Abstract
Newcastle disease virus (NDV) has a wide avian host range and a high degree of genetic variability, and virulent strains cause Newcastle disease (ND), a worldwide concern for poultry health. Although NDV has been studied in Nigeria, genetic information about the viruses involved in the endemicity of the disease and the transmission that likely occurs at the poultry-wildlife interface is still largely incomplete. Next-generation and Sanger sequencing was performed to provide complete (n = 73) and partial genomic sequence data (n = 38) for NDV isolates collected from domestic and wild birds in Nigeria during 2002-2015, including the first complete genome sequences of genotype IV and subgenotype VIh from the African continent. Phylogenetic analysis revealed that viruses of seven different genotypes circulated in that period, demonstrating high genetic diversity of NDV for a single country. In addition, a high degree of similarity between NDV isolates from domestic and wild birds was observed, suggesting that spillovers had occurred, including to three species that had not previously been shown to be susceptible to NDV infection. Furthermore, the first spillover of a mesogenic Komarov vaccine virus is documented, suggesting a previous spillover and evolution of this virus. The similarities between viruses from poultry and multiple bird species and the lack of evidence for host adaptation in codon usage suggest that transmission of NDV between poultry and non-poultry birds occurred recently. This is especially significant when considering that some viruses were isolated from species of conservation concern. The high diversity of NDV observed in both domestic and wild birds in Nigeria emphasizes the need for active surveillance and epidemiology of NDV in all bird species.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Avian avulavirus 1 (AAvV-1), commonly known as Newcastle disease virus (NDV, used hereafter), is a single-stranded non-segmented, negative-sense RNA virus that has high genetic variability [1]. The genetic variability and mobility of NDV are widely studied because virulent strains cause the highly contagious Newcastle disease, which causes high morbidity and mortality in domestic gallinaceous poultry [2, 3]. NDV has been classified into two classes [4] with class II being the more diverse, with at least 18 genotypes [5]. NDV in Nigeria was first recorded in the 1950s [6], but reports of molecular characterization of Nigerian isolates have only recently become available (as of 2007 [7]), and members of seven NDV genotypes, I, II, IV, VI, XIV, XVII, and XVIII, have been identified in the country [8,9,10]. The reports of genotypes XIV, XVII, and XVIII are strictly limited to West and Central Africa, with subgenotype XVIIb documented only in Nigeria. One exception is the two genotype XVIII strains that were found in wild birds at a quarantine station in the United States; however, the origin of these birds is unknown [11]. A recent report of NDV in Nigeria demonstrates that most genotypes are widely distributed across the country, but genotype XVII has only been seen in the northern states [8].
NDV has a wide variety of avian hosts and is known to cause disease in many species other than domestic poultry [12, 13]. Interactions between free-ranging wild birds and poultry are likely to occur frequently at the livestock-wildlife interface, and exchange of pathogens is highly probable. With the continued documentation of the presence of NDV in wild avifauna, spillover of virulent and vaccine viruses from poultry is evident [14,15,16,17]. Pigeons are known carriers of some subgenotypes of NDV [18, 19], virulent strains of NDV have been isolated from double-crested cormorants, and other isolates of low virulence have been identified in different waterbird species [20,21,22]. These wild-bird carriers are of great concern regarding the movement and transmission of pathogens, including NDV, to and from the poultry sector. It is important to document other virulent NDV hosts to understand the dynamics of disease beyond the poultry industry.
Poultry production is the second-most important industry in Nigeria [23], and widespread NDV outbreaks occur in both vaccinated and unvaccinated flocks [24, 25]. Chickens raised in a free-range management system rarely have shelter or veterinary care provided, and individual movements are not monitored as they are in commercial operations [23]. Thus, interactions with, and potential pathogen transmission between, chickens from neighboring farms and/or other bird species are likely to be common. Furthermore, the local environment has a constant, uncontrolled input of poultry waste products, which can contaminate soil or water [26]. This is a point of concern considering that NDV has been documented to remain infectious in litter and carcasses for at least a couple of weeks, and in feathers, it remains so for several months [27]. NDV also persists in soil or water for up to 90 days under ideal conditions [26]. These factors can easily facilitate pathogen transmission from chicken to chicken and/or from chickens to wild birds, thus contributing to the endemic circulation of NDV. Wild birds have been suggested to be important viral reservoirs [28], but the role of wild birds in circulation of NDV in Nigeria is not fully understood [29]. Furthermore, even with NDV being well documented in Nigeria and phylogenetic analyses published as early as 2007, this study, with 111 new isolates, further extends the number of species, hosts and locations while being the first to add complete genome sequences to the phylogeny of regional strains. Thus, the aim of this study was to use next-generation and Sanger sequencing to obtain complete genome and fusion gene sequences of NDV isolates from domestic and wild birds during active and passive surveillance in Nigeria between 2002 and 2015, as well as two archival strains from 1973 and 1980, and to perform comprehensive phylogenetic and codon usage analyses to help better understand the distribution and genetic variability of NDV in this country.
Materials and methods
Sample collection, processing, virus isolation, and identification
Whole carcasses were submitted all year round (between 2002 and 2015) from suspected ND outbreaks in poultry and wild-bird species. Post-mortem examinations were conducted at the Central Diagnostic Laboratory, National Veterinary Research Institute (NVRI) Vom, Nigeria, and spleens, lungs, tracheas, and intestines were collected for virus isolation. Similarly, tracheal and cloacal swabs were collected during an active surveillance conducted from June to August 2009 in live-bird markets (LBMs) from 15 of the 36 Nigerian States, including the Federal Capital Territory (FCT).
