key: cord-0003386-5qioku84
authors: Rehman, Zaib Ur.; Meng, Chunchun; Sun, Yingjie; Mahrose, Khalid M.; Umar, Sajid; Ding, Chan; Munir, Muhammad
title: Pathobiology of Avian avulavirus 1: special focus on waterfowl
date: 2018-09-19
journal: Vet Res
DOI: 10.1186/s13567-018-0587-x
sha: d8ec38752ec638efa9b55dffa8d0277ce889c976
doc_id: 3386
cord_uid: 5qioku84

Avian avulaviruses serotype 1 (abbreviated as APMV-1 for the historical name avian paramyxovirus 1) are capable of infecting a wide spectrum of avian species with variable clinical symptoms and outcomes. Ease of transmission has allowed the virus to spread worldwide with varying degrees of virulence depending upon the virus strain and host species. The emergence of new virulent genotypes from global epizootics, and the year-to-year genomic changes in low and high virulence APMV-1 imply that distinct genotypes of APMV-1 are simultaneously evolving at different geographic locations across the globe. This vast genomic diversity may be favoured by large variety of avian species susceptibility to APMV-1 infection, and by the availability of highly mobile wild birds. It has long been considered that waterfowls are not sensitive to APMV-1 and are unable to show any clinical signs, however, outbreaks from the 90′s contradict these concepts. The APMV-1 isolates are increasingly reported from the waterfowl. Waterfowl have strong innate immune responses, which minimize the impact of virus infection, however, are unable to prevent the viral shedding. Numerous APMV-1 are carried by domestic waterfowl intermingling with terrestrial poultry. Therefore, commercial ducks and geese should be vaccinated against APMV-1 to minimize the virus shedding and for the prevention the transmission. Genetic diversity within APMV-1 demonstrates the need for continual monitoring of viral evolution and periodic updates of vaccine seed-strains to achieve efficient control and eradication of APMV-1 in waterfowls. ELECTRONIC SUPPLEMENTARY MATERIAL: The online version of this article (10.1186/s13567-018-0587-x) contains supplementary material, which is available to authorized users.

Newcastle disease (ND) is one of the most devastating and commonly prevalent diseases in the poultry industry, around the world. Owing to immense economic losses, World Organization for Animal Health has categorized the disease as "notifiable" [1] . The disease outbreaks are enormous and the host spectrum is broad, thus making ND as one of the primary limiting factor in the development of the poultry industry, especially in the developing countries [2, 3] . It is caused by the Avian avulavirus 1 (APMV-1), which belongs to the Avulavirus genus within Paramyxoviridae family. All APMV-1 strains can be classified into velogenic (highly virulent), mesogenic (intermediate virulent) and lentogenic (non-virulent) based on the intracerebral pathogenicity index (ICPI) in day old specific pathogen free (SPF) chickens [4, 5] Additional file References un-cleaved fusion protein cleavage site. APMV-1 is considered to be virulent, if these amino acids are basic in nature with a phenylalanine at position 117, and having ICPI value of 0.7 in 1 day old chicks [3, 6] .

APMV-1 is a single-stranded, negative-sense, non-segmented and enveloped RNA virus with genome length of 15.2 kb. APMV-1 genome encodes for six co-linear genes that translate into six proteins and two non-structural proteins. Structural proteins include nucleoprotein (NP), matrix (M), fusion (F), hemagglutinin-neuraminidase (HN), phosphoprotein (P) and large RNA-dependent RNA-polymerase (L). The RNA editing of the P gene can result in the expression of V and W only in the virus infected cells [7] [8] [9] [10] . Virulence of APMV-1 varies and depends upon the host species, and chicken and turkey are more susceptible than ducks and geese.

Generally, waterfowls were considered to be the natural reservoir for APMV-1 [1] ; commonly for lentogenic APMV-1 [11] . Traditional view on the resistance of waterfowl against APMV-1 has been challenged since the report of continuous outbreaks in different provinces of china in goose (1997) [12, 13] and ducks (2002) [14] . Number of clinical ND outbreaks are increasing in the waterfowls [15] [16] [17] [18] . Outbreaks of ND in ducks and geese indicate that these are not only the carrier, but also show clinical outcome of the disease. Factors that led to the change in the pathogenic spectrum of APMV-1 in waterfowl remain elusive. Investigation of the molecular mechanisms of increased pathogenicity of APMV-1 in waterfowls would provide foundations in designing any control strategies for the disease, as well as to improve health and welfare standards of the waterfowl.

