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Article

Analysis of Avian Orthoavulavirus 1 Detected in the Russian Federation between 2017 and 2021

by
Nelly A. Guseva
1,*,
Sergey N. Kolosov
1,
Nikolay G. Zinyakov
1,
Artem V. Andriyasov
1,
Renfu Yin
2,
Lidya O. Scherbakova
1,
Evgenia V. Ovchinnikova
1,
Zoya B. Nikonova
1,
Dmitry B. Andreychuk
1,
Alexander V. Sprygin
1,
Ilya A. Chvala
1 and
Natalia V. Moroz
1
1
Reference Laboratory for Avian Viral Diseases, FGBI “Federal Centre for Animal Health” (FGBI “ARRIAH”), 600901 Vladimir, Russia
2
Key Laboratory of Zoonosis Research, Ministry of Education, College of Veterinary Medicine, Jilin University, Changchun 130062, China
*
Author to whom correspondence should be addressed.
Vaccines 2023, 11(6), 1032; https://0-doi-org.brum.beds.ac.uk/10.3390/vaccines11061032
Submission received: 20 February 2023 / Revised: 18 May 2023 / Accepted: 25 May 2023 / Published: 27 May 2023
(This article belongs to the Section Veterinary Vaccines)
Browse Figures
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Abstract

:
Newcastle disease virus (NDV, Avian orthoavulavirus type 1, AOAV-1) is a contagious high-impact poultry pathogen with infections detected worldwide. In the present study, 19,500 clinical samples from wild bird species and poultry collected from 28 regions of Russia between 2017 and 2021 were screened for the presence of the AOAV-1 genome. NDV RNA was detected in 15 samples from wild birds and 63 samples from poultry. All isolates were screened for a partial sequence of the fusion (F) gene that included the cleavage site. Phylogenetic analysis demonstrated that lentogenic AOAV-1 I.1.1, I.1.2.1, and II genotypes were dominant among vaccine-like viruses in the territory of the Russian Federation. A vaccine-like virus with a mutated cleavage site (112-RKQGR^L-117) was detected in turkeys. Among the virulent AOAV-1 strains, viruses of the XXI.1.1, VII.1.1, and VII.2 genotypes were identified. The cleavage site of viruses of the XXI.1.1 genotype had a 112-KRQKR^F-117 amino acid sequence. The cleavage site of viruses with VII.1.1 and VII.2 genotypes had a 112-RRQKR^F-117 amino acid sequence. The data collected by the present study demonstrate the distribution and dominance of the virulent VII.1.1 genotype in the Russian Federation between 2017 and 2021.

1. Introduction

Newcastle disease (ND) is an annually reported viral disease in poultry, including ducks, pigeons, geese, and turkeys. ND is of considerable economic significance for the poultry industry due to its impact and is reportable to the World Organization for Animal Health. Newcastle disease is caused by virulent strains of Avian orthoavulavirus type 1 (AOAV-1), also known as Newcastle disease virus (NDV), of the genus Orthoavulavirus belonging to the family Paramyxoviridae (International Committee on Taxonomy of Viruses). AOAV-1 has wide genetic diversity. All AOAV-1 strains and isolates are currently subdivided into two classes: class I and class II. Class I comprises genotype 1 only, which is subdivided into sub-genotypes 1.1.1, 1.1.2, and 1.2. Class II comprises at least 20 different genotypes, some of which are subdivided into sub-genotypes [1]. Recent studies have analyzed the NDV genome, including the F gene, to delineate the molecular evolution of circulating ND strains [2,3,4]. Cleavage of the F gene protein is considered to be a major determinant of AOAV-1 virulence. Following replication, the fusion gene is translated into a precursor protein, F0, followed by cleavage by host cell proteases into F1 and F2 subunits to produce infectious viral particles. The amino acid sequence at the F protein cleavage site is used to classify AOAV-1 strains according to low virulence (lentogenic pathotype) or high virulence (NDV or velogenic pathotype) [5,6,7].
Timely identification of circulating mesogenic and velogenic strains plays a key role in maintaining disease-free status, which can be accomplished by phylogenetic studies. Russia is crossed by many major migration flyways and serves as the major breeding area for many migratory species in the Palearctic. Identifying wildlife reservoirs may help predict new epizootics and facilitate the implementation of preventative measures. The most recent extensive studies of NDV in the territory of the Russian Federation and neighboring countries were conducted in 2010 [8]. The F gene fragment was comparatively analyzed in 79 NDV strains isolated from domestic and synanthropic birds in Kazakhstan, Kirghizia, Ukraine, and Russia between 1993 and 2007. All newly characterized isolates belonged to three NDV genotype VII subgroups: VIIa, VIIb, and VIId. Since then, no comparable studies have been undertaken despite the ongoing reports of NDV cases.
The current epidemiological situation shows the need to monitor NDV since the spread of NDV among migratory and synanthropic birds (pigeons, crows, and jackdaws) pose a serious threat to the commercial poultry industry. The goal of this study is to carry out a phylogenetic analysis of nucleotide sequences of the F gene of AOAV-1 isolates from avian species from the wild and poultry in an area stretching all over Russia in 2017–2021.