The tracheal and cloacal swabs were collected by trained field officers from both sick and apparently healthy birds, as well as birds that had recently been supplied to the LBMs. The swabs were collected in virus transport medium containing the antibiotics penicillin (10,000 units/ml), streptomycin (10,000 mg/ml), gentamicin (5000 mg/ml), and amphotericin B (50 mg/ml) with 50% glycerol adjusted to pH 7.2 and transported to the laboratory in a cool box containing ice packs. Virus isolation was conducted at the Regional Laboratory for Animal Influenza and other Transboundary Animal Diseases (RLAITAD), NVRI, Vom, Nigeria. Tissues and swabs in medium were processed and inoculated into 9- to 11-day-old embryonated chicken eggs from specific-antibody-negative flocks by the allantoic sac route following standard procedure [3]. Hemagglutinating agents (HA) from the inoculated eggs were checked for bacterial contamination using a blood agar plate.
Viruses from bacterium-free allantoic fluid were identified using a hemagglutination-inhibition (HI) test with NDV-specific antiserum (IZSVe, Italy) according to standard procedure [3]. In addition, all hemagglutinating allantoic fluids were screened for avian influenza virus using rRT-PCR and were negative [30]. Two archival NDV isolates from 1973 and 1980 were obtained from the RLAITAD repository. Additional viruses isolated between 2002 and 2015 from the passive and active surveillance were included. The wild-bird isolates were provided by Dr. John Ibu [31]. The confirmed NDV isolates (n = 101) were shipped to the Southeast Poultry Research Laboratory (SEPRL) of the U.S. Department of Agriculture in Athens, GA, USA (n = 57), or the University of Pretoria (UP), South Africa (n = 44), for further characterization. The available background information for all studied viruses is presented in Table 1.
Virus propagation, RNA isolation, library preparation
The isolates submitted to SEPRL (n = 57) were propagated in 9-day-old specific-pathogen-free embryonated chicken eggs (Table 1). RNA extraction of 35 samples was conducted using TRIzol LS reagent (Invitrogen, USA) and a QIAamp® Viral RNA Mini Kit (QIAGEN, USA) as described previously [32]. A Nextera XT DNA Library Preparation Kit was used for next-generation sequencing (NGS) library preparation. Sequencing and data assembly were performed as described previously [32]. Sanger sequencing was performed on 22 isolates after TRIzol extraction as described previously [33] using the following primers: CZ8 4008F, 4994R; CZ9 4715F, 5637R; CZ10b 5410F, Z6369R; NG 4311F, 5090R; NG4938F, 5887R; NG 5721F, 6375R (Table 2; [34]). An intracerebral pathogenicity index (ICPI) assay was performed on five samples at SEPRL following established procedures [3].
The isolates submitted to the University of Pretoria (n = 44) were shipped inactivated in MagNA Pure 96 External Lysis Buffer (Roche Diagnostics, Manheim, Germany), and total nucleic acids were extracted on a MagNA Pure robotic system (Roche). Libraries were prepared and sequenced on an Illumina HiScanSQ system as described elsewhere [35] (Table 1).
Collection of dataset sequences
The complete fusion (F) gene coding sequences (CDS) and the complete genome sequences of all available class II NDV isolates were downloaded from GenBank [36] on November 30, 2018, resulting in two preliminary datasets of 2,372 and 498 sequences, respectively, and the sequences obtained in the current study were also added to the datasets. The sequences in each dataset were aligned using Multiple Alignment with Fast Fourier Transformation (MAFFT v.7.221.3) [37]. For phylogenetic and codon usage analysis of all complete genome sequences, the coding sequences of all six genes were trimmed from the genomes and concatenated together.
Phylogenetic analysis
The generated datasets were used to estimate evolutionary distances between viruses and groups. The estimates of evolutionary distances were inferred using MEGA6 [38, 39]. Analyses were conducted using the maximum composite likelihood model. The rate variation among sites was modeled with a gamma distribution (shape parameter = 1). A preliminary phylogenetic analysis was performed to infer the evolutionary history in each dataset (data not shown). Smaller datasets of the complete fusion and complete gene coding sequences (n = 288 and n = 120, respectively; Online Resource 3, 4) including viruses closely related to the Nigerian viruses studied here and representative viruses from other genotypes were parsed from the initial datasets and further analyzed. Maximum-likelihood trees based on the general time-reversible (GTR) model were constructed by using RaxML version 8.2.11 [40] with 1,000 bootstrap replicates. A discrete gamma distribution was used to model evolutionary rate differences among sites. Trees were visualized using FigTree (v.1.4.2) [41]. The Roman numerals presented in the taxon names in the phylogenetic trees represent the respective genotype for each isolate, followed by the GenBank accession number, host name (if available), country of isolation, strain designation, and year of isolation. The isolates were classified into genotypes and subgenotypes following the criteria defined by Diel et al. [42].
Codon usage analysis of complete NDV genomes
Genome-wide analysis was completed for all poultry (n = 45) and wild-bird NDV (n = 35) sequences from genotypes II, XIV, and XVII (n = 80) as described previously [43]. Briefly, the DAMBE v7.0.35 software package [44, 45] was used to calculate relative synonymous codon usage (RSCU) [46], effective number of codons (ENC) [47], nucleotide composition, and codon adaptation index (CAI) [45]. RSCU, which is the value of the observed codon number divided by the expected codon number, was determined for each sequence. To determine the relationship among samples (r), Pearson correlation analysis was carried out on the RSCU results, using GraphPad Prism 6 software (GraphPad Software Inc., USA). The r coefficient was used to determine the presence and magnitude of the correlation, and the two-tailed P-test (P < 0.01) was used to determine significance.
In addition to RSCU, the ENC, a non-directional measurement for analyzing the unequal use of codons across the genome, was also determined for each sequence to compare poultry and wild-bird virus sequences. The nucleotide composition affects this measurement, so it is imperative not only to determine ENC values but to also look at GC and GT composition of the genome region of interest [47]. Therefore, 13,725 positions were analyzed with 4575 nucleotides for each of the three different codon positions; values are given in percent with the total nucleotide count divided by the total count of each specific nucleotide. Additionally, the CAI was also calculated for each sequence, which is used to explain any deviation from the expected codon usage and to study codon usage preference of the different NDV isolates compared to the Gallus gallus reference set (as implemented in DAMBE; the number of codons used is provided in Online Resource 6) [45].