The purpose of this review is to analyze our current understanding on the host-spectrum, molecular pathobiology of APMV-1 in waterfowls, and host immune responses that may play crucial roles in the disease prevention and control.

The Class I APMV-1 isolate was reported in 2006, however, currently these isolates are frequently being reported. Recent epidemiological studies direct that class I APMV-1 are common in domestic waterfowl. All viruses belong to class I are avirulent except JS10-A10 and 9a5b strains [19, 20] which were generated by experimental consecutive passages through chicken. Amongst all genotypes of Class II, genotype I and II are the most prevalent genotypes in the waterfowl and have been isolated from many countries (summarized in Table 1 ). Waterfowl-origin isolates belonging to genotype VII of APMV-1 are constantly increasing especially in China, Republic of Korea, and Taiwan [16, [21] [22] [23] [24] [25] [26] [27] [28] [29] [30] [31] [32] . These emerging outbreaks are increasing the global burden of APMV-1 and causes heavy economic losses [24] . Genotype IV and V have not been isolated from the waterfowl (Table 1) . Collectively, these epidemiological studies clearly demonstrate the susceptibility of waterfowls for APMV-1 and their possible roles in the epizootiology of viruses.

Most of our understanding on the surveillance of APMV-1 in wild birds came from epidemiological studies on avian influenza viruses. Thus, it is required to design APMV-1 dedicated studies to effectively assess the true prevalence of the virus in wild birds. It is essential to understand and establish the foundations to devise control strategies, especially in wild-birds populated and highly vulnerable commercial poultry areas.

Waterfowls are less susceptible to APMV-1 compared to chickens, such as ducks and geese. A key reason for less susceptibility of waterfowl to APMV-1 is the presence of retinoic acid-inducible gene I (RIG-I). RIG-I is absent in the chicken [33] whereas it is present in ducks and goose ( Figure 1 ) [7, 34] . RIG-I and melanoma differentiationassociated gene 5 (MDA5) are the foremost part of retinoic acid inducible gene-like receptors (RLRs) (Figure 1 ), which senses the cytoplasmic RNA [35] . These sensors can detect the nucleic acids of negative sense RNA such as APMV-1 and influenza viruses [36, 37] , resulting in the production of the IFN type I and III, cytokines, chemokines and expression of the antiviral genes [38] . There is a vital role of the RLRs in the recognition of the viruses and antiviral immune responses in macrophages, fibroblast, and dendritic cells [39, 40] . The V protein of APMV-1 blocks the "downstream" signaling pathway by interacting with MDA5 resulting in blockage of strong antiviral response of IFN-β in chicken, which provide the benefit to waterfowl via RIG-I pathway [41, 42] . Positive correlation exist between the resistance to APMV-1 infection and expression of the antiviral genes including RIG-I, IRF3, IRF7 and IFN-β [43] which was further confirmed in a study demonstrating increased expression of RIG-I ultimately leading to decreased APMV-1 load in vitro as well as in vivo [34] . APMV-1 infection increases the expression of interleukin (IL) IL-1β, tumor necrosis factor-α-like factor and interferon (IFN)-β in duck embryo fibroblast (DEF) cells. Distinct innate immune responses of the waterfowl against APMV-1 may reason the resistance of waterfowls to these infections [44] . A higher level of innate immune genes expression has been observed in chicken embryo fibroblast (CEF) compared to the DEF cells [44] . An experimental study reveals that APMV-1 stimulate a strong and intense expression of the IFN-β in ducks compared to chickens [42] , and also up-regulate the IFN-β, IFN-regulatory factor 7 (IRF-7), and decreases the virus titer in goose lung and air-sac postinfection [34] . These observations dictate that the strong innate immune responses is a plausible reasons for less susceptibility of duck [42] and geese because its strong protective effects have been revealed to decrease the virus titer in goose-transfected cell [34] , which may not be compensated by the IFN-α [33] .

