1. Introduction
The number of infectious diseases has been increasing in humans, with about 60% of those being zoonotic [1]. Of these emerging zoonoses, about 72% are transmitted from wildlife animals [2].
Wild boars are known to be reservoirs of a considerable number of zoonotic bacteria, viruses, and parasites [3], and these infections can be bi-directional (wild/domestic). The exposure to wild boars’ pathogens can happen through different pathways: Direct contact, meat consumption, or indirect intake of contaminated water, food, or through the environment [4]. Changes in human living habits, increased hunting activities, and consumption of wild boar meat play a role in the risk of human exposure to infectious agents [3].
Helicobacter species are Gram-negative, spiral-shaped motile bacteria that colonize the gastrointestinal tract of both humans and animals [5,6,7], and have been studied over the years for their association with gastrointestinal diseases [8]. In humans, Helicobacter pylori (H. pylori) is the most common gastric pathogen, affecting more than half of the world’s population, being responsible for development of gastritis, gastroduodenal ulcers, gastric adenocarcinoma, mucosa-associated lymphoid tissue (MALT) lymphoma, and extra digestive diseases [5,9,10]. In addition, Helicobacter suis (H. suis) is the most prevalent human gastric non-Helicobacter pylori Helicobacter (NHPH) and has been associated with a range of gastric pathologies, including MALT lymphoma, and possibly also extra digestive diseases. Recent reports reinforce that these infections most likely originate from pigs, emphasizing their zoonotic potential [5,11,12,13,14].
In pigs, H. suis mainly colonizes the fundic and pyloric gland zone of the stomach [15]. The bacterium presents tropism for the gastric acid-producing parietal cells [16]. Its prevalence appears to be very low prior to weaning, but increases rapidly thereafter, being very high at slaughter age (77%) and in adults (>90%) [15,16,17]. H. suis infection causes gastritis, decreased daily weight gain, and plays a role in induction of gastric ulcers, clearly affecting animal production and welfare [18,19,20].
In pigs, there is a report of a natural infection by a H. pylori-like bacterium, described as attached to the mucosa of the cardiac and antral portions of the stomach of two out of four healthy young pigs, without gross lesions associated [6,21]. This agent seemed to be morphologically similar to, but antigenically different from H. pylori, and its exact identity is not clear [18].
Until now, studies trying to assess the presence of H. suis in wild boars (Sus scrofa) have been mainly unsuccessful, as described by Flahou et al. [14] and others [22,23].
Helicobacter spp. have been described to have zoonotic potential and the close contact between humans, domestic animals, and wild animals deserves more consideration [14,24]. Although reservoirs of wild and domestic animals can be considered as important sources of emerging infectious diseases, it is the human impact on ecological systems that determines the level of risk at the human/animal interface upon the occurrence of emerging zoonotic diseases [14,24].
From an eco-epidemiological perspective, wild boars have an important role in spread of several pathogens [3,4]; thus, the aim of this study was to screen different regions of the stomach (Pars oesophagea, fundic, and pyloric gland zone) collected from wild boars for the presence of H. pylori and H. suis.
2. Materials and Methods
2.1. Samples Collection
Samples were collected using convenience sampling from fourteen hunted animals during two national campaigns, one in the north and other in the center of Portugal (Vila Real and Coimbra districts, respectively) (Figure 1). All the sampled animals were older than 9 months according to teeth assessment [25,26]. From each animal, gastric samples were collected from three different gastric regions: Pars oesophagea, fundic gland zone, and pyloric gland zone (gastric antrum) using a Kruuse® Biopsy punch 8 mm. After collection, samples were stored at −20 °C until DNA extraction.
The animals were not slaughtered or euthanized in order to carry out this study, and the fresh gastric tissue specimens were obtained as sub-products derived from the normal activity associated with the meat inspection procedures occurring during these conventional campaigns. None of the actions was performed solely for research purposes and the researchers had no influence on the campaign organization, nor in the meat inspection actions.
2.2. DNA Extraction, PCR Conditions and Sequencing
DNA was extracted from 8-mm gastric frozen tissue samples, using EXTRACTME® DNA tissue kit (BLIRT, Poland), according to the instructions provided by the supplier.
All the samples were tested for H. pylori and H. suis by conventional PCR, according to previously described protocols (Table 1).
