Development of a Multiplex PCR Assay for Rapid Differentiation of Fowlpox and Pigeonpox Viruses.

The aim of this study was to develop a multiplex PCR assay capable of rapidly differentiating two major Avipoxvirus (APV) species, Fowlpox virus (FWPV) and Pigeonpox virus (PGPV), which cause disease in bird species. Despite the importance of a rapid differentiation assay, no such assay exists that can differentiate the APV species without sequencing. To achieve this, species-specific target DNA fragments were selected from the fpv122 gene of FWPV and the HM89_gp120 gene of PGPV, which are unique to each genome. Nine samples collected from unvaccinated chickens, pigeons, and a turkey with typical pox lesions were genetically identified as FWPV and PGPV. The designed primers and target DNA fragments were validated using in silico analyses with the nucleotide Basic Local Alignment Search Tool. The multiplex PCR assay consisted of species-specific primers and previously described PanAPV primers (genus-specific) and was able to differentiate FWPV and PGPV, consistent with the phylogenetic outputs. This study represents the first successful differentiation of FWPV and PGPV genomes using a conventional multiplex PCR test. This assay has the potential to facilitate the rapid diagnosis and control of APV infections.

Desarrollo de un ensayo de PCR múltiple para la diferenciación rápida de los virus de la viruela aviar y la viruela de paloma. El objetivo de este estudio fue desarrollar un ensayo de PCR múltiple capaz de diferenciar rápidamente dos especies principales de Avipoxvirus (APV) (viruela del pollo), el Fowlpox virus (FWPV) y el Pigeonpox virus (PGPV), (viruela de la gallina), que causan enfermedades en especies de aves. A pesar de la importancia de un ensayo de diferenciación rápida, no existe ningún ensayo que pueda diferenciar las especies de APV sin secuenciación. Para lograr esto, se seleccionaron fragmentos blanco de ADN específicos de especie del gene fpv122 de FWPV y el gene HM89_gp120 de Pigeonpox virus, que son únicos para cada genoma. Nueve muestras recolectadas de pollos, palomas y un pavo que no fueron vacunados con lesiones típicas de la viruela se identificaron genéticamente como FWPV y PGPV. Los iniciadores diseñados y los fragmentos de ADN blanco se validaron mediante análisis in silico mediante la herramienta de búsqueda de alineación local básica de nucleótidos (BLAST). El ensayo de PCR múltiple consistió en iniciadores específicos de especie y cebadores PanAPV previamente descritos (específicos de género) y fue capaz de diferenciar entre Fowlpox virus y Pigeonpox virus, de acuerdo con los resultados filogenéticos. Este estudio representa la primera diferenciación exitosa de los genomas de Fowlpox virus y Pigeonpox virus utilizando una prueba de PCR múltiple convencional. Este ensayo tiene el potencial de facilitar el diagnóstico rápido y el control de las infecciones por Avipoxvirus.

Evidence of a Possible Viral Host Switch Event in an Avipoxvirus Isolated from an Endangered Northern Royal Albatross (Diomedea sanfordi).

Avipoxviruses have been characterized from many avian species. Two recent studies have reported avipoxvirus-like viruses with varying pathogenicity in reptiles. Avipoxviruses are considered to be restricted to avian hosts. However, reports of avipoxvirus-like viruses from reptiles such as the green sea turtle (Chelonia mydas) and crocodile tegu (Crocodilurus amazonicus) suggest that cross-species transmission, within avian species and beyond, may be possible. Here we report evidence for a possible host switching event with a fowlpox-like virus recovered from an endangered northern royal albatross (Diomodea sanfordi)-a species of Procellariiformes, unrelated to Galliformes, not previously known to have been infected with fowlpox-like viruses. Complete genome sequencing of this virus, tentatively designated albatrosspox virus 2 (ALPV2), contained many fowlpox virus-like genes, but also 63 unique genes that are not reported in any other poxvirus. The ALPV2 genome contained 296 predicted genes homologous to different avipoxviruses, 260 of which were homologous to an American strain of fowlpox virus (FWPV). Subsequent phylogenetic analyses indicate that ALPV2 likely originated from a fowlpox virus-like progenitor. These findings highlight the importance of host-switching events where viruses cross species barriers with the risk of disease in close and distantly related host populations.