2. Materials and Methods

2.1. Samples

Samples of avian biological material (internal organs, feces, and cloacal or tracheal swabs) were used in the present study. Samples were collected by inspectors of the Federal Service for Veterinary and Phytosanitary Surveillance and Veterinary Departments from poultry on commercial farms or in backyards and from wild and synanthropic birds. A total of 19,500 samples were accessioned for the present study.

2.2. RNA Extraction

RNA was extracted using RNeasy Mini Kit (Qiagen, Hilden, Germany) according to the manufacturer’s instructions.

2.3. PCR Assays

For diagnostic purposes, M gene-targeted real-time RT-PCR was performed with a Qiagen OneStep RT-PCR Kit (Qiagen, Hilden, Germany, forward primer (M4100F, 5′-agt-gat-gtg-ctc-gga-cct-tc-3′), reverse primer (M4220R, 5′-atc-gtt-tac-gga-gag-gag-tcc-3′), and probe (M4169, 5′-ttc-tct-agc-agt-ggg-aca-gcc-tgc-3′) using Rotor Gene Q machines (Qiagen, Hilden, Germany) [9]. RT-PCR was performed under the following temperature and time conditions: reverse transcription, 30 min at 50 °C; polymerase activation, 10 min at 95 °C, and 40 cycles of denaturation (10 s at 95 °C), annealing of primers (35 s at 55 °C), and elongation (10 s at 72 °C).
F gene-targeted RT and conventional PCR were performed using AMV reverse transcriptase and GoTaq®Flexi DNA polymerase (Promega, Madison, USA), forward primer (D1, 5′-cca-ttg-atg-gca-ggc-ctc-tt-3′), and reverse primer (D2, 5′-ccg-cta-ccg-att-aat-gag-ct-3′) following the manufacturer’s instructions. The reaction was performed using a Tercyc thermal cycler (DNA-Technology, Moscow, Russia) under the following temperature and time conditions: reverse transcription (25 min at 50 °C), polymerase activation (5 min at 95 °C), and 40 PCR cycles including denaturation (20 s at 95 °C), annealing of primers (30 sec at 55 °C), and elongation (40 s at 72 °C).

2.4. Sequencing

Nucleotide sequences of AOAV-1 F and HN genes were determined using an automated ABI Prism 3100 sequencer and BigDye Terminator Cycle Sequencing kits (Applied Biosystems, Waltham, MA, USA) according to the manufacturer’s instructions. Nucleotide sequences were analyzed using BioEdit software version 7.0.5.3. Sequences were aligned using ClustalW multiple sequence alignment software. Phylogenetic trees were constructed according to the NJ algorithm using MEGA software version 6.06. The sequences presented in this study have been added to the database “GenBank” under the numbers OQ435162–OQ435239 and OQ473027-OQ473028.

2.5. The Geographical Map

The Geographical Map Was Obtained from the Map Chart Service (https://www.mapchart.net/index.html, accessed on 10 May 2023).

