Avian Influenza Virus and Avian Paramyxoviruses in Wild Waterfowl of the Western Coast of the Caspian Sea (2017-2020).

The flyways of many different wild waterfowl pass through the Caspian Sea region. The western coast of the middle Caspian Sea is an area with many wetlands, where wintering grounds with large concentrations of birds are located. It is known that wild waterfowl are a natural reservoir of the influenza A virus. In the mid-2000s, in the north of this region, the mass deaths of swans, gulls, and pelicans from high pathogenicity avian influenza virus (HPAIV) were noted. At present, there is still little known about the presence of avian influenza virus (AIVs) and different avian paramyxoviruses (APMVs) in the region's waterfowl bird populations. Here, we report the results of monitoring these viruses in the wild waterfowl of the western coast of the middle Caspian Sea from 2017 to 2020. Samples from 1438 individuals of 26 bird species of 7 orders were collected, from which 21 strains of AIV were isolated, amounting to a 1.46% isolation rate of the total number of samples analyzed (none of these birds exhibited external signs of disease). The following subtypes were determined and whole-genome nucleotide sequences of the isolated strains were obtained: H1N1 (n = 2), H3N8 (n = 8), H4N6 (n = 2), H7N3 (n = 2), H8N4 (n = 1), H10N5 (n = 1), and H12N5 (n = 1). No high pathogenicity influenza virus H5 subtype was detected. Phylogenetic analysis of AIV genomes did not reveal any specific pattern for viruses in the Caspian Sea region, showing that all segments belong to the Eurasian clades of classic avian-like influenza viruses. We also did not find the amino acid substitutions in the polymerase complex (PA, PB1, and PB2) that are critical for the increase in virulence or adaptation to mammals. In total, 23 hemagglutinating viruses not related to influenza A virus were also isolated, of which 15 belonged to avian paramyxoviruses. We were able to sequence 12 avian paramyxoviruses of three species, as follows: Newcastle disease virus (n = 4); Avian paramyxovirus 4 (n = 5); and Avian paramyxovirus 6 (n = 3). In the Russian Federation, the Newcastle disease virus of the VII.1.1 sub-genotype was first isolated from a wild bird (common pheasant) in the Caspian Sea region. The five avian paramyxovirus 4 isolates obtained belonged to the common clade in Genotype I, whereas phylogenetic analysis of three isolates of Avian paramyxovirus 6 showed that two isolates, isolated in 2017, belonged to Genotype I and that an isolate identified in 2020 belonged to Genotype II. The continued regular monitoring of AIVs and APMVs, the obtaining of data on the biological properties of isolated strains, and the accumulation of information on virus host species will allow for the adequate planning of epidemiological measures, suggest the most likely routes of spread of the virus, and assist in the prediction of the introduction of the viruses in the western coastal region of the middle Caspian Sea.

Putative Novel Avian Paramyxovirus (AMPV) and Reidentification of APMV-2 and APMV-6 to the Species Level Based on Wild Bird Surveillance (United States, 2016-2018).

Avian paramyxoviruses (APMVs) (subfamily Avulavirinae) have been isolated from over 200 species of wild and domestic birds around the world. The International Committee on Taxonomy of Viruses (ICTV) currently defines 22 different APMV species, with Avian orthoavulavirus 1 (whose viruses are designated APMV-1) being the most frequently studied due to its economic burden to the poultry industry. Less is known about other APMV species, including limited knowledge on the genetic diversity in wild birds, and there is a paucity of public whole-genome sequences for APMV-2 to -22. The goal of this study was to use MinION sequencing to genetically characterize APMVs isolated from wild bird swab samples collected during 2016 to 2018 in the United States. Multiplexed MinION libraries were prepared using a random strand-switching approach using 37 egg-cultured, influenza-negative, hemagglutination-positive samples. Forty-one APMVs were detected, with 37 APMVs having complete polymerase coding sequences allowing for species identification using ICTV's current Paramyxoviridae phylogenetic methodology. APMV-1, -4, -6, and -8 viruses were classified, one putative novel species (Avian orthoavulavirus 23) was identified from viruses isolated in this study, two putative new APMV species (Avian metaavulavirus 24 and 27) were identified from viruses isolated in this study and from retrospective GenBank sequences, and two putative new APMV species (Avian metaavulavirus 25 and 26) were identified solely from retrospective GenBank sequences. Furthermore, coinfections of APMVs were identified in four samples. The potential limitations of the branch length being the only species identification criterion and the potential benefit of a group pairwise distance analysis are discussed. IMPORTANCE Most species of APMVs are understudied and/or underreported, and many species were incidentally identified from asymptomatic wild birds; however, the disease significance of APMVs in wild birds is not fully determined. The rapid rise in high-throughput sequencing coupled with avian influenza surveillance programs have identified 12 different APMV species in the last decade and have challenged the resolution of classical serological methods to identify new viral species. Currently, ICTV's only criterion for Paramyxoviridae species classification is the requirement of a branch length of >0.03 using a phylogenetic tree constructed from polymerase (L) amino acid sequences. The results from this study identify one new APMV species, propose four additional new APMV species, and highlight that the criterion may have insufficient resolution for APMV species demarcation and that refinement or expansion of this criterion may need to be established for Paramyxoviridae species identification.