Recently, Yang et al. [45] have demonstrated that overexpression of 2′-5′-oligoadenylate synthetase-like gene lessens the replication of APMV-1 in goose cells.

In conclusion, waterfowls have diverse innate immunity components, which possibly increase their resistance to the APMV-1 [42] .

Besides the strong innate immune responses, waterfowl are generally considered long-term carrier of APMV-1 and disease outbreaks have been reported since 1997 [12] [13] [14] , and were confirmed by follow up experimental studies. Clinically and naturally infected ducks and geese with APMV-1 show clinical signs such as elevated body temperature, excessively excreted oral mucus, dried cloaca, watery, greenish-white diarrhea, vain attempts of eating and drinking, listlessness, anorexia, crouch, eyelid edema and emaciation [14, 23, 46, 47] . Ducks may show up to 70% decrease in egg production, 80% morbidity and 67% mortality [15, 48] however the mortality in ducks varies with the different breeds, virus strain and dose of virus [15] . Some birds also show weakness of legs and wing along with unilateral or bilateral incomplete paralysis and the effects of this paralysis increases with progression of the disease [46] . Duck and geese also show the neurological signs such as muscular trembles, muscular dis-coordination, circling, and twisting of head and neck [23, 46, 48] . These clinical signs disappear according to infection status; mildly affected recover sooner and severely affected birds may recover after 15 days of infection [22, 46] . APMV-1 infected ducks and geese show the gross lesions on the immune organs such as bursa, spleen, thymus, mild to severe tracheitis, kidney enlargement, necrosis of pancreas, congestion on the meninx and in the brain and diffuse brain edema, focal hemorrhages in the mucosa of the proventriculus and intestine (especially duodenum and upper part of jejunum) [14, 22, 23, 46] . Bursal atrophy, hemorrhagic thymus and splenomegaly with white necrotic spots were found in the APMV-1 infected geese and duck [23, 46] . These lesions and histopathological changes may be due to higher viral loads, multi-systemic distribution of the virus in these immune organs [23] . As these immune organs are the reservoir of immune cells, and their destruction may lead to low antibody titer and other infections.

Experimental infection studies are necessary to determine the virulence and pathogenesis, in different bird types, age, species, intervention strategies, evaluation, comparison of vaccines etc. Different scientists propose diverse reasons for experimental infection studies and the design of the experimental infection studies varies greatly with the above-mentioned factors. Experimental infection studies on the pathogenesis, infection route, most susceptible age, bird line and immune responses are limited in waterfowl and available information is summarized in Additional file 1 and are briefly discussed below. Kang et al. [44] have studied the immune related gene expression of chicken and duck embryonic fibroblast (CEF, DEF), by infecting them with APMV-1 of moderate virulent strain NH-10 and highly virulent strain SS-10. Upregulated expression of the Toll like receptor (TLR) 3, TLR7, IL-1β, IL-6, IFN-α, IFN-γ, MHC-I and MHC-II were observed both in CEF and DEF, however, these expression levels were higher in CEF (mechanism is described briefly in Figure 1 ). Peking duck infection at 3 week of age with NH-10 and SS-10 via intranasal route showed the systemic replication of the virus into small intestine, cecal tonsils, brain, lung, bursa of Fabricius, thymus, and spleen. This study also demonstrated the increased expression of the TLR3, TLR7, RIG-I, MDA5, IL-1β, IL-2, IL-6, IL-8, IFN-α, IFN-β, IFN-γ in lungs compared to thymus. Furthermore, the higher expression level of TLR3, TLR7, IL-1β, IL-2, IL-8, IFN-α, IFN-γ and MHC II were induced by NH-10 than SS-10 in the lungs. Whereas, the expression of the IL-6 and IFN-β in lung as well as thymus was higher for SS-10 group [7] . Similarly, a study of the Zhong et al. [49] has demonstrated the upregulation of the viperin (an IFN stimulated gene) in the DEFs and also in the spleen, kidneys, liver, brain, and blood of Changbai ducks infected with G7 APMV-1 through intranasal or intramuscular route. Experimental infection of geese with genotype VII APMV-1 upregulate the expression of TLR 1-3, 5, 7, and 15, avian β-defensin 5-7, 10, 12, and 16, IL-8, IL-18, IL-1β, and IFN-γ, and MHC class I in different tissues [50] .