Genomic characterisation of a novel avipoxvirus, magpiepox virus 2, from an Australian magpie (Gymnorhina tibicen terraereginae).

Avipoxviruses are large, double-stranded DNA viruses and are considered significant pathogens that may impact on the conservation of numerous bird species. The vast majority of avipoxviruses in wild birds remain uncharacterised and their genetic variability is unclear. Here, we fully sequenced a novel avipoxvirus, magpiepox virus 2 (MPPV2), which was isolated 62 years ago (in 1956) from an Australian black-backed magpie. The MPPV2 genome was 298,392 bp in length and contained 419 predicted open-reading frames (ORFs). While 43 ORFs were novel, a further 24 ORFs were absent compared with another magpiepox virus (MPPV) characterised in 2018. The MPPV2 genome contained an additional ten genes that were homologs to shearwaterpox virus 2 (SWPV2). Subsequent phylogenetic analyses showed that the novel MPPV2 was most closely related to other avipoxviruses isolated from passerine and shearwater bird species, and demonstrated a high degree of sequence similarity (95.0%) with MPPV.

Genomic Characterisation of a Novel Avipoxvirus Isolated from an Endangered Yellow-Eyed Penguin (Megadyptes antipodes).

Emerging viral diseases have become a significant concern due to their potential consequences for animal and environmental health. Over the past few decades, it has become clear that viruses emerging in wildlife may pose a major threat to vulnerable or endangered species. Diphtheritic stomatitis, likely to be caused by an avipoxvirus, has been recognised as a significant cause of mortality for the endangered yellow-eyed penguin (Megadyptes antipodes) in New Zealand. However, the avipoxvirus that infects yellow-eyed penguins has remained uncharacterised. Here, we report the complete genome of a novel avipoxvirus, penguinpox virus 2 (PEPV2), which was derived from a virus isolate obtained from a skin lesion of a yellow-eyed penguin. The PEPV2 genome is 349.8 kbp in length and contains 327 predicted genes; five of these genes were found to be unique, while a further two genes were absent compared to shearwaterpox virus 2 (SWPV2). In comparison with penguinpox virus (PEPV) isolated from an African penguin, there was a lack of conservation within the central region of the genome. Subsequent phylogenetic analyses of the PEPV2 genome positioned it within a distinct subclade comprising the recently isolated avipoxvirus genome sequences from shearwater, canary, and magpie bird species, and demonstrated a high degree of sequence similarity with SWPV2 (96.27%). This is the first reported genome sequence of PEPV2 from a yellow-eyed penguin and will help to track the evolution of avipoxvirus infections in this rare and endangered species.

Molecular characterisation of a novel pathogenic avipoxvirus from an Australian passerine bird, mudlark (Grallina cyanoleuca).

Avipoxviruses have been recognised as significant pathogens in the conservation of numerous bird species. However, the vast majority of the avipoxviruses that infect wild birds remain uncharacterised. Here, we characterise a novel avipoxvirus, mudlarkpox virus (MLPV) isolated from an Australian passerine bird, mudlark (Grallina cyanoleuca). In this study, tissues with histopathologically confirmed lesions consistent with avian pox were used for transmission electron microscopy, and showed characteristic ovoid to brick-shaped virions, indicative of infectious particles. The MLPV genome was >342.7 Kbp in length and contained six predicted novel genes and a further six genes were missing compared to shearwaterpox virus-2 (SWPV-2). Subsequent phylogenetic analyses of the MLPV genome positioned the virus within a distinct subclade also containing recently characterised avipoxvirus genomes from shearwater, canary and magpie bird species, and demonstrated a high degree of sequence similarity with SWPV-2 (94.92%).

Avipoxvirus infection in two captive Japanese cormorants (Phalacrocorax capillatus).