Novel avian orthoavulavirus 13 in wild migratory waterfowl: biological and genetic considerations.

Avian orthoavulavirus 13 (AOAV-13), formerly known as Avian paramyxovirus 13 (APMV-13), is found scatteredly in wild birds around the world. Although four complete genome sequences of AOAV-13 had been identified since the first discovery in Japan in 2003, the information available on the genetic variation and biological characteristics of AOAV-13 is still limited. In the present study, we isolated six AOAV-13 strains from fecal samples of wild migratory waterfowls during annual (2014-2018) viral surveillance of wild bird populations from wetland and domestic poultry of live bird markets (LBMs) in China. The phylogenetic analyses based on the HN and F genes showed that they had very close relationship and the molecular clock estimations showed a low evolutionary rate of AOAV-13. However, Bean goose/Hubei/V97-1/2015 is 1953 nt in size (ORF, 1, 776 nt), which is a unique size and longer than other reported AOAV-13 strains. Additionally, four repeats of conserved sequences "AAAAAT" was presented in the 5'-end trailer region of Swan goose/Hubei/VI49-1/2016, which is unprecedented in the AOAV-13. These findings highlight the importance of continuous monitoring the specific species of APMVs.

Avian Orthoavulavirus 1 Vaccination Failure in Minnesota Turkeys.

Minnesota is the leading state in number of turkeys produced in the United States. Turkey flocks in the field are usually vaccinated several times with live avian orthoavulavirus 1 (AOAV-1) vaccines starting as early as 2 wk of age (WOA). During the years 2018-2019, many turkey flocks were diagnosed with low-virulence AOAV-1 infection around 9 WOA that led to respiratory disease, although they were previously vaccinated. This study was designed to investigate the immunity against AOAV-1 in Minnesota turkey flocks in the field and experimentally after vaccination. We reviewed antibody titers against AOAV-1 from turkey flocks tested by ELISA at Minnesota Poultry Testing Laboratory (n = 1292). Up to 9 WOA, more than 85% of the field flocks tested had unprotective antibody titers against AOAV-1. However, commercial poults at 3 WOA experimentally vaccinated by eye-drop method had an ELISA geometric mean titer of 6011 at 7 WOA. Oropharyngeal virus shedding after vaccination was 10%, 70%, 80%, and 40% at 1, 3, 5, and 7 days postvaccination, respectively. This study demonstrates that experimentally vaccinated turkeys respond very well to AOAV-1 vaccine when properly administered. However, there is clear vaccination failure in the field, where vaccine is commonly administered in drinking water, a method that is more susceptible to failure because of many variables in this procedure. We recommend choosing the most effective method of vaccine administration. Given the high incidence of inadequate immunity induced in commercial turkeys on mass application of live AOAV-1 vaccines in water, alternative application methods and subsequent monitoring of the serologic antibody response must be undertaken to ensure a proper immune response.

