Localized reactive badger culling increases risk of bovine tuberculosis in nearby cattle herds

Human and livestock diseases can be difficult to control where infection persists in wildlife populations. Control of bovine tuberculosis (bTB) in British cattle is complicated by the maintenance of Mycobacterium bovis (the causative agent of bTB) in badgers, acting as reservoirs of infection. Although over 20 000 badgers were culled to control bTB between 1975 and 1997, the incidence of bTB in cattle has substantially increased in parts of Great Britain in recent decades. Our case-control study, involving 1208 cattle herds, provides further evidence of the detrimental effect of localized reactive badger culling in response to the disclosure of a confirmed bTB herd breakdown in cattle. The presence of any reactive badger culling activity and increased numbers of badgers culled in the vicinity of a herd were associated with significantly increased bTB risk, even after adjusting for other important local risk factors. Such findings may partly explain why some earlier localized approaches to bTB control were ineffective.     

Herd-level risk factors associated with tuberculosis breakdowns among cattle herds in England before the 2001 foot-and-mouth disease epidemic

A case-control study of the factors associated with the risk of a bovine tuberculosis (TB) breakdown in cattle herds was undertaken within the randomized badger culling trial (RBCT). TB breakdowns occurring prior to the 2001 foot-and-mouth disease epidemic in three RBCT triplets were eligible to be cases; controls were selected from the same RBCT area. Data from 151 case farms and 117 control farms were analysed using logistic regression. The strongest factors associated with an increased TB risk were movement of cattle onto the farm from markets or farm sales, operating a farm over multiple premises and the use of either covered yard or 'other' housing types. Spreading artificial fertilizers or farmyard manure on grazing land were both associated with decreased risk. These first case-control results from the RBCT will be followed by similar analyses as more data become available.     

A model of bovine tuberculosis control in domesticated cattle herds.

A typical strategy for disease control in domesticated animals involves regular field tests and quarantine of infected herds. This prevents disease spread beyond the herd, while slaughter of diseased animals removes the infection from within the herd. A model of bovine tuberculosis (Tb) control in cattle is examined, which includes ''test and slaughter'' combined with herd isolation and vaccination. Herd status is represented by an integral equation expressing the duration of herd isolation. The current Tb situation in New Zealand is used as an example, and vaccination strategy discussed. Extrapolation of existing management strategies indicate that a vaccine of efficacy greater than 96% would be required, reaching 95% of target Tb levels within six years. These results suggest that a complementary strategy of vaccination and vector control may be more promising than vaccination alone.     

Impact of external sources of infection on the dynamics of bovine tuberculosis in modelled badger populations

ABSTRACT: BACKGROUND: The persistence of bovine TB (bTB) in various countries throughout the world is enhanced by the existence of wildlife hosts for the infection. In Britain and Ireland, the principal wildlife host for bTB is the badger (Meles meles). The objective of our study was to examine the dynamics of bTB in badgers in relation to both badger-derived infection from within the population and externally-derived, trickle-type, infection, such as could occur from other species or environmental sources, using a spatial stochastic simulation model. RESULTS: The presence of external sources of infection can increase mean prevalence and reduce the threshold group size for disease persistence. Above the threshold equilibrium group size of 6-8 individuals predicted by the model for bTB persistence in badgers based on internal infection alone, external sources of infection have relatively little impact on the persistence or level of disease. However, within a critical range of group sizes just below this threshold level, external infection becomes much more important in determining disease dynamics. Within this critical range, external infection increases the ratio of intra- to inter-group infections due to the greater probability of external infections entering fully-susceptible groups. The effect is to enable bTB persistence and increase bTB prevalence in badger populations which would not be able to maintain bTB based on internal infection alone. CONCLUSIONS: External sources of bTB infection can contribute to the persistence of bTB in badger populations. In high-density badger populations, internal badger-derived infections occur at a sufficient rate that the additional effect of external sources in exacerbating disease is minimal. However, in lower-density populations, external sources of infection are much more important in enhancing bTB prevalence and persistence. In such circumstances, it is particularly important that control strategies to reduce bTB in badgers include efforts to minimise such external sources of infection.     

