce IFN, RWSN-248 and RWSN-m848 had a higher viral titer (two fold) than RWSN-m248 and RWSN-848. It revealed that the deletion of nucleotides of NS from 263 - 277 of H5N1 influences decreases viral growth ability in IFN producing cell line. IVPI were done for the virulence test of reassorted H5N1 viruses. Ten six-week-old SPF White Leghorn chickens were inoculated intravenously with 0.2mL of a 1:10 dilution of allantoic fluid containing each of the four recombinant viruses. The chickens were daily monitored for disease signs and death for 10 days post-inoculation. Finally, IVPI was counted for each virus. RWSN-m248 caused 4 chickens died in 10 days and its index was 1.63. RWSN-248 only caused one chicken died and its index was 0.45. RWSN848 caused 3 chickens died in 10 days and its index was 0.81. RWSN-m848 caused one of the ten chickens died and its' index was only 0.175. The results revealed that the deletion of nucleotides of NS gene from 263 to 277 sites increases H5N1 pathogenesis in chicken.

[Establishment of reverse genetics system for H5N1 subtype AI].

H5N1 subtype influenza virus A/Duck/Shandong/093/2004 (A/SD/04) strain was chosen as the master strain for rescue research. 11 sets of primers for 8 plasmids construction were designed base on the sequencing of the full-length of A/SD/04. Eleven fragments of A/SD/04 were amplified by the designed primers and were ligated with PHW2000 for rescue plasmid construction. Eight transcription/expression plasmids were obtained, which encoded the eight segments of A/SD/04, and designated as 241, 242, 243, 244, 245, 246, 247 and 248, respectively. The COS-1 cell was cotransfected with eight plasmids with different combination of A/SD/04 and PR8. The eight reassortants shared the same HA (from A/SD/04) but contained different internal genes and NA. All of the eight reassorted viruses had some similar bio-characteristics, such as the viral title in fertilized eggs was range from 256 to 1024, the EID50 were between 10(-8.5) to approximately 10(-9), and MDT were between 34 to approximately 46h. But the IVPI of the eight reassortants was differently and all were lower than the wild-type A/SD/04. These results confirmed that different recombination of internal genes of H5N1 has influence on viral virulence to 6-week SPF chicken but not on viral replication ability in embryonated chicken eggs. The establishment of eight-plasmid rescue system for A/SD/04 is the base for farther research on genes function of H5N1. And A/SD/04 can be used as a backbone to replace PR8 entirely in generation of H5 AIV vaccine candidate.

[Recombinant fowlpox virus coexpressing HA and NA gene from subtype H5N1 of avian influenza virus and its protective efficacy].

The hemagglutinin (HA) and neuraminidase(NA)gene from subtype H5N1 avian influenza virus were directly inserted into the transferring vector pllS, resulting in the recombinant transferring vector p11SH5ANA. Then p11SH5ANA was transfected into the chicken embryo fibroblasts (CEF), which was pre-infected with wild type fowlpox virus, to generate the recombinant fowlpox virus coexpressing H5A and NA (rFPV-11SH5ANA). By selection of blue plaques on the CEF, rFPV-11SH5ANA was obtained and purified. Experiments on SPF chickens demonstrated that the HI antibody titers in chickens vaccinated with HA-NA coexpressed vaccine was higher than those with HA expressed monovalent vaccines, and all chickens receiving either rFPV-11SH5ANA or rFPV-11SH5A were completely protected from the virulent AIV(H5N1) challenge, while those receiving wt-FPV experienced 100% mortality. The results showed that the rFPV-11SH5ANA was a safe and highly efficient gene engineering vaccine candidate for preventing HPAI.

[Biological significance of amino acids deletion in NA stalk of H5N1 avian influenza virus].

