Newcastle Disease Virus In Chickens Research Articles

Integrated analysis of genes and long non-coding RNAs in trachea transcriptome to decipher the host response during Newcastle disease challenge in different breeds of chicken

Newcastle disease is a highly infectious economically devastating disease caused by Newcastle disease Virus in Chicken (Gallus gallus). Leghorn and Fayoumi are two breeds which show differential resistance patterns towards NDV. This study aims to identify the differentially expressed genes and lncRNAs during NDV challenge which could play a potential role in this differential resistance pattern. A total of 552 genes and 1580 lncRNAs were found to be differentially expressing. Of them, 52 genes were annotated with both Immune related pathways and Gene ontologies. We found that most of these genes were upregulated in Leghorn between normal and challenged chicken but several were down regulated between different timepoints after NDV challenge, while Fayoumi showed no such downregulation. We also observed that higher number of positively correlating lncRNAs was found to be downregulated along with these genes. This shows that although Leghorn is showing higher number of differentially expressed genes in challenged than in non-challenged, most of them were downregulated during the disease between different timepoints. With this we hypothesize that the downregulation of immune related genes and co-expressing lncRNAs could play a significant role behind the Leghorn being comparatively susceptible breed than Fayoumi. The computational pipeline is available at https://github.com/Venky2804/FHSpipe.

Role of Macrophages in the Pathogenesis of Genotype VII Newcastle Disease Virus in Chickens

Long-term evolution of Newcastle disease virus (NDV) results in substantial alteration in viral pathogenesis. NDVs of genotype VII, a late genotype, show marked tropism to lymphoid tissues, especially to macrophages in chickens. However, the role of macrophages in the pathogenesis of genotype VII NDV is still unclear. Herein, NDV infectivity in macrophages and the role of macrophages in the pathogenesis of genotype VII NDV in chickens were investigated. We reported that NDV strains of genotype VII (JS5/05) and IV (Herts/33) can replicate in the adherent (predominantly macrophages) and non-adherent cells (predominantly lymphocytes) derived from chicken peripheral blood mononuclear cells (PBMCs), and significantly higher virus gene copy was detected in the adherent cells. In addition, JS5/05 had significantly higher infectivity in PBMC-derived adherent cells than Herts/33, correlating with its enhanced tropism to macrophages in the spleen of chickens. Interestingly, the depletion of 68% of macrophages exerted no significant impact on clinical signs, mortality and the systematic replication of JS5/05 in chickens, which may be associated with the contribution of non-depleted macrophages and other virus-supportive cells to virus replication. Macrophage depletion resulted in a marked exacerbation of tissue damage and apoptosis in the spleen caused by JS5/05. These findings indicated that macrophages play a critical role in alleviating tissue damage caused by genotype VII NDV in chickens. Our results unveiled new roles of macrophages in NDV pathogenesis in chickens.

Effect of humic acid and probiotics on immunity of broiler chickens.

The immune system in chickens has a fundamental role in controlling many diseases based on vaccination, thus enhancement of the immune system response is a priority. The aim of this experiment was to study the effect of probiotics and humic acid on immunity of broiler chickens. Day-old 300 Ross broiler chicks were segregated into 5 groups of 60 chicks per group. Group C was considered as a control. Groups T1, T2, T3, and T4 were given probiotics, antibiotics, humic acid for the first 7 days and humic acid for 42 days, respectively. Samples were collected on days 27 and 42 to assess the humoral immunity, cellular immunity, lymphoid organs weight, and differential leucocyte count (DLC). The results showed a significant increase (p < 0.05) in antibodies titer against Newcastle disease virus in chickens given humic acid (T4) daily for 42 days as compared to the control. There was also a significant increase in antibodies titer in the T1 group given probiotic for the first week lasting up to day 27 as compared to the control. The skin thickness of T4 group showed a significant increase as compared to T1 and T2 groups after 24 hours of DNCB challenge. After 48 hours, the thickness was still significantly higher in the T4 group as compared to other groups except for the control. There were no significant differences in Bursa of Fabricius/Body weight (%) between the groups. Spleen/Body weight (%) was significantly higher in the control group and T1 than the other groups on day 42. The DLC remains normal in all groups. It is concluded that the humic acid has a stimulant and strengthening effect on the humoral and cellular immune system when given daily to broiler chickens. Moreover, the use of humic acid and probiotics with good hygiene in the first week of age may alternate the use of antibiotics which could be toxic and raise bacterial resistance.

