Spatial and Temporal Distribution of Mycobacterium tuberculosis Complex Infection in Eurasian Badger (Meles meles) and Cattle in Asturias, Spain
by
, , and
Cristina Blanco Vázquez
1, 
Thiago Doria Barral
2,
Beatriz Romero
3,
Manuel Queipo
4,
Isabel Merediz
5,
Pablo Quirós
6,
José Ángel Armenteros
6,
Ramón Juste
7,
Lucas Domínguez
3,8,
Mercedes Domínguez
9,
Rosa Casais
1 and
Ana Balseiro
10,11,* 1
Servicio Regional de Investigación y Desarrollo Agroalimentario del Principado de Asturias (SERIDA), 33300 Villaviciosa, Spain
2
Laboratório de Imunologia e Biologia Molecular, Instituto de Ciências da Saúde, Universidade Federal da Bahia, 40.110-100 Salvador, Bahia, Brazil
3
Centro de Vigilancia Sanitaria Veterinaria VISAVET, Universidad Complutense, 28040 Madrid, Spain
4
Servicio de Sanidad y Producción Animal del Principado de Asturias, 33007 Oviedo, Asturias, Spain
5
Laboratorio Regional de Sanidad Animal del Principado de Asturias, 33201 Gijón, Asturias, Spain
6
Dirección General del Medio Natural y Planificación Rural del Principado de Asturias, 33007 Oviedo, Asturias, Spain
7
Animal Health Department, NEIKER-Instituto Vasco de Investigación y Desarrollo Agrario, 48160 Derio, Bizkaia, Spain
8
Departamento de Sanidad Animal, Facultad de Veterinaria, Universidad Complutense, 28040 Madrid, Spain
9
Unidad de Inmunología Microbiana, Centro Nacional de Microbiología, Instituto de Salud Carlos III, 28029 Madrid, Spain
10
Departamento de Sanidad Animal, Facultad de Veterinaria, Universidad de León, 24071 León, Spain
11
Departamento de Sanidad Animal, Instituto de Ganadería de Montaña (CSIC-Universidad de León), Finca Marzanas, Grulleros, 24346 León, Spain
*
Author to whom correspondence should be addressed.
Animals 2021, 11(5), 1294; https://doi.org/10.3390/ani11051294
Submission received: 1 March 2021
/
Revised: 26 April 2021
/
Accepted: 28 April 2021
/
Published: 30 April 2021
(This article belongs to the Special Issue Zoonoses and Wildlife: One Health Approach)
Abstract
:Simple Summary
The aim of the present work was to investigate the prevalence, spatial distribution, and temporal distribution of tuberculosis in 673 free-ranging Eurasian badgers (Meles meles) and cattle from Asturias (Atlantic Spain) during a 13-year follow-up. The study objective was to assess the role of badgers as a reservoir of tuberculosis for cattle and other sympatric wild species in the region. During the follow-up, 27/639 badgers (4.23%) were positive for the Mycobacterium tuberculosis complex based on bacterial isolation, while 160/673 (23.77%) were positive based on P22 ELISA. Badger infection was spatially and temporally associated with cattle herd infection.
Abstract
The present work investigated the prevalence, spatial distribution, and temporal distribution of tuberculosis (TB) in free-ranging Eurasian badgers (Meles meles) and cattle in Asturias (Atlantic Spain) during a 13-year follow-up. The study objective was to assess the role of badgers as a TB reservoir for cattle and other sympatric wild species in the region. Between 2008 and 2020, 673 badgers (98 trapped and 575 killed in road traffic accidents) in Asturias were necropsied, and their tissue samples were cultured for the Mycobacterium tuberculosis complex (MTC) isolation. Serum samples were tested in an in-house indirect P22 ELISA to detect antibodies against the MTC. In parallel, data on MTC isolation and single intradermal tuberculin test results were extracted for cattle that were tested and culled as part of the Spanish National Program for the Eradication of Bovine TB. A total of 27/639 badgers (4.23%) were positive for MTC based on bacterial isolation, while 160/673 badgers (23.77%) were found to be positive with the P22 ELISA. The rate of seropositivity was higher among adult badgers than subadults. Badger TB status was spatially and temporally associated with cattle TB status. Our results cannot determine the direction of possible interspecies transmission, but they are consistent with the idea that the two hosts may exert infection pressure on each other. This study highlights the importance of the wildlife monitoring of infection and disease during epidemiological interventions in order to optimize outcomes.
1. Introduction
Animal tuberculosis (TB) is caused by infection with members of the Mycobacterium tuberculosis complex (MTC), mainly M. bovis and, to a lesser extent, M. caprae. TB is a zoonotic disease that subjects livestock worldwide and can cause substantial economic losses [1]. Its main domestic reservoir is cattle, and eradication campaigns spanning more than four decades in developed countries including Spain have been quite but not totally successful [2]. Wildlife hosts are also susceptible to M. bovis and can act as reservoirs of the infection for livestock. Badgers (Meles meles) and wild boars (Sus scrofa) are major wildlife reservoirs of M. bovis for bovine TB in several European countries. M. bovis-infected badgers have been found in Ireland [3], the United Kingdom (UK) [4], France [5,6], and Spain [7,8]; in Ireland and the UK, badgers are recognized as major reservoirs with the potential to transmit infection to local cattle herds [9,10]. Infection in wild boars has been described in France and Italy, as well as the southern and central Iberian Peninsula [5,11].
In Spain, the southern and central regions, which have a Mediterranean climate, show a TB cattle herd-prevalence as high as 12.3%, while the northwestern region with an Atlantic climate shows an overall prevalence of 0.02–0.08% but with hotspots where prevalence can be as high as 5% [2,12]. This variability may reflect several factors. One is climate: drier, hotter areas in the south favor animal aggregation and therefore disease spread [13]. Another factor is type of cattle: dairy herds, in which TB prevalence is lower, concentrate in the north, while beef and bullfighting cattle are more abundant in the central and southern regions [13]. A third factor is cattle management: beef and bullfighting cattle herds are extensively managed with a lower biosecurity and are therefore at higher risk of infection due to contact with animals in other herds, as well as with other potentially infected domestic (goat/sheep) or wildlife species [14,15,16].
Recent studies have suggested that badgers may be a reservoir of M. bovis infection in hotspots in Atlantic Spain, as reported in Ireland and the UK [12,17]. In addition, wild boar, red deer (Cervus elaphus), and, to a lesser extent, fallow deer (Dama dama) are major wildlife reservoirs in continental Mediterranean habitats, where wild boars can show a TB prevalence of >50% [14]. In contrast, wild boars in Atlantic habitats show a TB prevalence of around only 5% [16]. Mid- and long-term studies of wildlife reservoirs such as badgers and wild boar can shed light on the spatial and temporal dynamics of TB, as well as on risk to local livestock [14,18,19].
Along these lines, the present work investigated the prevalence, spatial distribution, and temporal distribution of TB in free-ranging Eurasian badgers and cattle from Asturias (Atlantic Spain) during a 13-year follow-up. The study objective was to assess the potential role of badgers as a TB reservoir for cattle and other sympatric wild species such as wild boar in the region.