Aliquots of each PCR product were electrophoresed on 1.5% agarose gel, stained with Xpert Green Safe DNA gel stain (GRISP, Porto, Portugal) and examined for the presence of a specific fragment under UV light. DNA fragment size was compared with the standard molecular weight, 100bp DNA ladder (GRISP, Porto, Portugal), and the molecular weight of the positive controls (H. pylori with 217 and H. suis with 150 bp) (Figure S1). As a negative control, distilled water was used. As positive controls, DNA was extracted from pure cultures of H. pylori strain 26695 and H. suis strain HS1.
To exclude false positive samples, the amplicons from each positive sample were sequenced. Bidirectional sequencing was performed with Sanger method at the genomics core facility of the Institute of Molecular Pathology and Immunology of the University of Porto, Portugal. Sequence editing and multiple alignments were performed with the MegaX Molecular Evolutionary Genetic Analysis version 10.1.8. The sequences obtained were subject to the basic local alignment search tool (BLAST) using the non-redundant nucleotide database (
3. Results and Discussion
A total of 42 samples, collected from 14 wild boars, were analyzed.
Based on PCR results, two samples corresponding to two distinct animals were H. pylori PCR-positive and another, also corresponding to a different animal, was H. suis PCR-positive. These positive samples all originated from the pyloric gland zone (gastric antrum) of these animals.
The bidirectional sequencing and BLAST analysis of consensus sequences of partial ureA and ureB genes showed a homology of 100% with H. pylori (GenBank® accession no. AF507994 and AY368264) for two of them and the other positive sample showed a homology of 95.39% with H. suis (GenBank® accession no. EF204592).
In the current study, H. pylori DNA was detected in the pyloric gland zone of the stomach (gastric antrum) from two animals and H. suis DNA in the same gastric region of another animal. This region is also a preferential colonization site of H. suis in domesticated pigs [17]. These findings might indicate that wild boars are occasionally colonized by H. pylori and H. suis. It can, however, not be excluded that presence of DNA of these microorganisms might be a consequence of recent contamination; for instance, through contact with domesticated pigs in the case of H. suis, or contaminated water or environments for both species. Both H. pylori PCR-positive cases did not present any macroscopic gastric alterations. The wild boar stomach where H. suis DNA was detected showed signs of mild antral inflammation consisting of mild erythema and congestion at gross examination. Unfortunately, the tissue preservation conditions prevented their detailed microscopic evaluation and the presence of microorganisms with Helicobacter-like morphology could not be examined. Further studies using a larger sample and including immunohistochemical and histopathological analysis of gastric tissue from wild boars are absolutely relevant to confirm our findings.
To the authors’ knowledge, this is the first report of H. pylori DNA detected in gastric samples of free-ranging wild boars and the first report of H. pylori and H. suis DNA detection in free-range wild boars in Portugal.
Previously, gastric antrum specimens of 17 free-ranging wild boars from Poland were tested, using a Helicobacter genus-specific 16S rRNA PCR and sequence analysis of positive samples [23]. In one sample, DNA was detected of a microorganism related to the group of NHPH mainly associated with dogs and cats (previously referred to as Helicobacter heilmannii type 2) [23]. More recently, a novel Helicobacter species, H. apri, was described in wild boars, but this is an enterohepatic Helicobacter species [22]. In another survey, very low numbers of H. suis were detected in the cardiac gland zone and Pars oesophagea from 2 out of 9 wild boars from Belgium. These gastric regions are not the preferential Helicobacter colonization sites in the porcine stomach, possibly indicating recent contamination for instance through contact with domesticated pigs or their excretes [14].
Wild boars are known to be reservoirs for several agents for important infectious diseases transmissible to other wild animals, domestic animals, and humans [3,4]. Depending on the pathogen properties and on wild boar density and management, the eco-epidemiological role of these animals can vary from a dead-end over spill over, up to maintenance host [3,4]. Contacts between wild boars and outdoor domestic pigs should be considered a risk for transmission of these pathogens that can directly affect the swine production and animal welfare, since wild boars and domestic pigs belong to the same species (Sus scrofa) [3,4,17,19,30].