Cormorant fishing is a traditional Japanese fishing method using captive Japanese cormorants (Phalacrocorax capillatus). Between June and July 2017, an avian pox outbreak was reported in captive cormorant populations throughout several distant cities in Japan. We examined the lesions obtained from two such affected cormorants, which were raised in distant cities. The affected cormorants were grossly characterized by the development of cutaneous nodules around the base of the beak. Histopathologically, these nodules consisted of marked epidermal hyperplasia with ballooning degeneration of spinous cells and eosinophilic intracytoplasmic inclusions (Bollinger bodies). The lesions displayed 4b core protein (P4b) of Avipoxvirus (APV) and DNA polymerase genes, which were detected by PCR. Moreover, the nucleotide sequences detected from both cormorants were found to be identical. No identical sequence was found in any international database. These findings suggest that both examined cormorants were infected with an identical APV, which has never been previously reported. According to the phylogenetic analysis, the detected sequences were observed to cluster in subclade A3, which consists mainly of the sequences detected from several marine birds, including other cormorant species. This observation suggests that the viruses might be maintained in Japanese cormorants in nature.

Molecular Phylogeny of an Avipoxvirus Isolated from Red-Flanked Blue Robin in China.

We first report avipoxvirus (APV) infection and an isolate named APV/03/2016 from a red-flanked blue robin (Tarsiger cyanurus) captured at Songhua Lake Scenic Area in Jilin City (Jilin Province, China) on March 24, 2016. The partial sequence of the 4b core protein gene and DNA polymerase gene of APV/03/2016 suggests that the virus belongs to the subclade B1 cluster of clade B (canarypox virus). The BLAST results showed the highest similarity of the two genes with the Pacific shearwater-isolated strain SWPV-2 (KX857215), canarypox virus strain D98-11133 (GQ487567), canarypox virus strain ATCC VR-111 (AY318871), avipoxvirus Mississippi isolate P89 (KC018048), and avipoxvirus Wisconsin isolate P92 (KC018051). The results indicate that APV/03/2016 is a canarypox-like virus. These findings demonstrate the continuous emergence of new APV hosts such as red-flanked blue robins and suggest that monitoring of APV circulation and evolution should be strengthened for T. cyanurus conservation.

Filogenia molecular de un Avipoxvirus aislado de ruiseñor coliazul en China. Se reporta por primera vez la infección por poxvirus aviar (APV) y un aislamiento denominado APV/03/2016 obtenido de un ruiseñor coliazul (Tarsiger cyanurus) capturado en el área escénica del Lago Songhua en la ciudad de Jilin (provincia de Jilin, China) el 24 de marzo de 2016. La secuencia parcial del gene de la proteína central 4b y el gene de la polimerasa de ADN del virus APV/03/2016 sugiere que el virus pertenece al subclado B1 del clado B (virus de la viruela del canario). Los resultados de la búsqueda mediante BLAST mostraron la mayor similitud de los dos genes con la cepa aislada de aves pelágicas del Pacífico (KX857215), virus de la viruela del canario cepa de virus D98-11133 (GQ487567), cepa de virus de la viruela del canario ATCC VR-111 (AY318871), aislamiento de avipoxvirus de Mississippi P89 (KC018048), y el aislamiento P89 de avipoxvirus en Wisconsin (KC018051). Los resultados indican que el virus APV/03/2016 es un virus similar al de la viruela del canario. Estos hallazgos demuestran la aparición continua de nuevos hospedadores de poxvirus aviares como el ruiseñor coliazul y sugieren que el monitoreo de la circulación y evolución de poxvirus aviares debería fortalecerse para la conservación del T. cyanurus.

The emergence of subclades A1 and A3 avipoxviruses in India.

During the years 2010-2018, avipoxvirus (APV) outbreaks were observed in the domestic chickens and pigeons present in the eastern Indian state of Odisha. Based on typical pox lesions, followed by molecular techniques, the overall morbidity was found to be 18%-19.23% and 16.92%-23% in chickens and pigeons, respectively. The cutaneous forms of the disease were observed with varied rates of mortality, being 47.36%-52.77% in chickens and 39.13%-92% in pigeons. PCR amplification targeting the viral P4b core protein-coding gene and the DNA polymerase gene confirmed the presence of APV strains in 10 birds. Subsequent phylogenetic analysis of these two genes confirmed that the circulating strains were members of APV clade A. The subclade analysis revealed the introduction of A1 and A3 subclades in Indian chickens and pigeons, respectively. This study is the first molecular record of APVs circulating in eastern Indian birds (Odisha) and involves the first use of the polymerase gene to reveal the circulating clades of Indian APVs.

Molecular characterisation of a novel pathogenic avipoxvirus from the Australian magpie (Gymnorhina tibicen).