2. Materials and Methods
2.1. Ethics Statement
All methods were carried out in accordance with relevant guidelines and regulations. All experimental procedures with trapped badgers were approved by the Government of the Principality of Asturias (010/07-01-2011, PROAE 20/2015, PROAE 47/2018).
2.2. Study Area
The study was carried out in the region of Asturias in northwestern Spain. This region has an Atlantic climate, and the temperature ranges from −4 to 8 °C in the coldest months; precipitation is abundant throughout the year, annually reaching 1400–2100 mm [20]. More than 30% of the territory is forest and mainly comprises oaks, beech, and birch woods. Asturias is bordered to the north by the Cantabrian Sea and to the south by the Cantabrian Range. Nowadays, the cattle population is 391,797 animals and 15,856 herds, and the well-studied badger population shows intermediate density of 3.81 adults/km2 [21].
2.3. Description of TB Detection in Badgers and Cattle in Asturias, 2008–2020
2.3.1. Badgers
From 2008 to 2020, 673 badgers from Asturias were necropsied (see Supplementary Material 1: Raw Data); these animals came from western (n = 77), central (n = 220), and eastern (n = 376) parts of Asturias. Of the 673 animals, 98 were trapped badgers that had been captured from setts located close to TB cattle herds and subsequently euthanized; these 98 animals came nearly equally from the three areas. Badgers were captured in steel mesh box traps baited with peanuts and anesthetized with ketamine hydrochloride (0.1 mL kg−1), medetomidine (Domtor®, Ecuphar Veterinaria, Barcelona, Spain; 0.05 mL kg−1), and butorphanol (Torbugesic®, Zoetis, Madrid, Spain; 0.1 mL kg−1) administered by means of intramuscular injection. Serum samples (2 mL) were taken from anesthetized trapped badgers by jugular venipuncture and collected in serum separation vacutainer tubes. Afterwards, badgers were euthanized with an overdose of sodium pentobarbital for post-mortem examination. The other 575 were killed in road traffic accidents and found by gamekeepers in the region. Serum samples (2 mL) from badgers killed in road traffic accidents were taken from the heart or thoracic cavity and collected in vacutainer tubes.
The location, sex, age class (subadult/adult), and weight were recorded for trapped and road-killed badgers. The entire group contained 301 males and 322 females, comprising 163 subadults and 460 adults based on body size and teeth. Sex and age class were undetermined for 50 individuals killed in road traffic accidents because of insufficient tissue availability. The numbers of animals analyzed per year were as follows: 2008: 21; 2009: 37; 2010: 68; 2011: 45; 2012: 20; 2013: 23; 2014: 43; 2015: 22; 2016: 92; 2017: 57; 2018: 63; 2019: 102; and 2020: 80. Trapping was not carried out in 2012–2015, 2017, or 2020, so all badgers studied in those years were killed in road traffic accidents. Badgers were preserved at 4 °C, and a complete post-mortem examination of each carcass was conducted at the laboratory in less than 24 h.
2.3.1.1. Pathology
Serial sections (0.2 cm) were taken from the lungs and lymph nodes (LNs) of the 673 badgers submitted for necropsy for further macroscopic observation. Gross visible lesions found during necropsy were recorded. Tissue samples from the lungs and retropharyngeal, submandibular, tracheobronchial, mediastinal, hepatic, and mesenteric LNs were further analyzed by histopathology from the nine animals that showed gross lesions. Samples for histopathology were fixed in 10% neutral buffered formalin and processed using standard methods. Sections were cut to a thickness of 4 µm and stained with hematoxylin and eosin and by the Ziehl–Neelsen method for the detection of acid-fast bacteria.
2.3.1.2. Bacteriology and Typing
Bacteriological and molecular studies were performed in 639 out of the 673 badgers (the remaining 34 animals were excluded due to insufficient tissue availability to make the pools). Pools (2 g) of lungs and mandibular, retropharyngeal, tracheobronchial, mediastinal, hepatic, and mesenteric LNs were frozen at −20 °C for no longer than two weeks and subsequently used to isolate potential bacteria as described previously [12]. Members of the MTC or the Mycobacterium avium complex (MAC) were isolated using the Mycobacteria Growth Indicator Tube (MGIT) liquid medium system, the Löwenstein–Jensen solid medium with sodium pyruvate, and Coletsos solid media. The samples were decontaminated using the BBL MycoPrep Becton Dickinson kit (BD Diagnostic Systems, Franklin Lakes, NJ, USA) and then incubated at 37 °C in an MGIT liquid medium for at least 6 weeks using the automated BACTEC MGIT 960 (BD Diagnostic Systems). Solid cultures were incubated at 37 °C for at least 10 weeks.
Quantitative PCR to identify MTC species was performed on culture isolates using the MTC forward primer 5′-TAGTGCATGCACCGAATTAGAACGT-3′, the MTC reverse primer 5′-CGAGTAGGTCATGGCTCCTCC-3′, and the TaqMan probe YY/BHQ 5′-AATCGCGTCGCCGGGAGC-3′, which amplifies a 184-bp fragment [22,23,24]. MTC isolates were characterized using DVR-spoligotyping after hybridizing biotin-labeled PCR products onto a home-made spoligotyping membrane (VISAVET, Madrid, Spain). Results were recorded in SB code followed by a field of four digits according to the M. bovis Spoligotype Database [23,24]. In order to confirm similarity between the isolates from cattle and badgers in the same area, MIRU-VNTR typing was performed as described previously [23] using the following nine VNTR markers: ETR-A, ETR-B, ETR-D, ETR-E, MIRU26, QUB11a, QUB11b, QUB26, and QUB3232. A badger was classified as positive if MTC was isolated. MAC isolates were identified as described previously [25].
2.3.1.3. Serology (P22 ELISA Assay)
Serum samples from the 673 badgers were frozen at −20 °C before processing and tested using a previous validated in-house indirect P22 ELISA to detect antibodies against the MTC in badgers [26].
Briefly, plates were coated overnight with P22 in phosphate-buffered saline (PBS) at 4 °C and then blocked with PBS containing 5% powdered skim milk. After three washes with PBS containing 0.05% Tween-20, sera (diluted 1:100 in PBS-powdered skim milk) were added to duplicate wells and incubated for 60 min at 37 °C. Horseradish peroxidase-conjugated anti-badger CF2/HRPo IgG (100 μL) [26] was diluted to 1.5 µg/mL in PBS and added to the plates. Then plates were incubated at room temperature for 15 min in the dark with 3,3′,5,5′-tetramethylbenzidine substrate (Perbio Science, Helsingborg, Sweden). The reaction was stopped by adding 100 μL of 2 M H2SO4. Optical density (OD) was measured at 450 nm using an ELISA reader. As a negative control, serum from a TB-free Spanish badger was included in quadruplicate in every plate. As a positive control, serum from a Spanish badger experimentally infected with M. bovis was included in every plate. OD readings were expressed as an ELISA percentage (E%): E% = (mean OD/(2 × mean ODnegative control)) × 100%. The cut-off was specifically defined for this study, since the previous P22 ELISA study in badgers suggested that the optimal cut-off (initially established between 100% and 150%) may depend on the epidemiological situation [26]. Indeed, when we applied the three cut-offs tested in that study (100%, 120%, and 150%), we found that sensitivity and specificity were too close to a random (50%) diagnostic value. Instead, we found that a cut-off of 260% gave 55.6% sensitivity and 80.4% specificity, corresponding to a moderate diagnostic value of 68% (Figure 1). In order to define the 260% cut-off, data sera from positive and negative animals (trapped and road-killed badgers) to bacteriological culture (MTC or MAC) were included.