Evolutionary Trajectories of Avian Avulaviruses and Vaccines Compatibilities in Poultry.

Newcastle disease virus (NDV) causes one of the highly infectious avian diseases in poultry leading to genuine financial misfortunes around the world. Recently, there has been an increasing trend in the number of ND-associated outbreaks in commercial Jordanian poultry flocks indicating a possible complex evolutionary dynamic of NDV infections in the country. To underpin the dynamics of circulating NDV strains and to assess the vaccine-escape potential, a total of 130 samples were collected from different poultry flocks in six Jordanian Governorates during 2019-2021. Twenty positive isolates, based on real-time reverse transcriptase PCR, were used for further genetic characterization and evolutionary analysis. Our results showed that there is a high evolutionary distance between the newly identified NDV strains (genotype VII.1.1) in this study and the commercially used vaccines (genotypes I and II), suggesting that circulating NDV field strains are under constant evolutionary pressure. These mutations may significantly affect flocks that have received vaccinations as well as flocks with insufficient immunity in terms of viral immunity and disease dynamics. To assess this further, we investigated the efficacy of the heterologous inactivated LaSota or homologous genotype VII.1.1 vaccine for their protection against virulent NDV in chicken. Vaccine-induced immunity was evaluated based on the serology, and protection efficacy was assessed based on clinical signs, survival rates, histopathology, and viral shedding. Chickens vaccinated with the inactivated genotype VII.1.1 based vaccine showed 100% protection with a significant reduction in virus shedding, and ameliorated histopathology lesions compared to LaSota vaccinated chicks that showed 60% protection. These results revealed that the usage of NDV inactivated vaccine from the circulating field strains can successfully ameliorate the clinical outcome and virus pathobiology in vaccinated chicks and will serve as an effective vaccine against the threat posed by commonly circulating NDV strains in the poultry industry.

Foreign gene expression attenuates a virulent Newcastle disease virus in chickens.

Newcastle disease virus (NDV) is an important pathogen for poultry and is used as a vector for developing novel poultry vaccines. Previous studies showed that foreign gene insertion in NDV vector decreases virulence determined by in vitro assays; however, the impact of foreign gene expression on the pathogenicity of NDV in susceptible chickens is not fully investigated. In this study, a recombinant NDV based on a velogenic strain carrying the orange fluorescent protein (OFP) gene between the phosphoprotein (P) and matrix (M) genes was generated using reverse genetics. Biological characteristics, including virus replication, virulence, and OFP expression, and the pathogenicity in chickens were evaluated. The recombinant NDV showed comparable replication capacity in eggs and cells as the parental virus, whereas OFP insertion resulted in a mild impairment of virulence, evidenced by longer mean death time in embryos. High OFP expression was detected in the cells inoculated with the recombinant NDV. In addition, the recombinant NDV induced delayed onset of disease, lower severity of clinical signs, and lower mortality in chickens compared to the parental virus. Moreover, high titers of the parental virus were detected in the spleen, lung, and intestinal tract, while no recombinant NDV was recovered from these tissues. Our findings suggest that in vitro characteristics related to the insertion of the OFP gene in a virulent NDV do not correlate to alteration of the pathogenicity in chickens. Our results provided new information regarding assessment of the impact of foreign gene expression on the pathogenicity of NDV.

