key: cord-0913109-0k4ldvt1
authors: Moutelíková, Romana; Dufková, Lucie; Kamler, Jiří; Drimaj, Jakub; Plhal, Radim; Prodělalová, Jana
title: Epidemiological survey of enteric viruses in wild boars in the Czech Republic: First evidence of close relationship between wild boar and human rotavirus A strains
date: 2016-09-25
journal: Vet Microbiol
DOI: 10.1016/j.vetmic.2016.08.003
sha: d428c833299e8f39140505fbff407a5ff5bbdc32
doc_id: 913109
cord_uid: 0k4ldvt1

Population of wild boar is increasing in the whole Europe, the animals migrate close to human habitats which greatly increases the possibility of natural transmission between domestic animals or humans and wild boars. The aim of the study was to estimate in population of free-living wild boar in the Czech Republic the prevalence of enteric viral pathogens, namely rotavirus groups A and C (RVA and RVC), porcine reproductive and respiratory syndrome virus (PRRSV), and members of family Coronaviridae (transmissible gastroenteritis virus – TGEV, porcine epidemic diarrhea virus − PEDV, porcine respiratory coronavirus – PRCV, and porcine hemagglutination encephalomyelitis virus – PHEV) and Picornaviridae,(teschovirus A – PTV, sapelovirus A – PSV, and enterovirus G – EV-G). In our study, stool samples from 203 wild boars culled during hunting season 2014–2015 (from October to January) were examined by RT-PCR. RVA was detected in 2.5% of tested samples. Nucleotide analysis of VP7, VP4, and VP6 genes revealed that four RVA strains belong to G4P[25]I1, G4P[6]I5, G11P[13]I5, and G5P[13]I5 genotypes and phylogenetic analysis suggested close relation to porcine and human RVAs. The prevalence of RVC in wild boar population reached 12.8%, PTV was detected in 20.2%, PSV in 8.9%, and EV-G in 2.5% of samples. During our study no PRRSV or coronaviruses were detected. Our study provides the first evidence of RVC prevalence in wild boars and indicates that wild boars might contribute to the genetic variability of RVA and also serve as an important reservoir of other enteric viruses.

Numbers of wild boar (Sus scrofa) within Europe has been growing continuously since 1980s. Insufficient hunting together with other various causes have been identified as factors contributing to the population increase. Nowadays, wild boar is one of the most widely distributed mammals in Europe (Massei et al., 2015) and its hunting bag on many localities exceeds 1 ind/ km 2 . High density of wild boar increased damage on field crops and also risk of transmission of pathogens in their populations. Moreover, spreading of human habitation to suburban areas, increased use of lands for agricultural purposes, and deforestation have all enhanced chances of contact between wild boars and humans or domestic animals. Together with recreational hunting and consumption of wild boar meat, that facts form an ideal environment for the transmission of pathogens between wild boars and both humans and domestic animals (Meng et al., 2009 ). On the contrary, wild boars could become infected from foraged waste of human or domestic animal origin due to their typical behaviour. Wild boar is an omnivore foraging for food mainly close to the soil surface or by grubbing and digging 15 cm deep (Škrkal et al., 2015) . Moreover, pigs have the ability to discriminate between food sites of different relative value and to remember their respective locations. Food foraging, reproduction, and other social factors may affect the aggregation of animal (Podgórski et al., 2014) presenting a determining role in epidemiology of diseases.

Wild boars have been recognized as a source of viral infectious diseases for domestic pigs. The presence of antibodies against viral pathogens or viral nucleic acids of viral pathogens representing a serious economic threat was confirmed in several epidemiological studies; it refers particularly to African swine fever virus (ASFV) (Wo zniakowski et al., 2015) , classical swine fever virus (CSFV) (recently reviewed by Moenning, 2015) , and Aujeszky's disease virus (ADV) (Meier et al., 2015) . However, not so much is known about other prevalent viral diseases of swine such as porcine circovirus type 2 (PCV-2), porcine reproductive and respiratory syndrome virus (PRRSV), influenza A virus (IAV), porcine parvovirus (PPV) (Gonzáles-Barrio et al., 2015; Sliz et al., 2015; Touloudi et al., 2015) . Unexpectedly, specific antibodies against Schmallenberg virus (SBV) were detected in wild boars (Mouchantat et al., 2015) . Despite of the fact that enteric viruses are significant pathogens of domestic pigs, they have been studied only sporadically in wild boar. Enteric viruses are transmitted by faecal-oral route, shed in extremely high numbers in the faeces of infected individuals, generally less susceptible to inactivation caused by environmental conditions, and can be easily transported in the environment (Fong and Lipp, 2005) . Antibodies against transmissible gastroenteritis virus (TGEV) have been detected extremely rarely (Hälli et al., 2012; McGregor et al., 2015) . Viral nucleic acids of porcine enteric picornaviruses, comprising teschoviruses, sapeloviruses, and enteroviruses G have been detected in stool samples (Prod elalová, 2012; Cano-Goméz et al., 2013) . Moreover, wild boars represent an important source of zoonotic hepatitis E virus (Schlosser et al., 2015) . The prevalence of rotaviruses in wild boars is almost unknown. The only study which detected rotavirus A (RVA) in wild boars was carried out in Japan. Okadera et al. (2013) detected RVA in four animals from 90 tested faecal samples.

