1.The expression of plasmid mediated afimbrial adhesin genes in an avian septicemic Escherichia coli strain.
Eliana Guedes STEHLING ; Tatiana Amabile CAMPOS ; Marcelo BROCCHI ; Vasco Ariston DE CARVALHO AZEVEDO ; Wanderley Dias DA SILVEIRA
Journal of Veterinary Science 2008;9(1):75-83
An Escherichia coli strain (SEPT13) isolated from the liver of a hen presenting clinical signs of septicaemia had a LD(50) of 4.0 x 10(5) CFU/ml in one-day-old chickens, expressed Ia, Ib, E1, E3, K and B colicins and aerobactin. The strain was ampicillin and streptomycin resistant, and found to have fimA, csgA and tsh DNA related sequences; it could adhere to and invade HEp-2 and tracheal epithelial cells, expressed fimbriae (observed by electron microscopy), and had five plasmids of 2.7, 4.7, 43, 56, and 88 MDa. Transposon mutagenesis of strain SEPT13, with transposon TnphoA, resulted in a mutant strain named ST16 that had a LD(50) of 1.2 x 10(12) CFU/ml. All other biological characteristics of strain ST16 were the same as those detected for strain SEPT13 except for the migration of an 88 MDa plasmid to the 93 MDa position indicating the insertion of the transposon into the 88 MDa plasmid. The 93 MDa plasmid of strain ST16 was transferred, by electroporation assay, to non-pathogenic receptor strains (E. coli strains K12 MS101 and HB101), resulting in transformant strains A and B, respectively. These strains exhibited adhesion properties to in vitro cultivated HEp-2 cells but did not have the capacity for invasion. The adherence occurred despite the absence of fimbriae; this finding suggests that the 88 MDa plasmid has afimbrial adhesin genes.
Adhesins, Escherichia coli/*genetics/*metabolism
;
Animals
;
Chickens
;
Escherichia coli/genetics/*metabolism
;
Gene Expression Regulation, Bacterial
;
Plasmids/*genetics/metabolism
;
Poultry Diseases/*microbiology
;
Sepsis/*microbiology
2.Expression patterns of influenza virus receptors in the respiratory tracts of four species of poultry.
Ji Eun YU ; Hakyoung YOON ; Hyun Jeong LEE ; Jong Hwan LEE ; Byung Joon CHANG ; Chang Seon SONG ; Sang Soep NAHM
Journal of Veterinary Science 2011;12(1):7-13
The primary determinant of influenza virus infectivity is the type of linkage between sialic acid and oligosaccharides on the host cells. Hemagglutinin of avian influenza viruses preferentially binds to sialic acids linked to galactose by an alpha-2,3 linkage whereas hemagglutinin of human influenza viruses binds to sialic acids with an alpha-2,6 linkage. The distribution patterns of influenza receptors in the avian respiratory tracts are of particular interest because these are important for initial viral attachment, replication, and transmission to other species. In this study, we examined the distribution patterns of influenza receptors in the respiratory tract of chickens, ducks, pheasants, and quails because these species have been known to act as intermediate hosts in interspecies transmission. Lectin histochemistry was performed to detect receptor-bearing cells. Cell-specific distribution of the receptors was determined and expression densities were compared. We observed species-, site-, and cell-specific variations in receptor expression. In general, receptor expression was the highest in quails and lowest in ducks. Pheasants and quails had abundant expression of both types of receptors throughout the respiratory tract. These results indicate that pheasants and quails may play important roles as intermediate hosts for the generation of influenza viruses with pandemic potential.
Animals
;
Cell Membrane/metabolism/virology
;
Hemagglutinin Glycoproteins, Influenza Virus/metabolism
;
Host-Pathogen Interactions
;
Influenza A virus/*metabolism
;
Influenza in Birds/metabolism/transmission
;
Lectins/metabolism
;
Poultry/metabolism/*virology
;
Poultry Diseases/metabolism
;
Receptors, Cell Surface/analysis/chemistry/metabolism
;
Receptors, Virus/*analysis/metabolism
;
Respiratory System/*chemistry
;
Sialic Acids/metabolism
;
Species Specificity
;
Specific Pathogen-Free Organisms
3.Isolation and phylogenetic analysis of hemagglutinin gene of H9N2 influenza viruses from chickens in South China from 2012 to 2013.