In silico Prediction of Molecular Docking between Chicken BRD2 and Newcastle Disease Virus Matrix Protein to Elucidate Host-pathogen Interaction

Background: Newcastle disease is one of the most contagious viral diseases caused by the Newcastle disease virus (NDV) which causes a huge loss in the terms of economy as well as mortality level in the poultry sector. The viral matrix protein is one of the proteins which helps in the attachment of virus, budding and assembly of progeny virions in the host cell. Host-pathogen interaction plays a very important role in the changeover of genetic diversity in organisms. Methods: The amino acid sequences of chicken BRD2 gene and matrix protein of NDV were used for structure prediction and visualization of protein-protein interaction between BRD2 and matrix protein by using Discovery Studio software. The nucleotide sequences of both genes were used for evolutionary analysis using MEGA7 software followed by selection pressure analysis using online Datamonkey server. Result: The results indicated that the ligand was attached with the matrix protein, which acts as a receptor on the virus surface. The purifying selection has been evident for the viral matrix protein gene. The docking of viral protein with host BRD2 protein has been detected in the study which further warrants experimental validation. In conclusion, the viral matrix protein interacts at amino acid position Tyrosine-148, Valine-339, Alanine-341 with ligand present on the chicken BRD2 protein. The evolutionary analysis revealed that the matrix protein of NDV R2B strain was the closest to that of Peacock, pigeon, duck and quail however, it exhibited maximum distance with the chicken NDV from Ireland, Vietnam and Haryana state of India.

Indicators of the molecular pathogenesis of virulent Newcastle disease virus in chickens revealed by transcriptomic profiling of spleen

Newcastle disease virus (NDV) has caused significant outbreaks in South-East Asia, particularly in Indonesia in recent years. Recently emerged genotype VII NDVs (NDV-GVII) have shifted their tropism from gastrointestinal/respiratory tropism to a lymphotropic virus, invading lymphoid organs including spleen and bursa of Fabricius to cause profound lymphoid depletion. In this study, we aimed to identify candidate genes and biological pathways that contribute to the disease caused by this velogenic NDV-GVII. A transcriptomic analysis based on RNA-Seq of spleen was performed in chickens challenged with NDV-GVII and a control group. In total, 6361 genes were differentially expressed that included 3506 up-regulated genes and 2855 down-regulated genes. Real-Time PCR of ten selected genes validated the RNA-Seq results as the correlation between them is 0.98. Functional and network analysis of Differentially Expressed Genes (DEGs) showed altered regulation of ElF2 signalling, mTOR signalling, proliferation of cells of the lymphoid system, signalling by Rho family GTPases and synaptogenesis signalling in spleen. We have also identified modified expression of IFIT5, PI3K, AGT and PLP1 genes in NDV-GVII infected chickens. Our findings in activation of autophagy-mediated cell death, lymphotropic and synaptogenesis signalling pathways provide new insights into the molecular pathogenesis of this newly emerged NDV-GVII.

The role of live chicken markets as a source of replication and dissemination of Newcastle disease virus in chickens, northwest Ethiopia

Newcastle disease (ND) is perceived to be the major constraint in village chickens of Ethiopia causing huge economic loss. Village chickens are mobile and pass through markets, and live chicken markets are a highly productive source of ND virus replication, maintenance, and spread. However, in northwest of Ethiopia, there is a dearth of information on the role of live chicken markets in the maintenance and spread of ND in the village chickens. Therefore, a total of 480 apparently healthy chickens in the 4 live chicken markets were sampled with the aim to detect and estimate ND virus infection. Tracheal and cloacal swabs were collected from each bird and processed for virus isolation in 9- to 11-day-old embryonated chicken eggs, and hemagglutination inhibition (HI) assay was performed on all sera samples. The overall infection rate of ND virus was reported to be 39.2% (95% CI: 34.8–43.5). Of all chickens, 34.6% (95% CI: 30.3–38.9) had mean HI titer ≥4 log2, which was considered as protective. The mean hemagglutination titer for the ND virus was reported to be 6.0 log2, and mean antibody titer was reported to be 6.2 log2, with no statistically significant variation among the markets (P > 0.05). Newcastle disease occurrence was detected in all seasons of the year in the live bird markets, with the highest prevalence (55.8%) during the prerainy dry season (April and May), showing evidence for climatic and socioeconomic aspects as a risk factor in the occurrence of ND in indigenous chicken. In vivo virulence tests, mean death time of the embryo, and the intracerebral pathogenicity index revealed the presence of all pathotypes of ND virus strains: velogenic, mesogenic, and lentogenic. Apparently, healthy appearing birds were reported to be reservoirs of velogenic ND virus strains that could initiate endemicity of ND cycles in the village setting. Hence, it is strongly recommended to implement appropriate prevention and control measures to mitigate the economic loss caused by the disease.