3. Results

Between 2017 and 2021, 7410 samples of biological material from wild and synanthropic birds collected from four regions of Russia and 12,090 samples of biological material collected from poultry on commercial poultry farms or in backyards from twenty-eight regions were tested for AOAV-1 at the Reference Laboratory for Avian Viral Diseases in the FGBI “ARRIAH” (Vladimir, Russia). The species and groups of birds from which samples of biological material were obtained are presented in Table 1.
The greatest number of samples of biological material from wild and synanthropic birds was obtained from species of the order Anseriformes (4066 samples). This group predominantly comprised samples obtained from the family Anatidae, which includes ducks, mallards, wild geese, and teals. Samples from other wild waterfowl and near-water birds (gulls, grebes, and cormorants among others) were also examined (1588 samples). AOAV-1 was detected in six samples from mallards (collected in 2017 or 2021), in one sample from gadwall (collected in 2017), in two samples from wild duck (collected in 2018), and in one sample from wild waterfowl (collected in 2020, species unknown).
A total of 1071 samples of biological material were received from synanthropic birds between 2017 and 2021. The greatest number of samples were obtained from rock pigeons (839 samples), with 232 samples obtained from crows, jackdaws, and sparrows, and 685 samples from other wild bird species (woodcock, lapwing, and pheasant among others). The AOAV-1 genome was detected in five samples from pigeons in 2017, 2018, and 2020.
The greatest number of samples from poultry were obtained from chickens (9580 samples), with 2510 samples from turkeys, quails, domestic geese, ducks, and other domestic birds (guinea fowl and Muscovy duck among others). The AOAV-1 genome was detected in fifty-eight samples from chickens (collected between 2017 and 2021), in two samples from turkeys (collected in 2018), in one sample from domestic geese (collected in 2019), and in two samples from poultry (collected in 2019 and 2020, species unknown).
The virus was detected in 78 samples collected from poultry and wild birds. Data on AOAV-1 isolates are provided in Table 2.
It should be noted that it was not possible to detect AOAV-1 for a number of years in a number of regions of the Russian Federation. At the same time, various AOAV-1 strains were repeatedly detected over a five-year period in much smaller geographic locations (Republic of Tatarstan, Vladimir, Kostroma, and Kursk regions). The regions of the Russian Federation where AOAV-1 was detected are shown in Figure 1.
The virulent AOAV-1 genotype XXI.1.1 was isolated from pigeons in the Kostroma and Vladimir Oblasts between 2017 and 2018 and in the Republic of Tatarstan in 2020 (five isolates; Figure 2). The cleavage site of viruses of genotype XXI.1.1 had an amino acid sequence of 112-KRQKR^F-117.
Avirulent genotype I.2 viruses were isolated from wild waterfowl in the Amur and Vladimir Oblasts between 2017 and 2018 and between 2020 and 2021 (ten isolates). The cleavage site of viruses of genotype I.2 had an amino acid structure of 112-GKQGR^L-117.
Virulent isolates of genotype VII.2 were recovered from domestic poultry in the Republic of Crimea in 2017 (one isolate). The cleavage site of viruses of genotype VII.2 had an amino acid structure of 112-RRQKR^F-117.
The collected data demonstrate the widespread distribution and dominance of the virulent genotype VII.1.1. in the Russian Federation between 2019 and 2021. The virulent AOAV-1 genotype VII.1.1 was detected in Krasnodar, Stavropol, Primorsky and Zabaikalsky Krais, the Republics of Chechnya and Ingushetia, Saratov, Omsk, Kursk, Vladimir and Nizhny Novgorod Oblasts, and Khanty-Mansi AO (31 isolates). The cleavage site of viruses of genotype VII.1.1 had an amino acid sequence of 112-RRQKR^F-117.
The phylogenetic positions of AOAV-1 isolates detected in the Russian Federation between 2017 and 2021 are shown in Figure 2.
Vaccine-like virus genotypes I.1.1 and I.1.2.1 were detected in chickens and turkey in Penza, Irkutsk, Samara, Kemerovo, Kursk, Kostroma, Vladimir, and Chelyabinsk Oblasts and in the Republic of Tatarstan between 2017 and 2021 (14 isolates). Genotype II vaccine-like viruses were detected in chickens in Moscow, Novgorod, Sverdlovsk, Vladimir, Kostroma, Tver, Samara, Vologda, and Tyumen Oblasts, Primorsky and Krasnoyarsk Krais, and in the Republic of Tatarstan and Udmurt Republic between 2017 and 2021 (16 isolates). Genotype III vaccine-like virus was isolated from chickens in the Stavropol Krai in 2020 (one isolate). In our studies, only a few vaccine-like viruses were identified that had nucleotide substitutions in the studied region of the F gene (Figure 3).
Of particular interest is the substitution in the turkey/Rus/Penza/3964/18 virus at position 334 of the ORF of gene F. The substitution of G for A leads to the appearance of the basic amino acid R in the cleavage site. As a result, the cleavage site in the isolate has an amino acid sequence of 112-RKQGR^L-117, while the cleavage site in the vaccine strain V4 has an amino acid sequence of 112-GKQGR^L-117. This substitution was again detected from the same poultry farm turkey/Rus/Penza/1425/18 four months later (Table 2).
Analysis of the HN gene of the turkey/Rus/Penza/3964/18 and turkey/Rus/Penza/1425/18 viruses also demonstrated a significant relationship with the V4 vaccine. In the studied region of the HN gene (nucleotides 70–430), one G to A substitution was noted at position 322 of the ORF of the HN gene in both viruses. In the turkey/Rus/Penza/1425/18 virus, a substitution of T for C was also detected at position 342 of the ORF of the HN gene.