2.3.2. Cattle
Single intradermal tuberculin test data and bacterial isolation were available for cattle that were tested and culled as part of the Spanish National Program for the Eradication of Bovine TB until 2019 [2]. A total of 17,474 herds were studied, of which 4762 belonged to the western area, 8281 belonged to the center area, and 4431 belonged to the eastern area.
2.4. Statistical Analysis
An overall descriptive analysis of absolute frequencies was performed based of tables and chi squared tests with the SAS (Cary, NC, USA) Freq procedure. Differences in MTC isolation, P22 ELISA E% value, and positive frequency in badgers stratified by area, sex, age class, origin, or time were tested using a generalized linear model (GLM) in SAS with Tukey or Tukey–Kramer’s t (T or TK t) test for main effects level means comparisons. Differences with a p < 0.05 were considered significant. Potential associations between P22 ELISA values and TB prevalence in cattle during follow-up were tested using a Pearson correlation analysis with the SAS CORR procedure. Another GLM model was built to assess a potential association between the ability to isolate MTC or MAC from samples and the sample’s P22 ELISA E%.
3. Results
3.1. Badgers
3.1.1. Gross and Microscopic Lesions
Gross lesions were observed in nine badgers from the eastern area, eight of which had been trapped and one of which had been killed in a road traffic accident. Lesions consisted of granulomatous areas of caseous necrosis and mineralization with diameters from 1 mm to 1 cm in submandibular, retropharyngeal, bronchial, or mediastinal LNs and lungs. Such lesions were also found in mesenteric LNs in two animals and in hepatic LNs in three animals. TB-like lesions were confirmed using histology, which revealed scarce, small granulomas with areas of central necrosis or mineralization. Ziehl–Neelsen staining revealed sparse acid-fast bacteria.
3.1.2. Bacteriological Isolation and Typing
Of the 639 badgers, 27 (4.23%) were positive for MTC, and the distribution of positives across the years was as follows (Figure 2): 2008: 2; 2009: 3; 2010: 4; 2011: 5; 2012: 1; 2016: 1; 2018: 10; and 2019: 1. Isolates were identified as spoligotype SB0828 with VNTR profile 5-5-3-4-5-9-3-3-6 (n = 7), spoligotype SB0121 with VNTR profile 5-4-3-3-5-F-2-5-8 (n = 3), spoligotype SB0120 (n = 2), spoligotype SB01019 (n = 2), spoligotype SB1312 (n = 1), and spoligotype SB0329 (n = 1). Spoligotypes SB0828 and SB0121 identified in badgers were also isolated from cattle in the same areas (Figure 2) [24]. Spoligotype SB0828 with VNTR profile 5-5-3-4-5-9-3-3-6 was also identified in cattle, but spoligotype SB0121 in badgers (VNTR profile 5-4-3-3-5-F-2-5-8) was different, albeit related to that in cattle (VNTR profile 4-4-3-3-5-10-2-5-8). SB1019 was identified in badgers and cattle but in populations from different geographical areas (Figure 3). Neither spoligotype nor VNTR profiles could be determined from other badgers because of insufficient DNA.
The rates of MTC positivity were 13.27% (13/98) among trapped badgers and 2.59% (14/541) (chi square = 23.37; p < 0.0001) among those killed in road traffic accidents (Figure 4, Supplementary Material 2: Trapped and RTA Badgers). The rate of positivity non-significantly varied with geographic region: 5 of 75 badgers (6.67%) from the western region were positive, compared to 4 of 209 (1.91%) from the central area and 18 of 355 (5.07%) from the eastern area. The rate of positivity was 3.81% (11/289) among males and 5.05% (16/317) among females. It was 4.40% (7/159) among subadults and 4.47% (20/447) among adults. Badgers with undetermined sex or age were all negative. No significant differences were found between areas (F = 1.78; p = 0.1695), sex (F = 1.12; p = 0.2898), or age class (F = 0.23; p = 0.6300) regarding MTC isolation. The only significant effects on isolation were year (F = 2.94; p = 0.0005) and origin (F = 6.01; p = 0.0145). We found significant differences in the P22 ELISA results between positive and negative animals in the bacteriological analyses (p < 0.0001).
Of the 639 badgers, 28 (4.38%) were positive for MAC (Figure 5a): Mycobacterium avium avium (Maa, n = 14), Mycobacterium avium hominissuis (Mah, n = 8), or both (n = 1). Three animals positive for Maa were also positive by M. bovis isolation, and the spoligotypes were identified as SB0120 in two animals and SB0828 in the other. MAC isolates from five badgers could not be typed because of insufficient DNA. No differences were observed between the years 2008 and 2020 (4.76%, 5.56%, 8.82%, 4.45%, 0.00%, 0.00%, 4.65%, 4.55%, 2.17%, 0.00%, 5.56%, 4.12%, and 7.94%) (chi square = 11.70; p = 0.4699), origins (2.04% and 4.81% for trapped and road-killed, respectively) (chi square = 0.80; p = 0.3700), areas (2.67%, 5.74%, and 3.94% for western, central, and eastern, respectively) (chi square = 1.71; p = 0.4242), sex (3.46% and 5.68% for males and females, respectively) (chi square = 5.05; p = 0.0799), and age class (5.03% and 4.47% for subadults and adults, respectively) (chi square = 1.91; p = 0.3848). Badgers with undetermined sex or age class were all negative.
3.1.3. Serological Assay (P22 ELISA)
A total of 160 badgers (23.77%) were positive in the P22 ELISA, and the distribution of positives by year was as follows (Figure 2): 2008: 9 (42.86%); 2009: 10 (27.03%); 2010: 5 (7.35%); 2011: 17 (37.78%); 2012: 4 (20.00%); 2013: 6 (26.09%); 2014: 11 (25.58%); 2015: 1 (4.55%); 2016: 15 (16.30%); 2017: 18 (31.58%); 2018: 30 (47.62%); 2019: 19 (18.63%); and 2020: 15 (18.75%). The rates of positivity based on P22 ELISA were 42.86% (42/98) among trapped badgers and 20.52% (118/575) among those killed in road traffic accidents.
The rate of seropositivity varied with geographic region as follows (Figure 5b): 17 of 77 badgers (22.08%) from the western region, 39 of 220 (17.73%) from the central area, and 104 of 376 (27.66%) from the eastern area were positive. The rate of seropositivity was 23.92% (72/301) among males, 22.05% (71/322) among females, and 34.00% (17/50) among animals whose sex was undetermined (Figure 5c). The rate of seropositivity was 17.79% (29/163) among subadults, 24.78% (114/460) among adults, and 34.00% (17/50) among badgers of underdetermined age class (Figure 5d).