Comparing badger (Meles meles) management strategies for reducing tuberculosis incidence in cattle

Bovine tuberculosis (bTB), caused by Mycobacterium bovis, continues to be a serious economic problem for the British cattle industry. The Eurasian badger (Meles meles) is partly responsible for maintenance of the disease and its transmission to cattle. Previous attempts to manage the disease by culling badgers have been hampered by social perturbation, which in some situations is associated with increases in the cattle herd incidence of bTB. Following the licensing of an injectable vaccine, we consider the relative merits of management strategies to reduce bTB in badgers, and thereby reduce cattle herd incidence. We used an established simulation model of the badger-cattle-TB system and investigated four proposed strategies: business as usual with no badger management, large-scale proactive badger culling, badger vaccination, and culling with a ring of vaccination around it. For ease of comparison with empirical data, model treatments were applied over 150 km(2) and were evaluated over the whole of a 300 km(2) area, comprising the core treatment area and a ring of approximately 2 km. The effects of treatment were evaluated over a 10-year period comprising treatment for five years and the subsequent five year period without treatment. Against a background of existing disease control measures, where 144 cattle herd incidents might be expected over 10 years, badger culling prevented 26 cattle herd incidents while vaccination prevented 16. Culling in the core 150 km(2) plus vaccination in a ring around it prevented about 40 cattle herd breakdowns by partly mitigating the negative effects of culling, although this approach clearly required greater effort. While model outcomes were robust to uncertainty in parameter estimates, the outcomes of culling were sensitive to low rates of land access for culling, low culling efficacy, and the early cessation of a culling strategy, all of which were likely to lead to an overall increase in cattle disease.     

Estimates for local and movement-based transmission of bovine tuberculosis in British cattle

Both badgers and livestock movements have been implicated in contributing to the ongoing epidemic of bovine tuberculosis (BTB) in British cattle. However, the relative contributions of these and other causes are not well quantified. We used cattle movement data to construct an individual (premises)-based model of BTB spread within Great Britain, accounting for spread due to recorded cattle movements and other causes. Outbreak data for 2004 were best explained by a model attributing 16% of herd infections directly to cattle movements, and a further 9% unexplained, potentially including spread from unrecorded movements. The best-fit model assumed low levels of cattle-to-cattle transmission. The remaining 75% of infection was attributed to local effects within specific high-risk areas. Annual and biennial testing is mandatory for herds deemed at high risk of infection, as is pre-movement testing from such herds. The herds identified as high risk in 2004 by our model are in broad agreement with those officially designated as such at that time. However, border areas at the edges of high-risk regions are different, suggesting possible areas that should be targeted to prevent further geographical spread of disease. With these areas expanding rapidly over the last decade, their close surveillance is important to both identify infected herds qucikly, and limit their further growth.     

Distribution of badger latrines in a high-density population: habitat selection and implications for the transmission of bovine tuberculosis to cattle

Eurasian badgers Meles meles habitually deposit droppings and other scent marks at latrines, which may be associated with territorial defence, and communicate information related to group and individual identity and status, and food resources. Understanding patterns of latrine distribution contributes to our understanding of badger social behaviour, and may be relevant to managing the risks of transmission of bovine tuberculosis from badgers to cattle. We investigated the distribution of badger latrines relative to habitat composition in a high-density badger population occupying a 7 km² area of diverse landscape in south-west England. Results indicated that the frequency and density of badger latrines varied according to land use, with woodland and linear landscape features (particularly hedges and stone walls) being positively selected. The number of latrines decreased significantly with distance from linear features. Grassland was negatively selected given its availability, but contained the highest number of latrines. The tendency for latrines to be associated with particular habitat types covaried spatially across the study area. We present a habitat selection probability function, based on the output of our analyses, to allow comparison of observed versus expected latrine counts per habitat type at different sites. Habitat manipulation on farmland may offer opportunities to manage exposure of cattle to badger latrines. However, our analyses indicate that other factors (perhaps demographic or environmental) may also exert a substantial local influence on latrine location.     