Artículo regular­Fracaso de la vacunación contra el Orthoavulavirus aviar 1 en pavos de Minnesota. Minnesota es el estado líder en número de pavos producidos en los Estados Unidos. Las parvadas de pavos en el campo generalmente se vacunan varias veces con vacunas vivas con Orthoavulavirus Aviar 1 (AOAV-1) comenzando desde las 2 semanas de edad (WOA). Durante los años 2018­2019, muchas parvadas de pavos fueron diagnosticadas con infección por Orthoavulavirus Aviar 1 de baja virulencia alrededor de las nueve semanas de edad que condujeron a una enfermedad respiratoria, aunque las aves fueron vacunadas previamente. Este estudio fue diseñado para investigar la inmunidad contra Orthoavulavirus Aviar 1 en parvadas de pavos de Minnesota en el campo y experimentalmente después de la vacunación. Se revisaron los títulos de anticuerpos contra Orthoavulavirus Aviar 1 de parvadas de pavos analizados por ELISA en el Laboratorio de Diagnóstico Avícola de Minnesota (n = 1292). Hasta las nueve semanas de edad, más del 85% de las parvadas de campo analizadas tenían títulos de anticuerpos no protectores contra Orthoavulavirus Aviar 1. Sin embargo, los pavipollos comerciales a las tres semanas de edad vacunados experimentalmente por el método de gota ocular tenían un título medio geométrico de ELISA de 6011 a las siete semanas de edad. La diseminación del virus orofaríngeo después de la vacunación fue del 10%, 70%, 80% y 40% a los 1, 3, 5 y 7 días después de la vacunación, respectivamente. Este estudio demuestra que los pavos vacunados experimentalmente respondieron muy bien a la vacuna con Orthoavulavirus Aviar 1 cuando se administra correctamente. Sin embargo, existe un claro fracaso de la vacunación en el campo, donde la vacuna se administra comúnmente en el agua potable, un método que es más susceptible al fracaso debido a muchas variables en este procedimiento. Se recomienda elegir el método de administración de vacunas más eficaz. Considerando la alta incidencia de inmunidad inadecuada inducida en pavos comerciales con la aplicación masiva de vacunas vivas con Orthoavulavirus Aviar 1 en agua, se deben llevar a cabo métodos de aplicación alternativos y monitoreo posterior de la respuesta de anticuerpos serológicos para asegurar una respuesta inmune adecuada.

Genetic and Antigenic Characterization of Avian Avulavirus Type 6 (AAvV-6) Circulating in Canadian Wild Birds (2005-2017).

We describe for the first time the genetic and antigenic characterization of 18 avian avulavirus type-6 viruses (AAvV-6) that were isolated from wild waterfowl in the Americas over the span of 12 years. Only one of the AAvV-6 viruses isolated failed to hemagglutinate chicken red blood cells. We were able to obtain full genome sequences of 16 and 2 fusion gene sequences from the remaining 2 isolates. This is more than double the number of full genome sequences available at the NCBI database. These AAvV-6 viruses phylogenetically grouped into the 2 existing AAvV-6 genotype subgroups indicating the existence of an intercontinental epidemiological link with other AAvV-6 viruses isolated from migratory waterfowl from different Eurasian countries. Antigenic maps made using HI assay data for these isolates showed that the two genetic groups were also antigenically distinct. An isolate representing each genotype was inoculated in specific pathogen free (SPF) chickens, however, no clinical symptoms were observed. A duplex fusion gene based real-time assay for the detection and genotyping of AAvV-6 to genotype 1 and 2 was developed. Using the developed assay, the viral shedding pattern in the infected chickens was examined. The chickens infected with both genotypes were able to shed the virus orally for about a week, however, no significant cloacal shedding was detected in chickens of both groups. Chickens in both groups developed detectable levels of anti-hemagglutinin antibodies 7 days after infection.

Recovery of Recombinant Avian Paramyxovirus Type-3 Strain Wisconsin by Reverse Genetics and Its Evaluation as a Vaccine Vector for Chickens.

A reverse genetic system for avian paramyxovirus type-3 (APMV-3) strain Wisconsin was created and the infectious virus was recovered from a plasmid-based viral antigenomic cDNA. Green fluorescent protein (GFP) gene was cloned into the recombinant APMV-3 genome as a foreign gene. Stable expression of GFP by the recovered virus was confirmed for at least 10 consecutive passages. APMV-3 strain Wisconsin was evaluated against APMV-3 strain Netherlands and APMV-1 strain LaSota as a vaccine vector. The three viral vectors expressing GFP as a foreign protein were compared for level of GFP expression level, growth rate in chicken embryo fibroblast (DF-1) cells, and tissue distribution and immunogenicity in specific pathogen-free (SPF) day-old chickens. APMV-3 strain Netherlands showed highest growth rate and GFP expression level among the three APMV vectors in vitro. APMV-3 strain Wisconsin and APMV-1 strain LaSota vectors were mainly confined to the trachea after vaccination of day-old SPF chickens without any observable pathogenicity, whereas APMV-3 strain Netherlands showed wide tissue distribution in different body organs (brain, lungs, trachea, and spleen) with mild observable pathogenicity. In terms of immunogenicity, both APMV-3 strain-vaccinated groups showed HI titers two to three fold higher than that induced by APMV-1 strain LaSota vaccinated group. This study offers a novel paramyxovirus vector (APMV-3 strain Wisconsin) which can be used safely for vaccination of young chickens as an alternative for APMV-1 strain LaSota vector.

Genomic and biological characteristics of Avian Orthoavulavirus-1 strains isolated from multiple wild birds and backyard chickens in Pakistan.