Comparative pathogenicity of two closely related Newcastle disease virus isolates from chicken and pigeon respectively

Newcastle disease (ND), caused by virulent Newcastle disease virus (NDV), is a highly contagious disease that has led to tremendous economic losses worldwide. Pigeon paramyxovirus type 1 (PPMV-1) is an antigenic and host variant of NDV. However, limited in-depth studies are available concerning side-by-side comparison of pathogenicity of PPMV-1 and its phylogenetically close NDV both in chickens and pigeons. To this end, two phylogenetically closely related NDV isolates, Kuwait 256 and JS/07/04/Pi from chicken and pigeon respectively were pathotypically and genotypically characterized in this study. The results indicated that Kuwait 256 was a velogenic strain, while JS/07/04/Pi was a mesogenic strain based on the mean death time of chick embryos (MDT) and intracerebral pathogenicity index in 1-day-old chicks (ICPI). Pathogenicity tests showed that Kuwait 256 caused severe clinical signs and 100 % mortality, while JS/07/04/Pi caused no apparent disease in chickens. Interestingly, both Kuwait 256 and JS/07/04/Pi caused morbidity and mortality in pigeons. Notably, pigeons infected with JS/07/04/Pi exhibited viral shedding for longer time compared to Kuwait 256-infected pigeons. Collectively, the findings of this study suggested that PPMV-1 decreased the pathogenicity in chickens but gained a survival advantage over NDV of chicken origin after its adaptive variation in pigeons based on the previous evidence that PPMV-1 originated from chicken-origin viruses. This study laid the foundation for the elucidation of the molecularmechanism underlying difference in pathogenicity of PPMV-1 and chicken-origin NDV in chickens.

Establishment of reverse transcription recombinase–aided amplification-lateral-flow dipstick and real-time fluorescence–based reverse transcription recombinase–aided amplification methods for detection of the Newcastle disease virus in chickens

Newcastle disease is an acute and highly contagious disease of poultry caused by Newcastle disease virus infection, which does great harm to the poultry industry all over the world. To diagnose the disease simply and quickly, 2 detection methods were established based on reverse transcription recombinase–aided amplification (RT-RAA) technology. One is reverse transcription recombinase–aided amplification-lateral flow dipstick (RT-RAA-LFD) that is to combine RT-RAA with lateral flow dipstick; the other is real-time fluorescence-based reverse transcription recombinase–aided amplification (RF-RT-RAA) that is the combination of RT-RAA and exo probe. In this study, the reaction conditions such as reaction temperature and reaction time of the 2 methods were optimized, and their specificity and sensitivity were tested. The results showed that the RT-RAA-LFD method could be used to complete reaction within 23 min, and its lowest detectable limit was 102 copies/μL, 10 times higher than that of the conventional PCR method (103 copies/μL); the RF-RT-RAA method could be used to complete reaction within 26 min, and its lowest detectable limit was 10 copies/μL, 100 times higher than that of conventional PCR method (103 copies/μL), and it was as sensitive as real-time fluorescence–based quantitative PCR (10 copies/μL). The 2 methods had no cross reaction to the nucleic acid of other avian pathogens and showed good specificity. A total of 86 clinical samples suspected of the Newcastle disease virus were tested by conventional PCR, real-time fluorescence–based quantitative PCR, RT-RAA-LFD, and RF-RT-RAA. Based on the commonly used conventional PCR method, the other 3 detection methods had a coincidence rate of higher than 93%. In summary, RT-RAA-LFD and RF-RT-RAA had high specificity, sensitivity, and efficiency, which were suitable for clinical and laboratory diagnosis, respectively, and provided technical support for the prevention and control of Newcastle disease.