Intranasal inoculation of the Japanese commercial ducks and chicken males with artificially made APMV-1 class I virus 9a5b results in the higher IFN-β in the duck compared to chicken. This study also demonstrated that replication, distribution, tissue damage and apoptosis were more in the immune organs of the chicken compared to duck [42] . Intramuscular infection of different ducks (mallard, Gaoyou, Shaoxing, Jinding, Shanma, and Peking ducks) with JSD0812 strain showed that different strains vary in the susceptibility to the disease [46] . Mallard are the most susceptible and Peking ducks are the most resistant species of birds. Infection of the Gaoyou duck at 15, 30, 45, 60, and 110 with different routes indicate that their susceptibility to disease and virus shedding decreases with the age and birds seldom die after infection through the natural route [46] . Experimental co-infection of ducks with APMV-1, and low or high pathogenic avian influenza virus (LPAIV and HPAIV) indicate that it decreases the virus shedding and transmission to the naïve ducks by contact [51] . Duck after immunization with inactivated vaccine of APMV-1, and challenge with the same live virulent Kenyan APMV-1 resulted in the development of more antibody titer than the unchallenged birds [52] . Experimental infection of geese with virulent APMV-1 genotype VIId and goose origin APMV-1 showed the extensive replication of geese in the immune organs which correlated with the clinical signs and lesions [12, 23] and also it transmission to SPF chickens [12] . Geese and chicken were vaccinated, then infected with goose-origin APMV-1/NA-1 and chickenorigin APMV-1/F48E9, and F48E8 viruses (Additional file 1). Geese are more resistant to F48E8 virus after vaccination. Results indicate that NA-1 vaccine provides a better protection in the form of less morbidity, less mortality and less virus shedding after challenge [53] . Although several natural outbreaks and experimental infections of APMV-1 in waterfowl had been reported. However, it remain to be clarified whether it cause the disease in waterfowl [46] . Inconsistent results in the infection of APMV-1 in waterfowl are due to APMV-1 strain, dose and rout of inoculation, breed, and maternal antibody titer (Additional file 1). Ducks are more resistant to infection through natural route than the geese [46] .

In conclusion, these studies indicate that different viruses affect the immune organs and innate immune genes in diverse mechanisms. Waterfowls are more susceptible to APMV-1 infection at an early age, and through natural route results in less damage to immune organs. More comprehensive and detailed studies are warranted for the control of ND in waterfowl.

Waterfowl are naturally infected with large number of the viruses which are avirulent and do not cause the diseases in domesticated poultry. Waterfowl are commonly considered to be the natural host as well as carrier of APMV-1 [4] . APMV-1 isolates from the waterfowl are generally lentogenic or potentially pathogenic [54] , and may be transmitted to the avian species, leading to increase attention for their role in the transmission/spread and emergence of ND [55] [56] [57] .

There are increasing concerns about the increased virulence from the lentogenic to mesogenic to virulent pathotypes upon cyclic replication in poultry. These lentogenic isolates may converted to pathogenic viruses through serial passage in susceptible birds [19, 20, 58] and one such isolate have already been documented to be the causative agent of the outbreak in the Ireland [59] , but disappeared quickly. All the Class I APMV-1′s had been isolated from the waterfowl, indicating them the natural carrier of these viruses (Table 1) . Live bird market (LBM) epidemiological study in United States indicated that from avirulent viruses, 70% belong to class I and 30% belongs to Class II [60] . There is close phylogenetic relationship between the avirulent viruses isolated from the LBM and waterfowl, indicating that APMV-1′s may be transmitted from the waterfowl to the domestic poultry [60, 61] . Transmission of APMV-1 may occur through different routes like, ingestion of the contaminated feed, water air, contaminated feces, animals, humans, contaminated eggs etc. [62] . Mostly domestic waterfowl are reared in semi-closed areas, where they may have the contact with the wild birds and domestic poultry. Therefore, it provides the best natural environment for the spread of APMV-1′s [20, 63] .