Circulation of the dominant sub-genotype VII.2 of Avian Orthoavulavirus-1 (AOAV-1) is affecting multiple poultry and non-poultry avian species and causing significant economic losses to the poultry industry worldwide. In countries where ND is endemic, continuous monitoring and characterization of field strains are necessary. In this study, genetic characteristics of eleven AOAV-1 strains were analyzed isolated from wild birds including parakeets (n = 3), lovebird parrot (n = 1), pheasant (n = 1), peacock (n = 1), and backyard chickens (n = 5) during 2015-2016. Genetic characterization (genome size [15,192 nucleotides], the presence of typical cleavage site [112-RRQKRF-117]) and biological assessment (HA log 27 to 29 and intracerebral pathogenicity index [ICPI] value ranging from 1.50 to 1.86) showed virulent AOAV-1. Phylogenetic analysis showed that the studied isolates belonged to sub-genotype VII.2 and genetically very closely related (> 98.9%) to viruses repeatedly isolated (2011-2018) from commercial poultry. These findings provide evidence for the existence of epidemiological links between poultry and wild bird species in the region where the disease is prevalent. The deduced amino acid analysis revealed several substitutions in critical domains of fusion and hemagglutinin-neuraminidase genes. The pathogenesis and transmission potential of wild bird-origin AOAV-1 strain (AW-Pht/2015) was evaluated in 21-day-old chickens that showed the strain was highly virulent causing clinical signs and killed all chickens. High viral loads were detected in different organs of the infected chickens correlating with the severity of lesions developed. The continuous monitoring of AOAV-1 isolates in different species of birds will improve our knowledge of the evolution of these viruses, thereby preventing possible panzootic.

Characterization of ten paramyxovirus type 1 viruses isolated from pigeons in China during 1996-2019.

Pigeon paramyxovirus type 1 (PPMV-1) is an antigenic variant of avian paramyxovirus type 1, which mainly infects pigeons. Here, we characterized ten PPMV-1 viruses isolated from pigeons in China during 1996-2019. Phylogenetic analysis of available complete genomes, F and HN genes of PPMV-1 from China showed that multiple PPMV-1 genotypes (I, II, VI, and VII) exist in pigeons in China. Ten PPMV-1 viruses isolated in this study belonged to genotypes VI.1.2.2.2, VI.2.1.1.2.1, VI.2.1.1.2.2 and VII respectively. Genotype VI is predominant in pigeons. VI.2.1.1.2.2 contains most recently isolated PPMV-1 viruses, suggesting that VI.2.1.1.2.2 is a prevalent genotype in pigeons in China. In vitro and in vivo studies showed that four representative viruses from genotypes VI.2.1.1.2.1 (TA14), VI.2.1.1.2.2 (SD19), VI.1.2.2.2 (SD16), and VII (JN08) could replicate efficiently in chicken embryo fibroblasts, while the replication titer of JN08 (VII) virus was significantly lower than that of VI gene viruses in pigeon embryo fibroblasts. The TA14 (VI.2.1.1.2.1) and SD19 (VI.2.1.1.2.2) viruses caused 20 % and 30 % mortality in pigeons, respectively. No birds infected with SD16 (VI.1.2.2.2) died during the study period. JN08 (VII) virus did not cause obvious clinical signs in infected pigeons. All data indicated that VI.2.1.1.2.2 is the prevalent genotype circulating in China and poses a major threat to pigeons, suggesting that a matched vaccine is necessary to control the disease.

Complete Genome Sequencing, Molecular Epidemiological, and Pathogenicity Analysis of Pigeon Paramyxoviruses Type 1 Isolated in Guangxi, China during 2012-2018.

Newcastle disease is an important poultry disease that also affects Columbiform birds. The viruses adapted to pigeons and doves are referred to as pigeon paramyxoviruses 1 (PPMV-1). PPMV-1 are frequently isolated from pigeons worldwide and have the potential to cause disease in chickens. The complete genomes of 18 PPMV-1 isolated in China during 2012-2018 were sequenced by next-generation sequencing (NGS). Comprehensive phylogenetic analyses showed that five of the viruses belong to sub-genotype VI1.2.1.1.2.1 and 13 isolates belong to sub-genotype VI.2.1.1.2.2. The results demonstrate that these sub-genotypes have been predominant in China during the last decade. The viruses of these sub-genotypes have been independently maintained and continuously evolved for over 20 years, and differ significantly from those causing outbreaks worldwide during the 1980s to 2010s. The viral reservoir remains unknown and possibilities of the viruses being maintained in both pigeon farms and wild bird populations are viable. In vivo characterization of the isolates' pathogenicity estimated mean death times between 62 and 114 hours and intracerebral pathogenicity indices between 0.00 and 0.63. Cross-reactivity testing showed minor antigenic differences between the studied viruses and the genotype II LaSota vaccine. These data will facilitate PPMV-1 epidemiology studies, vaccine development, and control of Newcastle disease in pigeons and poultry.