Seropositivity significantly varied with year (F = 3.36; p < 0.0001), although a clear trend across years did not emerge. Seropositivity rates did not significantly differ (F = 1.93; p = 0.1465) between areas, although the frequency was slightly higher in the eastern area (37.04%) than in the central (30.94%) and western (29.44%) areas. However, mean E% did significantly differ according to geographical area (F = 3.91; p = 0.0204), with the eastern area (E% = 273.55) being higher than the western area (E% = 214.53; TK t = 2.73; p = 0.0179) but not than the central area (E% = 254.41; TK t = 1.31; p = 0.3881). The GLM identified origin (trapped or road-killed badgers) as the most influential factor on seropositivity (F = 15.86; p < 0.0001), with trapped animals being more positive (42.36%) than the road-killed ones (22.58%). Neither sex (F = 0.35; p = 0.5515) nor age class (F = 0.85; p = 0.3568) showed significant differences between categories (Figure 5d). Mean E% values were higher for badgers from which MTC was isolated (367.34) than for badgers from which MAC was isolated (162.35, TK t = 4.37; p < 0.0001) and badgers from which neither MTC nor MAC was isolated (204.91, TK t = 4.63; p < 0.0001). In turn, the mean E% values of culture-negative animals (neither MTC nor MAC was isolated) were higher (204.91) than those of MAC-positive animals (162.35), although they were non-significantly different (TK t = 1.30; p = 0.6884).
3.2. Cattle
During the study period, 362 cattle herds (2.07%) were positive for TB [2]: 84 (1.76%) were from the western area, 144 (1.74%) were from the central area, and 134 (3.04%) were from the eastern region. Prevalence remained below 1% throughout the period of study (Figure 2). The shared M. bovis spoligotypes identified in cattle and badgers from 2008 to 2020 in Asturias are shown in Figure 3.
The prevalence of TB in cattle tended to negatively correlate with mean E% in the P22 ELISA in badgers, but the correlation was not significant (Pearson r; p = 0.489). In addition, the tendency inverted over time: it was positive between 2008 and 2010 and between 2012 to 2014, but it was negative for the rest of the period (Figure 6).
4. Discussion
This study examined the prevalence of TB in free-ranging Eurasian badgers in Spain for a 13-year period, which was longer than a previous seven-year study [12]. One study in England examined TB prevalence in badgers over 24 years [19], but only trapped animals were analyzed. In the present study, trapped animals and those killed in road traffic accidents were examined, with 4.23% badgers positive for MTC based on isolation and 23.77% badgers positive based on P22 ELISA. Such studies are essential for understanding pathogen transmission between species, particularly in endemic areas or hotspots, since such transmission can vary strongly from location to location [27].
P22 ELISA has provided high levels of sensitivity in previous studies in badgers [26]. Other available serological tests for diagnosing TB in badgers [28], e.g., the DPP Vet TB, the BrockTB STAT-PAK, and the chemiluminescent multiplex ELISA system have shown low-to-moderate sensitivity (from 30.77% to 58%) in naturally infected badgers [29,30,31,32,33]. P22 is mainly composed of MPB70 and MPB83, but there are other proteins shared with MAC or other non-tuberculous mycobacteria with a high sequence similarity to MPB70 and MPB83 [34]; that is why the cut-off is advisable to specifically define for each epidemiological situation [26]. We considered the cut-off of 260% adequate for the present study in order to avoid misclassification in an epidemiological context where MAC isolates were frequent. We found a big difference in TB prevalence using bacteriology or serology (4.32 vs. 23.77, respectively). The isolation of MTC has been considered as the gold standard method for the diagnosis of TB in wildlife [28], but sensitivity can be variable due to the lack of the active shedding of the microorganism from infected animals—hence the absence of mycobacteria in collected samples or when the number of viable microorganisms is low [35].
We detected TB-positive badgers in all parts of Asturias using both techniques, suggesting the widespread distribution of infection, mainly in trapped badgers from areas close to TB-positive farms. Our results were consistent with the idea that badgers are good hosts for TB; for example, TB-infected badgers living more than 1 km away from culled setts were detected even five years after the most recent outbreak in local cattle [36]. Indeed, TB transmission within badger subpopulations has been observed [37]. Given the widespread geographic distribution of positive badgers in our study, we suspect that badgers in Asturias have been infected on several occasions at different locations. We cannot exclude the possibility of transmission from cattle to badgers since both species shared the same or similar M. bovis genotypes, although this transmission is more likely when cattle have advanced disease [37] and such animals should be rare due to annual testing of all cattle in Asturias. Nevertheless, we observed a trend toward higher numbers of TB infections in cattle and badgers in the eastern part of the region, which supports the idea of cattle-to-badger transmission. This trend undoubtedly also reflects that most TB hotspots in Asturias lie in the eastern part, where several outbreaks of TB in cattle and badgers have been described, suggesting interspecies transmission and a high environmental contamination [12]. The presence of such hotspots may help explain why TB prevalence among trapped badgers in our study was more than two times the prevalence in road-killed badgers based on serology and more than four times the prevalence based on MTC isolation—trapped animals were captured in areas under active surveillance because of recent and ongoing outbreaks in cattle. Indeed, eight of the nine animals that showed gross lesions and whose infection was further confirmed by histopathology had been trapped. At the same time, we cannot exclude that at least some of the large difference in TB prevalence between the two groups of animals reflected the greater sensitivity of MTC detection in serum and tissue samples from trapped animals given that the quality of those samples may have been higher than the quality of samples from animals killed in road traffic accidents due to better preservation.
In a total geographical context, while TB prevalence among cattle herds has decreased in Asturias in recent years (reflecting the success of the official national eradication campaigns), TB prevalence among badgers has slightly increased. The increase in prevalence among badgers correlated with an increase in prevalence among cattle from 2008 to 2010 but with a decrease in prevalence among cattle from 2011 to 2019. This correlation was weaker regarding badger prevalence, as measured either by isolation or by P22 ELISA. Nevertheless, the number of positive badgers might have increased from 2016 to 2019 due to outbreaks in cattle, which itself was likely due to environmental contamination and indirect interspecies transmission [12]. This illustrates how badgers might likely transmit TB back to cattle in the future, highlighting the importance of understanding badger ecology for monitoring and controlling TB risk in cattle [12].
In our study, male badgers were marginally but not significantly more likely than female badgers to test positive for TB, which was different to studies in UK [38,39]. A study of 94 badgers killed in road traffic accidents in the UK found no sex difference in TB prevalence [40]. Studies have suggested that male badgers may transmit M. bovis to one another through biting during aggressive behavior [27,41]. We did not observe bite wounds in the present study, but this possibility should be explored in future work.
Adult badgers in our sample were more likely, although not significantly, to test seropositive than subadults. In our study, adult animals also showed higher E% in the P22 ELISA than subadults, probably reflecting the longer time available for animals to come into contact with M. bovis. The rates of MTC isolation did not significantly vary with badger age class, consistent with other studies in Europe [36,40]. Badgers in our study from which neither MAC nor MTC was isolated gave slightly higher E% in the P22 ELISA than badgers from which MAC was isolated, supporting the specificity of the assay. Our observation of intermediate E% for badgers from which neither MAC nor MTC was isolated suggests that some of these cases may have been false negatives because an immune response was apparent.