Waterfowl and shorebirds are not only the host, but are also infected by the APMV-1 and these viruses can also cause the disease in domesticated poultry [55, 56, 64] . Many virulent isolates from the domestic poultry cannot cause disease in waterfowl [21, 53] . Most prevalent virulent genotype VII causing the endemics in China, Japan, Korea [18, 60, 65] are co circulating into the ducks and chicken [66] . This coevolution was further confirmed when the results of Huang et al. [67] declared that some of the circulating APMV-1 had the multiple homologous genomes from chicken, ducks and geese. So, there is dire need to modernize the housing system of waterfowl according to biosecurity point of view to prevent their contact with terrestrial poultry and wild birds. Otherwise, number of virulent [16, [21] [22] [23] [24] [25] [26] [27] [28] [29] and avirulent [21, 63, 68, 69] isolates from the waterfowl may easily transmit to commercial poultry farm.

APMV-1 infected waterfowls shed the virus for an extended period of time [24] whereas, the infected chickens clears themselves rapidly and shed virus for short duration [70] . This prolonged virus shedding may facilitate the transmission, persistence and evolved to get some point mutation in the virus [66] . Major issue that should be concerned for virologists is the high evolution rate of some Class I APMV-1 isolates from waterfowls. Pathogenicity of some Class I APMV-1 isolates are constantly increasing and they are naturally converted to low virulent from avirulent viruses (unpublished findings from our lab). This was confirmed by the results of the Meng et al. [20] and Shengqing et al. [19] in which they artificially develop the virulent viruses through serial passage in the air sac and brain of chicken, from avirulent viruses of waterfowl origin. Although the conditions provided in these studies are not naturally existing but recovery of the virus from the air sacs after challenged via nasal or ocular route indicate the possibility of this mechanism.

In conclusion waterfowl plays a vital role in the transmission and re-emergence of ND in terrestrial poultry. It is recommended that rearing facilities of the waterfowl should be separated from commercial poultry.

Cumulating evidences indicate that genetic resistance to APMV-1 exists in various breeds of waterfowl [15] . Comprehensive studies are needed to determine the genetic variability against APMV-1 in different breeds of waterfowls. Genetic resistance of more susceptible breeds can be improved by including the resistant birds in the breeding programs of the commercial waterfowl [6] . APMV-1 resistant breeds should be used to produce highly efficient transgenic poultry birds [6] . Although constant outbreaks of ND have been reported in waterfowl from China and other East Asian countries, however, vaccination against ND in waterfowl is still a matter of debate. There are two consortia of scientists; one favors the vaccination and, others think that domestic waterfowl should not be vaccinated. These veterinarians have their own views, scientist, in the favors of vaccination argue, that it will decrease the chances of outbreaks and lessons the virus shedding. But, scientists, which are against vaccination argue that it will increase the virus burden on the birds, consequently increase the variation rate. The annual rate of change of virulent viruses could be as high as ten times the rate of change of low virulence APMV-1, suggesting that other selective pressures such as vaccination may accelerate the rate of evolution of virulent viruses [71, 72] . They claim that the rearing conditions of waterfowl could not be changed in future because they require water for breeding. Therefore, it is not plausible to prevent their contact with wild birds, resulting in transfer of the wild bird viruses to domestic waterfowls. Secondly, they claim vaccine will develop the antibody titers that will interact with the virus in the future exposures. These antibody responses may force the viruses for evolution. Our viewpoint supports the group of scientists, which claims that birds should be vaccinated. Because, it had already been established that APMV-1 cause the disease in waterfowl [7, 46, 49, 52] and vaccination prevent the chances of the outbreak. Second most important reason is the prolonged virus shedding by non-vaccinated birds, which may transfer to other poultry species and cause heavy economic losses. Theory, that vaccination will increase the virus burden is not very interesting in case of waterfowl because, without vaccination we have to face the same consequences of the high evolution rate. Waterfowls are naturally infected with large and diverse groups of viruses [73] . Development of the vaccines for waterfowl may require strains of waterfowl origin [53] because some lentogenic vaccines phylogenetically are far away than the infectious virus thus may provide partial protection to waterfowl [74] . Vaccine should also be killed because live vaccine virus replicates in the body and leads to shedding of the virus. Virus shedding of live vaccine may interact with the other APMV-1's present in the environment or birds and results in recombination and future evolution.

