key: cord-0948582-umm6ur36 authors: Al-Shekaili, Thunai; Baylis, Matthew; Ganapathy, Kannan title: Molecular detection of infectious bronchitis and avian metapneumoviruses in Oman backyard poultry date: 2014-12-30 journal: Res Vet Sci DOI: 10.1016/j.rvsc.2014.12.018 sha: 96463c2432795b88c66565d58142bec50bb90aa7 doc_id: 948582 cord_uid: umm6ur36 Infectious bronchitis virus (IBV) and avian metapneumovirus (aMPV) are economically important viral pathogens infecting chickens globally. Identification of endemic IBV and aMPV strains promotes better control of both diseases and prevents production losses. Orophrayngeal swab samples were taken from 2317 birds within 243 different backyard flocks in Oman. Swabs from each flock were examined by RT-PCR using part-S1 and G gene primers for IBV and aMPV respectively. Thirty-nine chicken flocks were positive for IBV. Thirty two of these were genotyped and they were closely related to 793/B, M41, D274, IS/1494/06 and IS/885/00. 793/B-like IBV was also found in one turkey and one duck flock. Five flocks were positive for aMPV subtype B. Though no disease was witnessed at the time of sampling, identified viruses including variant IBV strains, may still pose a threat for both backyard and commercial poultry in Oman. Infectious bronchitis virus (IBV) is a highly contagious viral pathogen of chickens. It is a type 3 coronavirus and part of the family Coronaviridae (Cavanagh, 2001) . Most IBVs infect the respiratory, urinary and reproductive tracts causing considerable production losses (Dolz et al., 2008; Jones, 2010; Roussan et al., 2008; Villarreal et al., 2007; Worthington et al., 2008) . IBV infections can also be further aggravated by the presence of bacterial infections such as Escherichia coli, Mycoplasma gallisepticum, Mycoplasma synoviae and Ornithobacterium rhinotracheale (Landman and Feberwee, 2004; Matthijs et al., 2003; Naqi et al., 2001; van Empel et al., 1996) . Since the first description of IBV in 1931 (Schalk and Hawn, 1931) , a number of different IBV genotypes have been detected worldwide (Jackwood, 2012) . Virulent IBV genotypes (eg. 793/B, QX, IS/ 1494/06, IS/885/00, Q1) that have a severe impact on chicken health and production have been reported in recent decades (Gough et al, 1992; Kahya et al., 2013; Meir et al., 2004b; Yu et al., 2001) . Infections from different IBV genotypes present a challenge for poultry producers worldwide (Dolz et al., 2008; Jones, 2010; Worthington et al., 2008) , and also for owners of backyard chicken flocks. The spike subunit 1 (S1) is highly variable in IBV and analysis of S1 using reverse transcription-polymerase chain reaction (RT-PCR) and sequencing has allowed for genotyping of IBV strains (Kingham et al., 2000) . Avian metapneumovirus (aMPV) is an avian virus belonging to the Paramyxoviridae family (Lee et al., 2007b) . It is capable of infecting the respiratory tract of birds, causing avian rhinotracheitis in turkeys (Jones, 2010) and swollen head syndrome in chickens (Georgiades et al., 2001) . Furthermore, it also causes a drop in egg production and/or egg quality in both turkeys and chickens (Banet-Noach et al., 2005; Hess et al., 2004) . The virus was first reported in South Africa in the 1970s (Buys et al., 1989) and has since spread to other continents (Jones, 2010) . There are four distinct aMPV subtypes; A, B, C and D (Cook and Cavanagh, 2002) . Subtypes A and B are widespread throughout Asia, Europe, Africa and South America (Jones, 2010; Kwon et al., 2010; Owoade et al., 2008) . Reports of infections by subtypes C and D are infrequent and to date, subtype C has been reported in France, Korea and the US (Alvarez et al., 2003; Bayon-Auboyer et al., 2000; Lee et al., 2007a) , with D so far only detected in France (Bayon-Auboyer et al., 2000) . There is a particular paucity of information from Oman, with almost no published studies of avian respiratory viruses for any species. This is despite Oman's geographic location (between the horn of Africa and southern Asia), its importance as a site for migrating wild birds and the presence of large commercial poultry production farms. These farms produce the majority of the Omani poultry requirements; however census data in 2004 reports there were around 25,000 backyard flocks bred for household consumption (Anon, 2004) . Due to the avian influenza contingency plan implemented between 2004 and 2012, this number has been reduced to nearly 10,000 flocks (Rural Women Development Department, personal communication, 2012) . Maintaining a good health status of backyard flocks is crucial for both the flock owners and the owners of nearby commercial flocks (McBride et al., 1991) . Backyard poultry in Oman are not vaccinated against IBV or aMPV. This paper reports the first study on the prevalence of IBV genotypes and aMPV subtypes within backyard poultry flocks in