Accession numbers
The complete fusion gene and complete genome sequences of NDV isolates determined in this study were submitted to GenBank and are available under the accession numbers KC568204, MH392227, MH082804-MH092818, MH092820-MH082824, and MH996905-MH996993.
Results
A total of 101 samples collected in Nigeria from 2002 to 2015 were confirmed to contain NDV and were sent to SEPRL and UP for characterization. Ten submitted samples (7 at SEPRL and 3 at UP) contained mixed infections, and two NDV strains were identified in each of them, resulting in a total of 111 viruses characterized in this study. Of the samples with mixed infections, five contained two virulent viruses, four contained one vaccine-like virus and one virulent virus, and the remaining one contained one lentogenic virus and one virulent virus. Sixty-four viruses were confirmed as NDV at SEPRL, from which 42 complete or near-complete genome sequences and 22 complete F gene CDS were obtained. Forty-seven viruses were confirmed as NDV at UP, and 31 near-complete genome sequences and 16 F gene CDS were obtained. In total, 73 complete or near-complete genome sequences and 38 F gene CDS were determined from the studied viruses.
The geographic spread of NDV isolates sequenced in this study showed no relationship between genotype density and poultry density in Nigeria (Fig. 1). However, because sampling was random and irregular, no statistically significant conclusion can be drawn. Genotype II appears to occur in the more densely poultry populated states (central and southern regions), whereas genotypes XIV and XVII are more evenly dispersed throughout the country. This may be attributed to the regular use of live genotype II vaccines in commercial poultry production in these areas [9]. Three states had more viruses isolated from them compared to the other states, possibly because their locations were nearest to veterinary laboratories.
NDV virulence and/or pathogenicity markers were examined for all 111 sequenced viruses. Ninety-nine viruses had cleavage site motifs (113RQKR↓F117, 113RQRR↓F117, and 113RRKR↓F117) that are specific to virulent viruses based on criteria utilized by the World Organisation for Animal Health (OIE) to assess the virulence of NDV strains [3]. The remaining 12 viruses had cleavage sites that are specific to viruses of low virulence (113RQGR↓L117 and 113KQGR↓L117) (Table 1). Pathogenicity evaluation was done for five viruses using ICPI. Four of the viruses were selected from genotypes XIV and XVII, which are the most widespread genotypes in Africa. The fifth virus was selected because it belongs to genotype VI (typically isolated from columbiform birds) but was isolated from a quail (a galliform species). All of the viruses tested using the ICPI assay yielded values ranging from 1.76 to 1.86, which characterizes them as virulent NDV based on OIE standards [3], and this is in agreement with the predictions based on deduced amino acid cleavage site sequences (Table 1). ICPI values above 0.7 indicate a virulent strain, and those above 1.5 indicate a velogenic strain [48]. The results of the expanded F-gene phylogeny are displayed in Online Resource 1 and demonstrate that the viruses from Nigeria sequenced in this study are classified into seven different NDV genotypes. A tree based on the coding sequences of the complete genome displayed similar topology, confirming the phylogenetic classification of the viruses studied here and their relationship to other NDV viruses (Online Resource 2).
Subgenotype Ia. Two viruses sequenced for this study clustered in subgenotype Ia together with the I-2 vaccine strain (AY935499, 99.8-99.9% nucleotide sequence identity). Both viruses were isolated from chickens in 2009 in Plateau state. Live genotype I vaccines are used in Nigeria [9, personal communication from AT Laleye], and the high nucleotide sequence similarity of the two new isolates to the vaccine likely reflects isolation of a vaccine strain or vaccine spillover. The viruses isolated in this study are not closely related to the subgenotype Ia virulent viruses that caused an ND outbreak in Australia in 1998-1999 (nucleotide distance, 5.1 %) (Fig. 2a).
Genotype II. Twelve viruses obtained in this study were classified as members of genotype II in the central and southern regions, which have more commercial poultry operations (and subsequently higher use of live genotype II vaccine [9]) (Fig. 2a). Nine viruses were almost identical to the LaSota vaccine strain (AF077761), with between 99.82 and 99.94% nucleotide sequence identity. Three of these viruses were isolated from wild birds from 2002 to 2003: a free-flying house sparrow (Passer domesticus) in Benue state, a free-flying white-backed vulture (Gyps africanus) in Plateau state, and a captive African hawk-eagle (Aquila spilogaster) in Plateau state. One virus isolated from a chicken in Ebonyi state in 2013 was similar to the B1 vaccine (JN872151, 99.88% identity). The remaining two studied viruses from genotype II were related to the mesogenic Komarov strain (KT445901) (Fig. 2a), displaying 99.32 and 99.69% nucleotide sequence identity. The first was isolated from a chicken sample collected in 2015 in the FCT, while the second was isolated from an apparently healthy free-flying African black kite (Milvus migrans) in Plateau state in 2006.
Genotype IV. Two historical NDVs isolated in Oyo and Plateau states sequenced in this study were identified as members of the probably extinct genotype IV. The viruses were isolated from a chicken in 1973 and from a duck in 1980, respectively. The duck virus (duck/Nigeria/Vom/1980/N55/1980) grouped in a separate branch within genotype IV with three more viruses isolated from chickens in Nigeria in 1973. The chicken isolate (chicken/Nigeria/Ibadan/Oyo_state/VRD/1973) clustered in a different monophyletic group within genotype IV with poultry viruses from the UK (1933), Italy (1944), and Bulgaria (1959) (Fig. 2a). The mean distance between the viruses in both groups was 6.3% (Fig. 2a). This sequence obtained from the chicken isolate from Oyo state is the first complete genome sequence of a genotype IV virus available from the African continent.