Of the 612 badgers that were TB-negative based on culture, 133 were seropositive based on the P22 ELISA, which means that the ELISA had a complementary sensitivity of 492.59% with respect to bacteriological isolation. Thus, taking the positives to either isolation or ELISA as reference, ELISA sensitivity was 84.57% compared to 15.43% for isolation. The sensitivity of culture tests might have been low because of poor sample condition, the technical limitations of the microbiological procedure, and the clinical stage of the badgers. In fact, only nine animals (a third of MTC-positive badgers) showed gross lesions, implying that most animals might have been in an early stage of infection or be MTC subclinical carriers, when MTC isolation is less sensitive [8,37]. Those early or latent stages, with infection confirmed by either immunology or bacteriological culture but with an absence of detectable pathology, are usual in badgers and have less risk of shedding greater numbers of mycobacteria than badgers in the late stages of disease [37]. We cannot exclude that other members of the MTC were present but not recovered by culture and cross-react in P22 ELISA, i.e., Mycobacterium microti infections have been reported in both wildlife [42,43] and domestic animals [44,45] in France, although the direct detection of that species on tissue samples was not included in this study. On the other hand, the relative specificity of each method with respect to the other remained much higher for isolation (97.45% vs. 78.27% for culture and P22 ELISA, respectively). In this regard, bacterial isolation remains the gold standard for the diagnosis of TB despite of methodological issues such as moderate sensitivity and long incubation times. Nevertheless, our results highlighted the P22 ELISA as a useful screening tool that is faster and more cost-effective and sensitive in the early or latent stages of disease than isolation for TB detection. Similarly, direct qPCR on tissue samples is also considered to be a sensitive and valuable alternative to culture that is faster than bacterial isolation [46]. Though qPCR can also detect non-viable mycobacteria, both techniques (P22 ELISA and qPCR) might be used in parallel in order to increase sensitivity and specificity of TB diagnosis in badgers.
5. Conclusions
We found that the TB status of badgers in Asturias during 2008–2020 was associated with the TB status of local cattle herds. Our results could not determine the direction of possible interspecies transmission, but they were consistent with the idea that the two hosts may exert infection pressure on each other. Adult badgers were more likely to be TB-positive than subadults. This study highlights the importance of monitoring this multi-host infection and disease in wildlife during epidemiological interventions in order to optimize outcomes under the One Health concept.
Supplementary Materials
The following are available online at https://www.mdpi.com/article/10.3390/ani11051294/s1, Supplementary Material 1: Raw Data; Supplementary Material 2: Trapped and RTA Badgers.
Author Contributions
Conceptualization, A.B.; methodology, C.B.V., T.D.B., B.R., M.Q., I.M., P.Q., J.Á.A., R.J., L.D., M.D. and A.B.; validation, A.B. and R.J.; formal analysis, C.B.V., T.D.B. and A.B.; investigation, C.B.V., T.D.B., B.R., M.Q., I.M., P.Q., J.Á.A., L.D., M.D., R.C. and A.B.; resources, A.B.; data curation, C.B.V., T.D.B., R.J. and A.B.; writing—original draft preparation, C.B.V., T.D.B. and A.B.; writing—review and editing, C.B.V., T.D.B., B.R., M.Q., I.M., P.Q., J.Á.A., R.J., L.D., M.D., R.C. and A.B. All authors have read and agreed to the published version of the manuscript.
Funding
This work was funded by the Ministerio de Ciencia, Innovación y Universidades (MCIU), the Agencia Estatal de Investigación (AEI) reference project RTI2018-096010-B-C21 (FEDER co-funded), PCTI 2018–2020 (GRUPIN: IDI2018-000237), and FEDER and Ministerio de Agricultura, Pesca y Alimentación. C.B.V. was supported by a grant from the Instituto Nacional de Investigación y Tecnología Agraria y Alimentaria (INIA), Spain. Publication costs were covered with funds from RTI2018-096010-B-C21 (FEDER co-funded). T.D.B. was supported by a fellowship from the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES; process number 88887.511077/2020-00).
Institutional Review Board Statement
The study was conducted according to the European Ethical guidelines for the experimental procedures with trapped badgers. They were approved by the Government of the Principality of Asturias Ethics Committee (reference numbers: 010/07-01-2011, PROAE 20/2015, PROAE 47/2018).
Data Availability Statement
The data published in this study are available in Supplementary Material 1: Raw Data and Supplementary Material 2: Trapped and RTA Badgers.
Acknowledgments
The authors acknowledge invaluable support from their colleagues at SERIDA (Miguel Prieto and Alberto Espí), the University of León, the Servicio de Espacios Protegidos y Conservación de la Naturaleza, the Dirección General del Medio Natural y Planificación Rural del Principado de Asturias, the Servicio de Sanidad y Producción Animal del Principado de Asturias, the Regional Animal Health Laboratory of Principado de Asturias, VISAVET and Instituto de Salud Carlos III. We thank A. Chapin Rodríguez (Creaducate Consulting GmbH) for critically reviewing the manuscript.
Conflicts of Interest
The authors declare no conflict of interest.
References
- Olea-Popelka, F.J.; Muwonge, A.; Perera, A.; Dean, A.S.; Mumford, E.; Erlacher-Vindel, E.; Forcella, S.; Silk, B.J.; Ditiu, L.; El Idrissi, A.; et al. Zoonotic tuberculosis in humans begins caused by Mycobacterium bovis- a call for action. Lancet Infect. Dis. 2017, 1, e21–e25. [Google Scholar] [CrossRef] [Green Version]
- MAPA. 2020. Available online: https://www.mapa.gob.es/es/ganaderia/temas/sanidad-animal-higiene-ganadera/pnetb_2020final_tcm30-523317.PDF (accessed on 8 January 2021).