Effect of Toll Like Receptor Agonists on Adaptive Immune Response Generated Against Newcastle Disease Virus in Chicken

Effect of Toll Like Receptor Agonists on Adaptive Immune Response Generated Against Newcastle Disease Virus in Chicken

Seroprevalence and detection of newcastle disease virus matrix gene in domestic local breed of chickens from eight communities in Bauchi State, Nigeria

Indigenous breed of domestic chickens have been identified as an appropriate tool for eradication poverty and hunger because of the ease at which poor people can acquire, grow and consume or sale the meat and eggs of these animals. The production of these chickens is largely constrained by disease especially, velogenic Newcastle disease (ND) which have the potential of wiping out an entire susceptible chicken population. Foundational to the control of ND in local breed of chickens in every community is the need for baseline information. Such information is scanty in Bauchi State even though the state is one of the major producers of these chickens in Nigeria. The aim of this study is to determine the seroprevalence of ND and also detect Newcastle disease virus (NDV) for the purpose of understanding the presence and distribution of the disease in the State. This study was conducted among 1085 village chickens from nine (9) randomly selected communities in Bauchi State, Nigeria. The seroprevalence of ND by Haemagglutination inhibition test was 36.4%. Matrix gene of ND virus (NDV) was also detected from 29.9% of 281 pooled cloacal swabs of the same chickens. The result indicates that ND virus (NDV) and its antibodies were widespread among village chickens in these communities. Vaccination is suggested as an appropriate control measure to protect chickens against a possible attack by a velogenic strain of NDV in chickens from these communities.Keywords: Newcastle disease, seroprevalence, molecular detection, domestic breed of local chickens, Bauchi State

Recombinant Newcastle Disease Virus (NDV) Expressing Sigma C Protein of Avian Reovirus (ARV) Protects against Both ARV and NDV in Chickens.

Newcastle disease (ND) and avian reovirus (ARV) infections are a serious threat to the poultry industry, which causes heavy economic losses. The mesogenic NDV strain R2B is commonly used as a booster vaccine in many Asian countries to control the disease. In this seminal work, a recombinant NDV strain R2B expressing the sigma C (σC) gene of ARV (rNDV-R2B-σC) was generated by reverse genetics, characterized in vitro and tested as a bivalent vaccine candidate in chickens. The recombinant rNDV-R2B-σC virus was attenuated as compared to the parent rNDV-R2B virus as revealed by standard pathogenicity assays. The generated vaccine candidate, rNDV-R2B-σC, could induce both humoral and cell mediated immune responses in birds and gave complete protection against virulent NDV and ARV challenges. Post-challenge virus shedding analysis revealed a drastic reduction in NDV shed, as compared to unvaccinated birds.

Phylogeny, pathogenicity and transmissibility of a genotype XII Newcastle disease virus in chicken and goose.

Although Newcastle disease virus (NDV) has a worldwide distribution, some NDV genotypes have more regional geographical ranges within continents. In this study, we isolated a subgenotype XIIb NDV strain, Goose/CH/GD/E115/2017 (E115), from geese in Guangdong province, Southern China, in 2017. Phylogenetic analysis showed that E115 and six other NDVs from geese in China were grouped under subgenotype XIIb and were distinct from subgenotype XIIa, isolated from chickens in South Africa, and subgenotype XIId, isolated from chickens in Vietnam. To better understand the pathogenicity and transmission of the subgenotype XIIb NDVs from geese in Guangdong province, we inoculated chickens and geese with 106 EID50 of the E115 virus. Eight hours after inoculation, three naïve chickens and three naïve geese were co-housed with the infected chickens or geese to assess intraspecific and interspecific horizontal transmission of the E115 virus. The E115 virus induced significant clinical signs without mortality in chickens, while it was not pathogenic to geese. Intraspecific and interspecific horizontal transmission of the E115 virus was observed among chickens and geese via direct contact. Furthermore, although the current vaccines provided complete protection against disease in chickens after challenging them with the E115 virus, the virus could also be transmitted from vaccinated chickens to naïve contact chickens. Collectively, our findings highlight the need for avoiding the mixing of different bird species to reduce cross-species transmission and for surveillance of NDV in waterfowl.