Subgenotype VIh. Three viruses sequenced here clustered into subgenotype VIh with pigeon and quail viruses from Nigeria isolated between 2007 and 2013, a laughing dove virus from Kenya from 2012, and virus isolated from a pigeon in Argentina in 1997 (Fig. 2a) with 4.17% mean evolutionary distance between them. One of the newly sequenced viruses was isolated from a quail in Plateau state in 2008, and the other two were from pigeons in Jigawa state in 2008 and Lagos state in 2015. The complete genome of the quail virus was also sequenced.
Subgenotype VIg. One pigeon virus from 2007 isolated in Jigawa state clustered in subgenotype VIg together with a Nigerian pigeon virus from 2007 and viruses obtained from pigeons, a dove, and a mallard from Nigeria, Russia, Ukraine, Pakistan, Kazakhstan, and Egypt between 2005 and 2016 (Fig. 2a). The two Nigerian viruses were very closely related and shared 99.14% nucleotide sequence identity. They were more distant (4.65% nucleotide distance) to the rest of the viruses in the subgenotype.
Genotype XIVb. The most widespread group of viruses (Fig. 1) sequenced in this study was subgenotype XIVb. Twenty-eight viruses were isolated predominantly from domestic bird species (chickens, pigeons, ducks, and a turkey) between 2006 and 2015 from many states, namely Adamawa, Bauchi, Gombe, Imo, Jigawa, Kaduna, Kano, Katsina, Kebbi, Kogi, Kwara, Nassarawa, Plateau, Taraba, Yobe, and Zamfara. One additional virus from subgenotype XIVb was obtained from a free-flying raptor (unknown species) that was originally banded in Finland but captured in 2009 by a fisherman in Nigeria (Fig. 2b). Interestingly, some of the viruses within subgenotype XIVb had nucleotide distances of 2 to 3% despite being isolated during the same year, suggesting co-circulation of variant lineages.
Genotype XVIIa. The most prevalent group, with 62 viruses sequenced in this study, was subgenotype XVIIa. Most of these NDV isolates were isolated from domestic species (chickens, ducks, guinea fowl, a turkey, a quail, and a pigeon) between 2002 and 2015 from many states (Adamawa, Bauchi, Borno, Gombe, Imo, Jigawa, Kaduna, Kano, Katsina, Kogi, Nassarawa, Plateau, Rivers, Yobe, Zamfara). Two of the viruses were isolated from wild birds: one malachite kingfisher (Corythornis cristatus) in Adamawa state in 2010 and one white-backed vulture (Gyps africanus; critically endangered [49]) in Plateau state in 2002-2003. Interestingly, this vulture’s sample showed a mixed infection with both genotype II and XVIIa viruses. As was observed with subgenotype XIVb, some viruses within subgenotype XVIIa that were isolated during the same years displayed a large genetic distance between them (2.5 to 3.5%). Phylogenetic analysis also demonstrated that there are two subgroups within subgenotype XVIIa (Fig. 2c) that are 2.42% distant from each other.
Sub-genotype XVIIIb. One NDV isolate from a chicken in Ogun state in 2009 and sequenced in this study was characterized as member of subgenotype XVIIIb. The virus clustered with two other Nigerian chicken NDV isolates from 2011, HF969216 and HF969217 (with 97.34 and 97.41% nucleotide sequence identity, respectively), and viruses from Ivory Coast, Togo, and Mali isolated between 2006 and 2010 from chickens, a duck, a finch and a village weaver (2.94% nucleotide distance) (Fig. 2b).
Codon usage analysis
In order to determine if the isolations from wild birds represent spillover events from poultry or if the viruses isolated from wild birds were evolutionary adapted to and possibly maintained in these species, we conducted a complete genome comparison of the codon usage of viruses isolated from poultry and wild birds. RSCU values were determined for 80 of the Nigerian virus sequences (genotypes II, XIV, and XVII) isolated from both poultry and wild birds, and the averages for each are reported in Online Resource 5. RSCU values of >1 have a positive codon usage bias and are considered abundantly used codons. Those that have RSCU values <1 have a negative codon usage bias and are used less. Codons with RSCU values of 1 lack any bias and are used equally within the analyzed sequences. The codons AUG (M) and UGG (W) have an RSCU value of 1 because there is only one codon for that amino acid. For all of the sequences studied here, all codons were used similarly in the complete genome among the Nigerian poultry and wild-bird viruses (Fig. 3), with a Pearson r coefficient of 0.9987 that was statistically significant (P < 0.01). Correlation plots with a Pearson r coefficient of 0.5 to 1 have a high correlation, those with 0.3 to 0.5 have a medium correlation, those with 0.1 to 0.3 have low correlation, and those with < 0.1 have no correlation.
In addition to RSCU, ENC values were also determined for those same viruses (Table 3). ENC values range from 20 to 61, with 20 being exceptionally rare, indicating that only one of the synonymous codons is used for each amino acid, whereas an ENC value of 61 corresponds to the use of all synonymous codons equally [47]. The average ENC value for both poultry and wild-bird viruses was 59.9, indicating that all synonymous codons were used equally, and no bias was observed for either group of viruses. This finding is supported by the observation that the nucleotide composition for each group was determined to be approximately 46% and 47% for GC and GT content, respectively (Table 3). Although there were no deviations from the expected codon usage, CAI was determined for the virus sequences as an additional confirmatory test, using Gallus gallus as the reference [45], and the average for both poultry and wild-bird-isolated viruses was 0.74 out of 1, which was expected. These same analyses were repeated using 213 fusion gene sequences, and the results were similar, with no observed biases (data not shown).