- Olea-Popelka, F.J.; Costello, E.; White, P.; McGrath, G.; Collins, J.D.; O’Keeffe, J.; Felton, D.F.; Berke, O.; More, S.; Martin, S.W. Risk factors for disclosureof additional tuberculous cattle in attested-clear herds that had one animal with a confirmed lesion of tuberculosis at slaughter during 2003 in Ireland. Prev. Vet. Med. 2008, 85, 81–91. [Google Scholar] [CrossRef]
- Delahay, R.J.; Smith, G.C.; Barlow, A.M.; Walker, N.; Harris, A.; Clifton-Hadley, R.S.; Cheeseman, C.L. Bovine tuberculosis infection in wild mammals in the South-West region of England: A survey of prevalence and a semi-quantitative assessment of the relative risks to cattle. Vet. J. 2007, 173, 287–301. [Google Scholar] [CrossRef]
- Zanella, G.; Duvauchelle, A.; Hars, J.; Moutou, F.; Boschiroli, M.L.; Durand, B. Patterns of lesions of bovine tuberculosis in wild red deer and wild boar. Vet. Rec. 2008, 163, 43–47. [Google Scholar] [CrossRef]
- Payne, A.; Philipon, S.; Hars, J.; Dufour, B.; Gilot-Fromont, E. Wildlife Interactions on baited places and waterholes in a French area Infected by bovine tuberculosis. Front. Vet. Sci. 2017, 3, 122. [Google Scholar] [CrossRef] [Green Version]
- Sobrino, R.; Martín-Hernando, M.P.; Vicente, J.; Aurtenetxe, O.; Garrido, J.M.; Gortázar, C. Bovine tuberculosis in a badger (Meles meles) in Spain. Vet. Rec. 2008, 163, 159–160. [Google Scholar] [CrossRef]
- Balseiro, A.; Rodríguez, O.; González-Quirós, P.; Merediz, I.; Sevilla, I.A.; Davé, D.; Dalley, D.J.; Lesellier, S.; Chambers, M.A.; Bezos, J. Infection of Eurasian badgers (Meles meles) with Mycobacterium bovis and Mycobacterium avium complex in Spain. Vet. J. 2011, 190, 21–25. [Google Scholar] [CrossRef] [PubMed]
- Corner, L.A.L.; Clegg, T.A.; More, S.J.; Williams, D.H.; O’Boyle, I.; Costello, E.; Sleeman, D.P.; Griffin, J.M. The effect of varying levels of population control on the prevalence of tuberculosis in badgers in Ireland. Res. Vet. Sci. 2008, 85, 238–249. [Google Scholar] [CrossRef] [PubMed]
- Jenkins, H.E.; Woodroffe, R.; Donnelly, C.A. The duration of the effects of repeated widespread badger culling on cattle tuberculosis following the cessation of culling. PLoS ONE 2010, 5, e9090. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Gortázar, C.; Delahay, R.J.; McDonald, R.A.; Boadella, M.; Wilson, G.J.; Gavier-Widen, D.; Acevedo, P. The status of tuberculosis in European wild mammals. Mammal Rev. 2012, 42, 193–206. [Google Scholar] [CrossRef]
- Acevedo, P.; Prieto, M.; Quirós, P.; Merediz, I.; de Juan, L.; Infantes-Lorenzo, J.A.; Triguero-Ocaña, R.; Balseiro, A. Tuberculosis epidemiology and badger (Meles meles) spatial ecology in a hotspot-area in Atlantic Spain. Pathogens. 2019, 8, 292. [Google Scholar] [CrossRef] [Green Version]
- Barasona, J.A.; Vicente, J.; Díez-Delgado, I.; Aznar, J.; Gortázar, C.; Torres, M.J. Environmental presence of Mycobacterium tuberculosis complex in aggregation points at the wildlife/livestock interface. Transbound. Emerg. Dis. 2017, 64, 1148–1158. [Google Scholar] [CrossRef] [PubMed]
- Vicente, J.; Barasona, J.A.; Acevedo, P.; Ruíz-Fons, J.F.; Boadella, M.; Diez-Delgado, I.; Beltrán-Beck, B.; González-Barrio, D.; Queirós, J.; Montoro, V.; et al. Temporal trend of tuberculosis in wild ungulates from Mediterranean Spain. Transbound. Emerg. Dis. 2013, 1, 92–103. [Google Scholar] [CrossRef] [PubMed]
- LaHue, N.P.; Baños, J.V.; Acevedo, P.; Gortázar, C.; Martínez-López, B. Spatially explicit modeling of animal tuberculosis at the wildlife-livestock interface in Ciudad Real province, Spain. Prev. Vet. Med. 2016, 128, 101–111. [Google Scholar] [CrossRef]
- Muñoz-Mendoza, M.; Marreros, N.; Boadella, M.; Gortázar, C.; Menéndez, S.; de Juan, L.; Bezos, J.; Romero, B.; Copano, M.F.; Amado, J.; et al. Wild boar tuberculosis in Iberian Atlantic Spain: A different picture from Mediterranean habitats. BMC Vet. Res. 2013, 9, 176. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Balseiro, A.; González-Quirós, P.; Rodríguez, O.; Copano, M.F.; Merediz, I.; De-Juan, L.; Chambers, M.A.; Delahay, R.J.; Marreros, N.; Royo, L.J.; et al. Spatial relationships between Eurasian badgers (Meles meles) and cattle infected with Mycobacterium bovis in Northern Spain. Vet. J. 2013, 197, 739–745. [Google Scholar] [CrossRef]
- Byrne, A.W.; Kenny, K.; Fogarty, U.; O’Keeffe, J.J.; More, S.J.; McGrath, G.; Teeling, M.; Martin, S.W.; Dohoo, I.R. Spatial and temporal analyses of metrics of tuberculosis infection in badgers (Meles meles) from the Republic of Ireland: Trends in apparent prevalence. Prev. Vet. Med. 2015, 122, 345–354. [Google Scholar] [CrossRef] [PubMed]
- Delahay, R.J.; Walker, N.; Smith, G.C.; Wilkinson, D.; Clifton-Hadley, R.S.; Cheeseman, C.L.; Tomlinson, A.J.; Chambers, M.A. Long-term temporal trends and estimated transmission rates for Mycobacterium bovis infection in an undisturbed high-density badger (Meles meles) population. Epidemiol. Infect. 2013, 141, 1445–1456. [Google Scholar] [CrossRef]
- Ninyerola, M.; Pons, X.; Roure, J.M. Atlas Climático Digital de la Península Ibérica. Metolodología y Aplicaciones en Bioclimatología y Geobotánica, 1st ed.; Universidad Autónoma de Barcelona: Bellaterra, Spain, 2005. [Google Scholar]
- Acevedo, P.; González-Quirós, P.; Etherington, T.R.; Prieto, J.M.; Gortázar, C.; Balseiro, A. Generalizing and transferring spatial models: A case study to predict Eurasian badger abundance in Atlantic Spain. Ecol. Model. 2014, 275, 1–8. [Google Scholar] [CrossRef]
- Coetsier, C.; Vannuffel, P.; Bloondel, N.; Denef, J.F.; Cocito, C.; Gala, J.L. Duplex PCR for differential identification of Mycobacterium bovis, M. avium, and M. avium subsp. paratuberculosis in formalin-fixed paraffin-embedded tissues from cattle. J. Clin. Microbiol. 2000, 38, 3048–3054. [Google Scholar] [CrossRef] [Green Version]
- Rodríguez-Campos, S.; Aranaz, A.; de Juan, L.; Sáez-Llorente, J.L.; Romero, B.; Bezos, J.; Jiménez, A.; Mateos, A.; Domínguez, L. Limitations of spoligotyping and variable number tandem repeat typing for molecular tracing of Mycobacterium bovis in a high diversity setting. J. Clin. Microbiol. 2011, 49, 3361–3364. [Google Scholar] [CrossRef] [Green Version]
- Mycobacterium bovis Spoligotype Database Website. Available online: www.Mbovis.org (accessed on 2 October 2019).