Aim of the study was to survey population of wild boar in the Czech Republic for the presence of enteric RNA-viruses including RVA, RVC, PRRSV, and members of family Coronaviridae and Picornaviridae, and to assess the role of wild boars as natural reservoirs of those important pathogens which can be transmitted to domestic pigs and in case of rotaviruses also to humans.

Faecal samples or intestinal contents from wild boar (n = 203, 91 males and 112 females) were collected from animals culled between October 2014 and January 2015 and come from four regions representing almost half of the Czech Republic area (South Moravian, Central and South Bohemian, and Vysocina Regions). The age of culled animals was determined by mandibular tooth eruption and wear and ranged between 2 and 90 months with the average age of 12.9 months and median age of 9 months. The sites of sample collection are specified on the map of the Czech Republic (Supplementary data -see the map in the online version at DOI: 10.1016/j.vetmic.2016.08.003).

In the day of collection the 10% faecal suspensions in phosphate buffered saline (PBS) were prepared and homogenized with added glass beads (diameter 2 mm) for 10 min at 2100 rpm in a vortex and then clarified in a table centrifuge for 1 min at 12,000 rpm. If not processed immediately, the supernatants were stored at À80 C.

Total RNA was extracted from 100 ml of the supernatant using 1 ml of TRI Reagent (Sigma, St. Louis, USA) according to the manufacturer's instructions. Extracted RNA was dissolved in 100 ml of RNase-free dH 2 O, divided into aliquots and stored at À80 C until further analysis.

Random primed reverse transcription (RT) was carried out with the use of Transcriptor First Strand cDNA Synthesis Kit (Roche, Germany) following the manufacturer's instructions. PCR for detection of specific RNA-viruses was accomplished with Fast Start Taq DNA Polymerase (Roche, Germany) and with gene specific primers. The presence of viral RNA of following enteric pathogens was surveyed: RVA, RVC, members of family Coronaviridae (specifically TGEV, PEDV, porcine respiratory coronavirus À PRCV, and porcine hemagglutination encephalomyelitis virus À PHEV), PRRSV, enterovirus G (EV-G), teschovirus A (PTV), sapelovirus A (PSV). Detection of PTV and PSV was carried out with the use of one primer pair; the two virus species were distinguished according to the PCR product length (PTV -161 bp, PSV -180 bp) and verified with sequencing (Eurofins MWG Operon, Germany). Detection of members of Coronaviridae family was accomplished with the use of universal primers detecting four viral species (TGEV, PEDV, PRCV, and PHEV). The specificity of detection primers was verified on the specific pathogens deposited in the Collection of Animal Pathogenic Microorganisms (CAPM, Veterinary Research Institute, Brno) and in the case of RVC on own field isolates of porcine strains (Moutelíková et al., 2014) . To increase the sensitivity of the reactions, the second round of PCR was carried out with a seminested pair of primers (in RVC and Coronaviridae detection) or with the same set of primers as in the first round. Limit of detection (LOD) of the RT-PCR assay with re-amplification was specified for RVA assay by 10-fold serial dilution of porcine RVA strain with known original concentration which was determined by transmission electron microscope virus quantitation using latex particles (Malenovska, 2013) . The minimal concentration of RVA still detected was 1.2 Â 10 3 virus particles/1 g of faeces. Used primers, sizes of the expected amplicons and references are listed in Supplementary Table S1 (see Supplementary material Table S1 in the online version at DOI: doi:10.1016/j.vetmic.2016.08.003). The PCR products were examined by electrophoreses in a 2% agarose gel, stained with Midori Green stain (Nippon Genetics Europe, Germany) and visualized by ultraviolet transillumination. Selected PCR products of used diagnostic assays were submitted to sequencing and obtained sequences were analysed with the use of BLAST on-line tool to confirm their classification into respective viral species.