4. Discussion

Vaccination of commercial poultry against Newcastle disease, which is mandatory in the Russian Federation, is responsible for the regular detection of AOAV-1 vaccine-like viruses. The majority of ND vaccines are lentogenic class II AOAV-1 strains of genotypes I (strains V4 and BOR74 of sub-genotypes I.1.1 and I.1.2.1, respectively) and II (strains LaSota and B1), while a few are class II mesogenic strains of genotype II (Roakin, Komarov, and Beaudette C) and III (H). Lentogenic isolates of sub-genotypes I.1.1 and I.1.2.1 are also detected in wild birds [11]. Regarding the genotype II vaccine strains, LaSota and B1 strains are prevalent in Russia. Genotype II isolates were first reported in North America and were further detected in Africa, Asia, Europe, and South America [12,13,14,15]. The viruses of this genotype are currently used as live vaccines for backyard and commercial poultry in different regions of the world [15].
Long-term use of live vaccines probably leads to natural variability in isolates from poultry farms and the appearance of substitutions in manufacturing factories [16,17]. It is not always possible to determine whether isolates are a vaccine or a circulating vaccine-like isolate based on sequencing results. In our studies, only a few vaccine-like viruses were identified that had nucleotide substitutions in the examined fragment of the F gene. Examination of this short nucleotide sequence does not always distinguish between vaccines and vaccine-like viruses that may have re-infected birds. The repeated detection of a vaccine-like virus from a material in the Penza region indicates the possibility of vaccine strains acquiring pathogenic properties. The possibility of AOAV-1 acquiring virulent properties has already been reported in Australia [18]. The appearance of an additional substitution at position 342 of the gene NH four months later for the virus turkey/Rus/Penza/1425/18 indicates the circulation of a vaccine-like virus among susceptible livestock and further evolution of this strain.
In 2020, the vaccine strain of class II genotype III was detected in backyard chickens in Stavropol Krai. The available data on genotype III isolate sequences suggest that all viruses of this genotype have virulent properties [15]. This genotype includes related strains H and Mukteswar, which are mesogenic and used as vaccines in some regions of the world [19,20].
In 2017, 2018, 2020, and 2021, class II genotype I.2 AOAV-1 isolates were recovered in the Russian Federation. All isolates were detected in wild waterfowl. This subgenotype comprises avirulent viruses isolated in many European, Asian, African, and North American countries from different wild and domestic waterfowl species as natural reservoirs [15]. A number of such isolates have also been detected in Russia [21].
AOAV-1 isolates of genotype VIg (according to the classification of Diel 2012 et al.) [10] or genotype XXI.1.1 (according to the classification of Dimitrov 2019 et al.) [1] are repeatedly reported in the Russian Federation. Genotype VI viruses, sometimes called pigeon paramyxovirus type 1 or PPMV-1, are considered panzootic. The majority of the genotype VI virus sub-genotypes have predominantly been isolated from birds of the Columbidae family, which includes different species of wild and domestic pigeons. The viruses of this genotype appear to have spread worldwide due to the trade in sport pigeons and natural migration of wild pigeons [15,22]. Various genotype VI AOAV-1 variants and their derivatives are continuously circulating in Russia [22,23,24].