Experimental pigeon paramyxovirus-1 infection in chicken: evaluation of infectivity, clinical and pathological manifestations and diagnostic methods.

Several pigeon paramyxovirus-1 (PPMV-1) outbreaks in feral pigeons were described recently in Switzerland. The potential of PPMV-1 to induce the notifiable Newcastle disease in chickens is discussed controversially. Therefore, in order to study epidemiologically relevant parameters such as the kinetics of PPMV-1 replication and shedding as well as seroconversion after infection, chickens were infected experimentally with a Swiss PPMV-1 isolate. This generated also defined sample material for the comparison of diagnostic tests. The infectivity of the Swiss PPMV-1 isolate for chickens was demonstrated successfully by virus shedding after experimental inoculation. Our data suggest that long-lasting shedding for up to 60 days can occur in chickens infected with PPMV-1. The isolate used here was of low pathogenicity for chickens. Different quantitative reverse transcription PCR assays were evaluated with a set of Swiss PPMV-1 isolates, and various samples from experimentally infected chickens were analysed with respect to their suitability for viral RNA detection. At 14 days post-infection, virus genome was detected mainly in spleen, caecal tonsils, heart, cloacal swabs, liver, proventriculus, duodenum and kidney tissue samples. Overall, the level of virus replication was low. Not all assays used routinely in diagnostics were capable of detecting viral genome from the isolates tested. Possible explanations are the genetic divergence of PPMV-1 and the low level of viral RNA in the samples. In contrast, two methods that are not used routinely proved more suitable for virus-genome detection. Importantly, the collection of material from various different organs is recommended, in addition to the kidney and brain analysed routinely. In conclusion, this study shows that there is a need to reconsider the type of samples and the protocols used for the detection of PPMV-1 RNA in chickens.

Comparative clinico-pathological assessment of velogenic (sub-genotype VIIi) and mesogenic (sub-genotype VIm) Avian avulavirus 1 in chickens and pigeons.

Newcastle disease (ND), caused by virulent Avian avulavirus 1 (AAvV 1), affects a wide range of avian species worldwide. Recently, several AAvVs of diverse genotypes have emerged with varying genomic and residue substitutions, and subsequent clinical impact on susceptible avian species. We assessed the clinico-pathological influence of two different AAvV 1 pathotypes [wild bird originated-velogenic strain (sub-genotype VIIi, MF437287) and feral pigeon originated-mesogenic strain (sub-genotype VIm, KU885949)] in commercial broiler chickens and pigeons. The velogenic strain caused 100% mortality in both avian species while the mesogenic strain caused 0% and 30% mortality in chickens and pigeons, respectively. Both strains showed tissue tropism for multiple tissues including visceral organs; however, minor variances were observed according to host and pathotype. The observed gross and microscopic lesions were typical of AAvV 1 infection. Utilizing oropharyngeal and cloacal swabs, a comparable pattern of viral shedding was observed for both strains from each of the infected individuals of both avian species. The study concludes a varying susceptibility of chickens and pigeons to different wild bird-originated AAvV 1 pathotypes and, therefore, suggests continuous monitoring and surveillance of currently prevailing strains for effective control of the disease worldwide, particularly in disease-endemic countries.

The Emergence of Avian Orthoavulavirus 13 in Wild Migratory Waterfowl in China Revealed the Existence of Diversified Trailer Region Sequences and HN Gene Lengths within this Serotype.

Avian orthoavulavirus 13 (AOAV-13), also named avian paramyxovirus 13 (APMV-13), has been found sporadically in wild birds around the world ever since the discovery of AOAV-13 (AOAV-13/wild goose/Shimane/67/2000) in a wild goose from Japan in 2000. However, there are no reports of AOAV-13 in China. In the present study, a novel AOAV-13 virus (AOAV-13/wild goose/China/Hubei/V93-1/2015), isolated from a wild migratory waterfowl in a wetland of Hubei province of China, during active surveillance from 2013 to 2018, was biologically and genetically characterized. Phylogenetic analyses demonstrated a very close genetic relationship among all AOAV-13 strains, as revealed by very few genetic variations. Moreover, pathogenicity tests indicated that the V93-1 strain is a low virulent virus for chickens. However, the genome of the V93-1 virus was found to be 16,158 nucleotides (nt) in length, which is 12 nt or 162 nt longer than the other AOAV-13 strains that have been reported to date. The length difference of 12 nt in strain V93-1 is due to the existence of three repeats of the conserved sequence, "AAAAAT", in the 5'-end trailer of the genome. Moreover, the HN gene of the V93-1 virus is 2070 nt in size, encoding 610 aa, which is the same size as the AOAV-13 strain from Japan, whereas that of two strains from Ukraine and Kazakhstan are 2080 nt in length, encoding 579 aa. We describe a novel AOAV-13 in migratory waterfowl in China, which suggests that diversified trailer region sequences and HN gene lengths exist within serotype AOAV-13, and highlight the need for its constant surveillance in poultry from live animal markets, and especially migratory birds.