Oman. Oropharyngeal swabs were collected from a total of 243 backyard flocks (2317 birds) from 237 backyard farms within all regions and governorates of Oman (Fig. 1) , from June to September 2012. More than one flock was sampled if the farm had more than one species of bird. The samples were collected during a study on the prevalence of respiratory viruses, such as avian influenza (AI), Newcastle disease (ND), IB and aMPV. The number and location of sampled farms was determined based on the estimated prevalence of Avian Influenza (AI) and Newcastle Disease (ND) in Oman backyard poultry. Sampling criteria were calculated based on an estimated prevalence of AI of 30% and between-cluster variance of 0.7. The number of flocks to be sampled was stratified by region according to the number of poultry farms, total number of poultry, number of people and number of backyard poultry present in each region. A confidence level of 95% was utilised along with a twostage cluster sampling method (Thrusfield, 1986) . The total backyard poultry population in Oman was estimated by the Ministry of Agriculture and Fisheries, Department of Rural Women Development to be approximately 10,000 poultry flocks (Table 1 ) with a median size of 50 birds per flock. The vast majority of the sampled farms raised local village chickens; however turkeys, guinea fowl, duck and geese were also present. Local veterinarians and animal health engineers from the Ministry of Agriculture and Fisheries in each state aided with the selection of farms at different locations. Inclusion criteria involved a minimum distance between two farms (>1 km) and <3 farms from each village. If only one flock was present at a farm, 10 healthy adult (>3 months) birds were selected randomly and sampled. If more than one species of bird was present in the farm, then two flocks would be randomly chosen and 10 birds sampled from each flock. If there were fewer than 10 birds within a chosen flock, then all were sampled. For detection of respiratory viruses, oropharyngeal swabs were collected from each flock and pooled into 1.5 ml distilled water in a sterile 5 ml plastic bijou container. All samples were kept cool in crushed ice within a thermal-box and brought to the nearby Veterinary Research Centre. The bijou was vortexed and 100 μl was inoculated into the centre of a Flinders Technology Associates (FTA) card (Sigma Aldrich, Dorset, UK) using a sterile pipette and tips. Cards were left to dry for 1 hour at room temperature (22°C), away from direct light sources, then stored at 4°C in air-tight plastic bags. Samples were transported to the University of Liverpool, UK, for processing and analysis. Data such as sampling date, farm location (village, state, and region), species of birds, flock size, species of sampled birds, housing conditions, and water sources were recorded for each farm. Spatial coordinates of the location were recorded using GPS (Garmin GPS MAP 62s, USA). One circle from each FTA card was removed using sterile scissors and forceps and placed in a bijou containing 800-1000 μl of TE buffer (10 mM Tris-HCl, 0.1 mM EDTA, pH 8.0), vortexed and incubated at room temperature for 10 min (Abdelwhab et al., 2011) . The supernatant was then used to extract viral RNA. RNA extraction was performed using the QIAamp Viral RNA Mini Kit (Qiagen Ltd, Hilden, Germany) according to the manufacturer's instructions and stored at −20°C until required. RT-PCR was performed on each of the 243 RNA extracts using both primers and cycle conditions as previously published (Cavanagh et al., 1999) . A 268 bp band corresponds to type A, whereas a 361 bp band is type B. Positive isolates were typed by comparison of amplicon size to an aMPV type B positive control. This PCR protocol has previously been shown to detect up to 10 1.56 and 10 1.51 CD50/ ml viral concentration of aMPV type A and B respectively from FTA cards and one log higher from TOC medium (Awad et al., 2014) . Subtypes C and D were not examined in this study. All samples were subjected to RT-PCR to detect IBV positive flocks. Primers and cycle conditions were as previously described (Cavanagh et al., 1999) . The presence of a 380 bp amplicon (relating to the S1 gene) demonstrates that the sample is positive for IBV. The IBV M41 genotype was utilised as the positive control. It is possible to detect IBV up to 10 2.3 EID50/ml from FTA cards (Awad et al., 2012) . Positive PCR reactions were purified using 0.15 μl exonuclease 1 (EXO) and 0.99 μl of shrimp alkaline phosphatase (SAP). The mixture was incubated at 37°C for 30 min and then a further 10 min at 80°C to remove any residual impurities. Purified DNA along with the forward primer SX3+ was sent for commercial sequencing (Source Bioscience Ltd, Nottingham, UK). Sequences were initially analysed in ChromasPRO v1.7.3 (http://technelysium.com.au/) to confirm good