Discussion
In this study, we used next-generation and Sanger sequencing to obtain complete genome and F gene sequences of NDV isolates from domestic and wild birds in Nigeria from 2002 to 2015 as well as archived viruses from 1973 and 1980. We performed comprehensive phylogenetic analysis to facilitate the better understanding of the distribution and genetic variability of NDV in this country. We added 38 new complete F gene CDS and 73 new complete or near-complete genome sequences to the GenBank database. These sequences were used in our codon usage analysis and will also be useful for future evolutionary studies of NDV circulating on the African continent, specifically for genotypes XVII and XVIII, for which only 12 complete genomes were available before this study. Phylogenetic analysis showed continued circulation of virulent viruses among both domestic and wild birds in Nigeria. The genotypes of the newly characterized viruses correspond to those previously reported in West Africa, and there is no evidence of additional introduction of virulent viruses. Snoeck et al. [50] recently classified genotypes XIV and XVII as new genotypes but only found them in domestic species. This is the first study in which these genotypes were identified in wild birds. The further division of XIVb and XVIIa into two separate groups indicates local divergence and evolution of these viruses over time. Furthermore, the subgroups of viruses in genotype IV indicate that Nigeria was also affected by the first NDV panzootic, which occurred during the 1930s and 1940s. Indeed, the phylogenetic distance between the two formed branches within genotype IV suggests that once introduced, these viruses persisted locally and circulated until the 1970s and 1980s in Nigeria. The Nigerian viruses clustered into a possible extinct subgenotype of genotype IV that cannot be classified and named here due to the lack of enough epidemiologically independent isolates (at least four) as per the classification criteria put forth by Diel et al. [42].
Some genotypes were more widespread (XIVb and XVIIa), and others clustered in the southern or central regions (II and XVIIIb). However, there was no significant relationship between poultry density and the number of NDV isolates present in a region. We suspect that this may be an artefact of biased data (e.g., outdated poultry population data and inconsistent surveillance activities over many years). A recent report [8] suggests that Sokoto state is a potential hotspot of different NDV genotypes, which contradicts our observation of widespread distribution of genotypes across multiple states and Plateau state having the largest diversity of genotypes. The identification of NDV of genotypes XIV and XVII in Nigeria and West Africa over a period of 14 years is indicative that these viruses became established in the country and the region, but these viruses have not been reported elsewhere on the continent or in other regions of the world. The larger nucleotide distances identified between viruses isolated in the same years from within subgenotypes XIVb and XVIIa and between the two monophyletic branches within subgenotype XVIIa provide enough evidence to suggest that these viruses continuously evolve locally as a result of active transmission. Despite the identified evolution and cross-species transmission of these viruses, no evidence of codon usage adaptation in wild birds compared to poultry was detected, confirming that codon adaptation in NDV is a slow process [43].
In a previous study, active surveillance of wild birds resulted in the identification of 13 NDV strains with varying degrees of virulence based on mean death time (MDT), intracerebral pathogenicity index (ICPI), intravenous pathogenicity index (IVPI), and a triple one-step reverse transcription polymerase chain reaction (RT-PCR) assay [31]. These results showed that the isolate from the white-backed vulture was mesogenic and that the black kite, house sparrow, and African hawk eagle isolates were lentogenic. In our sequencing results, we documented that the white-backed vulture sample contained two viruses, one virulent and the other of low virulence, and that the virus from the black kite was virulent. These differences might be a result of the mixed infection of two viruses in the vulture sample, which might have affected the ICPI value obtained by Ibu et al. [31], or of advances in technology and the higher sensitivity of random deep sequencing used here.
Genotype VI is present in Nigeria with subgenotypes VIh and VIg continuing to circulate in pigeons. Additionally, this study provides the first isolation of a VIh virus from a quail and the first complete genome sequence available for this subgenotype. It is known that pigeons may possibly play an important role in the transmission of genotype VI viruses to poultry, which proves to be an interesting case when considering the relatedness of viruses in distant countries, especially considering that pigeons are a non-migratory species [51].
Poultry health is of high concern around the world, and thus NDV surveillance is currently more focused on domesticated species than on wild birds. Therefore, NDV in wild birds is not well documented, and there may be many undocumented cases of wild bird deaths or morbidity, or of clinically healthy individuals that harbor the virus. This study is indicative of the possible diversity of NDV in wild-bird species in Nigeria. This highlights the need to conduct wide-scale NDV surveillance of wild-bird populations in the region to identify epidemiological relationships and possible ecological costs of the circulation of NDV in the wild avifauna. White-backed vultures, African hawk eagles, and malachite kingfishers have not been reported previously to be infected with any pathotype of NDV. While raptors have been shown to become infected by eating diseased or dead chickens and this mode of spread to wild birds is plausible, we have no specific evidence to suggest it from our isolations. Our study provides the first isolation and complete NDV genome sequences from these species. Although the presence of NDV has been confirmed in black kites in Switzerland [52] and Nigeria [53] the virus obtained here from a black kite is the first example of a mesogenic vaccine virus detected in a wild bird. There have been multiple studies documenting the presence of NDV in house sparrows, including experimentally infected birds from Sudan [54] and sequenced isolates of class II and genotypes VII and II in China [55].
Close contact between free-ranging wild birds and backyard poultry regularly occurs at the livestock-wildlife interface [29], thus highlighting an important point for NDV transmission. This study provides evidence for reverse spillover of a mesogenic vaccine virus (Komarov vaccine) used in Nigeria [8, 9] to wild birds (African black kite). The observed nucleotide sequence distance between the vaccine and the isolate suggests that further circulation and evolution occurred after the spillover, indicating that such transmission events may have a prolonged effect on wild avifauna. Mesogenic viruses have cleavage site motifs and ICPI values that allow them to be classified as virulent according to the definitions outlined by OIE; therefore, some countries have specified that only lentogenic NDV strains can be used as vaccines [3, 56]. Spillover of the LaSota vaccine virus is also documented, as was previously documented in other countries [15]. While the lentogenic strains are expected to have low or no adverse effects on wild birds, the effects of the mesogenic vaccine virus (Komarov strain) in wild birds may be of higher cost. Mixed infections in wild birds may be another point of concern, since an infection with two pathogens may increase the likelihood of disease; however, our study shows a single case in which we observed an apparently healthy, free-flying white-backed vulture (Gyps africanus) that showed a mixed infection with genotypes II and XVIIa. Although random individuals were sampled, ND may have a great effect on and be undersampled in wild bird populations, e.g., due to undetected infections or mortalities or migratory movements out of the study area.