Novel penguin Avian avulaviruses 17, 18 and 19 are widely distributed in the Antarctic Peninsula.

Three novel Avian avulavirus species were discovered and isolated during 2017 from Gentoo penguins (Pygoscelis papua) at Kopaitic island in the Northwestern region of the Antarctic Peninsula. The viruses were officially named as Avian avulavirus 17 (AAV17), Avian avulavirus 18 (AAV18) and Avian avulavirus 19 (AAV19), collectively referred to as penguin avulaviruses (PAVs). To determine whether these viruses are capable of infecting the three species of Pygoscelis spp. penguins (Gentoo, Adelie and Chinstrap) and assess its geographical distribution, serum samples were collected from seven locations across the Antarctic Peninsula and Southern Shetland Islands. The samples were tested by Hemagglutination inhibition assay using reference viruses for AAV17, AAV18 and AAV19. A total of 498 sera were tested, and 40 were positive for antibodies against AAV17, 20 for AAV18 and 45 for AAV19. Positive sera were obtained for the penguin's species for each virus; however, antibodies against AAV18 were not identified in Adelie penguins. Positive penguins were identified in all regions studied. Positive locations include Ardley Island and Cape Shirreff at Livingston Island (Southern Shetland Region); Anvers Island, Doumer Island and Paradise Bay in the Central Western region; and Avian Island at Southwestern region of the Antarctic Peninsula. The lowest occurrence was observed at the Southwestern region at Lagotellerie Island, where all samples were negative. On the other hand, Cape Shirreff and Paradise Bay showed the highest antibody titres. Field samples did not evidence cross-reactivity between viruses, and detection was significantly higher for AAV19 and lower for AAV18. This is the first serologic study on the prevalence of the novel Avian avulaviruses including different locations in the white continent. The results indicate that these novel viruses can infect the three Pygoscelis spp. penguins, which extend across large distances of the Antarctic Peninsula.

A comparative genomic and evolutionary analysis of circulating strains of Avian avulavirus 1 in Pakistan.

Newcastle disease, caused by Avian avulavirus 1 (AAvV 1), is endemic to many developing countries around the globe including Pakistan. Frequent epidemics are not uncommon even in vaccinated populations and are largely attributed to the genetic divergence of prevailing isolates and their transmission in the environment. With the strengthening of laboratory capabilities in Pakistan, a number of genetically diverse AAvV 1 strains have recently been isolated and individually characterized in comparison with isolates reported elsewhere in the world. However, there lacks sufficient comparative genomic and phylogenomic analyses of field circulating strains that can elucidate the evolutionary dynamics over a period of time. Herein, we enriched the whole genome sequences of AAvV reported so far (n = 35) from Pakistan and performed comparative genomic, phylogenetic and evolutionary analyses. Based on these analyses, we found only isolates belonging to genotypes VI, VII and XIII of AAvV 1 in a wide range of avian and human hosts. Comparative phylogeny revealed the concurrent circulation of avulaviruses representing different sub-genotypes such as VIg, VIm, VIIa, VIIb, VIIe, VIIf, VIIi, XIIIb and XIIId. We found that the isolates of genotype VII were more closely associated with viruses of genotype XIII than genotype VI. An inter-genotype comparative residue analysis revealed a few substitutions in structurally and functionally important motifs. Putative recombination events were reported for only one of the captive-wild bird (pheasant)-origin isolates. The viruses of genotype VII had a high genetic diversity as compared to isolates from genotypes VI and XIII and, therefore, have more potential to evolve over a period of time. Taken together, the current study provides an insight into the genetic diversity and evolutionary dynamics of AAvV 1 strains circulating in Pakistan. Such findings are expected to facilitate better intervention strategies for the prevention and control of ND in disease-endemic countries across the globe particularly Pakistan.

A comparative phylogenomic analysis of avian avulavirus 1 isolated from non-avian hosts: conquering new frontiers of zoonotic potential among species.