Waterfowls are not only the carrier but also susceptible to APMV-1. Strong innate immune responses may attribute to the less susceptibility of ND to waterfowl. Viral shedding by waterfowl for prolonged duration may increase the transmission, evolution and emergence of new viral strains. A number of APMV-1 isolates from the waterfowl are reported with high mutation rate, which is an alarming matter and may cause the endemics in future. Pathogenicity of ND is affected by different factors such as type, dose, and inoculation route of the virus, and species and age of birds.

Further studies are needed to explore the mechanism, and its intervention to prevent the virus shedding by the waterfowl for a long period. Continuous studies are also required to monitor the APMV-1 in the waterfowl, which may be the future threat to commercial poultry industry. Studies on the humoral immune responses of waterfowl are crucial to develop better intervention strategies. It is recommended that rearing facilities of the waterfowl including ducks and geese should be separated from chicken and turkey flocks to prevent the virus transmission.

Additional file 1. Experimental infection studies of ducks and geese with Avian Avulavirus 1. Table summarizes 

Temporal, geographic, and host distribution of avian paramyxovirus 1 (Newcastle disease virus)

Infectivity and pathogenicity of Newcastle disease virus strains of different avian origin and different virulence for mallard ducklings

Terrestrial Manual 2012. Manual of diagnostic tests and vaccines for terrestrial animals. World Organisation for Animal Health

Newcastle disease

Pathological alterations during co-infection of Newcastle disease virus with Escherichia coli in broiler chicken

Immune responses of poultry to Newcastle disease virus

Host innate immune responses of ducks infected with Newcastle disease viruses of different pathogenicities

Vitamin E supplementation ameliorates Newcastle disease virus-induced oxidative stress and alleviates tissue damage in the brains of chickens

Raza-ur-Rehman Hussain I (2017) Molecular characterization and epitope mapping of fusion (F) and hemagglutinin (HN) genes of avian paramyxovirus serotype i from peacocks in Pakistan

Supplementation of vitamin e protects chickens from Newcastle disease virus-mediated exacerbation of intestinal oxidative stress and tissue damage

Genetic diversity and mutation of avian paramyxovirus serotype 1 (Newcastle disease virus) in wild birds and evidence for intercontinental spread

Newcastle disease in geese: natural occurrence and experimental infection

Development and field application of a competitive enzyme-linked immunosorbent assay for detection of Newcastle disease virus antibodies in chickens and ducks

Isolation and identification of paramyxovirus type 1 from duck

Genomic sequence of an avian paramyxovirus type 1 strain isolated from Muscovy duck (Cairina moschata) in China

Phylogenetic and pathotypical analysis of two virulent Newcastle disease viruses isolated from domestic ducks in China

Genome sequence of a virulent genotype III Newcastle disease virus isolated from laying ducks in China

Pathotypical and genotypical characterization of strains of Newcastle disease virus isolated from outbreaks in chicken and goose flocks in some regions of China during

Generation of velogenic Newcastle disease viruses from a nonpathogenic waterfowl isolate by passaging in chickens

Evolution of Newcastle disease virus quasispecies diversity and enhanced virulence after passage through chicken air sacs

Phylogenetic and pathotypic characterization of Newcastle disease viruses circulating in South China and transmission in different birds

Molecular and antigenic characteristics of Newcastle disease virus isolates from domestic ducks in China

Evaluation of histopathological changes, viral load and immune function of domestic geese infected with Newcastle disease virus

Phylogenetic relationships and pathogenicity variation of two Newcastle disease viruses isolated from domestic ducks in southern China

Characterization and sequencing of a genotype VIId Newcastle disease virus isolated from laying ducks in

Identification of a genotype VIId Newcastle disease virus isolated from sansui sheldrake ducks in Guizhou province

Complete genome sequences of Newcastle disease virus strains isolated from three different poultry species in China

Serologic and virologic survey for evidence of infection with velogenic Newcastle disease virus in Chinese duck farms

Characterization of velogenic Newcastle disease viruses isolated from dead wild birds in Serbia during

Molecular epidemiological analysis of Newcastle disease virus isolated in China in 2005