To further characterize RVA-positive samples we attempted to determine the genotypes of the VP7, VP4, and VP6 segments. The primers used for the whole (VP7, VP6) or partial (VP4) ORF preparation are described in the Supplementary Table S2 (see  Supplementary material Table S2 in the online version at DOI: http://dx.doi.org/10.1016/j.vetmic.2016.08.003). The obtained sequences were phylogenetically analysed with the MEGA version 6 (Tamura et al., 2013) . The dendrograms were prepared with the neighbor-joining method and the evolutionary distances were calculated with the use of Kimura 2-parameter model (Kimura, 1980) . To assess the reliability of constructed phylogenetic trees, the bootstrap test with 1000 of replicates was used. The bootstrap value >75% indicates satisfactory topology of phylogenetic tree branches; the bootstrap value of 95-100% is very good. To classify the RVA sequence into the corresponding genotype, the percentage of nucleotide sequence similarity between the Czech RVA strains and RVA sequences deposited in the GenBank was calculated using the p-distances method. The VP7, VP4, and VP6 genotypes of RVA strains were determined with the use of previously published cut-off values (Matthijnssens et al., 2008) . The assigned genotypes were verified with RotaC online tool (Maes et al., 2009) in accord with the Rotavirus Classification Working Group (RCWG) guidelines.

In total, 203 faeces samples from wild boars were surveyed for RNA-viruses. The screening revealed presence of RVA, RVC, and members of family Picornaviridae. Single infections with enteral viruses as well as mixed infections with two or three viruses were also evaluated. No members of family Coronaviridae (TGEV, PEDV, PRCV, and PHEV) or PRRSV were found. The results are summarized in Table 1 . The distribution of detected viruses on different sites of collection may be seen on the map of the Czech Republic (Supplementary data). The acquired sequences were compared with RVA sequences available in the GenBank and the phylogenetic trees based on the nucleotide sequences of VP7, VP4 (VP8* region), and VP6 genes were constructed (Figs. 1-3 (Table 2) . Although some of the Czech wild boar RVA strains shared the same genotypes (e.g. P211/2014, P218/2014, and P245/2014 were I5 genotype the in the segment coding VP6, or P70/2015 and P211/2014 were G4 genotype in the segment coding VP7), the cross similarities of their sequences on nucleotide level were quite low for most of the analysed gene segments (68.1-81.6% for VP7, 57.5-83.3% for VP4, and 83.4-93.5% for VP6).

RVC was detected in 12.8% (n = 26) of the faecal samples. Two thirds of RVC-positive samples (n = 18) contained RVC as a single detected pathogen. In the rest of RVC-positive samples one or more other pathogens were detected (RVA, PSV, PTV). The percentage of RVC-positive samples was higher in the group of animals younger than 6 months of age (15.6%) than among older animals (11.5%) but the difference was not statistically significant (p < 0.05, Fisher's exact test, GraphPad Prism 5). Sixteen randomly selected RVCpositive PCR products (326 bp) were submitted to sequencing. The similarity of analysed sequences detected in the Czech wild boars and sequences of VP6 segment of porcine RVC strains deposited in the GenBank ranged between 87 and 98% on nucleotide level (data on request).

The most prevalent virus detected during our study in wild boars was PTV which was detected in 20.2% (n = 41) of all tested samples including coinfections with other viruses. PSV was less prevalent with 8.9% (n = 18) of positive samples. Infections with PTV were found evenly in both age groups of animals while PSV was more often detected in the group of animals above 6 months of age (10.1% of samples were PSV-positive) than in the group of younger animals (6.3% of samples PSV-positive) but the difference was not found statistically significant (p < 0.05, Fisher's exact test, GraphPad Prism 5). EV-G was detected only in 2.5% (n = 5) of all tested samples (including mixed infections). All PCR products of PTV-, PSV-, and EV-G-positive samples were sequenced and nucleotide sequences compared to sequences available in the GenBank. The similarities of picornavirus sequences detected in the Czech wild boars and the sequences in the GenBank were 97-100% for PTV and EV-G, and 97-99% for PSV (data on request).

This study investigated the prevalence of eleven enteric viral infections in 203 wild boars culled during the 2014/2015 hunting season in the Czech Republic. Previously described RT-PCR primers were used to detect RVA, RVC, PRRSV and members of families Coronaviridae (TGEV, PEDV, PRCV, and PHEV) and Picornaviridae (PTV, PSV, and EV-G).