Mycobacterium tuberculosis: the honey badger of pathogens

Mycobacterium tuberculosis is a fascinating object of study: it is one of the deadliest pathogens of humankind, able to fend off persistent attacks by the immune system or drugs Subject Categories: Immunology, Microbiology, Virology & Host Pathogen Interaction, Chemical Biology

I have always been interested in infectious diseases since I began to study biology. As a graduate student, my pathogen of choice was Salmonella typhimurium, which typically causes diarrhea that can potentially lead to death. Salmonella''s rapid doubling time, and the availability of elegant genetic tools, a wealth of reagents, and a robust animal infection model put this bug at the apex of ideal host–pathogen systems to study. After I finished my PhD studies—and for reasons to be told another day—my career took an unexpected detour into an area of research I never thought I would be interested in: I went from the sublime to the ridiculous, from Salmonella to Mycobacterium tuberculosis (Mtb), an excruciatingly slow‐growing bacillus with few genetic tools, a paucity of reagents, and an animal model in which an experiment can take a year or longer. Having said all of that, I love working on this pathogen.For those of you who do not know much about Mtb, it is the world''s deadliest bacterium that causes the disease tuberculosis (TB). As Mtb is spread in aerosol droplets coughed up by infected individuals, TB is highly contagious, and about one‐third of the world''s population may be infected with Mtb, although this number has been reasonably challenged (Behr et al, 2021). Even if the numbers of latent or asymptomatic infections are debated, there are some back‐of‐the‐envelope estimates that Mtb has killed more than a billion humans over the millennia. Although TB is often treatable with antibiotics and most Mtb‐infected healthy individuals are asymptomatic, the appearance of multi‐drug‐resistant Mtb and HIV/AIDS has further increased the number of deaths caused by this pathogen.How has Mtb become such a successful pathogen? For one, we lack an effective vaccine to prevent infection. Many readers may point out that they have themselves been given a TB vaccine; known as “BCG” for bacille Calmette–Guérin, this is a laboratory‐attenuated strain of a species related to Mtb called Mycobacterium bovis. While BCG does provide some protection for children against TB, BCG is essentially ineffective against pulmonary TB in adults. For this reason, it is not used in the USA and many other countries.Another major challenge to treating TB has been a lack of antimicrobials that can access Mtb bacilli in privileged sites known as granulomas, which are cell‐fortified structures our immune system builds to contain microbial growth. In addition to the granuloma walls, Mtb has a highly complex cell envelope that protects it from many small molecules. I imagine that antimicrobial molecules have the challenging task of reaching an enemy shielded in armor, hiding deep inside a castle keep, and surrounded by a vast moat, and an army of orcs.On top of these therapeutic barriers, most antimicrobials work on metabolically active or growing bacteria. Mtb, however, grows very slowly, with a doubling time under optimal laboratory conditions of about 20 h—compared with 20 min for Salmonella. Moreover, Mtb is believed to enter a “persistent” or “latent” state in its natural host with limited cell divisions. This extremely slow growth makes treatment a long and tedious prospect: 6–12 months of antibiotic treatment are generally required, during which time one cannot drink alcohol due to the potential liver toxicity of the drugs. Believe it or not, there are people who would rather refuse TB treatment than give up alcohol for a few months. Additionally, the perception of “feeling cured” after a few weeks of TB therapy can also lead to a lapse in compliance. The consequence of failing to clear a partially treated infection is the emergence of drug resistance, which has created strains that are extensively resistant to most frontline TB drugs.When thinking about the difficulty of curing Mtb infections, I am reminded of the fierce and fearless honey badger, which came to fame through a viral YouTube video. The narrator points out how honey badgers “don''t care” about battling vicious predators in order to get food: venomous snakes, stinging bees—you name it. I once saw a photo of a honey badger that looked more like a pin cushion, harpooned with numerous porcupine quills. This battle royale of the wilderness is a perfect analogy of Mtb versus the immune system: Like the honey badger, Mtb really don''t care.Vaccines primarily work by coaxing our immune system to make antibodies that neutralize foreign invaders, most typically viruses, but also bacteria, some of which have evolved mechanisms to evade detection by antibodies or otherwise render them useless. In most cases, phagocytes then gobble up and kill invading bacteria. While phagocytes are critical in controlling Mtb infections, it is unclear which of their molecules or “effectors” act as executioners of Mtb. For example, nitric oxide and copper play roles in controlling Mtb in a mouse model, but it is unknown how these molecules exert their host‐protective activity, and whether or not they play a similar role in humans. Furthermore, despite the production of these antibacterial effectors—the “porcupine quills”—Mtb often persists due to intrinsic resistance mechanisms. Thus, while our immune system may have the tools to keep Mtb under control, it falls short of eradicating it from our bodies and, in many cases, fails to prevent the progression of the disease. Perhaps a most worrying observation is that prior infection, which is generally considered the most effective path to immunity for many infectious diseases, does not consistently protect against reinfection with Mtb.The above facts have left the TB field scrambling to identify new ways to fight this disease. Much of this work requires that researchers understand both the fundamental processes of the bacterium and its host. Studies of human populations around the globe have revealed differences in susceptibility to infection, the genetic and immunological bases of which are being investigated (Bellamy et al, 2000; Berry et al, 2010; Möller et al, 2010). These studies have made researchers increasingly aware that how the immune system responds to Mtb may play a critical role in disease control. For example, understanding why some individuals or populations are more or less susceptible to TB may help in the development of better vaccines. Also, the more we understand what makes this pathogen so resilient to the immune system could facilitate the development of new antibacterial drugs or host‐directed therapies. These questions can only be answered once we fully understand how the host combats Mtb infections, and how the bacteria counteract these host defenses. While it is a daunting endeavor, my hope is that the efforts of many laboratories around the world will get a better understanding of the host–Mtb interface and ultimately help to eradicate this disease for good.     