Hunting dogs and humans can be exposed to wild boars’ pathogens either from fresh carcass contact, handling or consumption of raw, undercooked meat, or indirect contact from contaminated water or environment, and therefore, high risk exposure would include game wardens, hunters, butchers, and other wildlife professional duties [3,4]. Another aspect to consider is the increasing wild boar population and its adaptability to urban areas that can prompt wild boar contact with humans in these areas, making humans more vulnerable to be exposed to wild boars’ pathogens [3,4,31]. The current findings raise One health concerns regarding the impact of H. suis and H. pylori in wild boar welfare, its role and impact on bacterial spread and transmission to the environment, and also to wild and domestic animals, and, ultimately, to humans [3,13,24,31].
4. Conclusions
H. pylori and H. suis DNA was detected in the stomach of free-range wild boars, which might indicate that these animals were colonized by these microorganisms. It can be hypothesized that wild boars might act as reservoirs and contribute to the spread of the H. pylori and H. suis in the environment, raising a public health concern.
Supplementary Materials
The following are available online at
Author Contributions
Conceptualization, F.C.N., T.L.M., and I.A.; methodology, F.C.N., T.L.M., S.T., and I.A.; formal analysis, F.C.N., P.B., T.L.M., and I.A.; investigation, F.C.N.; resources, F.C.N., T.L.M., and I.A.; data curation, F.C.N., T.L.M., and I.A.; writing—original draft preparation, F.C.N., T.L.M., and I.A.; writing—review and editing, S.T., T.L.M., I.A., P.B., C.d.W., F.H., and F.G.; supervision, T.L.M., I.A., C.d.W., F.H., and F.G. All authors have read and agreed to the published version of the manuscript.
Funding
This research received no external funding.
Institutional Review Board Statement
Not applicable.
Data Availability Statement
The data presented in this study are available on request from the corresponding author
Acknowledgments
We thank Madalena Vieira-Pinto (University of Trás-dos-Montes e Alto Douro) and Carlos Venâncio (University of Trás dos-Monte e Alto Douro) for facilitating the sample collection during the hunting campaign. F.C. Nunes (SFRH/BD/147761/2019) and S. Teixeira (SFRH/BD/139669/2018) acknowledge the FCT—Portuguese Foundation for Science and Technology for financial support.
Conflicts of Interest
The authors declare no conflict of interest.
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Figure and Table
Enlarge this image.Figure 1. Illustration of the geographical origin of the samples collected in Portugal and evaluated in this study. Samples were collected from 10 wild boars during a national campaign in Vila Real (VR10) and 4 wild boars during a national campaign in Coimbra (C4).
Primer sequences used for detection of H. pylori and H. suis and thermo cycling conditions.
| Primer | Sequence | Region | Amplicon Size | Cycle | Ref. | ||
|---|---|---|---|---|---|---|---|
| Nr. Cycles | Temp. (°C) | Time | |||||
| BFHsuis_F1 | 5′-AAA ACA MAG GCG ATC GCC CTG TA-3′ | ureA gene | 150bp | 40 | 95 |
20 s |
[5] |
| BFHsuis_R1 | 5′-TTT CTT CGC CAG GTT CAA AGC G-3′ | ureA gene | |||||
| BFHpyl_F1 | 5′-AAA GAG CGT GGT TTT CAT GGC G-3′ | ureAB gene | 217bp | 45 | 94 |
30 s |
[27] |
| BFHpyl_ R1 | 5′-GGG TTT TAC CGC CAC CGA ATT TAA-3′ | ureAB gene | |||||
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Details
; Mateus, Teresa Letra 2
; Teixeira, Sílvia 1 ; Barradas, Patrícia 3 ; de Witte, Chloë 4
; Haesebrouck, Freddy 5
; Amorim, Irina 1
; Gärtner, Fátima 1
1 Institute of Biomedical Sciences Abel Salazar (ICBAS), University of Porto, 4050-313 Porto, Portugal;
2 CISAS—Centre for Research and Development in Agrifood Systems and Sustainability, Escola Superior Agrária, Instituto Politécnico de Viana do Castelo, 4900-347 Viana do Castelo, Portugal;
3 Epidemiology Research Unit (EPIUnit), Institute of Public Health, University of Porto, 4050-091 Porto, Portugal;
4 Department of Pharmaceutics, Faculty of Pharmaceutical Sciences, Ghent University, 9820 Merelbeke, Belgium;
5 Department of Pathology, Bacteriology and Avian Diseases, Faculty of Veterinary Medicine, Ghent University, 9820 Merelbeke, Belgium;