Characterization of Newcastle disease virus isolated from waterfowl in China

Antigenic and genotypical characterization of Newcastle disease viruses isolated in Taiwan between

Association of RIG-I with innate immunity of ducks to influenza

Goose RIG-I functions in innate immunity against Newcastle disease virus infections

The RNA helicase RIG-I has an essential function in double-stranded RNA-induced innate antiviral responses

Promoter structures and differential responses to viral and nonviral inducers of chicken type I interferon genes

Distinct RIG-I and MDA5 signaling by RNA viruses in innate immunity

Viral evasion and subversion of pattern-recognition receptor signalling

The specific and essential role of MAVS in antiviral innate immune responses

Essential role of IPS-1 in innate immune responses against RNA viruses

The V proteins of paramyxoviruses bind the IFN-inducible RNA helicase, mda-5, and inhibit its activation of the IFN-beta promoter

Histopathological alterations in immune organs of chickens and ducks after experimental infection with virulent 9a5b newcastle disease virus

Expression of RIG-I, IRF3, IFN-beta and IRF7 determines resistance or susceptibility of cells to infection by Newcastle Disease Virus

Newcastle disease virus infection in chicken embryonic fibroblasts but not duck embryonic fibroblasts is associated with elevated host innate immune response

Identification of 2′-5′-oligoadenylate synthetase-like gene in goose: gene structure, expression patterns, and antiviral activity against Newcastle disease virus

Experimental infection of duck origin virulent Newcastle disease virus strain in ducks

Lack of detection of host associated differences in Newcastle disease viruses of genotype VIId isolated from chickens and geese

Isolation and preliminary identification of a virulent Newcastle disease virus isolate of duck origin

Molecular characterization and expression analysis of the duck viperin gene

Infection of goose with genotype VIId Newcastle disease virus of goose origin elicits strong immune responses at early stage

Experimental co-infections of domestic ducks with a virulent Newcastle disease virus and low or highly pathogenic avian influenza viruses

Effect of immunosuppression on newcastle disease virus persistence in ducks with different immune status

Antigenic variation between Newcastle disease viruses of goose and chicken origin

Molecular epidemiological investigation of Newcastle disease virus from domestic ducks in Korea

A preliminary study of the role of ducks in the transmission of Newcastle disease virus to in-contact rural free-range chickens

The response of ducks to V4 Newcastle disease virus and its transmission to contact ducks and domestic chickens

An epizootiological report of the re-emergence and spread of a lineage of virulent Newcastle disease virus into Eastern Europe

Passaging of a Newcastle disease virus pigeon variant in chickens results in selection of viruses with mutations in the polymerase complex enhancing virus replication and virulence

Characterisation of an antigenically unusual virus responsible for two outbreaks of Newcastle disease in the Republic of Ireland in 1990

Phylogenetic diversity among low-virulence newcastle disease viruses from waterfowl and shorebirds and comparison of genotype distributions to those of poultry-origin isolates

Multiplex RT-PCR for rapid detection and differentiation of class I and class II Newcastle disease viruses

Avian paramyxovirus serotype-1: a review of disease distribution, clinical symptoms, and laboratory diagnostics

Surveillance of avirulent Newcastle disease viruses at live bird markets in eastern China during 2008-2012 reveals a new sub-genotype of class I virus

A review of virulent Newcastle disease viruses in the United States and the role of wild birds in viral persistence and spread

Characterization of complete genome sequence of genotype VI and VII velogenic Newcastle disease virus from Japan

Potential of genotype VII Newcastle diseaseviruses to cause differential infections in chickens and ducks

Genetic, pathogenic and antigenic diversity of Newcastle disease viruses in

Phylogenetic analysis of Newcastle disease viruses isolated from wild birds in the Poyang Lake region of China

Temporal dynamics, diversity, and interplay in three components of the virodiversity of a Mallard population: influenza A virus, avian paramyxovirus and avian coronavirus

Comparison of viral shedding following vaccination with inactivated and live Newcastle disease vaccines formulated with wild-type and recombinant viruses