Avipoxviruses are significant pathogens infecting a wide range of wild and domestic bird species globally. Here, we describe a novel genome sequence of magpiepox virus (MPPV) isolated from an Australian magpie. In the present study, histopathologically confirmed cutaneous pox lesions were used for transmission electron microscopic analysis, which demonstrated brick-shaped virions with regular spaced thread-like ridges, indicative of likely infectious particles. Subsequent analysis of the recovered MPPV genome positioned phylogenetically to a distinct sub-clade with the recently isolated avipoxvirus genome sequences from shearwater and canary bird species, and demonstrates a high degree of sequence similarity with CNPV (96.14%) and SWPV-2 (95.87%). The novel MPPV complete genome is missing 19 genes with a further 41 genes being truncated/fragmented compared to SWPV-2 and contains nine predicted unique genes. This is the first avipoxvirus complete genome sequence that infects Australian magpie.

Outbreak of Systemic Avian Pox in Canaries (Serinus canaria domestica) Associated with the B1 Subgroup of Avian Pox Viruses.

This study reports an outbreak of avian pox in a quarantine of canaries imported from Europe, with a mortality of 30% and clinical signs of dyspnea and blepharoconjunctivitis. During necropsy, beak cyanosis, serous blepharitis, caseous sinusitis, oropharyngitis, tracheitis, pulmonary edema, pneumonia, fibrinous airsacculitis, and splenomegaly were observed. Microscopically, edema, epithelial hyperplasia, hydropic degeneration, and vacuolated eosinophilic intracytoplasmic inclusion bodies were found; similar lesions were observed in the thymus, spleen, and other organs. The virus was isolated in chicken embryos, and it was identified and characterized using a sequence of 913 nucleotides of the DNA polymerase gene. Pathologic characteristics and molecular biology indicate the systemic presence of avian pox associated with an avipoxvirus of the B1 subgroup. Additionally, other lesions associated with Aspergillus sp., Macrorhabdus ornithogaster, and Isospora sp. were found, which could contribute to the high mortality. Canarypox virus should be considered a differential diagnosis in cases of dyspnea and high mortality in canary flocks.

Reporte de caso- Brote de viruela aviar sistémica en canarios (Serinus canaria domestica) asociado con el virus de la viruela aviar subgrupo B1. En este estudio se reporta un brote de viruela aviar en unos canarios importados de Europa que estaban bajo cuarentena, con una mortalidad del 30% y signos clínicos de disnea y blefaroconjuntivitis. Durante la necropsia, se observó cianosis de pico, blefaritis serosa, sinusitis caseosa, orofaringitis, traqueítis, edema pulmonar, neumonía, fibrinosa respiratoria y esplenomegalia. Microscópicamente, se encontró edema, hiperplasia epitelial, degeneración hidrópica y cuerpos de inclusión intracitoplásmicos eosinófilos vacuolados; Se observaron lesiones similares en el timo, el bazo y otros órganos. El virus se aisló en embriones de pollo, se identificó y caracterizó analizando una secuencia de 913 nucleótidos del gene de la polimerasa de ADN. Las características patológicas y la biología molecular indican la presentación sistémica de la viruela aviar asociada a un avipoxvirus del subgrupo B1. Además, se encontraron otras lesiones asociadas con Aspergillus sp., Macrorhabdus ornithogaster y Isopora sp., lo que pudo contribuir a la alta mortalidad. El virus de la viruela del canario debe considerarse un diagnóstico diferencial en casos de disnea y alta mortalidad en parvadas de canarios.

Rapid whole-genome based typing and surveillance of avipoxviruses using nanopore sequencing.