It has been reported that NA gene of some H1N1 Influenza A virus strains isolated since 1933 is characterized by a deletion of 11 to 16 amino acids in the stalk. The spontaneous mutant in NA stalk of H1N1 virus lacks enzyme activity with large substrate (fetuin) but not with small substrate (sialyllactose). Recently, H5N1 virus also has been found that NA has the same unique mutation in the stalk, a deletion of 15 to 20 amino acids. However, biological significance of this mutation has not yet been reported. In order to investigate biological significance of the amino acids deletion in NA stalk of H5N1, five reassorted H5N1/PR8 viruses were generated via eight-plasmid based reverse genetics system. These five viruses were named 506, m506-, 646, m646+ and 196, respectively. The six internal genes of recombinants were all from A/PR8/34(H1N1), and HA gene was from A/G/JS/03(H5N1), however, they had different NA genes. 506 and m506- held NA fragments derived from A/G/HD/00(H5N1), and the former was distinguished with a longer NA which had no 20 amino acids deletion in the stalk. 646 and m646+ held NA fragments from A/G/JS/03(H5N1), and the NA stalk of m646+ was 20 amino acids longer than that of 646. The NA of 196 was derived from A/PR8/34 which had 15 amino acids deletion in its stalk. Biological characteristics of these viruses showed that recombinants with different NA length could grow well in embryonated SPF eggs, and their EID50, MDT, and viral titers were similar. However, the length of NA was related to the capacity of eluting viruses from erythrocytes for 506 and 646+ which holding longer NA stalks eluted from erythrocytes more quickly than m506-, 646 and 196 did. Moreover, 15 or 20 amino acids deletion in NA stalk had a pronounced effect on virus growth ability in MDCK cells. Viral titers in supernatant of MDCK infected with m506- or 646 were 10 to 100 folds higher than those infected by 506 or m646+. And the plaque size of m506- and 646 were larger than that of 506 and m646+. The results reveals that H5N1 AIV with amino acids deletion in NA stalk would expand its host range. The unique amino acids deletion in NA molecule of H5N1 may be associated with the adaptation of virus to terrestrial poultry or the increasing ability of interspecies transmission.

[Identification of genomic differences in avian pathogenic Escherichia coli using suppression subtractive hybridization analysis].

To identify unique DNA fragments associated with avian pathogenic Escherichia coli strains, suppression subtractive hybridization (SSH) was used. The genome of nonpathogenic E. coli K-12 strain MG1655 was subtracted from the genome of avian highly pathogenic strain E037 (serotype O78) resulting in the identification of 17 specific fragments. And the genome of avian low pathogenic E. coli strain E526 (serotype O2) was subtracted from the genome of avian highly pathogenic strain E058 (serotype O2) resulting in the identification of 32 specific fragments. Sequence homology analysis was done and four types of fragments were identified: plasmid sequences, phage sequences, sequences with known function and sequences without any currently known function. And 12 specific fragments that were not found in E. coli K-12 were identified from two avian E. coli strains. The results suggested that there were some genetic differences between the highly pathogenic strains and low pathogenic or nonpathogenic strains.

[Cloning of full-length genes of H5N1 subtype Avian influenza virus strain A/duck/Shandong/093/2004 and analysis of the sequences].

The eight full-length genes, including the 5' and 3' ends of H5N1 subtype Avian influenza virus (A/duck/ Shandong/093/2004) were amplified by using the universal primers and H5 specific primers. The method used for the amplification of Avian influenza virus's full-length sequence was more easily and rapidly than that of rapid amplification of cDNA ends assay (RACE). The amplified segments were cloned into the T vector PCR 2.1, respectively. Three to five positive clones of each gene were sequenced and the same two sequencing results of the full-length genes were obtained. The phylogenetic analysis results showed that all the eight segments of the A/duck/Shandong/093/2004 were different from the A/Quail/Hongkong/G1/97 and A/Chicken/Beijing/1/94, but showed highly similarity (99% and above) to that of four H5N1 strains, which were isolated in 2002 in duck. It revealed that this strain was resulted from re-assortment of H5N1 rather than H9N2. The NA sequence of A/D/SD/04 was analyzed and the result demonstrated that there are 20 amino acids missing in 48 - 68 sites, however, there was no residue lost in NS gene in 263 to 277 sites. The motif of HA cleavage site is PQRERRRKKR/G, which is the characteristic of HPAIV. The 226 amino acid residue was Met (M), which can react with both Aalpha-2, 3Gal and SAalpha-2, 6Gal receptor. And the 627 residue of PB2 was Glutamic acid (E). The result mentioned above confirmed that H5N1 subtype AIV has multiple determinants in its virulence. A/D/SD/04 is the mid-strain evolving from HPAIV to a virulent strain of mammal.

[Phylogenetic analysis of the surface glycoprotein genes of an aquatic bird origin influenza virus isolate A/Duck/Yangzhou/233/2002 (H6N2)].

Several H6 subtype avian A influenza viruses were isolated from aquatic birds in some live bird markets when we surveyed the ecology of the influenza in East China for more than two years and identified by specific RT-PCR. In this paper, the hemagglutinin (HA) and neuraminidase (NA) gene of one representative virus named A/Duck/Yangzhou/233/ 2002 (H6N2) (Dk/YZ/233/02) had been sequenced. Phylogenetic analysis of the H6 gene sequences available in the Influenza Sequence Database showed that the Dk/YZ/233/02 viruse cluster together with Dk/HK/3461/99 (H6N1) and Ck/Taiwan/na3/98 (H6N1). Phylogenetic analysis of the N2 NA genes of Dk/YZ/233/02 revealed that the NA gene of Dk/YZ/233/02 had genetically close relationships with that of H9N2 viruses isolated from duck in Japan and from chickens in South Korea, which were distinct from those of Ck/Beijing/94 (H9N2). The sequence of cleavage site between HA1 and HA2 of Dk/YZ/233/02 is P-Q-I-E-T-R-D, which was the typical characterization of the LPAIV.