Scoring System for Lesions Induced by Different Strains of Newcastle Disease Virus in Chicken.

Newcastle disease virus strains are velogenic, mesogenic, and lentogenic. This study aims to design a scoring system for lesions induced by different strains of Newcastle disease virus in chicken. Three experiments were conducted. In experiments 1 and 2, chickens were divided into infected and control groups. Infected groups of experiments 1 and 2 consisted of 6 and 24 specific pathogen-free (SPF) chickens, respectively. Control groups in experiments 1 and 2 consisted of 6 and 15 SPF chickens, respectively. In infected groups, infection was induced by intranasal administration of 105 50% EID50/0.1 mL of velogenic Newcastle disease virus strain (vNDV). Infected chickens in experiment 1 were euthanised by cervical dislocation on days 3, 6, and 7 postinoculation (pi). Infected chickens in experiment 2 were euthanised at hours (hrs) 2, 4, 6, 12 and days 1, 2, 4, and 6 pi. Chickens of the control group in experiment 1 were euthanised on days 3 and 7 pi, whereas control group chickens in experiment 2 were euthanised on days 0, 1, 2, 4, and 6 pi. Then in experiment 3, 15 SPF chickens were divided into three groups; in the first group, 5 SPF chickens were infected with vNDV, in the second group, 5 SPF chickens were infected with lentogenic NDV (lNDV) (103.0 EID50/0.1 mL), and the third group was kept without infection as a control group. Chickens were euthanised on day 5 pi. In all previous experiments, tissues of brain, trachea, lung, caecal tonsil, liver, kidney, spleen, heart, proventriculus, intestine, and thymus were collected, fixed in 10% buffered formalin, embedded in paraffin, and sectioned. HS staining was applied. Tissues were examined under light microscope and changes were recorded. A scoring system was designed for lesions induced by different strains of NDV and, accordingly, lesions were scored. The scoring system was found helpful in the evaluation of disease severity.

Transcriptome Analysis in Spleen Reveals Differential Regulation of Response to Newcastle Disease Virus in Two Chicken Lines

Enhancing genetic resistance of chickens to Newcastle Disease Virus (NDV) provides a promising way to improve poultry health, and to alleviate poverty and food insecurity in developing countries. In this study, two inbred chicken lines with different responses to NDV, Fayoumi and Leghorn, were challenged with LaSota NDV strain at 21 days of age. Through transcriptome analysis, gene expression in spleen at 2 and 6 days post-inoculation was compared between NDV-infected and control groups, as well as between chicken lines. At a false discovery rate <0.05, Fayoumi chickens, which are relatively more resistant to NDV, showed fewer differentially expressed genes (DEGs) than Leghorn chickens. Several interferon-stimulated genes were identified as important DEGs regulating immune response to NDV in chicken. Pathways predicted by IPA analysis, such as "EIF-signaling", "actin cytoskeleton organization nitric oxide production" and "coagulation system" may contribute to resistance to NDV in Fayoumi chickens. The identified DEGs and predicted pathways may contribute to differential responses to NDV between the two chicken lines and provide potential targets for breeding chickens that are more resistant to NDV.

α2,3- and α2,6-linked sialic acids are important for cell binding and replication of Newcastle disease virus in chicken primary neuronal cells.

Velogenic Newcastle disease virus (NDV) causes encephalitis and severe neurological disorders in avian species. Sialic acid (SA) has been considered as a receptor for NDV infection and determining tissue tropism. The neurotropic mechanism of NDV in birds is completely unknown. Here we have investigated the role of viral receptor SA in neurotropism of NDV in chickens. We determined that α2,3- and α2,6-linked SA receptors were implicated in NDV encephalitis and viral binding to primary neuronal cells using immunohistofluorescence and virus-cell binding assay. Both SA receptors were found to co-localize with velogenic strain F48E9 in neuropathological lesions of chicken brains after infection through intraocular-nasal routes. The replication of velogenic F48E9 in primary neuronal cells was more efficient than that of lentogenic strain LaSota. The virus-neuronal cell binding capabilities of both the velogenic and the lentogenic strains have no difference. Furthermore, the cell-binding capability and the replication of both strains were significantly decreased by pretreatment with sialidases in neuronal cells. These results demonstrated that α2,3- and α2,6-linked SA receptors were important for the initiation of NDV infection in the chicken nervous system. This study should provide preliminary evidence for a better understanding of the neurotropism of NDV in chickens.