Between 2017 and 2021, NDV isolates of class II genotype VII were sporadically detected in poultry in Russia. In 2017, NDV isolates of subgenotype VII.2.1 were detected in the Republic of Crimea. This subgenotype was reported in Indonesia, Israel, and Pakistan between 2010 and 2013, and it further spread over Eastern Europe [25]. Previously, viruses of subgenotype VII.2.2, closely related to subgenotype VII.2.1, were detected in the Kaliningrad region of the Russian Federation in 2013. The virus was detected in backyard chickens [26]. This subgenotype, also related to viruses previously circulating in Indonesia (1998–2010), was also reported in poultry in Malaysia (2004–2006), China (2011, 2012), and Cambodia (2012). The vast and rapid spread of these genotypes in poultry indicates the high panzootic potential of this group of viruses. In addition, these groups of viruses are unlikely to have originated from isolates previously identified from poultry but rather from strains isolated from wild birds in the 1980s [27]. However, viruses of this genotype have not generally been widely distributed in the Russian Federation.
In 2019, a genotype VII.1.1 NDV isolate was detected in the Krasnodar Krai, and was responsible for a large-scale ND outbreak in between 2019 and 2021. Phylogenetic analysis of these nucleotide sequences demonstrated that the group of Iranian isolates designated as VII.1.1 (VIIL) was the most closely related to the Russian isolates from 2019–2021 (Figure 2) [28,29,30]. The rapid spread of the NDV genotype VII.1.1 across the territory of the Russian Federation in 2019 indicates that birds are the main vector for the spread of the ND virus. The low detection rate of NDV in wild birds in the present study contradicts this hypothesis. Despite the rare detection of NDV from wild birds, cases of genotype VII.1.1 NDV detected in wild birds have been reported. NDV was detected in a wild bird in Turkey [31], from two waterfowl (Common Moorhen and Mallard), in tissue samples taken from two little owls (Little_Owl/1/Istanbul/TR/2018 and Little_owl/2/Istanbul/TR/2018), and in one common kestrel (Common_kestrel/Istanbul/TR/2018). The NDV genotype VII.1.1 was detected in cattle egrets and house sparrows by RRT-PCR in Egypt during outbreaks between 2017 and 2019 [32]. However, a small proportion of previous studies have reported the detection of virulent viruses. According to the results of previous virus isolation studies, the prevalence of AOAV-1 prevailed is between 0.5% and 2.5% in waterfowl, including ducks [33,34]. In our opinion, it is worth highlighting the main hypothesis for such a massive spread of the NDV genotype VII.1.1 across the territory of the Russian Federation: the spread of NDV only by certain species of birds. A small number of bird species act as carriers of NDV, which is confirmed by the absence of mass epizootics during the migration of infected birds, in contrast to the spread of the avian influenza virus where mass deaths are recorded among susceptible species. This limited number of bird species should include synanthropic birds. According to the results of monitoring studies conducted in Kazakhstan and covering 73 species of birds, virulent viruses were detected only in pigeons (Columbiformes) and a velogenic NDV of genotype XIII was also detected in cormorants [35]. The results of a recent study of ND outbreaks in Kazakhstan indicate that NDV outbreaks of genotype VIIb (according to the classification of Diel et al.) in Central Asia are associated with cormorant migration [36]. These studies confirm the role of wild and synanthropic birds in the spread of AOAV-1 in poultry. At the same time, numerous vaccine-like viruses have been detected in wild and synanthropic birds, including Peregrine falcon/Brazil/PET26711/2009 (KU133356.1), River Eagle/Nigeria/PL JZ04/N49/896/2002–2003 (MH996916.1), Vulture/Nigeria/PL038-II/N47/895/2002–2003 (MH996914.1), Duck/Pakistan/ISLM/AW-17/2015 (MG686586.1), Mute swan/Bulgaria/Malko Tarnovo/2006 (KU133353.1), Eurasian_Teal/China/Ningxia/6/2014 (KT282108.1), and Pigeon/China/Heilongjiang/YA05/2014 (KU200240.1) et al.), which may indicate immunity to the AOAV-1 among synanthropic birds. Apparently, constant contact with vaccine-like and avirulent viruses protects synanthropic birds from mass death upon contact with velogenic NDV. Accordingly, the results of the present study demonstrate the active circulation of various AOAV-1 strains in the territory of the Russian Federation and the need for enhanced surveillance of synanthropic birds.