Evolutionary dynamics of Newcastle disease virus

Imperfect vaccination can enhance the transmission of highly virulent pathogens

Newcastle disease: evolution of genotypes and the related diagnostic challenges

A vaccine candidate of attenuated genotype VII Newcastle disease virus generated by reverse genetics

Genotyping of Newcastle disease viruses isolated from 2001 to 2007 in Japan

Avian influenza virus and Newcastle disease virus (NDV) surveillance in commercial breeding farm in China and the characterization of Class I NDV isolates

Molecular epidemiology of outbreak-associated and wild-waterfowl-derived newcastle disease virus strains in Finland, including a novel class I genotype

Genomic characterizations of a Newcastle disease virus isolated from ducks in live bird markets in China

Complete genome sequences of two subgenotype 1b Newcastle disease viruses isolated from Sansui sheldrake Ducks in Guizhou

Wood ducks (Aix sponsa) as potential reservoirs for avian influenza and avian paramyxoviruses

Genomic characterization of the first class I Newcastle disease virus isolated from the mainland of China

Surveillance for avirulent Newcastle disease viruses in domestic ducks (Anas platyrhynchos and Cairina moschata) at live bird markets in Eastern China and characterization of the viruses isolated

Whole genome sequencing and biological characterization of Duck/JS/10, a new lentogenic class I Newcastle disease virus

Genetic characterization and evolutionary analysis of Newcastle disease virus isolated from domestic duck in South Korea

Complete genome sequence of genotype IB Newcastle disease virus isolated from a mallard (Anas platyrhynchos) in Russia

Prevalence of avian paramyxovirus type 1 in Mallards during autumn migration in the western Baltic Sea region

Characterization of newcastle disease viruses in wild and domestic birds in Luxembourg from

Genetic diversity of newcastle disease virus in wild birds and pigeons in West Africa

Exchange of Newcastle disease viruses in Korea: the relatedness of isolates between wild birds, live bird markets, poultry farms and neighboring countries

Monitoring of wild birds for Newcastle disease virus in north Queensland

Molecular epidemiologic investigation of lentogenic Newcastle disease virus from domestic birds at live bird markets in Korea

Characterization of avian paramyxovirus type 1 from migratory wild birds in chickens

Surveillance and characterization of Newcastle disease viruses isolated from northern pintail (Anas acuta) in Japan during 2006-09

Genetic characterization and evolutionary analysis of 4 Newcastle disease virus isolate full genomes from waterbirds in South China during

Phylogenetic analysis of Newcastle disease viruses isolated from waterfowl in the upper midwest region of the United States

Orthomyxo-, paramyxo-and flavivirus infections in wild waterfowl in Finland

Characterization of Newcastle disease virus isolated from northern pintail (Anas acuta) in Japan

Pathotyping and genetic characterization of avian avulavirus-1 from domestic and wild waterfowl, geese and black swans in Pakistan

Complete genome sequences of two Newcastle disease virus strains isolated from a wild duck and a pigeon in Russia

Complete genome sequence of a virulent Newcastle disease virus strain isolated from a clinically healthy duck (Anas platyrhynchos domesticus) in Pakistan

Genomic and biological characterization of Newcastle disease viruses isolated from migratory mallards (Anas platyrhynchos)

Identification of a genotype IX Newcastle disease virus in a Guangxi white duck

Potentially virulent Newcastle disease viruses are maintained in migratory waterfowl populations

Pathotypical characterization and molecular epidemiology of Newcastle disease virus isolates from different hosts in China from 1996 to

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

Biological characteristics and sequence analysis of fusion genes of Newcastle disease virus isolates

Isolation, identification, and sequencing of a goose-derived Newcastle disease virus and determination of its pathogenicity

Genomic analysis of Newcastle disease virus strain NA-1 isolated from geese in China

Genetic diversity of Newcastle disease viruses isolated from domestic poultry species in Eastern China during

Complete genome sequences of new emerging Newcastle disease virus strains isolated from china

The authors declare that they have no competing interests.Authors' contributions ZUR, CM and CD developed the idea; ZUR and CM collected the data, wrote and revised the manuscript; CM, YS, KMM and SU helped in collection of data and contributed to writing the manuscript; MM helped in the illustrations; MM and CD critically revised the manuscript. All authors read and approved the final manuscript.