Porcine rotaviruses (both RVA and RVC) are considered to be major pathogens causing diarrhoea in pigs. Transmission of RVC from animal reservoir to human host was reported only once in Brazil (Gabbay et al., 2008) and owing to high degree of conservation (>93% of nucleotide sequence identity) of all segments of human RVC isolates (except for the VP3 gene) (Ghosh and Kobayashi, 2011) it may be presumed that zoonotic transmission of RVC strains is a rare event. However, zoonotic potential of RVA strains has been proven repeatedly (Zeller et al., 2012; Papp et al., 2013) . So far, there is no available information concerning RVC prevalence in wild boars and only very limited knowledge about RVA detected in wild boars in Japan (Okadera et al., 2013) . The detected RVC prevalence in our study was 12.8% (26/203) including coinfections with other enteral viruses. Similar prevalence of RVC was detected in domestic pigs in the Czech Republic (25.6%) (Moutelíková et al., 2014) , in South Korea (26.2%) (Jeong et al., 2009) or in Italy (31.3%) (Martella et al., 2007) . Although the RVC infection can cause severe gastroenteritis in pigs of all ages, it may also have subclinical course (Amimo et al., 2013) . The samples collected during our study came from animals without any apparent clinical signs of a disease and the faeces processed were of normal consistence. RVA was in the Czech wild boars detected in 2.5% (5/203) of tested samples which is in agreement with results of Okadera et al. (2013) . They found RVA in 4.4% of tested faecal samples from wild boars in Japan. The possibility of RVA transmission between wild boars and domestic pigs in Japan was supported by very close phylogenetic relationship between their VP7 and VP4 nucleotide sequences. The RVApositive strain P70/2015 detected during our survey showed the highest similarities of all studied genomic segments to human RVA strains which were described elsewhere as porcine-human reassortments (Mullick et al., 2013; Zhou et al., 2015) . It is of great interest that the P[25] genotype of VP4 segment was found so far only very rarely in several RVA strains isolated from humans. This genotype is thought to be of porcine origin but so far no porcine (or other animal) sample was described to bear this scarce VP4 genotype (Matthijnssens et al., 2010) . This is the first time the possible animal progenitor strain reservoir of P[25] genotype was Fig. 1 . Phylogenetic tree based on the complete CDS (981 bp) of the VP7 gene (G-genotypes). The Czech RVA strains described in this study are marked with a black dot (*). All other available RVA strains obtained from wild boars are marked with a black circle (). The tree was generated by the neighbor-joining method using MEGA version 6. Bootstrap values (1000 replicates) below 70% were hidden. The cut-off value of 80% is indicated with a dashed line. described and surprisingly it might be the wild boar population. Up to date, only eight RVA strains isolated from wild boars were genetically described so we cannot reason out how frequent separate RVA genotypes might be among wild boars and whether the proportional representation of genotypes is similar as in domestic pigs. Phylogenetic analysis of VP7 and VP4 genome segments of another RVA strain from our study (P211/2014) also clustered this wild boar RVA strain together with human RVA strains isolated in Hungary and Belgium (Zeller et al., 2012; Papp et al., 2013) . The whole genomic sequences of those human RVA strains were described and it was found that those human strains originated from porcine or porcine-human reassortment RVA strains. It is of interest, that all analysed wild boar RVA strains were found in the region of South Moravia, namely near the town of Brno (RVA strain P245/2014) and in the vicinity of the confluence of Morava and Thaya Rivers very close to the Czech and Slovakian borders (RVA strains P70/2015 (RVA strains P70/ , P211/2014 (RVA strains P70/ , P218/2015 . This area of the confluence is regularly flooded which forces increased migration of wildlife animals and it can also contribute to spreading of enteric viruses through contaminated water. The Morava River later joins the Danube River near Slovakian and Hungarian borders. At present, it is not possible to answer if the wild boar RVA strains which show close relationship to Hungarian human strains (P70/2015, P211/2014) are also circulating among wild boars in Hungary, as there is no relevant data available. Considering very low nucleotide sequences similarities of the Czech wild boar RVA strains we may presume that a large numbers of different RVA strains is currently circulating among wild boars.