Author Contributions

Conceptualization, N.A.G. and S.N.K.; methodology, N.G.Z. and A.V.A.; software, N.G.Z. and S.N.K.; formal analysis, A.V.A. and N.A.G.; investigation, L.O.S., E.V.O., and Z.B.N.; resources, A.V.A. and D.B.A.; data curation, D.B.A. and I.A.C.; writing—original draft preparation, N.A.G. and N.G.Z.; writing—review and editing, N.A.G., S.N.K., and R.Y.; visualization, S.N.K., N.A.G., and N.G.Z.; supervision, I.C, N.V.M., and A.V.S.; project administration, I.A.C., N.V.M., and A.V.S. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Ministry of Education and Science of Russia, to implement the objectives of the Federal Scientific and Technical Pro-gram for the Development of Genetic Technologies during 2019–2027, grant number 075-15-2021-1054.

Institutional Review Board Statements

This research was conducted on clinical diagnostic samples submitted for diagnostic testing. No permission was required to use the samples. No work with animals was performed in this study.

Informed Consent Statement

Not applicable.

Data Availability Statement

The article shows the numbers under which the data was deposited in GenBank.

Conflicts of Interest

The authors declare no conflict of interest.

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Vaccines 11 01032 g001 550
Figure 1. Regions of the Russian Federation where the AOAV-1 was detected of between 2017 and 2021.
Figure 1. Regions of the Russian Federation where the AOAV-1 was detected of between 2017 and 2021.
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Vaccines 11 01032 g002 550
Figure 2. Phylogenetic positions of AOAV-1 isolates recovered in the Russian Federation between 2017 and 2021. The tree was constructed using the NJ method with MEGA 6.06 software using F gene fragment sequences (nucleotides 203–550).
Figure 2. Phylogenetic positions of AOAV-1 isolates recovered in the Russian Federation between 2017 and 2021. The tree was constructed using the NJ method with MEGA 6.06 software using F gene fragment sequences (nucleotides 203–550).
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Vaccines 11 01032 g003 550
Figure 3. Nucleotide substitutions in the studied region of the gene F in AOAV-1 vaccine-like viruses (nucleotides 203–550).
Figure 3. Nucleotide substitutions in the studied region of the gene F in AOAV-1 vaccine-like viruses (nucleotides 203–550).
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Table
Table 1. Species and groups of birds from which samples were obtained.
Table 1. Species and groups of birds from which samples were obtained.
Bird Species20172018201920202021
Poultry
Chicken8581018229524842925
Turkey172552587277
Quail---41
Domestic geese and ducks59144171139
Other domestic birds (guinea fowl, Muscovy duck, etc.)281432323286
Total samples from poultry13701217298530503468
Wild waterfowl
Wild duck300278515358218
Mallard2149025976183
Wild geese23787173247179
Teal45-9359143
Others of the family Anatidae59205828147
Other wild waterfowl and near-water birds (gulls, grebes, cormorants, etc.)57167433587344
Synanthropic birds and other wild bird species
Rock pigeon10239177343178
Others of the order Passerine (crows, jackdaws, and sparrows)1335956029
Woodcock40191023826
Other wild bird species (lapwing, pheasant, etc.)634811015485