quality read data. Alignments were carried out in MEGA6 (Tamura et al., 2013) using Clustal W (Thompson et al., 1994) . Following alignment, BLAST searches were conducted to confirm isolate identification. Obtained IBV sequences were compared against reference strains for S1 retrieved from GenBank (National Centre of Biotechnology Information). Reference strains used throughout this study were UK/ 3/91 (Z83977) Maximum likelihood analysis was utilised to infer phylogeny of both isolate and reference sequences, with default settings and 1000 bootstrap re-sampling. BLAST was utilised for nucleotide and amino acid identity comparisons between representative isolates within identified clusters. From the total of 243 flocks sampled during the study, five tested aMPV positive (2.06%). All five samples were from chickens and all were identified as aMPV subtype B. The positive samples came from northern regions of Oman; three from the Ad Dhahirah region (Albrimi, Ibri and Dank), one from the Ash Sharqiyah region (Snaw) and the fifth from the Muscat Governorate (Qurayat). Four of the infected flocks were located within the mainland, with a single flock from the coastal town of Qurayat (Fig. 1A) . From the 243 flocks assayed using RT-PCR, a total of 39 tested positive for IBV (16.05%) (Fig. 1B) . Of the 39 isolates sequenced, it was possible to determine the genotypes of 32 (82.05%) using BLAST (Table 2) . A total of five genotypes were represented within the sample size. The majority of samples showed greatest homology to genotype 793/B (n = 26/39; 66.67%), with the remaining isolates relating closely to M41 (n = 2/39; 5.12%), D274 (n = 2/39; 5.12%), IS/ 1494/06 (n = 1/39; 2.56%) and IS/885/00 (n = 1/39; 2.56%). All 32 sequenced samples were submitted to GenBank and assigned accession numbers (Fig. 2) . The Al Wusta region demonstrated the highest flock prevalence rate (37.5%) followed by the Dhofar Governorate (28.5%). The 793/B-like genotype was identified from all regions and governorates, except the Muscat Governorate which remained the only region to have no IBV positive flocks. Dhofar Governorate was the only infected region to demonstrate a single genotype (793/B), while the other infected regions had a presence of ≥2 genotypes. All IBV infected flocks consisted of solely chickens, with the exception of one duck and one turkey flock. Genotype 793/B was detected in the duck and turkey flocks from Ad Dakhliyah and Al Batinah regions respectively. The 793/B genotype was also detected within chicken flocks from these regions. Table 1 The estimated total number of flocks in each region, the number of flocks sampled, the number and type of each poultry species sampled in the eight regions of Oman. Results from the maximum likelihood analysis demonstrate that the isolates formed five distinct clusters (Fig. 2) , relating to genotypes of strains previously reported. Representative isolates from each of the five clusters were chosen for comparison of nucleotide and amino acid similarities (Table 3) . The majority of the 26 isolates clustering with UK/4/91 had between 96% and 100% nucleotide homology (resulting in 92-100% amino acid similarity). The IS/885/00-like strain had a higher We present the first study to identify the circulating IBV genotypes and aMPV subtypes in backyard flocks in Oman. For this study, an epidemiologically representative number of samples were collected from different regions of Oman and transferred to the University of Liverpool on FTA cards. The cards inactivate genomic material and allow for RNA extraction once back in the laboratory, proving useful for analysing field isolates away from the point of sampling. The successful use of the cards for both IBV and aMPV has been previously described (Awad et al., 2014; Moscoso et al., 2005) . Using RT-PCR and direct amplicon sequencing, we identified the prevalence of both viruses within backyard flocks in relation to location and poultry species. Thirty-nine flocks were identified as IBV positive, with an overall prevalence of 16.04%. This finding is lower than previously reported in production farms within neighbouring countries, for example 58.8% and 42.8% in Jordan and Iran respectively (Roussan et al., 2009; Seyfi Abad Shapouri et al., 2004) . However both studies sampled chickens within a higher density environment, which may have contributed to the higher prevalence rate compared with the backyard flocks. In this study, 793/B was the dominant IBV genotype infecting backyard flocks, with an overall prevalence of 66.67% in IBVpositive flocks. The presence of 793/B in commercial flocks has previously been reported in other Middle East countries such as Iran, Jordan and Israel (Meir et al., 2004b; Roussan et al., 2008; Seyfi Abad Shapouri et al., 2004) . In the last few years, 793/B vaccines and strains closely-related to 793/B, have