Avian pox is an infectious disease caused by avipoxviruses (APV), resulting in cutaneous and/or tracheal lesions. Poxviruses share large genome sizes (from 130 to 360 kb), featuring repetitions, deletions or insertions as a result of a long-term recombination history. The increasing performances of next-generation sequencing (NGS) opened new opportunities for surveillance of poxviruses, based on timely and affordable workflows. We investigated the application of the 3rd generation Oxford Nanopore Minion technology to achieve real-time whole-genome sequencing directly from lesions, without any enrichment or isolation step. Fowlpox lesions were sampled on hens, total DNA was extracted and processed for sequencing on a MinION, Oxford Nanopore. We readily generated whole APV genomes from cutaneous or tracheal lesions, without any isolation or PCR-based enrichment: Fowlpox virus reads loads ranged from 0.75% to 2.62% and reads up to 61 kbp were generated and readily assembled into 3 APV complete genomes. This long read size eases the assembly step and lowers the bioinformatics capacity requirements and processing time compared to huge sets of short reads. The complete genome analysis confirmed that these Fowlpox viruses cluster within clade A1 and host full length reticuloendotheliovirus (REV) inserts. The pathobiological relevance of REV insert, although a classical feature of fowlpoxviruses (FPVs), should be further investigated. Surveillance of emerging poxviruses could greatly benefit from real-time whole genome sequencing.

Molecular characterization of avipoxviruses circulating in Mozambique, 2016-2018.

Samples from 45 chickens, two turkeys, one peacock and one quail with symptoms of fowlpox were collected in Mozambique between November 2016 and January 2018. Phylogenetic analysis revealed that the samples contained avipoxviruses belonging to both clade A1 and clade A2. In addition, all of the Clade A1 viruses were positive by PCR for the integration of reticuloendotheliosis virus, while the clade A2 avipoxvirus samples were negative. This study confirms the circulation of clade A1 avipoxviruses in Mozambique in addition to identifying clade A2 for the first time in the country.

Comparative analysis of avian poxvirus genomes, including a novel poxvirus from lesser flamingos (Phoenicopterus minor), highlights the lack of conservation of the central region.

BACKGROUND: Avian poxviruses are important pathogens of both wild and domestic birds. To date, seven isolates from subclades A and B and one from proposed subclade E, have had their genomes completely sequenced. The genomes of these isolates have been shown to exhibit typical poxvirus genome characteristics with conserved central regions and more variable terminal regions. Infection with avian poxviruses (APVs) has been reported in three species of captive flamingo, as well as a free-living, lesser flamingo at Kamfers dam, near Kimberley, South Africa. This study was undertaken to further characterise this virus which may have long term effects on this important and vulnerable, breeding population. RESULTS: Gene content and synteny as well as percentage identities between conserved orthologues was compared between Flamingopox virus (FGPV) and the other sequenced APV genomes. Dotplot comparisons revealed major differences in central regions that have been thought to be conserved. Further analysis revealed five regions of difference, of differing lengths, spread across the central, conserved regions of the various genomes. Although individual gene identities at the nucleotide level did not vary greatly, gene content and synteny between isolates/species at these identified regions were more divergent than expected. CONCLUSION: Basic comparative genomics revealed the expected similarities in genome architecture but an in depth, comparative, analysis showed all avian poxvirus genomes to differ from other poxvirus genomes in fundamental and unexpected ways. The reasons for these large genomic rearrangements in regions of the genome that were thought to be relatively conserved are yet to be elucidated. Sequencing and analysis of further avian poxvirus genomes will help characterise this complex genus of poxviruses.

Identification of Clade E Avipoxvirus, Mozambique, 2016.

Analysis of scab samples collected from poultry during outbreaks of fowlpox in Mozambique in 2016 revealed the presence of clade E avipoxviruses. Infected poultry were from flocks that had been vaccinated against fowlpox virus. These findings require urgent reevaluation of the vaccine formula and control strategies in this country.

MOLECULAR EPIDEMIOLOGY OF AVIAN POXVIRUS IN THE ORIENTAL TURTLE DOVE (STREPTOPELIA ORIENTALIS) AND THE BITING MIDGE (CULICOIDES ARAKAWAE) IN THE REPUBLIC OF KOREA.