- Álvarez, J.; García, I.G.; Aranaz, A.; Bezos, J.; Romero, B.; de Juan, L.; Mateos, A.; Gómez-Mampaso, E.; Domínguez, L.J. Genetic diversity of Mycobacterium avium isolates recovered from clinical samples and from the environment: Molecular characterization for diagnostic purposes. Clin. Microbiol. 2008, 46, 1246–1251. [Google Scholar] [CrossRef] [Green Version]
- Infantes-Lorenzo, J.A.; Dave, D.; Moreno, I.; Anderson, P.; Lesellier, S.; Gormley, E.; Domínguez, L.; Balseiro, A.; Gortázar, C.; Domínguez, M.; et al. New serological platform for detecting antibodies against Mycobacterium tuberculosis complex in European badgers. Vet. Med. Sci. 2019, 5, 61–69. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Schroeder, P.; Hopkins, B.; Jones, J.; Galloway, T.; Pike, R.; Rolfe, S.; Hewinson, G. Temporal and spatial Mycobacterium bovis prevalence patterns as evidenced in the All Wales Badgers Found Dead (AWBFD) survey of infection 2014–2016. Sci. Rep. 2020, 10, 1–11. [Google Scholar] [CrossRef]
- Thomas, J.; Balseiro, A.; Gortázar, C.; Risalde, M.A. Diagnostic of tuerculosis in wildlife: A systematic review. Vet. Res. 2021, 52, 31. [Google Scholar] [CrossRef]
- Courcier, E.A.; Pascual-Linaza, A.V.; Arnold, M.E.; McCormick, C.M.; Corbett, D.M.; O’Hagan, M.J.H.; Collins, S.F.; Trimble, N.A.; McGeown, C.F.; McHugh, G.E.; et al. Evaluating the application of the dual path platform VetTB tests for badgers (Meles meles) in the test and vaccinate or remove (TVR) wildlife research intervention project in Northern Ireland. Res. Vet. Sci. 2020, 130, 170–178. [Google Scholar] [CrossRef] [PubMed]
- Drewe, J.A.; Tomlinson, A.J.; Walker, N.J.; Delahay, R.J. Diagnostic accuracy and optimal use of three tests for tuberculosis in live badgers. PLoS ONE. 2010, 5, e11196. [Google Scholar] [CrossRef]
- Buzdugan, S.N.; Chambers, M.A.; Delahay, R.J.; Drewe, J.A. Diagnosis of tuberculosis in groups of badgers: An exploration of the impact of trapping efficiency, infection prevalence and the use of multiple tests. Epidemiol. Infect. 2016, 144, 1717–1727. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Chambers, M.A.; Waterhouse, S.; Lyashchenko, K.; Delahay, R.; Sayers, R.; Hewinson, R.G. Performance of TB immunodiagnostic tests in Eurasian badgers (Meles meles) of different ages and the influence of duration of infection on serological sensitivity. BMC Vet. Res. 2009, 5, 42. [Google Scholar] [CrossRef] [Green Version]
- Aznar, I.; Frankena, K.; More, S.J.; O’Keeffe, J.; McGrath, G.; de Jong, M.C.M. Quantification of Mycobacterium bovis transmission in a badger vaccine field trial. Prev. Vet. Med. 2017, 149, 29–37. [Google Scholar] [CrossRef]
- Infantes-Lorenzo, J.A.; Moreno, I.; de los Ángeles Risalde, M.; Roy, A.; Villar, M.; Romero, B.; Ibarrola, N.; de la Fuente, J.; Puentes, E.; de Juan, L.; et al. Proteomic characterisation of bovine and avian purified protein derivatives and identification of specific antigens for serodiagnosis of bovine tuberculosis. Clin. Proteomics. 2017, 14, 36. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Miller, M.; Buss, P.; Hofmeyr, J.; Olea-Popelka, F.; Parsons, S.; van Helden, P. Antemortem diagnosis of Mycobacterium bovis infection in free-ranging African lions (Panthera leo) and implications for transmission. J. Wildl. Dis. 2015, 51, 493–497. [Google Scholar] [CrossRef]
- Murphy, D.; Gormley, E.; Collins, D.M.; McGrath, G.; Sovsic, E.; Costello, E.; Corner, L.A.L. Tuberculosis in cattle herds are sentinels for Mycobacterium bovis infection in European badgers (Meles meles): The Irish Greenfield Study. Vet. Microbiol. 2011, 151, 120–125. [Google Scholar] [CrossRef] [PubMed]
- Corner, L.A.L.; Murphy, D.; Gormley, E. Mycobacterium bovis infection in the Eurasian badger (Meles meles): The disease, pathogenesis, epidemiology and control. J. Comp. Pathol. 2011, 144, 1–24. [Google Scholar] [CrossRef]
- Cheeseman, C.L.; Jones, G.W.; Gallagher, J.; Mallinson, P.J. The population structure, density and prevalence of tuberculosis (Mycobacterium bovis) in badgers (Meles meles) from four areas in south west England. J. Appl. Ecol. 1981, 18, 795–804. [Google Scholar] [CrossRef]
- Bourne, F.J.; Donnelly, C.A.; Cox, D.R.; Gettinby, G.; Mclnerney, J.P.; Morrison, W.I.; Woodroffe, R. TB policy and the ISG’s findings. Vet. Rec. 2007, 161, 633–635. [Google Scholar] [CrossRef]
- Sandoval Barron, E.; Swift, B.; Chantrey, J.; Christley, R.; Gardner, R.; Jewell, C.; McGrath, I.; Mitchell, A.; O’Cathail, C.; Prosser, A.; et al. A study of tuberculosis in road traffic-killed badgers on the edge of the British bovine TB epidemic area. Sci. Rep. 2018, 8, 17206. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Delahay, R.J.; Walker, N.J.; Forrester, G.J.; Harmsen, B.; Riordan, P.; Macdonald, D.W.; Newman, C.; Cheeseman, C.L. Demographic correlates of bite wounding in Eurasian badgers, Meles meles L., in stable and perturbed populations. Anim. Behav. 2006, 71, 1047–1055. [Google Scholar] [CrossRef]
- Reveillaud, E.; Desvaux, S.; Boschiroli, M.L.; Hars, J.; Faure, E.; Fediaevsky, A.; Cavalerie, L.; Chevalier, F.; Jabert, P.; Poliak, S.; et al. Infection of wildlife by Mycobacterium bovis in France assessment through a national surveillance system, Sylvatub. Front. Vet. Sci. 2018, 5, 262. [Google Scholar] [CrossRef]
- Michelet, L.; de Cruz, K.; Tambosco, J.; Hénault, S.; Boschiroli, M.L. Mycobacterium microti interferes with bovine tuberculosis surveillance. Microorganisms 2020, 8, 1850. [Google Scholar] [CrossRef]
- Michelet, L.; de Cruz, K.; Phalente, Y.; Karoui, C.; Henault, S.; Beral, M.; Boschiroli, M.L. Mycobacterium microti infection in dairy goats, France. Emerg. Infect. Dis. 2016, 22, 569–570. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Michelet, L.; de Cruz, K.; Karoui, C.; Henault, S.; Boschiroli, M.L. Mycobacterium microti infection in a cow in France. Vet. Rec. 2017, 180, 429. [Google Scholar] [CrossRef]
- Lorente-Leal, V.; Liandris, E.; Pacciarini, M.; Botelho, A.; Kenny, K.; Loyo, B.; Fernández, R.; Bezos, J.; Domínguez, L.; de Juan, L.; et al. Direct PCR on tissue samples to detect Mycobacterium tuberculosis complex: An alternative to the bacteriological culture. J. Clin. Microbiol. 2021, 59, e01404-20. [Google Scholar] [CrossRef] [PubMed]
Figure 1.