Chicken galectin-1B inhibits Newcastle disease virus adsorption and replication through binding to hemagglutinin–neuraminidase (HN) glycoprotein

Galectin-1 is an important immunoregulatory factor and can mediate the host-pathogen interaction via binding glycans on the surface of various viruses. We previously reported that avian respiratory viruses, including lentogenic Newcastle disease virus (NDV), can induce up-regulation of chicken galectin (CG)-1B in the primary target organ. In this study, we investigated whether CG-1B participated in the infectious process of NDV in chickens. We demonstrated that velogenic NDV induced up-regulation of CG-1B in target organs. We also found that CG-1B directly bound to NDV virions and inhibited their hemagglutination activity in vitro We confirmed that CG-1B interacted with NDV hemagglutinin-neuraminidase (HN) glycoprotein, in which the specific G4 N-glycans significantly contributed to the interaction between CG-1B and HN glycoprotein. The presence of extracellular CG-1B, rather than the internalization process, inhibited adsorption of NDV. The interaction between intracellular CG-1B and NDV HN glycoproteins inhibited cell-surface expression of HN glycoprotein and reduced the titer of progeny virus in NDV-infected DF-1 cells. Significantly, the replication of parental and HN glycosylation mutant viruses in CG-1B knockdown and overexpression cells demonstrated that the replication of NDV was correlated with the expression of CG-1B in a specific glycan-dependent manner. Collectively, our results indicate that CG-1B has anti-NDV activity by binding to N-glycans on HN glycoprotein.

Synergy or interference of a H9N2 avian influenza virus with a velogenic Newcastle disease virus in chickens is dose dependent

ABSTRACTField observations indicate that the impact of velogenic Newcastle disease virus (vNDV) is more severe in countries with concomitant circulation of low pathogenicity avian influenza virus, as is the case in the Middle East, in particular in Israel, where H9N2 and NDV are endemic. In our study, we evaluated how the exposure of chickens to an H9N2 challenge either favours or interferes with a subsequent vNDV infection and its transmission to sentinels. For this purpose, single vNDV and sequential H9/NDV challenges were performed with increasing doses of vNDV (101–106 EID50). The H9N2 challenge made birds more susceptible to the vNDV, lowering the minimum dose required to cause an infection, exacerbating the clinical outcome, while delaying the onset of the disease and time of death. Interestingly, the presence and degree of these seemingly contrasting effects were dose-dependent and not mutually exclusive.

Genetic, antigenic, and pathogenic characteristics of Newcastle disease viruses isolated from geese in China.

Four Newcastle disease virus (NDV) strains were isolated from domestic, commercial geese that showed clinical signs that were believed to be the result of NDV infections. The genetic, antigenic, and pathogenic characteristics of the 4 NDVs were compared with those of NDV strains that were isolated from chickens. The complete genomes of 2 of the NDV strains contained 15,186 nucleotides (nt); the other 2 contained 15,192 nt, and exhibited the typical genomic organization of genotype II NDV and molecular characteristics of VIId NDVs. Phylogenetic analysis confirmed that the genotype II and VIId NDVs that were isolated from geese belonged to the same clusters as the corresponding genotypes of the chicken isolates. A serologic assay demonstrated that the antigenic relatedness among the NDVs was associated with their genotypes, rather than their hosts, and that amino acid substitutions in the F and/or HN proteins may contribute to the antigenic differences among these NDV genotypes. Geese infected with genotype VIId NDVs that were isolated from geese and chickens showed similar pathologic characteristics. NDVs that were isolated from geese did not differ in genetic, serologic, and pathogenic characteristics from those isolated from chickens, indicating that these NDVs were derived from chicken NDVs. Given the significance of geese in NDV epidemiology, effective biosecurity measures should be adopted to prevent the interspecies transmission of NDVs.