Total samples from synanthropic and wild birds1130783201519501532
Total samples per year25002000500050005000
Table
Table 2. AOAV-1 isolates recovered in the Russian Federation between 2017 and 2021.
Table 2. AOAV-1 isolates recovered in the Russian Federation between 2017 and 2021.
No.RegionDate of Sample CollectionSpecies Isolate Designation
Genotype I.1.1 (Ia, V4) a
1Penza Oblast07.02.18Turkey turkey/Rus/Penza/3964/18
2Penza Oblast23.06.18Turkeyturkey/Rus/Penza/1425/18
3Republic of Tatarstan09.04.19Chicken chicken/Rus/Tatarstan/119/19
4Irkutsk Oblast23.06.20Chickenchicken/Rus/Irkutsk/861/20
5Samara Oblast08.04.21Chickenchicken/Rus/Samara/429/21
6Republic of Tatarstan29.04.21Chickenchicken/Rus/Tatarstan/566/21
7Kemerovo Oblast05.07.21Chickenchicken/Rus/Kemerovo/957/21
8Republic of Tatarstan07.10.21Chickenchicken/Rus/Tatarstan/1590/21
9Kursk Oblast13.10.21Chickenchicken/Rus/Kursk/1632/21
Genotype I.2 (Ib) a
1Amur Oblast23.11.17Mallard mallard/Rus/Amur/80/17
2Amur Oblast23.11.17Mallardmallard/Rus/Amur/84/17
3Amur Oblast23.11.17Mallardmallard/Rus/Amur/124/17
4Amur Oblast23.11.17Mallardmallard/Rus/Amur/132/17
5Amur Oblast23.11.17Mallardmallard/Rus/Amur/146/17
6Amur Oblast23.11.17Gadwall gadwall/Rus/Amur/158/17
7Vladimir Oblast12.07.18Wild duckwildduck/Rus/Vladimir/1848/18
8Vladimir Oblast12.07.18Wild duckwildduck/Rus/Vladimir/1849/18
9Amur Oblast02.10.20Wild waterfowlwildwaterfowl/Rus/Amur/1636/20
10Vladimir Oblast23.08.21Mallard Mallard/Rus/Vladimir/1239/21
Genotype I.1.2.1 (Ic; BOR74) a
1Kostroma Oblast19.09.17Chickenchicken/Rus/Kostroma/2890/17
2Kostroma Oblast19.09.17Chickenchicken/Rus/Kostroma/2908/17
3Vladimir Oblast07.02.18Chickenchicken/Rus/Vladimir/3963/18
4Chelyabinsk Oblast17.03.20Chickenchicken/Rus/Cheliabinsk/4762/20
5Kostroma Oblast18.11.21Chickenchicken/Rus/Kostroma/1916/21
Genotype II (La-Sota, B1) a
1Moscow Oblast21.01.17Chickenchicken/Rus/Moscow/3545/2/17
2Novgorod Oblast04.04.17Chickenchicken/Rus/Novgorod/3618/17
3Sverdlovsk Oblast30.06.17Chickenchicken/Rus/Sverdlovsk/3786/17
4Primorsky Krai18.07.17Chickenchicken/Rus/Primorje/1688/17
5Republic of Tatarstan30.08.17Chickenchicken/Rus/Tatarstan/3838/17
6Vladimir Oblast01.11.17Chickenchicken/Rus/Vladimir/3896/17
7Krasnoyarsk Krai23.05.18Chickenchicken/Rus/Krasnoyarsk/1120/18
8Kostroma Oblast24.05.18Chickenchicken/Rus/Kostroma/1138/18
9Tver Oblast16.10.18Chickenchicken/Rus/Tver/4266/18
10Samara Oblast18.12.18Chickenchicken/Rus/Samara/3163/2018
11Vladimir Oblast17.01.19Chickenchicken/Rus/Vladimir/4350/19
12Vladimir Oblast15.05.20Chickenchicken/Rus/Bioritm/4858/20
13Krasnoyarsk Krai10.11.20Chickenchicken/Rus/Krasnojarsk/1620/20
14Vologda Oblast23.11.20Chickenchicken/Rus/Vologda/1648/20
15Udmurt Republic29.04.21Chickenchicken/Rus/Udmurtia/558/21
16Tyumen Oblast01.11.21Chickenchicken/Rus/Tumen/1774/21
Genotype III (H) a
1Stavropol Krai11.12.20Chicken chicken/Rus/Stavropol/2/20
Genotype XXI.1.1 (VIg) a
1Kostroma Oblast28.03.17Pigeon pigeon/Rus/Kostroma/3606/17
2Vladimir Oblast14.06.18Pigeonpigeon/Rus/Vladimir/1141/18
3Vladimir Oblast14.06.18Pigeonpigeon/Rus/Vladimir/1142/18
4Republic of Tatarstan13.03.20Domestic pigeonpigeon/Rus/Tatarstan/311-1/20
5Republic of Tatarstan13.03.20Domestic pigeonpigeon/Rus/Tatarstan/311-2/20
Genotype VII.2.1 (VIIi) a