been detected in the Omani commercial chicken (K. Ganapathy, unpublished data, 2010) . The 793/B isolates detected within the backyard flocks formed a close phylogenetic cluster, indicating that potentially the same 793/B strain may be circulating between different Omani backyard flocks and regions. Oman-Lewa-4-12 was distinct from other 793/B-type isolates, with only 92% identity with the vaccine strain, which shows that it could be a virulent 793/B virus circulating in this flock. The Mass serotype was the first to be isolated in the 1930s (Jackwood, 2012) and adopted for use in early IBV vaccines (Jackwood, 2012; Sjaak de Wit et al., 2011) . Strains belonging to the D274 serotype were first isolated in the Netherlands (Davelaar et al., 1984) and later developed as a vaccine. In the current study, we detected M41-like and D274-like infections within four chicken flocks at a low prevalence of 0.82% each. Both genotypes have been previously reported in commercial flocks in the Middle East (Roussan et al., 2008; Seyfi Abad Shapouri et al., 2004; Sjaak de Wit et al., 2011) , albeit at a much higher prevalence than witnessed during this study. Despite no clinical disease being identified in the M41 or D274 positive birds, both viruses are known for their ability to cause disease in chickens (Bourogaa et al., 2009; Feng et al., 2012) . IBV genotypes IS/1494/06 and IS/885/00 were originally isolated in Israel and are currently circulating in a number of Middle East countries (Kahya et al., 2013; Meir et al., 2004a) . Here, for the first time, we report the detection of these important Middle East variant IBV in backyard flocks. Even though a low prevalence was witnessed in this study, their importance cannot be ignored due to their ability to cause severe respiratory, reproductive and renal diseases (Kahya et al., 2013) . These viruses pose a threat not only to backyard flocks but also to the commercial poultry industry in Oman and possibly further afield in the region. It is of interest to note that IBV genotype 793/B was detected in a flock of Muscovy ducks from the Ad Dakhliyah region and in a turkey flock in the Al Batinah region. This presence suggests that common circulating IBV genotypes (such as 793/B) could potentially establish an infection in both ducks and turkeys. Using RT-PCR, IBV has previously been detected in apparently healthy ducks in China and Nigeria (Feng et al., 2012; Semeka et al., 2013) . Despite previous reports having identified a turkey coronavirus closely related to IBV (Breslin et al., 1999; Cavanagh et al., 2001) , to date there has been only one report of IBV infecting turkeys (Semeka et al., 2013) . To our knowledge, this appears to be the first report of an IBV-like detection in both duck and turkey flocks in the Middle East. All five aMPV positive samples from this study were of subtype B and were isolated from five different states within four northern regions, highlighting the sporadic distribution pattern of aMPV in the backyard flocks. Although subtype A was not identified in this study, co-circulation of both subtypes A and B within commercial flocks in the Middle East has been previously reported (Banet-Noach et al., 2005) . This appears to be the first detection of aMPV within backyard flocks in Oman. With its involvement in respiratory and reproductive disorders (Georgiades et al., 2001; Jones, 2010) , the circulation of this pathogen is likely to pose a threat to backyard and commercial poultry in Oman. As subtype C has only previously been reported in France, Korea and the US, and subtype D is Table 3 Nucleotide and amino acid similarity between representatives from each distinct cluster (n = 9) and closely related reference strains (n = 7) for partial S1 sequences. only present in France, neither subtypes were investigated during this study. Our study demonstrates the complex epidemiology of both IBV and aMPV in backyard flocks in Oman. The reasons for the predominant detection of 793/B-like over other IBV genotypes and the presence of a single aMPV subtype (subtype B) are unknown. Further to this, the potential sources of these viruses in the sampled flocks are not known. The detection of 793/B in duck and turkey flocks highlights the possible role of these birds as potential mechanical or biological carriers. With the expanding commercial poultry industry and the increasing role of backyard poultry in Oman, it is essential to improve our understanding on the epidemiology of IBV and aMPV strains for better control of these pathogens. The use of FTA® filter papers for diagnosis of avian influenza virus Nucleotide and predicted amino acid sequence-based analysis of the avian metapneumovirus type C cell attachment glycoprotein gene: phylogenetic analysis and molecular epidemiology of Oman Agriculture Census Detection of multiple poultry respiratory pathogens