Bovine tuberculosis in cattle: reduced risk on wildlife-friendly farms

The associations between habitat and other factors that lead to the risk of bovine tuberculosis (bTB) in diary cattle were examined in an unmatched case-control study. Data from 60 herds with recent history of bTB and 60 controls were analysed using logistic regression. The predictors included farmland habitat, topography, indices of badger density and herd size. Information-theoretic approaches were used to identify those predictor variables explaining the greatest variation in cattle herd bTB breakdowns. Reduced risk of bTB was associated with the management of farmland in ways favourable to wildlife conservation, as encouraged by recent (2005) European Common Agricultural Policy reforms.     

Environmental monitoring of Mycobacterium bovis in badger feces and badger sett soil by real-time PCR, as confirmed by immunofluorescence, immunocapture, and cultivation

Real-time PCR was used to detect and quantify Mycobacterium bovis cells in naturally infected soil and badger feces. Immunomagnetic capture, immunofluorescence, and selective culture confirmed species identification and cell viability. These techniques will prove useful for monitoring M. bovis in the environment and for elucidating transmission routes between wildlife and cattle.     

Estimating epidemiological parameters for bovine tuberculosis in British cattle using a Bayesian partial-likelihood approach

Fitting models with Bayesian likelihood-based parameter inference is becoming increasingly important in infectious disease epidemiology. Detailed datasets present the opportunity to identify subsets of these data that capture important characteristics of the underlying epidemiology. One such dataset describes the epidemic of bovine tuberculosis (bTB) in British cattle, which is also an important exemplar of a disease with a wildlife reservoir (the Eurasian badger). Here, we evaluate a set of nested dynamic models of bTB transmission, including individual- and herd-level transmission heterogeneity and assuming minimal prior knowledge of the transmission and diagnostic test parameters. We performed a likelihood-based bootstrapping operation on the model to infer parameters based only on the recorded numbers of cattle testing positive for bTB at the start of each herd outbreak considering high- and low-risk areas separately. Models without herd heterogeneity are preferred in both areas though there is some evidence for super-spreading cattle. Similar to previous studies, we found low test sensitivities and high within-herd basic reproduction numbers (R₀), suggesting that there may be many unobserved infections in cattle, even though the current testing regime is sufficient to control within-herd epidemics in most cases. Compared with other, more data-heavy approaches, the summary data used in our approach are easily collected, making our approach attractive for other systems.     

A preliminary study of genetic factors that influence susceptibility to bovine tuberculosis in the British cattle herd

Associations between specific host genes and susceptibility to Mycobacterial infections such as tuberculosis have been reported in several species. Bovine tuberculosis (bTB) impacts greatly the UK cattle industry, yet genetic predispositions have yet to be identified. We therefore used a candidate gene approach to study 384 cattle of which 160 had reacted positively to an antigenic skin test ('reactors'). Our approach was unusual in that it used microsatellite markers, embraced high breed diversity and focused particularly on detecting genes showing heterozygote advantage, a mode of action often overlooked in SNP-based studies. A panel of neutral markers was used to control for population substructure and using a general linear model-based approach we were also able to control for age. We found that substructure was surprisingly weak and identified two genomic regions that were strongly associated with reactor status, identified by markers INRA111 and BMS2753. In general the strength of association detected tended to vary depending on whether age was included in the model. At INRA111 a single genotype appears strongly protective with an overall odds ratio of 2.2, the effect being consistent across nine diverse breeds. Our results suggest that breeding strategies could be devised that would appreciably increase genetic resistance of cattle to bTB (strictly, reduce the frequency of incidence of reactors) with implications for the current debate concerning badger-culling.     