Han Qin SHEN ; Zhuan Qiang YAN ; Fan Gui ZENG ; Chang Tao LIAO ; Qing Feng ZHOU ; Jian Ping QIN ; Qing Mei XIE ; Ying Zuo BI ; Feng CHEN
Journal of Veterinary Science 2015;16(3):317-324
As part of our ongoing influenza surveillance program in South China, 19 field strains of H9N2 subtype avian influenza viruses (AIVs) were isolated from dead or diseased chicken flocks in Guangdong province, South China, between 2012 and 2013. Hemagglutinin (HA) genes of these strains were sequenced and analyzed and phylogenic analysis showed that 12 of the 19 isolates belonged to the lineage h9.4.2.5, while the other seven belonged to h9.4.2.6. Specifically, we found that all of the viruses isolated in 2013 belonged to lineage h9.4.2.5. The lineage h9.4.2.5 viruses contained a PSRSSRdownward arrowGLF motif at HA cleavage site, while the lineage h9.4.2.6 viruses contained a PARSSRdownward arrowGLF at the same position. Most of the isolates in lineage h9.4.2.5 lost one potential glycosylation site at residues 200-202, and had an additional one at residues 295-297 in HA1. Notably, 19 isolates had an amino acid exchange (Q226L) in the receptor binding site, which indicated that the viruses had potential affinity of binding to human like receptor. The present study shows the importance of continuing surveillance of new H9N2 strains to better prepare for the next epidemic or pandemic outbreak of H9N2 AIV infections in chicken flocks.
Animals
;
*Chickens
;
China
;
Hemagglutinin Glycoproteins, Influenza Virus/chemistry/*genetics/metabolism
;
Influenza A Virus, H9N2 Subtype/*genetics/metabolism
;
Influenza in Birds/virology
;
Phylogeny
;
Poultry Diseases/*virology
;
Sequence Analysis, RNA/veterinary
4.Identification of a new subgroup of avian leukosis virus isolated from Chinese indigenous chicken breeds.
Xin WANG ; Peng ZHAO ; Zhi-Zhong CUI
Chinese Journal of Virology 2012;28(6):609-614
In order to clarify Avian leukosis virus (ALV) characteristics from Chinese native chicken breeds, three ALV JS11C1, JS11C2 and JS11C3 were isolated from Chinese native breed "luhua" by inoculation of DF1 cell culture and detection of p27 antigen. Using PCR amplification of env gene, the amplified gp85 genes were analyzed and compared to all six chicken ALV subgroups reported. The gp85 genes of these three viruses were 1 005bp in length and encoded 335 amino acids, and the gp37 genes were 609bp and encoded 203 amino acids. The homology of gp85 among these three isolated strains was 91.9%-97.0%. Comparing to 18 stains of subgroup A, B, C, D, E published in GenBank, the homology was only in the range of 77.7%-84.6%, significantly lower than the gp85 homology observed within the common chicken subgroups A (88.2%-98.5%), B (91.6%-98.8%), and E (97.9%-99.4%). The gp85 homology compared with subgroup J was only 34.2%-36.5%. These results suggested that three isolated strains from Chinese native breed "luhua" belong to a new subgroup different from all six known subgroups from Chickens, and thus designated as subgroup K.
Animals
;
Avian Leukosis
;
virology
;
Avian Leukosis Virus
;
classification
;
genetics
;
isolation & purification
;
metabolism
;
Breeding
;
Chickens
;
genetics
;
virology
;
Molecular Sequence Data
;
Phylogeny
;
Poultry Diseases
;
virology
;
Viral Envelope Proteins
;
genetics
;
metabolism
5.Marek's disease virus can infect chicken brain microglia and promote the transcription of toll-like receptor 15 and 1LB genes.