These reverse-spillover events are likely to increase as poultry production and vaccination against viral threats increase across the globe [14,15,16,17,18,19]. In Nigeria, like many other countries, free-ranging chickens have no borders or measures protecting them against NDV transmission to or from wild birds [57]. Many of these backyard farms may not have as intensive vaccination of biosecurity protocols as commercial operations [23]. This is especially significant if it is considered that the current vaccines are not completely effective and that workers at commercial poultry farms typically have backyard poultry at their household [31]. Thus, if a pathogen enters the backyard flock, it can be devastating. Soos et al. [58] showed that backyard chickens are significantly more likely to show clinical signs, which is correlated with active shedding of the disease agent [59]. We suggest further investigation into the epidemiology of NDV on free-range poultry farms in order to identify points of transmission and to provide information on virus diversity to support planning of optimal disease control.
References
Amarasinghe GK et al (2018) Taxonomy of the order Mononegavirales: update 2018. Arch Virol 163(8):2283–2294
Alexander DJ, Aldous EW, Fuller CM (2012) The long view: a selective review of 40 years of Newcastle disease research. Avian Pathol 41(4):329–335
OIE (2012) Newcastle disease. In: Manual of diagnostic tests and vaccines for terrestrial animals, pp 555–574 http://www.oie.int/standard-setting/terrestrial-manual/access-online/. Accessed 10 Feb 2019
Czeglédi A, Ujvári D, Somogyi E, Wehmann E, Werner O, Lomniczi B (2006) Third genome size category of avian paramyxovirus serotype 1 (Newcastle disease virus) and evolutionary implications. Virus Res 120(1–2):36–48
Dimitrov KM, Ramey AM, Qiu X, Bahl J, Afonso CL (2016) Temporal, geographic, and host distribution of avian paramyxovirus 1 (Newcastle disease virus). Infect Genet Evol 39:22–34
Hill DH, Davis OS, Wilde JKH (1953) Newcastle disease in Nigeria. Br Vet J 109(9):381–385
Snoeck CJ, Ducatez MF, Owoade AA, Faleke OO, Alkali BR, Tahita MC, Tarnagda Z, Ouedraogo JB, Maikano I, Mbah PO, Kremer JR, Muller CP (2007) Newcastle disease virus in West Africa: new virulent strains identified in non-commercial farms. Arch Virol 154(1):47–54
Bello MB, Yusoff KM, Ideris A, Hair-Bejo M, Peeters BP, Jibril AH, Tambuwal FM, Omar AR (2018) Genotype diversity of Newcastle disease virus in Nigeria: disease control challenges and future outlook. Adv Virol. https://doi.org/10.1155/2018/6097291
Shittu I, Joannis TM, Odaibo GN, Olaleye OD (2016) Newcastle disease in Nigeria: epizootiology and current knowledge of circulating genotypes. Virus Dis 27(4):329–339
Snoeck CJ, Owoade AA, Couacy-Hymann E, Alkali BR, Okwen MP, Adeyanju AT, Komoyo GF, Nakoune E, Le Faou A, Muller CP (2013) High genetic diversity of Newcastle disease virus in poultry in West and Central Africa: co-circulation of genotypes XIV and newly defined genotypes XVII and XVIII. J Clin Microbiol 51:2250–2260
Snoeck CJ, Adeyanju AT, Owoade AA, Couacy-Hymann E, Alkali BR, Ottosson U, Muller CP (2013) Genetic diversity of Newcastle disease virus in wild birds and pigeons in West Africa. Appl Environ Microbiol 79:7867–7874
Kaleta EF, Baldauf C (1988) Newcastle disease in free-living and pet birds. Newcastle disease. Springer, Boston, pp 197–246
Miller PJ, Koch G (2013) Newcastle disease. Dis Poult 13:89–138
Cardenas-Garcia S, Lopez RN, Morales R, Olvera MA, Marquez MA, Merino R, Miller PJ, Afonso CL (2013) Molecular epidemiology of Newcastle disease in Mexico: potential spillover of viruses from poultry into wild bird species. Appl Environ Microbiol 79:4985–4992
Ayala AJ, Dimitrov KM, Becker CR, Goraichuk IV, Arns CW, Bolotin VI, Ferreira HL, Gerilovych AP, Goujgoulova GV, Martini MC, Muzyka DV, Orsi MA, Scagion GP, Silva RK, Solodiankin OS, Stegniy BT, Miller PJ, Afonso CL (2016) Presence of vaccine-derived Newcastle disease viruses in wild birds. PLoS One 11(9):e0162484
Dimitrov KM, Lee DH, Williams-Coplin D, Olivier TL, Miller PJ, Afonso CL (2016) Newcastle disease viruses causing recent outbreaks worldwide show unexpectedly high genetic similarity with historical virulent isolates from the 1940’s. J Clin Microbiol 54:1228–1235
Vidanović D, Šekler M, Ašanin R, Milić N, Nišavić J, Petrović T, Savić V (2011) Characterization of velogenic Newcastle disease viruses isolated from dead wild birds in Serbia during 2007. J Wildl Dis 47(2):433–441
Carrasco ADOT, Seki MC, de Freitas Raso T, Paulillo AC, Pinto AA (2008) Experimental infection of Newcastle disease virus in pigeons (Columba livia): Humoral antibody response, contact transmission and viral genome shedding. Vet Microbiol 129(1–2):89–96
Kapczynski DR, Wise MG, King DJ (2006) Susceptibility and protection of naive and vaccinated racing pigeons (Columbia livia) against exotic Newcastle disease virus from the California 2002–2003 outbreak. Avian Dis 50(3):336–341
Ramey AM, Reeves AB, Ogawa H, Ip HS, Imai K, Bui VN, Yamaguchi E, Silko NY, Afonso CL (2013) Genetic diversity and mutation of avian paramyxovirus serotype 1 (Newcastle disease virus) in wild birds and evidence for intercontinental spread. Arch Virol 158(12):2495–2503