Definition of the P22 ELISA cut-off against a Mycobacterium tuberculosis complex (MTC) isolation reference. The graph includes data sera from positive and negative animals to bacteriological culture, as well as both trapped and road-killed animals. Sen: sensitivity; Spe: specificity; SE + SP: semi-sum or diagnostic value of sensitivity and specificity; SeDI: sensitivity discriminatory index (ratio of sensitivity to 1-specificity); SpDI: specificity discriminatory index (ratio of specificity to 1-sensitivity).
Figure 1.
Definition of the P22 ELISA cut-off against a Mycobacterium tuberculosis complex (MTC) isolation reference. The graph includes data sera from positive and negative animals to bacteriological culture, as well as both trapped and road-killed animals. Sen: sensitivity; Spe: specificity; SE + SP: semi-sum or diagnostic value of sensitivity and specificity; SeDI: sensitivity discriminatory index (ratio of sensitivity to 1-specificity); SpDI: specificity discriminatory index (ratio of specificity to 1-sensitivity).
Figure 2.
Prevalence of tuberculosis (TB) among badgers (red lines) and cattle (blue line) by year (2008–2020). Red circles refer to results based on bacterial isolation; red squares refer to results based on the P22 ELISA. TB prevalence based on single intradermal tuberculin test data and bacterial isolation was available for cattle herds as part of the Spanish National Program for the Eradication of Bovine TB [2].
Figure 2.
Prevalence of tuberculosis (TB) among badgers (red lines) and cattle (blue line) by year (2008–2020). Red circles refer to results based on bacterial isolation; red squares refer to results based on the P22 ELISA. TB prevalence based on single intradermal tuberculin test data and bacterial isolation was available for cattle herds as part of the Spanish National Program for the Eradication of Bovine TB [2].
Figure 3.
Shared Mycobacterium bovis spoligotypes (SB) identified in badgers and cattle herds in the three regions of Asturias (Atlantic Spain) from 2008 to 2020. The numbers within the color circles or stars indicate the number of badgers or cattle herds, respectively, positive to that SB during the 13-year follow-up. Red lines within the map establish the three regions of Asturias.
Figure 3.
Shared Mycobacterium bovis spoligotypes (SB) identified in badgers and cattle herds in the three regions of Asturias (Atlantic Spain) from 2008 to 2020. The numbers within the color circles or stars indicate the number of badgers or cattle herds, respectively, positive to that SB during the 13-year follow-up. Red lines within the map establish the three regions of Asturias.
Figure 4.
Prevalence of tuberculosis among trapped badgers (purple color) or badgers killed in road traffic accidents (RTA) (orange color) by year. The isolates are represented with columns for each of the two animal groups, and the lines represent seroprevalence. Circles refer to results based on P22 ELISA for the RTA, and the squares refer to results based on P22 ELISA for trapped animals. Note that trapping was not carried out in 2012–2015, 2017, or 2020, so all badgers studied in those years were RTA.
Figure 4.
Prevalence of tuberculosis among trapped badgers (purple color) or badgers killed in road traffic accidents (RTA) (orange color) by year. The isolates are represented with columns for each of the two animal groups, and the lines represent seroprevalence. Circles refer to results based on P22 ELISA for the RTA, and the squares refer to results based on P22 ELISA for trapped animals. Note that trapping was not carried out in 2012–2015, 2017, or 2020, so all badgers studied in those years were RTA.
Figure 5.
Proportions of badgers testing positive based on E% value in the P22 ELISA. (a) Positive badgers for Mycobacterium tuberculosis complex (MTC), positive for the M. avium complex (MAC), or negative for both complexes. (b) Positive badgers in western, central, and eastern parts of Asturias. (c) Male and female positive badgers. (d) Adult and sub-adult positive badgers. In all graphs, the horizontal black line represents the cut-off of 260% (see Section 2.3.1.3). The red lines represent means and standard deviations. Data connected with the same letter (A or B) are not significantly different based on Tukey–Kramer’s test (p > 0.05). Results from animals in which sex or age class were unknown are not included in panels c and d.
Figure 5.
Proportions of badgers testing positive based on E% value in the P22 ELISA. (a) Positive badgers for Mycobacterium tuberculosis complex (MTC), positive for the M. avium complex (MAC), or negative for both complexes. (b) Positive badgers in western, central, and eastern parts of Asturias. (c) Male and female positive badgers. (d) Adult and sub-adult positive badgers. In all graphs, the horizontal black line represents the cut-off of 260% (see Section 2.3.1.3). The red lines represent means and standard deviations. Data connected with the same letter (A or B) are not significantly different based on Tukey–Kramer’s test (p > 0.05). Results from animals in which sex or age class were unknown are not included in panels c and d.
Figure 6.
Correlation of tuberculosis (TB) prevalence in badgers and cattle herds in Asturias (Atlantic Spain). (a) Evolution of TB prevalence in badgers (red line) and cattle (blue line) by year. Prevalence in badgers was based on mean E% in the P22 ELISA. (b) Correlation between TB prevalence in cattle herds and mean E% in the P22 ELISA in badgers.
Figure 6.
Correlation of tuberculosis (TB) prevalence in badgers and cattle herds in Asturias (Atlantic Spain). (a) Evolution of TB prevalence in badgers (red line) and cattle (blue line) by year. Prevalence in badgers was based on mean E% in the P22 ELISA. (b) Correlation between TB prevalence in cattle herds and mean E% in the P22 ELISA in badgers.
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. |
© 2021 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Share and Cite
MDPI and ACS Style
Blanco Vázquez, C.; Barral, T.D.; Romero, B.; Queipo, M.; Merediz, I.; Quirós, P.; Armenteros, J.Á.; Juste, R.; Domínguez, L.; Domínguez, M.; et al. Spatial and Temporal Distribution of Mycobacterium tuberculosis Complex Infection in Eurasian Badger (Meles meles) and Cattle in Asturias, Spain. Animals 2021, 11, 1294. https://doi.org/10.3390/ani11051294
AMA Style
Blanco Vázquez C, Barral TD, Romero B, Queipo M, Merediz I, Quirós P, Armenteros JÁ, Juste R, Domínguez L, Domínguez M, et al. Spatial and Temporal Distribution of Mycobacterium tuberculosis Complex Infection in Eurasian Badger (Meles meles) and Cattle in Asturias, Spain. Animals. 2021; 11(5):1294. https://doi.org/10.3390/ani11051294
Chicago/Turabian StyleBlanco Vázquez, Cristina, Thiago Doria Barral, Beatriz Romero, Manuel Queipo, Isabel Merediz, Pablo Quirós, José Ángel Armenteros, Ramón Juste, Lucas Domínguez, Mercedes Domínguez, and et al. 2021. "Spatial and Temporal Distribution of Mycobacterium tuberculosis Complex Infection in Eurasian Badger (Meles meles) and Cattle in Asturias, Spain" Animals 11, no. 5: 1294. https://doi.org/10.3390/ani11051294
APA StyleBlanco Vázquez, C., Barral, T. D., Romero, B., Queipo, M., Merediz, I., Quirós, P., Armenteros, J. Á., Juste, R., Domínguez, L., Domínguez, M., Casais, R., & Balseiro, A. (2021). Spatial and Temporal Distribution of Mycobacterium tuberculosis Complex Infection in Eurasian Badger (Meles meles) and Cattle in Asturias, Spain. Animals, 11(5), 1294. https://doi.org/10.3390/ani11051294
Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.