Qing-li YANG ; Hao CHEN ; Ping WEI
Chinese Journal of Virology 2011;27(1):18-25
Microglial cells were purified from a mixed neuroglia culture prepared from the neonatal chicken brain in vitro, and were infected with the vvMDV YL040920 isolate and an attenuated MDV vaccine strain CVI988/Rispens, respectively. The presence of cytopathic effect (CPE) was examined daily, and the MEQ expression in MDV-infected microglia was detected by immunohistochemistry assay. DNA replication of the MDV meq gene and transcription of the gB gene were determined by real-time quantitative PCR (qPCR) and qRT-PCR, respectively. The transcripts of Toll-like receptor (TLR) mRNA in microglia post MDV infection were quantified by qRT-PCR. The results of this study showed that both vvMDV YL040920 and attenuated vaccine strain CVI988/Rispens could infect microglia and produce characteristic CPE with plaque formation. The plaques were formed due to cells shedding at multi-sites, then quickly expanded and integrated. Furthermore, the MEQ protein was detected in nuclei of YL040920 and CVI988/ Rispens-infected microglia, and MDV meq DNA replication and gB gene transcription in MDV-infected microglia were also confirmed. Although both MDV DNA copies and gB transcripts were increased in the virus-infected microglia, the higher viral DNA load and gB transcript were observed for CVI988/Rispens than for YL040920 in vitro (P < or = 0.05/0.001). The transcriptions of TLR15 and TLR1LB gene were found to be up-regulated in microglia following MDV infection in vitro. Purified microglia infected with YL040920 was observed increased TLR15 and TLR1LB transcripts as early as 1 day post infection (dpi), and reached its peak level at 3 dpi, then decreased mildly at 5 dpi. For CVI988/Rispens, it induced an increase of TLR15 transcript as early as 1 dpi, and rose rapidly at 3 dpi, and then decreased slightly at 5 dpi. At the same time, CVI988/Rispens induced the increase of chTLR1LB transcript at 3 dpi and decreased at 5 dpi. By comparing the TLRs transcription between YL040920 and CVI988/Rispens-infected microglia, it was suggested that vvMDV YL040920 might induce more TLR15 transcript than the attenuated vaccine strain CVI988/Rispens (P < or = 0.01/0.001), while CVI988/Rispens induced more TLR1LB transcript than YL040920 (P < or = 0.001).
Animals
;
Brain
;
metabolism
;
virology
;
Chickens
;
Gene Expression
;
Herpesvirus 2, Gallid
;
genetics
;
physiology
;
Marek Disease
;
genetics
;
metabolism
;
virology
;
Microglia
;
metabolism
;
virology
;
Poultry Diseases
;
genetics
;
metabolism
;
virology
;
Toll-Like Receptor 1
;
genetics
;
metabolism
;
Toll-Like Receptors
;
genetics
;
metabolism
;
Transcription, Genetic
6.Construction of subtractive cDNA libraries of the sporogony stage of Eimeria tenella by suppression subtractive hybridization.
Hong-Yu HAN ; Jiao-Jiao LIN ; Qi-Ping ZHAO ; Hui DONG ; Lian-Lian JIANG ; Xin WANG ; Jing-Fang HAN ; Bing HUANG
Chinese Journal of Biotechnology 2007;23(6):1005-1010
In order to clone and identify differentially expressed genes in the sporogony stage of Eimeria tenella, the cDNAs from unsporulated oocysts and sporulated oocysts of E. tenella were used as driver, respectively, the cDNAs from sporozoites of E. tenella was used tester, Two subtractive cDNA libraries of sporozoites were constructed by using the technique of suppression subtractive hybridization (SSH). the cDNAs from unsporulated oocysts was used driver, the cDNAs from sporulated ooceysts was used tester, one subtractive cDNA library of sporulated oocysts was constructed. PCR amplification revealed that the two subtractive cDNA libraries of sporozoites and one subtractive cDNA library of sporulated oocysts contained approximated 96%, 96% and 98% recombinant clones, respectively. Fifty positive clones were sequenced and analyzed in GenBank with Blast search from three subtractive cDNA libraries, respectively, thirteen unique sequences were found from the subtractive cDNA library of sporulated oocysts, eight ESTs shared significant identity with previously described. A total of forty unique sequences were obtained from the two subtractive cDNA libraries, nine ESTs shared significant identity with previously described, the other sequences represent novel genes of E. tenella with no significant homology to the proteins in Genbank. These results have provided the foundation for cloning new genes of E. tenella and further studying new approaches to control coccidiosis.
Animals
;
Chickens
;
parasitology
;
Coccidiosis
;
parasitology
;
veterinary
;
DNA, Protozoan
;
genetics
;
Eimeria tenella
;
genetics
;
physiology
;
Gene Expression Regulation
;
Gene Library
;
Nucleic Acid Hybridization
;
methods
;
Oocytes
;
metabolism
;
Poultry Diseases
;
parasitology
;
Spores
7.The relationship of virus load, receptor expression and tumor spectrum in layer chickens infected by ALV-J.