from FTA ® card Evaluation of Flinders Technology Associates cards for storage and molecular detection of avian metapneumoviruses Characterization of Israeli avian metapneumovirus strains in turkeys and chickens Nucleotide sequences of the F, L and G protein genes of two non-A/non-B avian pneumoviruses (APV) reveal a novel APV subgroup Characterization of new variants of avian infectious bronchitis virus in Tunisia Sequence analysis of the turkey coronavirus nucleocapsid protein gene and 3′ untranslated region identifies the virus as a close relative of infectious bronchitis virus The isolation and attenuation of a virus causing rhinotracheitis in turkeys in South Africa A nomenclature for avian coronavirus isolates and the question of species status Longitudinal field studies of infectious bronchitis virus and avian pneumovirus in broilers using typespecific polymerase chain reactions Detection of a coronavirus from turkey poults in Europe genetically related to infectious bronchitis virus of chickens Detection and differentiation of avian pneumoviruses (metapneumoviruses) Occurrence and significance of infectious bronchitis virus variant strains in egg and broiler production in the Netherlands Molecular epidemiology and evolution of avian infectious bronchitis virus in Spain over a fourteen-year period Virulent avian infectious bronchitis virus, People's Republic of China Cases of swollen head syndrome in broiler chickens in Greece A 'new' strain of infectious bronchitis virus infecting domestic fowl in Great Britain Avian metapneumovirus excretion in vaccinated and non-vaccinated specified pathogen free laying chickens Review of infectious bronchitis virus around the world Viral respiratory diseases (ILT, aMPV infections, IB): are they ever under control? Presence of IS/1494/06 genotype-related infectious bronchitis virus in breeder and broiler flocks in Turkey Identification of avian infectious bronchitis virus by direct automated cycle sequencing of the S-1 gene Isolation and characterization of avian metapneumovirus from chickens in Korea Aerosol-induced Mycoplasma synoviae arthritis: the synergistic effect of infectious bronchitis virus infection Genetic characterization of avian metapneumovirus subtype C isolated from pheasants in a live bird market Genetic characterization of avian metapneumovirus subtype C isolated from pheasants in a live bird market Ability of Massachusetts-type infectious bronchitis virus to increase colibacillosis susceptibility in commercial broilers: a comparison between vaccine and virulent field virus Health survey of backyard poultry and other avian species located within one mile of commercial California meat-turkey flocks Identification of a novel nephropathogenic infectious bronchitis virus in Israel Identification of a novel nephropathogenic infectious bronchitis virus in Israel Molecular detection and serotyping of infectious bronchitis virus from FTA® filter paper The exacerbating effect of infectious bronchitis virus infection on the infectious bursal disease virusinduced suppression of opsonization by Escherichia coil antibody in chickens Avian metapneumovirus subtype A in China and subtypes A and B in Nigeria Molecular subtype of infectious bronchitis virus in broiler flocks in Jordan Infectious bronchitis virus in Jordanian chickens: seroprevalence and detection An apparently new respiratory disease of baby chicks Prevalence of respiratory viruses in ducks, chickens and turkey flocks in Benue state A survey of the prevalence of infectious bronchitis virus type 4/91 in Iran Infectious bronchitis virus variants: a review of the history, current situation and control measures MEGA6: molecular evolutionary genetics analysis version 6.0 CLUSTAL W: improving the sensitivity of progressive multiple sequence alignment through sequence weighting, position-specific gap penalties and weight matrix choice Veterinary Epidemiology Experimental infection in turkeys and chickens with Ornithobacterium rhinotracheale Orchitis in roosters with reduced fertility associated with avian infectious bronchitis virus and avian metapneumovirus infections A reverse transcriptase-polymerase chain reaction survey of infectious bronchitis virus genotypes in Western Europe from Characterization of three infectious bronchitis virus isolates from China associated with proventriculus in vaccinated chickens Thunai Al Shekaili is the recipient of a PhD scholarship from the Government of Oman. We thank Anne Forrester, Chris Ball, Emma Newsham and Faez Awad for assistance with laboratory testing, molecular sequencing and analysis. This study was approved by the Veterinary Research Ethic Committee, University of Liverpool (Ref: VREC55). (%) 1 2 3 4 5 6 7 8 9 1 0 1 1 1 2 1 3 1 4 1 5 1 6 1 82 81 82 82 82 81 82 82 98 82 81 83 79 83 83 1 Oman/Snaw/6/12 2 62 81 81 78 79 78 78 79 82 99 81 82 81 79