Does inbreeding affect the extinction risk of small populations?: predictions from Drosophila

A fundamental assumption underlying the importance of genetic risks within conservation biology is that inbreeding increases the extinction probability of populations. Although inbreeding has been shown to have a detrimental impact on individual fitness, its contribution to extinction is still poorly understood. We have studied the consequences of different levels of prior inbreeding for the persistence of small populations using Drosophila melanogaster as a model organism. To this end, we determined the extinction rate of small vial populations differing in the level of inbreeding under both optimal and stress conditions, i.e. high temperature stress and ethanol stress. We show that inbred populations have a significantly higher short‐term probability of extinction than non‐inbred populations, even for low levels of inbreeding, and that the extinction probability increases with increasing inbreeding levels. In addition, we observed that the effects of inbreeding become greatly enhanced under stressful environmental conditions. More importantly, our results show that the impact of environmental stress becomes significantly greater for higher inbreeding levels, demonstrating explicitly that inbreeding and environmental stress are not independent but can act synergistically. These effects seem long lasting as the impact of prior inbreeding was still qualitatively the same after the inbred populations had been expanded to appreciable numbers and maintained as such for approximately 50 generations. Our observations have significant consequences for conservation biology.     

Environmental risk factors associated with bovine tuberculosis among cattle in high-risk areas

Our research shows that environmental features are important predictors of bovine tuberculosis (bTB) in British cattle herds in high-prevalence regions. Data from 503 case and 808 control farms included in the randomized badger culling trial (RBCT) were analysed. bTB risk increased in larger herds and on farms with greater areas of maize, deciduous woodland and marsh, whereas a higher percentage of boundaries composed of hedgerows decreased the risk. The model was tested on another case–control study outside RBCT areas, and here it had a much smaller predictive power. This suggests that different infection dynamics operate outside high-risk areas, although it is possible that unknown confounding factors may also have played a role.     

Epidemiology of trace elements deficiencies in Belgian beef and dairy cattle herds

Selenium (Se), iodine (I), zinc (Zn) and copper (Cu) deficiencies in cattle have been reported in Europe. These deficiencies are often associated with diseases. The aim of the study was to assess trace element status in Belgian cattle herds showing pathologies and to compare them to healthy cattle herds. Eighty-two beef herds with pathologies, 11 healthy beef herds, 65 dairy herds with pathologies and 20 healthy dairy herds were studied during barn period. Blood and/or milk samples were taken in healthy animals. Plasma Zn, Cu, inorganic I (PII) and activity of glutathione peroxidase in erythrocytes (GPX) were assayed. In milk, I concentration was measured. Data about pathologies and nutrition in the herds were collected. According to defined thresholds, it appeared that a large proportion of deficient herds belonged to “sick” group of herds. This conclusion was supported by the mean value of trace elements and by the fact that a majority of individual values of trace elements was below the threshold. Dairy herds had mean values of trace elements higher than beef herds. More concentrates and minerals were used in healthy herds versus “sick” herds. These feed supplements were also used more often in dairy herds, compared to beef herds. Trace elements deficiencies are present in cattle herds in Belgium and are linked to diseases. Nutrition plays a major role in the trace elements status.     

Absence of antibodies against canine distemper virus in free-ranging populations of the Eurasian badger in Great Britain

Canine distemper virus (CDV) is a serious disease of wild carnivores throughout the world. In Europe, infection has been detected in several carnivores including the Eurasian badger (Meles meles). In the present study 182 badger blood samples were collected from an intensively studied population of wild badgers in southwestern England (January-July, 1997), and a further 286 from throughout southern Britain (June 1996-November 1998). A neutralizing peroxidase-linked antibody test was used for the detection of antibodies against CDV. All the samples were negative for CDV antibodies, suggesting that in contrast to mainland Europe, the disease may be either absent or maintained at low levels in British badgers.     

Migratory herds of wildebeests and zebras indirectly affect calf survival of giraffes

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