Li-ming CAI ; Zhen-zhen WANG ; Yan-ming WANG ; Yan wei SHEN ; Rong-rong WEI ; Zi-qiang CHENG
Chinese Journal of Virology 2013;29(5):515-521
Abstract:Subgroup J avian leukosis virus (ALV-J) infect cells by binding to the chNHE1 receptor protein of the host and causes tumors. The tumor incidence of the ALV-J-infected chickens was observed by histo pathology, and virus was isolated on DF-1 cell line. The ALV-J load and mRNA of chNHElreceptor protein were detected by real time PCR. The relationship between ALV-J load, chNHE1 receptor expression levels and tumor spectrum was analyzed. The results showed that the tumors induced by ALV-J in laying hens and local lines of chicken were different. No significant relationship was observed between ALV-J load and tumor spectrum. ALV-J load was positively correlated with mRNA expression of chNHE1. The mRNA expression of chNHE1 increased when the tumors occurred. Our results suggest the chNHE1 protein is not only the receptor of ALV-J infected host but also play an important role in the process of tumor development. This study provides a scientific basis for further studying of oncogenic mechanism of ALV-J.
Animals
;
Avian Leukosis
;
genetics
;
metabolism
;
virology
;
Avian Leukosis Virus
;
genetics
;
physiology
;
Chickens
;
genetics
;
metabolism
;
Poultry Diseases
;
genetics
;
metabolism
;
virology
;
Receptors, Virus
;
genetics
;
metabolism
;
Sodium-Hydrogen Exchangers
;
genetics
;
metabolism
;
Viral Load
8.Lentivirus Delivery of the Short Hairpin RNA Targeting NDV P Gene Inhibits Production of the Newcastle Disease Virus in Chicken Embryo Fibroblasts and Chicken Embryos.
Shaohua YANG ; Chuantian XU ; Lin ZHANG ; Yanyan HUANG ; Qinghua HUANG ; Beixia HU ; Xiumei ZHANG
Chinese Journal of Virology 2016;32(1):39-45
Small interfering ribonucleic acid (siRNA)-induced RNA degradation can inhibit viral infection, and has been investigated extensively for its efficacy as antiviral therapy. The potential therapeutic role of lentiviral-mediated short hairpin ribonucleic acid (shRNA) to Newcastle disease virus (NDV) replication in vivo has been explored less often. We constructed two recombinant lentiviral vectors containing shRNA against the phosphoprotein (P) of the NDV, RNAi-341 and RNAi-671. Recombinant shRNA lentivirus vectors were co-transfected into 293T cells, along with helper plasmids, to package the recombinant shRNA lentivirus. Lentivirus-based shRNAs were titrated and transduced into NDV-susceptible chicken embryo fibroblasts (CEFs) and chick embryos. Antiviral activity against the NDV strain was evaluated by virus titration and real-time reverse transcription-polymerase chain reaction. RNAi-341 and RNAi-671 strongly suppressed transient expression of a FLAG-tagged P fusion protein in 293T cells. RNAi-341 and RNAi-671 NDV reduced virus titers by 66.6-fold and 30.6-fold, respectively, in CEFs 16 h after infection. RNAi-341 and RNAi-671 reduced virus titers in specific pathogen-free chick embryos by 99% and 98%, respectively, 48 h after infection. Both shRNAs inhibited accumulation of not only P-gene mRNA, but also nucleocapsid, M-, F-, HN-, and L-gene mRNA. RNAi-341 silenced P-gene mRNA more potently than RNAi-671. These results suggest that shRNAs silencing the P gene had substantial antiviral properties and inhibited NDV replication in CEFs and chick embryos.
Animals
;
Chick Embryo
;
Chickens
;
Down-Regulation
;
Fibroblasts
;
virology
;
Gene Targeting
;
Lentivirus
;
genetics
;
metabolism
;
Newcastle Disease
;
virology
;
Newcastle disease virus
;
genetics
;
physiology
;
Phosphoproteins
;
genetics
;
metabolism
;
Poultry Diseases
;
virology
;
RNA Interference
;
RNA, Small Interfering
;
genetics
;
metabolism
;
Viral Proteins
;
genetics
;
metabolism
;
Virus Replication
9.Construction and biological characteristics of H5N1 avian influenza viruses with different patterns of the glycosylation sites in HA protein.