1Republic of Crimea12.01.17Chicken chicken/Rus/Crimea/054/17
Genotype VII.1.1 (VIIL) a
1Krasnodar Krai01.02.19Chickenchicken/Rus/Krasnodar/11/19
2Republic of Chechnya12.04.19Chickenchicken/Rus/Chechnya/431/19
3Stavropol Krai23.04.19Chickenchicken/Rus/Stavropol/509/19
4Stavropol Krai26.04.19Chickenchicken/Rus/Stavropol/888/19
5Stavropol Krai15.05.19Goose goose/Rus/Stavropol/1190/19
6Primorsky Krai22.05.19Chickenchicken/Rus/Primorsky/1284/19
7Saratov Oblast20.06.19Chickenchicken/Rus/Saratov/4521/19
8Saratov Oblast27.08.19Chickenchicken/Rus/Saratov/3122/19
9Zabaikalsky Krai04.10.19Chickenchicken/Rus/Zabaikalsky/3915/19
10Omsk Oblast10.10.19Chickenchicken/Rus/Omsk/3941/19
11Zabaikalsky Krai21.10.19Chickenchicken/Rus/Zabaikalsky/4635/19
12Omsk Oblast08.11.19Chickenchicken/Rus/Omsk/2677/19
13Kursk Oblast18.11.19Poultry poultry/Rus/Kursk/2819/19
14Kursk Oblast03.12.19Chickenchicken/Rus/Kursk/2949/19
15Primorsky Krai19.12.19Chickenchicken/Rus/Primorsky/3087/19
16Kursk Oblast20.01.20Chickenchicken/Rus/Kursk/68/20
17Kursk Oblast30.01.20Chickenchicken/Rus/Kursk/142/20
18Vladimir Oblast15.05.20Chickenchicken/Rus/Vladimir/709/20
19Vladimir Oblast09.09.20Poultry poultry/Rus/Vladimir/1464/20
20Vladimir Oblast09.09.20Chickenchicken/Rus/Vladimir/1474/20
21Vladimir Oblast17.09.20Chickenchicken/Rus/Vladimir/1553/20
22Vladimir Oblast13.10.20Chickenchicken/Rus/Vladimir/1715/20
23Republic of Ingushetia13.10.20Chickenchicken/Rus/Ingushetia/1750/20
24Vladimir Oblast10.11.20Chickenchicken/Rus/Vladimir/1931/20
25Vladimir Oblast02.12.20Chickenchicken/Rus/Vladimir/2125/20
26Republic of Chechnya11.12.20Chickenchicken/Rus/Chechnya/2191/20
27Nizhny Novgorod Oblast18.05.21Chickenchicken/Rus/N.Novgorod/667/21
28Vladimir Oblast20.07.21Chickenchicken/Rus/Vladimir/1035/21
29Khanty-Mansi AO23.08.21Chickenchicken/Rus/Khanty-Mansi/1240/21
30Primorsky Krai27.09.21Chickenchicken/Rus/Primorsk/1472/21
31Vladimir Oblast29.12.21Chickenchicken/Rus/Vladimir/2271/21
a Phylogenetic groups are according to Dimitrov et al. (2019) and Diel et al. (2012) [1,10]. The strain designations of vaccines are indicated in brackets.
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Guseva, N.A.; Kolosov, S.N.; Zinyakov, N.G.; Andriyasov, A.V.; Yin, R.; Scherbakova, L.O.; Ovchinnikova, E.V.; Nikonova, Z.B.; Andreychuk, D.B.; Sprygin, A.V.; et al. Analysis of Avian Orthoavulavirus 1 Detected in the Russian Federation between 2017 and 2021. Vaccines 2023, 11, 1032. https://0-doi-org.brum.beds.ac.uk/10.3390/vaccines11061032

AMA Style

Guseva NA, Kolosov SN, Zinyakov NG, Andriyasov AV, Yin R, Scherbakova LO, Ovchinnikova EV, Nikonova ZB, Andreychuk DB, Sprygin AV, et al. Analysis of Avian Orthoavulavirus 1 Detected in the Russian Federation between 2017 and 2021. Vaccines. 2023; 11(6):1032. https://0-doi-org.brum.beds.ac.uk/10.3390/vaccines11061032

Chicago/Turabian Style

Guseva, Nelly A., Sergey N. Kolosov, Nikolay G. Zinyakov, Artem V. Andriyasov, Renfu Yin, Lidya O. Scherbakova, Evgenia V. Ovchinnikova, Zoya B. Nikonova, Dmitry B. Andreychuk, Alexander V. Sprygin, and et al. 2023. "Analysis of Avian Orthoavulavirus 1 Detected in the Russian Federation between 2017 and 2021" Vaccines 11, no. 6: 1032. https://0-doi-org.brum.beds.ac.uk/10.3390/vaccines11061032

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