A total of 600 wild birds were analyzed for the causes of mortality in the Republic of Korea (ROK) from 2011 to 2013. Avian poxvirus (APV) infections were identified as the primary cause of mortality in 39% (29/74) Oriental Turtle Doves (Streptopelia orientalis). At necropsy, all 29 S. orientalis birds, of which, 76% (22/29) were juveniles, had severe diphtheritic lesions in their oral and nasal cavities and on their eyelids, which were the lesions of APV that resulted in mortality. We detected APV infection by chorioallantoic membrane inoculation and molecular study of the partial region of the P4b gene. All isolates belonged to the same APV strain and were identical to strains isolated from several different pigeon species in South Africa. Phylogenetically, the APV strain identified in S. orientalis belonged to subclade A2, which includes isolates from several species of pigeons from different parts of the world, including the United Kingdom, Germany, India, Egypt, Hawaii, Georgia, Hungary, South Africa, Tanzania, and the ROK. This identity indicated that this diphtheritic APV strain may be a potential pathogen of other pigeon species in the ROK and neighboring countries throughout the range of S. orientalis. However, reticuloendotheliosis virus insertion into the APV genome was not detected by PCR in any of the 29 APV infections. An identical strain of APV observed in S. orientalis was also detected in Culicoides arakawae (biting midge), with annual peak populations corresponding to the presence of APV in S. orientalis. Culicoides arakawae may be a primary vector of APV in S. orientalis. Active surveillance of APVs in wild birds and C. arakawae is needed to better understand the epidemiology of APVs, host-vector relationships, and its ecological effects on S. orientalis in the ROK.

Avian Pox in Native Captive Psittacines, Brazil, 2015.

To investigate an outbreak of avian pox in psittacines in a conservation facility, we examined 94 birds of 10 psittacine species, including sick and healthy birds. We found psittacine pox virus in 23 of 27 sick birds and 4 of 67 healthy birds. Further characterization is needed for these isolates.

Unique genomic organization of a novel Avipoxvirus detected in turkey (Meleagris gallopavo).

Avipoxviruses are emerging pathogens affecting over 200 bird species worldwide. Genetic characterization of avipoxviruses is performed by analysis of genomic regions encoding the 4b and DNA polymerase. Whole genome sequence data are limited to a few avipoxvirus isolates. Based on phylogenetic analysis three major genetic clades are distinguished. In this study we report a novel avipoxvirus strain causing skin lesions in domestic turkey. The virus was identified in Hungary during 2011 in a flock of turkey vaccinated against avipoxvirus infection. The genome of the isolated strain, TKPV-HU1124/2011, was uniquely short (∼188.5kbp) and was predicted to encode reduced number of proteins. Phylogenetic analysis of the genes encoding the 4b and DNA polymerase separated TKPV-HU1124/2011 from other turkey origin avipoxviruses and classified it into a new genetic clade. This study permits new insight into the genetic and genomic heterogeneity of avipoxviruses and pinpoints the importance of strain diversity in vaccine efficacy.

Time scale evolution of avipoxviruses.

Avipoxviruses are divided into three clades: canarypox-like viruses, fowlpox-like viruses, and psittacinepox-like viruses. Several molecular clock and demographic models available in the BEAST package were compared on three avipoxvirus genes (P4b, cnpv186 and DNA polymerase genes), which enabled to determine that avipoxviruses evolved at a rate of 2-8×10(-5)substitution/site/year, in the range of poxviruses previously reported evolution rates. In addition, the date of mean time of divergence of avipoxviruses from a common ancestor was extrapolated to be about 10,000-30,000years ago, at the same period as modern poxvirus species. Our findings will facilitate epidemiological investigations on avipoxviruses' spread, origin and circulation.

Diversity of avipoxviruses in captive-bred Houbara bustard.

Implementation of conservation breeding programs is a key step to ensuring the sustainability of many endangered species. Infectious diseases can be serious threats for the success of such initiatives especially since knowledge on pathogens affecting those species is usually scarce. Houbara bustard species (Chlamydotis undulata and Chlamydotis macqueenii), whose populations have declined over the last decades, have been captive-bred for conservation purposes for more than 15 years. Avipoxviruses are of the highest concern for these species in captivity. Pox lesions were collected from breeding projects in North Africa, the Middle East and Central Asia for 6 years in order to study the diversity of avipoxviruses responsible for clinical infections in Houbara bustard. Molecular and phylogenetic analyses of 113 and 75 DNA sequences for P4b and fpv140 loci respectively, revealed an unexpected wide diversity of viruses affecting Houbara bustard even at a project scale: 17 genotypes equally distributed between fowlpox virus-like and canarypox virus-like have been identified in the present study. This suggests multiple and repeated introductions of virus and questions host specificity and control strategy of avipoxviruses. We also show that the observed high virus burden and co-evolution of diverse avipoxvirus strains at endemic levels may be responsible for the emergence of novel recombinant strains.