A number of avian avulavirus 1 (AAvV 1) isolates have been reported from avian and non-avian hosts worldwide with varying clinical consequences. In this regard, robust surveillance coupled with advanced diagnostics, genomic analysis, and disease modelling has provided insight into the molecular epidemiology and evolution of this virus. The genomic and evolutionary characteristics of AAvV 1 isolates originating from avian hosts have been well studied, but those originating from non-avian hosts have not. Here, we report a comparative genomic and evolutionary analysis of so-far reported AAvV 1 isolates originating from hosts other than avian species (humans, mink and swine). Phylogenetic analysis showed that AAvV 1 isolates clustered in five distinct genotypes (I, II, VI, VII and XIII). Further analysis revealed clustering of isolates into clades distant enough to be considered distinct subgenotypes, along with a few substitutions in several significant motifs. Although further investigation is needed, the clustering of AAvV 1 strains isolated from non-avian hosts into novel subgenotypes and the presence of substitutions in important structural and biological motifs suggest that this virus can adapt to novel hosts and therefore could have zoonotic potential.

Genetic characterization of one duck-origin paramyxovirus type 4 strain in China.

Avian paramyxovirus type 4 (APMV-4) has been frequently reported from wildfowl and waterfowl in recent year. However, few studies have reported on the molecular characteristics and regional transmission of APMV-4, knowledge of which is important for understanding the genetic diversity and epidemiology of avian paramyxovirus. Herein, we report the isolation of one APMV-4 strain, designated as QY17, from the duck in eastern China. The determined complete genome of the isolate with six gene segments 3'-N-P-M-F-HN-L-5' was 15,054 nt in length. Genetic analysis of the whole-fusion gene of this isolate showed that QY17 was derived from a Eurasian lineage. Further phylogenetic analysis showed that the duck-origin strain QY17 had a highly genetic relationship with representative APMV-4 strains from wildfowl in neighbouring regions. These genetic results suggested that APMV-4 viral exchange may occur in wildfowl and poultry via wild bird migration.

Co-Circulation and Excretion Dynamics of Diverse Rubula- and Related Viruses in Egyptian Rousette Bats from South Africa.

The Egyptian rousette bat (Rousettus aegyptiacus) has previously been implicated as the natural host of a zoonotic rubulavirus; however, its association with rubulaviruses has been studied to a limited extent. Urine, spleen, and other organs collected from the R. aegyptiacus population within South Africa were tested with a hemi-nested RT-PCR assay targeting a partial polymerase gene region of viruses from the Avula- and Rubulavirus genera. Urine was collected over a 14-month period to study the temporal dynamics of viral excretion. Diverse rubulaviruses, including viruses related to human mumps and parainfluenza virus 2, were detected. Active excretion was identified during two peak periods coinciding with the host reproductive cycle. Analysis of additional organs indicated co-infection of individual bats with a number of different putative rubulaviruses, highlighting the limitations of using a single sample type when determining viral presence and diversity. Our findings suggest that R. aegyptiacus can harbor a range of Rubula- and related viruses, some of which are related to known human pathogens. The observed peaks in viral excretion represents potential periods of a higher risk of virus transmission and zoonotic disease spill-over.

[Molecular-genetic characterization of Avian avulavirus 20 strains isolated from wild birds.]

INTRODUCTION: Previously unknown paramyxovirus strains were isolated from wild birds in 2013-2014 in Kazakhstan and subsequently identified as representatives of the novel Avian avulavirus 20 species. The aims and tasks were molecular genetic characterization of novel avulaviruses and investigation of their phylogenetic relationships. MATERIAL AND METHODS: Embryonated chicken eggs were inoculated with cloacal and tracheal swabs from wild birds with subsequent virus isolation. The complete nucleotide sequences of viral genomes were obtained by massive parallel sequencing with subsequent bioinformatics processing. RESULTS: By initial infection of chicken embryos with samples from 179 wild birds belonging to the Anatidae, Laridae, Scolopacidae and Charadriidae families, 19 hemagglutinating agents were isolated, and five of them were identified as representatives of new viral species. The study of their sequenced genomes revealed their similarity in size, but there was a significant genetic variability within the species. 2,640 nucleotide substitutions were identified and 273 of them were nonsynonymous, influencing the protein structure of viruses. It was shown that isolates Avian avulavirus 20/black-headed gull/Balkhash/5844/2013 and Avian avulavirus 20 /great black-headed gull/Atyrau/5541/2013 were 86% and 95% respectively identical to the previously described reference strain, indicating a significant evolutionary divergence within species. DISCUSSION: The authors suggest the existence of two independent lineages - the Caspian, represented by the reference strain Aktau/5976 and Atyrau/5541, as well as the second, geographically significantly distant Balkhash lineage. CONCLUSION: The study confirms the role of the birds of the Laridae family as the main reservoir of Avian avulavirus 20 in the avifauna that plays a key role in maintaining viruses of the genus Avulavirus in the biosphere and is a potential natural source for the emergence of new viral variants. Continuous surveillance of them in the wild is one of the most important tasks in ensuring the safety of the poultry industry.