Although PTVs, PSVs, and EV-Gs are generally considered to be nonpathogenic (causing asymptomatic infections in most cases), PTV-1 strains are causative agents of acute disease of swine called Teschovirus encephalomyelitis, which is characterised by central nervous system disorders. Some PTV serotypes were detected rarely in association with reproductive failure, diarrhoea, pneumonia, pericarditis, and myocarditis (Knowles, 2006) . PSVs were connected with clinical signs of diarrhoea, pneumonia, and reproductive disorders. EV-G was originally isolated from atypical skin lesions and the role of the virus as enteric pathogen causing diarrhoea was discussed (Knowles, 2006) . Infected pigs are an important source of PTV, PSV, or EV-G infection and contamination of water and environment since these viruses are easily transferred by faecal-oral route. The zoonotic potential of porcine enteric picornaviruses was not described so far but the transmission between domestic pigs and wild boars is highly probable (Prod elalová, 2012). One or more members of family Picornaviridae (PTV, PSV, and EV-G) were detected in 26.6% of wild boars tested in our study. PTV was the most prevalent of all detected viruses and was found in 20.2% of all samples. PSV was found less often (8.9% of Fig. 2 . Phylogenetic tree based on the partial CDS (839 bp) of the VP4 (VP8* region, nucleotide 16-854 of the Gottfried strain KR052749) gene (P-genotypes). The Czech RVA strains described in this study are marked with a black dot (*). All other available RVA strains obtained from wild boars are marked with a black circle (). The tree was generated by the neighbor-joining method using MEGA version 6. Bootstrap values (1000 replicates) below 70% were hidden. The cut-off value of 80% is indicated with a dashed line. all samples). Even higher prevalence of PTV was described in wild boars in Spain where 50.8% of tested samples were PTV-positive, while only 6.4% of samples contained PSV (Cano-Goméz et al., 2013) . Similarly high prevalence of porcine enteric picornaviruses was earlier shown in wild boars in the Czech Republic (Prod elalová, 2012), where 44.4% of tested samples were positive for PTV and 27.8% for PSV. EV-G was in the Czech Republic detected in 69.4% which is more than ten times higher prevalence than the number of EV-G-positive samples detected in this study. The reason might be that wild boars tested previously in the Czech Republic were animals kept in enclosure in four wild boar farms where there is a higher probability of virus transmission between animals. In the present study the animals tested were free-ranging wild boars culled during hunting season in at least 16 places located in four regions covering over 35 000 km 2 .

No members of family Coronaviridae were detected during our study. It is in agreement with serological surveys in wild boar population which were carried out in Slovenia, Finland, or in Canada and did not detect antibodies against TGEV (Vengust et al., 2006; Hälli et al., 2012; McGregor et al., 2015) . In Slovenian wild boars 3% of animals tested positive for anti-PRCV antibodies (Vengust et al., 2006) . The viral loads of PRCV in faeces would be very low (if present at all), so no PRCV was detected during our survey.

Antibodies against PRRSV were detected in wild boars in 12.8% of tested animals in Greece (Touloudi et al., 2015) . The Czech RVA strains described in this study are marked with a black dot (*). The tree was generated by the neighbor-joining method using MEGA version 6. Bootstrap values (1000 replicates) below 70% were hidden. The cut-off value of 85% is indicated with a dashed line.

The highest nucleotide (nt) identities of VP7, VP4 (VP8* region), and VP6 genes of the Czech RVA strains detected in wild boars and other available RVA sequences specified with the use of the p-distances method of MEGA version 6.

Gene segment studies carried out in Slovenia, Finland, and Canada did not find any anti-PRRSV antibodies (Vengust et al., 2006; Hälli et al., 2012; McGregor et al., 2015) . So far, the evidence of PRRS virus presence in wild boar was confirmed in Germany (Reiner et al., 2009) or recently in Slovakia . In those studies, tissues of lungs, tonsils or spleen were used for PRRSV detection, which are the places of virus replication. Our study did not confirm presence of PRRSV nucleic acid in wild boar faeces although the shedding of virus in faeces of domestic pigs was previously documented (Ramírez et al., 2008) .

In summary, our survey shows that RVA and RVC are circulating in the population of wild boar in the Czech Republic. To the best of our knowledge, this is the first time the prevalence of RVC was assessed in wild boars. RVA strains isolated from wild boars were genetically described and close relationship with human and domestic pig RVA strains was found so the transmission of RVA between wild boars and humans or between domestic pigs and humans and subsequently between domestic pigs and wild boars is highly probable. Furthermore, high prevalence of PTV in Czech wild boars was confirmed, PSV and EV-G were found less frequently. During our study no PRRSV or members of family Coronaviridae were detected. Our findings indicate that wild boars might contribute to the genetic variability of RVA and also serve as an important reservoir of other enteric viruses including RVC, PTV, PSV, and EV-G.

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This study was supported by grants from the Ministry of Agriculture of the Czech Republic numbers QJ1510108 and RO0516.

The authors declared no potential conflicts of interest with respect to the research, authorship, and/or publication of this article.