Stanislawek WL, Wilks CR, Meers J, Horner GW, Alexander DJ, Manvell RJ, Kattenbelt JA, Gould AR (2002) Avian paramyxoviruses and influenza viruses isolated from mallard ducks (Anas platyrhynchos) in New Zealand. Arch Virol 147(7):1287–1302
Banerjee M, Reed WM, Fitzgerald SD, Panigrahy B (1994) Neurotropic velogenic Newcastle disease in cormorants in Michigan: pathology and virus characterization. Avian Dis 38(4):873–878
Ducatez MF, Olinger CM, Owoade AA, Tarnagda Z, Tahita MC, Sow A, De Landtsheer S, Ammerlaan W, Oudraogo JB, Osterhaus ADME, Fouchier RAM, Muller CP (2007) Molecular and antigenic evolution and geographical spread of H5N1 highly pathogenic avian influenza viruses in western Africa. J General Virol 88(8):2297–2306
Musa U, Abdu PA, Dafwang II, Umoh JU, Saidu L, Mera UM, Edache JA (2009) Seroprevalence, seasonal occurrence and clinical manifestation of Newcastle disease in rural household chickens in Plateau State, Nigeria. Int J Poult Sci 8(2):200–204
Sa’idu L, Abdu PA (2008) Outbreak of Viscerotropic Velogenic form of Newcastle dis-ease in vaccinated six weeks old pullets. Sokoto J Vet Sci 7(1):37–40
Barre J, Delor V (2004) Newcastle disease in wildlife (unpublished document)
Heckert FLR (2007) Newcastle disease and related avian paramyxoviruses. In: Thomas NJ, Hunterand DB, Atkinson CT (eds) Infectious diseases of wild birds. Blackwell Publishing, Oxford, pp 3–16
Cappelle J, Caron A, De Almeida RS, Gil P, Pedrono M, Mundava J, Fofana B, Balanca G, Dakouo M, Ould El Mamy AB, Abolnik C, Maminiaina OF, Cumming GS, De Visscher MN, Albina E, Chevalier V, Gaidet N (2015) Empirical analysis suggests continuous and homogeneous circulation of Newcastle disease virus in a wide range of wild bird species in Africa. Epidemiol Infect 143(6):1292–1303
Miguel E, Grosbois V, Berthouly-Salazar C, Caron A, Cappelle J, Roger F (2013) A meta-analysis of observational epidemiological studies of Newcastle disease in African agro-systems, 1980–2009. Epidemiol Infect 141(6):1117–1133
Spackman E, Senne DA, Myers TJ, Bulaga LL, Garber LP, Perdue ML, Lohman K, Daum LT, Suarez DL (2002) Development of a real-time reverse transcriptase PCR assay for type A influenza virus and the avian H5 and H7 hemagglutinin subtypes. J Clin Microbiol 40(9):3256–3260
Ibu OJ, Okoye JOA, Adulugba EP, Chah KF, Shoyinka SVO, Salihu E, Chukwuedo AA, Baba SS (2009) Prevalence of Newcastle disease virus in wild and captive birds in Central Nigeria. Int J Poult Sci 8(6):574–578
Dimitrov KM, Sharma P, Volkening JD, Goraichuk IV, Wajid A, Rehmani SF, Basharat A, Shittu I, Joannis T, Miller PJ, Afonso CL (2017) A robust and cost-effective approach to sequence and analyze complete genomes of small RNA viruses. Virol J 14(1):72
Dimitrov KM, Bolotin V, Muzyka D, Goraichuk IV, Solodiankin O, Gerilovych A, Stegniy B, Goujgoulova GV, Silko NY, Pantin-Jackwood MJ, Miller PJ, Afonso CL (2016) Repeated isolation of virulent Newcastle disease viruses of sub-genotype VIId from backyard chickens in Bulgaria and Ukraine between 2002 and 2013. Arch Virol 161(12):3345–3353
Miller PJ, Dimitrov KM, Williams-Coplin D, Peterson MP, Pantin-Jackwood MJ, Swayne DE, Suarez DL, Afonso CL (2015) International biological engagement programs facilitate Newcastle disease epidemiological studies. Front Public Health 3:235
Abolnik C, de Castro M, Rees J (2012) Full genomic sequence of an African Avian Paramyxovirus Type 4 strain isolated from a wild duck. Virus Genes 45:537–541
Benson DA, Cavanaugh M, Clark K, Karsch-Mizrachi I, Lipman DJ, Ostell J, Sayers EW (2017) GenBank. Nucleic Acids Res 45:D37–D42
Katoh K, Standley DM (2013) MAFFT multiple sequence alignment software version 7: improvements in performance and usability. Mol Biol Evol 30:772–780
Tamura K, Stecher G, Peterson D, Filipski A, Kumar S (2013) MEGA6: molecular evolutionary genetics analysis version 6.0
Tamura K, Nei M, Kumar S (2004) Prospects for inferring very large phylogenies by using the neighbor-joining method. Proc Natl Acad Sci USA 101:11030–11035
Stamatakis A (2014) RAxML version 8: a tool for phylogenetic analysis and post-analysis of large phylogenies. Bioinformatics 30(9):1312–1313
Rambaut A, Drummond A (2012) FigTree: tree figure drawing tool, v1. 4.2. Institute of Evolutionary Biology, University of Edinburgh
Diel DG, da Silva LH, Liu H, Wang Z, Miller PJ, Afonso CL (2012) Genetic diversity of avian paramyxovirus type 1: proposal for a unified nomenclature and classification system of Newcastle disease virus genotypes. Infect Genet Evol 12(8):1770–1779
Taylor TL, Dimitrov KM, Afonso CL (2017) Genome-wide analysis reveals class and gene specific codon usage adaptation in avian paramyxoviruses 1. Infect Genet Evol 50:28–37
Xia X (2013) DAMBE5: a comprehensive software package for data analysis in molecular biology and evolution. Mol Biol Evol 30(7):1720–1728
Xia X (2007) An improved implementation of codon adaptation index. Evolut Bioinform 3:117693430700300028