Development of an avian avulavirus 1 (AAvV-1) L-gene real-time RT-PCR assay using minor groove binding probes for application as a routine diagnostic tool.

Newcastle disease is a devastating disease of poultry caused by Newcastle disease virus (NDV), a virulent form of avian avulavirus 1 (AAvV-1). A rapid, sensitive and specific means for the detection of NDV is fundamental for the control of this notifiable transboundary virus. Although several real-time RT-PCR assays exist for the detection of AAvV-1, diagnostic sensitivity and specificities can be sub-optimal. In this study, we describe a modification to an existing AAvV-1 l-gene RT-PCR screening assay, where the original probe set was replaced with minor groove binding (MGB) probes, to create the MGB l-gene assay. The diagnostic sensitivity and specificity of this assay was evaluated against a broad panel of both Class I and Class II AAvV-1 viruses of diverse and representative lineages/genotypes in both clinical samples and amplified viruses, and compared with a number of previously published real-time RT-PCR screening assays for AAvV-1. The MGB l-gene assay outperformed all other assays in this assessment, with enhanced sensitivity and specificity, detecting isolates from a broad range of virus lineages/genotypes (including contemporaneously-circulating strains). The assay has also proved its value for screening original clinical samples for the presence of AAvV-1, thus providing an improved screening assay for routine detection of this notifiable disease agent.

Pathological and molecular findings of avian avulavirus type 1 outbreak in pigeons (Columba livia) of southern Brazil / Achados patológicos e moleculares da infecção por avulavirus aviário tipo 1 em pombos (Columba livia) do sul do Brasil

The Newcastle disease, caused by avian avulavirus type 1 strains (APMV-1) is an important avian disease involved into high rates of mortality and economic losses. Several outbreaks have been reported over the last 30 years in Columbiformes in different parts of the world, caused by a adapted variant strain of AAvV-1, called pigeon paramyxovirus type 1 (PPMV-1). A high mortality associated with an outbreak was analyzed in free-living pigeons (Columba livia) in a public square in Porto Alegre in Southern Brazil. A total of 24 pigeons moribund or freshly dead, within five weeks interval were submitted to necropsy, histopathological, immunohistochemical (anti-Newcastle), and RT-PCR followed by sequencing of the amplification products analysis. They presented neurological signs, non-suppurative encephalitis and encephalomyelitis, and mononuclear inflammatory infiltrate in different organs. Immunohistochemical analysis in nine pigeons tissue showed that anti-Newcastle was expressed in brain, kidney, liver and pancreas. The RT-PCR test for the M protein of Newcastle disease virus was positive in six pigeons. The differential diagnosis of Influenza, West Nile, Mycoplasma gallisepticum and Mycoplasma synoviae in all pigeons presented negative results. The sequence of amino acids in the cleavage site region of the F protein was 112RRQKRF117 classifying the strain as virulent. The phylogenetic analysis classified this virus strain into Class II and VI genotype.(AU)

A doença de Newcastle, causada por cepas de avulavirus aviário tipo 1 (AAvV-1), é uma doença de aves importante por causar altos índices de mortalidade e perdas econômicas. Vários surtos têm sido relatados ao longo de 30 anos em aves da ordem Columbiformes, em diferentes partes do mundo, causados por uma cepa variante específica de AAvV-1, denominada Pigeon paramyxovirus tipo 1 (PPMV-1). Foi analisado um surto de mortalidade em pombos domésticos (Columba livia), provenientes de uma praça pública em Porto Alegre, no Sul do Brasil. Vinte e quatro aves moribundas ou mortas foram submetidas, no intervalo de cinco semanas, ao exame de necropsia, exame histopatológico, imuno-histoquímico anti-Newcastle, RT-PCR e sequenciamento. Apresentaram sinais neurológicos, encefalite e encefalomielite não supurativas, além de infiltrado inflamatório mononuclear em diversos órgãos. Nove aves demonstraram exame imuno-histoquímico positivo em órgãos como cérebro, rim, fígado e pâncreas. Seis aves foram positivas no exame de RT-PCR para a proteína M do vírus da Doença de Newcastle. Nos exames de diagnósticos diferenciais de Influenza, West Nile, Mycoplasma gallisepticum e Mycoplasma synoviae, todas as aves testadas foram negativas. A sequência dos aminoácidos na região do sítio de clivagem da proteína foi 112RRQKRF117, classificando a cepa como virulenta. De acordo com a análise filogenética o vírus identificado foi classificado como pertencente à classe II e ao genótipo VI.(AU)