[Influence of nonessential region on protective efficacy of recombinant fowlpox viruses].

Because of the interference of maternal antibodies, the recombinant fowlpox virus (rFPV) vaccine has not been used widely. The selection of a well-defined FPV nonessential region might be a desirable way to solve this problem. Two pairs of primers were designed according to the genome of a pathogenic FPV to amplify two flanking regions (FPV1 and FPV2) of the supposed nonessential region by PCR, and then a series of plasmid vectors were constructed to generate the expression vector pP12LS, which containing FPV1, FPV2, the expression cassette of P11-LacZ reporter gene and the promoter Ps. To abtain the vector pP12LSF, the F gene of ZJ1 strain Newcastle Disease Virus (NDV) was inserted into pP12LS, in which the F gene was located downstream of the promoter Ps. pP12LSF was transfected into chicken embryo fibroblast (CEF) pre-nfected with 282E4 strain FPV. The recombinant FPV, rFPV-FSC, was purified by blue plaque selection. The LacZ and F genes could be expressed by rFPV-FSC after 20 successive passages in CEF. The FPV nonessential region was the only difference between rFPV-FSC and rFPV-FSB. These two rFPVs could induce completely protection in SPF chickens against lethal challenge with F48E8 strain NDV. However, the protective efficacy showed a significant difference in commercial chickens with maternal antibodies. The protective efficacy of rFPV-FSC was 100% and rFPV-FSB was 61.54%. The results indicate that the selection of a well-defined FPV nonessencial region is an effective way to increase the protective efficacy of rFPVs, especially in chickens with maternal antibodies.

[Generation of A/Chicken/Shanghai/F/98 (H9N2) avian influenza virus from eight plasmids].

Eight-plasmid system was used for the generation of Avian influenza virus (AIV) strain A/Chicken/Shanghai/F/98 (H9N2) which was isolated in China in 1998. In this plasmid-based expression system, viral cDNA was inserted beteen the RNA polymerase I (pol I) promoter and terminator sequences. The entire pol I transcription unit was flanked by an RNA polymerase II (pol II) promoter and a poly (A) site. Twenty-four hours after the transfection of eight expression plasmid into cos1 cells, the supernatant and cos1 cells transfected were inoculated into the allantoic cavity of 10-day-old specific-pothgen-free (SPF) chicken eggs. The HA titer was determined after passage of the rescued virus in chicken eggs, and as high as that of the parental wild-type virus.

[Generation of attenuated H5N1 and H5N2 subtypes of influenza virus recombinants by reverse genetics system].

The HA connecting peptide at cleavage site, PQRERRKKR / GL, of an H5N1 subtype avian influenza virus (AIV) was replaced with PQRESR / GL, and then the modified HA gene was cloned into the transcription/expression vector, pHW2000, constructing a plasmid named pHW524-HA. The NA (N1) gene from the H5N1 virus and the NA (N2) gene from an H9N2 AIV were also cloned into pHW2000 separately, resulting in plasmids pHW506-NA and pHW206-NA. With the organization of pHW524-HA, pHW506-NA or pHW206-NA, and six plasmids containing internal genes from A/WSN/33 backbone virus, two transfectants, H5N1/WSN and H5N2/WSN, were subsequently generated by eight-plasmid system. After 15 consecutive passages in embryonated eggs, the two recombinants grew up to high titers of 1:2(9) in hemagglutination test with no changes in nucleotide sequences of the surface genes detected. Both the recombinant viruses belonged to mildly pathogen when evaluated by the pathogenicity test in six-week-old SPF chickens. H5N2/WSN recombinant virus was obviously less pathogenic than H5N1/WSN virus for embryonated chicken eggs. This presentation showed that the reverse genetics system is a very useful tool for studying the construction and function of individual genes and for the generation of virus as vaccine candidate.

[Construction of minigenome of Newcastle disease virus of goose origin and its preliminary application].