Xiao-jian ZHANG ; Yan-fang LI ; Li-ping XIONG ; Su-juan CHEN ; Da-xin PENG ; Xiu-fan LIU
Chinese Journal of Virology 2013;29(5):495-499
The distribution of glycosylation sites in HA proteins was various among H5 subtype avian influenza viruses (AIVs), however, the role of glycosylation sites to the virus is still unclear. In this study, avian influenza H5N1 viruses with deletion of the glycosylation sites in HA were constructed and rescued by site direct mutation and reverse genetic method, and their biological characteristics and virulence were determined. The result showed that the mutants were confirmed to be corrected by HA gene sequencing and Western blot analysis. The EID50 and TCID50 tested in SPF chick embryo and MDCK cells of a mutant rSdelta158 with deletion of glycosylation site at position 158 were slight lower than that of wild type rescued virus rS, and the plaque diameter of rSdelta158 was significant smaller than that of rS. The EID50 and TCID50 of mutants rSdelta169 and rSdelta290 with deletion of glycosylation sites at position 169 and 290, respectively, were slight higher than that of wild type rescued virus rS, the plaque diameters of rSdelta169 and rSdelta290 were similar as that of rS, but the plaque numbers of rSdelta169 and rSdelta290 were 10-fold higher than that to rS. On the other hand, the rSdelta158, rSdelta169 and rSdelta290 showed similar growth rate in chicken embryo fibroblast as rS. All viruses remained high pathogenicity to SPF chickens. Therefore, the growth of AIV can be affected by changes of glycosylation sites in HA protein, by which the effect is variable in different cells.
Amino Acid Motifs
;
Animals
;
Cell Line
;
Chick Embryo
;
Chickens
;
Glycosylation
;
Hemagglutinin Glycoproteins, Influenza Virus
;
chemistry
;
genetics
;
metabolism
;
Influenza A Virus, H5N1 Subtype
;
chemistry
;
genetics
;
growth & development
;
metabolism
;
Influenza in Birds
;
virology
;
Poultry Diseases
;
virology
10.Rescue of the recombinant infectious bronchitis virus with the ectodomain region of H120 spike glycoprotein.
Yan-quan WEI ; Hui-chen GUO ; Hai-ming WANG ; De-hui SUN ; Shi-chong HAN ; Shi-qi SUN
Chinese Journal of Virology 2014;30(6):668-674
To explore the expression potential of heterogeneous genes using the backbone of infectious bronchitis virus (IBV) Beaudette strain, the ectodomain region of the Spike gene (1,302 bp) of IBV H120 strain was amplified by RT-PCR and replaced into the corresponding location of the IBV Beaudette strain full-length cDNA. This recombinant was designated as BeauR-H120(S1). BeauR-H120(S1) was directly used as the DNA template for the transcription of viral genomic RNA in vitro. Then, the transcription product was transfected into Vero cells by electroporation. At 48 h post-transfection, the transfected Vero cells were harvested, and passaging continued. A syncytium was not observed until the recombinant virus had passed through four passages. The presence of rBeau-H120(S1) was verified by the detection of the replaced ectodomain region of the H120 Spike gene using RT-PCR. Western blot analysis of rBeau-H120 (S1)-infected Vero cell lysates demonstrated that the nucleocapsid (N) protein was expressed, which implied that rBeau-H120(S1) could propagate in Vero cells. The TCIDs0 and EIDs0 data demonstrated that the titer levels of rBeau-H120(S1) reached 10(590+/-0.22)TCID50/mL and 10(6.13+/-0.23)EID50/mL in Vero cells and 9-day-old SPF chicken embryos, respectively. Protection studies showed that the percentage of antibody-positive chickens, which were vaccinated with rBeau-H120(S1) at 7 days after hatching, rose to 90% at 21 days post-inoculation. Inoculation provided an 85% rate of immune protection against a challenge of the virulent IBV M41 strain (103EID50/chicken). This recombinant virus constructed using reverse genetic techniques could be further developed as a novel genetic engineering vaccine against infectious bronchitis.
Animals
;
Cercopithecus aethiops
;
Chick Embryo
;
Chickens
;
Coronavirus Infections
;
veterinary
;
virology
;
Infectious bronchitis virus
;
chemistry
;
genetics
;
growth & development
;
metabolism
;
Poultry Diseases
;
virology
;
Protein Structure, Tertiary
;
Spike Glycoprotein, Coronavirus
;
chemistry
;
genetics
;
metabolism
;
Transfection
;
Vero Cells