Sharp PM, Li WH (1987) The codon adaptation index-a measure of directional synonymous codon usage bias, and its potential applications. Nucleic Acids Res 15(3):1281–1295
Wright F (1990) The ‘effective number of codons’ used in a gene. Gene 87(1):23–29
Alexander DJ, Swayne DE (1998) Newcastle disease virus and other avian paramyxoviruses. In: Swayne DE, Glisson JR, Jackwood MW, Pearson JE, Reed WM (eds) A Laboratory Manual for the Isolation and Identification of Avian Pathogens. The American Association of Avian Pathologists, Kennett Square, pp 156–163
BirdLife International (2018) Gyps africanus. The IUCN red list of threatened species 2018: http://dx.doi.org/10.2305/IUCN.UK.2018-2.RLTS.T22695189A126667006.en. Accessed 30 Jan 2019
Snoeck CJ, Adeyanju AT, Owoade AA, Couacy-Hymann E, Alkali BR, Ottosson U, Muller CP (2013) Genetic diversity of Newcastle disease virus in wild birds and pigeons in West Africa. Appl Environ Microbiol 79:7867–7874
Sabra M, Dimitrov KM, Goraichuk IV, Wajid A, Sharma P, Williams-Coplin D, Basharat A, Rehmani SF, Muzyka DV, Miller PJ, Afonso CL (2017) Phylogenetic assessment reveals continuous evolution and circulation of pigeon-derived virulent avian avulaviruses 1 in Eastern Europe, Asia, and Africa. BMC Vet Res 13(1):291
Schelling E, Thur B, Griot C, Audige L (1999) Epidemiological study of Newcastle disease in backyard poultry and wild bird populations in Switzerland. Avian Pathol 28(3):263–272
Ameji ON, Saidu L, Abdu PA (2015) Newcastle disease antibodies in apparently healthy wild birds in Kogi State, Nigeria. Res J Vet Sci 8:52–60
Khalafalla AI, Hajer I, Nimir AH (1990) Role of some Passeriformes birds in transmission of Newcastle disease II Pathogenesis of Newcastle disease virus in Sudan house sparrows (Passer domesticus arborius). Bull Animal Health Prod Africa 38(1):51–54
Zhu W, Dong J, Xie Z, Liu Q, Khan MI (2010) Phylogenetic and pathogenic analysis of Newcastle disease virus isolated from house sparrow (Passer domesticus) living around poultry farm in southern China. Virus Genes 40(2):231–235
Wehmann E, Czegledi A, Werner O, Kaleta EF, Lomniczi B (2003) Occurrence of genotypes IV, V, VI and VIIa in Newcastle disease outbreaks in Germany between 1939 and 1995. Avian Pathol 32:157–163
Adene DF (2004) An integrated rural poultry improvement scheme. Poultry health and production, principles and practices. Stirling Horden Publishers, Ibadan, pp 280–284
Soos C, Padilla L, Iglesias A, Gottdenker N, Bédon MC, Rios A, Parker PG (2008) Comparison of pathogens in broiler and backyard chickens on the Galapagos Islands: implications for transmission to wildlife. Auk 125(2):445–455
Saif YM, Fadly AM, Glisson JR, McDougald LR, Nolan LK, Swayne DE (2008) Diseases of Poultry, 12th edn. Blackwell Publishing, Iowa
Acknowledgements
We want to thank the staff of the Central Diagnostic Laboratory /Regional Laboratory NVRI Vom and surveillance officers in the State and Federal Ministries of Agriculture, Nigeria. This research was supported by the Agricultural Research Service (ARS) and supported by the USDA Current Research Information System (CRIS) (number 6612-32000-072-00D) and partially funded by The Defense Threat Reduction Agency (DTRA) (FRCALL12-6-2-0015).
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
The authors declare that they have no conflict of interest.
Additional information
Communicated by William G Dundon.
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Electronic supplementary material
Below is the link to the electronic supplementary material.
Online Resource 1
Maximum composite likelihood tree with no collapsed branches, constructed using complete fusion gene coding sequences. Genotypes and subgenotypes of viruses are presented with Roman numerals and lowercase letters in each taxon name. (PDF 134 kb)
Online Resource 2
Maximum composite likelihood tree constructed using complete genome coding sequences. Genotypes and subgenotypes of viruses are presented with Roman numerals and lowercase letters in each taxon name. Red lettering indicates viruses sequenced for this study. (PDF 60 kb)
Online Resource 3
List of sequences used for the maximum composite likelihood tree constructed using complete fusion gene coding sequences (Fig. 2, Online Resource 1). Isolates indicated in bold were sequenced for this study. (PDF 164 kb)
Online Resource 4
List of sequences used for the maximum composite likelihood tree constructed using complete gene coding sequences (Online Resource 2). Isolates indicated in bold were sequenced for this study. (PDF 74 kb)
Online Resource 5
Complete genome relative synonymous codon usage (RSCU) values among poultry and wild bird viruses. (PDF 101 kb)
Online Resource 6
Number of codons used in the reference Gallus gallus dataset as implemented in DAMBE. (PDF 9 kb)
Rights and permissions
About this article
Cite this article
Welch, C.N., Shittu, I., Abolnik, C. et al. Genomic comparison of Newcastle disease viruses isolated in Nigeria between 2002 and 2015 reveals circulation of highly diverse genotypes and spillover into wild birds. Arch Virol 164, 2031–2047 (2019). https://doi.org/10.1007/s00705-019-04288-9
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00705-019-04288-9