On the base of obtaining the full length genome sequence of a Newcastle disease virus (NDV) isolated from goose, the minigenome was constructed by replacing all the encoding region with the reporter gene of enhanced green fluorescent protein (eGFP), except the virus regulating sequences relating to replication, transcription and packing of virus genome. The reporter gene could be expressed after it was transfected into the HEp-2 cells infected with helper virus of NDV. This result indicated that the minigenome could be translated by the NDV NP, P and L proteins provided by helper virus. Furthermore, the support plasmids expressing NDV NP, P and L protein were constructed respectively and the function of these plasmids was identified using the minigenome. Additionally, the virus rescue system was optimized by changing the infection dose of the recombinant vaccinia virus expressing T7 RNA polymerase. The work mentioned above will accelerate greatly the rescue of NDV and other relative research.

[Safety and efficacy of attenuated Salmonella typhimurium harbouring DNA vaccine against Newcastle disease virus].

A pair of primers were designed and synthesized according to the previously published sequence of fusion protein (F) gene of Newcastle disease virus (NDV) and used to amplify F gene by reverse-transcription polymerase chain reaction (RT-PCR) from the genomic RNA of a NDV strain JS5 isolated from goose. The PCR product was identified by sequencing. Then recombinant eukaryotic expression vector pVAX1-F was constructed through inserting F gene into MCS of pVAX1. The recombinant plasmid pVAX1-F was transfected in COS-7 cells, and identified for the transient expression of F gene by indirect immunofluorescent assay. Finally, the recombinant plasmid was transformed into attenuated Salmonella typhimurium SL7207, and the recombinant was screened and designated as SL7207 (pVAX1-F). It was verified that SL7207 (pVAX1-F) as the oral NDV DNA vaccine was safe for chickens after oral immunization at dosage of 10(10) CFU or below. 1-day-old commercial ISA brown chickens were immunized orally with SL7207 (pVAX1-F) at two different dosages (10(9) CFU and 10(8) CFU) on day 1, 14 and 28. On day 7 after the last immunization, no significant difference was observed in the body weight between these two groups (p > 0.05), and also no significant difference between those two groups and negative control group (p > 0.05). Since there were maternal antibodies, high ELISA titers of serum antibodies against NDV were detected in the chickens of all groups on day 14. However, the levels of serum antibodies were decreased in the chickens of all groups on day 28, but the anti-NDV antibody response detected in the sera of chickens immunized with SL7207 (pVAX1-F) at the dosage of 10(9) CFU were increased and significantly higher than the response induced by immunization with SL7207 (pVAX1) on day 35 (p < 0.05). Intestinal mucosal immune response was observed in chickens immunized with SL7207 (pVAX1-F) at the dosage of 10(9) CFU or 10(8) CFU. The high ELISA titers of antibodies against NDV in small intestinal mucosal samples from immunized chickens were on day 28 and 35. After challenged intranasally with virulent NDV strain F48E8, the chickens immunized with SL7207 (pVAX1-F) at the dosage of 10(9) CFU could be protected with the protective rate of 77.27%, significantly higher than those with SL7207 (pVAX1) (p < 0.05). In summary, the DNA vaccine delivered by attenuated Salmonella typhimurium was safe and has good immunogenicity for chickens. A novel mucosal DNA vaccine was developed and could be useful for controlling the infection and epidemic of ND in the poultry.

[Generation of newcastle disease virus strain ZJI isolated from an outbreak in the goose using reverse genetics technique].

The full-length cDNA clone, NDV3GM122, and the three helperplasmids pCI-NP, pCI-P and pCI-L of Newcastle disease virus strain ZJI isolated from an outbreak in the goose were cotransfected into BSR-T7/5 cell expressing T7 RNA polymerase. Meanwhile, the full-length cDNA clone NDV3GM122 and the three helperplasmids, pCIneoNP, pCIneoP and pCIneoL which were derived from NDV strain La Sota, were also cotransfected into the cell, respectively. Indiect immunofluorescence assay (IFA) was performed 48 to 96 hours post-transfection using NDV HN-specific monoclonal anbtibody (McAb) 6B1 and bright stainings were found in the transfectants, indicating that the full-length clone was functional and the HN protein was expressed. The transfected cell and the supernatant were mixed well and thereafter the mixture was inoculated into specific pathogen free (SPF) chicken eggs. The allanotoic fluid of the injected eggs gave a positive hemagglutinin( HA) titer ranging from 16 to 32 in the secondary passage and increased to 128 in the third passage, which was same to the level of parent wild-type virus. The allantoic fluid containing the recovered NDV was analyzed in hemagglutination inhibition( HI) test by using McAb 6B1 and the specific inhibition was found. The typical morphology of the produced NDV was detected in the electronic microscope. The results mentioned above demonstrated that infectious NDV of strain ZJI was successfully generated, which laid good foundation for the further related research.