Disease management at the wildlife‐livestock interface: Using whole‐genome sequencing to study the role of elk in <i>Mycobacterium bovis</i> transmission in Michigan, USA

Salvador, Liliana C. M.; O’Brien, Daniel J.; Cosgrove, Melinda K.; Stuber, Tod; Schooley, Angie M.; Crispell, Joseph; Church, Steven; Gröhn, Yrjö T.; Robbe‐Austerman, Suelee; Kao, Rowland R.

doi:10.1111/mec.15061

Cited by 60 publications

(66 citation statements)

References 76 publications

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“…The distribution for the substitution rate ( μ ) was a beta-PERT, with mode, minimum and maximum respectively set to 0.31, 0.1 and 0.94 base pair × genome × year. These values corresponded to the average, minimum, and maximum of literature estimates from other systems 27,59–61 . We assigned a similar prior to the latency period ( 1/σ ), based on the published literature for data relevant to the geographical area (south-east England).…”

Section: Methodssupporting

confidence: 76%

Identifying likely transmission pairs with pathogen sequence data using Kolmogorov Forward Equations; an application toM.bovisin cattle and badgers

Rossi

Crispell

Balaz

et al. 2020

Preprint

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18Established methods for whole-genome-sequencing (WGS) technology allow for the detection of 19 single-nucleotide polymorphisms (SNPs) in the pathogen genomes sourced from host samples. The 20 information obtained can be used to track the pathogen's evolution in time and potentially identify 21 'who-infected-whom' with unprecedented accuracy. Successful methods include 'phylodynamic 22 bovine/zoonotic tuberculosis, bTB) infection. 31Our results show that, even with such limited data and low diversity, the computation of the 32 transmission probability between host pairs can help discriminate between likely and unlikely 33 infection pathways and therefore help to identify potential transmission networks, but can be 34 sensitive to assumptions about within-host evolution. 35 36 Keywords: bovine tuberculosis, inter-species transmission, contact network, within-host evolution, 37Mycobacterium bovis, Woodchester Park 38 39 40 contacts between them as links (edges). 46 An important distinction exists between the contact network and the transmission network: while 47 the former includes all potential transmission contacts, the latter is a subset of the former describing 48 pathogen transmission patterns 5,6 . Identifying the transmission network, even when the contact 49 network is well described, can be a challenging filtering process informed by multiple factors. 50Techniques are still needed to disentangle these factors, using the different sources of information 51 (evolutionary, immunological, and epidemiological) available to infer likely transmission pathways. 52Most importantly, we wish to know "how likely is it that individual A infected individual B?", or 53 "how likely is it that a third unsampled individual was involved in the transmission chain between 54 individuals A and B?", the key questions in forensic or 'precision' epidemiology. The answers to 55 these questions, and transmission pathway reconstruction, are important for gathering information 56 about outbreaks, to shed light on transmission dynamics, and to help infer epidemiological 57 parameters. 58Whole genome sequencing (WGS) can be used to detect polymorphisms in a genome with high 59 resolution, and therefore discriminate between closely related strains. Polymorphisms are caused by 60 errors that occur during pathogen replication within the host. Generally these single nucleotide 61 polymorphisms (SNPs) are considered to be neutral in bacterial species within the timescale of 62 disease outbreaks 7 . In the absence of horizontal genetic transfer, tracking these SNPs would be 63 expected to follow the pattern of transmission. In combination with an increasing ability to extract 64 genetic material (either directly from clinical samples or from cultured isolates) and with rapid and 65 minimal processing, large-scale characterization of populations of pathogen genomes is now 66 4 possible 8-10 . These advances have proven to be transformative for forensic epidemiology, 67 especially when populations can be sampled densely. 68The observed gen...

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Section: Methodssupporting

confidence: 76%

Identifying likely transmission pairs with pathogen sequence data using Kolmogorov Forward Equations; an application toM.bovisin cattle and badgers

Rossi

Crispell

Balaz

et al. 2020

Preprint

Self Cite

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“…Whole-genome sequencing of M. bovis has been used to track transmission within and between cattle and wildlife populations [21,[33][34][35][36][37]. These studies have demonstrated that genomics adds unprecedented resolution, in comparison to previous molecular-typing technologies, in many cases distinguishing infection between individual animals.…”

Section: Introductionmentioning

confidence: 99%

Mycobacterium bovis genomics reveals transmission of infection between cattle and deer in Ireland

Crispell

Cassidy

Kenny³

et al. 2020

Microbial Genomics

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Control of bovine tuberculosis (bTB), caused by Mycobacterium bovis , in the Republic of Ireland costs €84 million each year. Badgers are recognized as being a wildlife source for M. bovis infection of cattle. Deer are thought to act as spillover hosts for infection; however, population density is recognized as an important driver in shifting their epidemiological role, and deer populations across the country have been increasing in density and range. County Wicklow represents one specific area in the Republic of Ireland with a high density of deer that has had consistently high bTB prevalence for over a decade, despite control operations in both cattle and badgers. Our research used whole-genome sequencing of M. bovis sourced from infected cattle, deer and badgers in County Wicklow to evaluate whether the epidemiological role of deer could have shifted from spillover host to source. Our analyses reveal that cattle and deer share highly similar M. bovis strains, suggesting that transmission between these species is occurring in the area. In addition, the high level of diversity observed in the sampled deer population suggests deer may be acting as a source of infection for local cattle populations. These findings have important implications for the control and ultimate eradication of bTB in Ireland.

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“…Many aspects of animal TB epidemiology are yet to be elucidated, which limits the estimation of transmission model parameters. Disease modelling approaches could be helpful in decision‐making, by evaluating potential alternative diagnostic and control measures in high prevalence scenarios (Guta et al, 2014); and to improve surveillance and streamline the eradication strategies in low prevalence scenarios, when a disease outbreak occurs (Salvador et al, 2019), never losing the heterogeneity parameter from the equation. The way these knowledge gaps are considered within the mathematical models, and the different considered assumptions, may have a critical impact on the model outcomes and robustness, so extrapolation of results to a certain scenario and the underlying definition for interventions should be done with caution (Álvarez et al, 2014; Conlan et al, 2012).…”

Section: Implications Of Animal Tb Heterogeneity In Management Contrmentioning

confidence: 99%

Animal tuberculosis: impact of disease heterogeneity in transmission, diagnosis, and control

Pereira

Reis

Ramos

et al. 2020

Transbound Emerg Dis

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Animal tuberculosis (TB) in terrestrial mammals is mainly caused by Mycobacterium bovis. This pathogen is adapted to a wide range of host species, representing a threat to livestock, wildlife and human health. Disease heterogeneity is a hallmark of multi‐host TB and a challenge for control. Drivers of animal TB heterogeneity are very diverse and may act at the level of the causative agent, the host species, the interface between mycobacteria and the host, community of hosts, the environment and even policy behind control programmes. In this paper, we examine the drivers that seem to contribute to this phenomenon. We begin by reviewing evidence accumulated to date supporting the consensus that a complex range of genetic, biological and socio‐environmental factors contribute to the establishment and maintenance of animal TB, setting the grounds for heterogeneity. We then highlight the complex interplay between individual, species‐specific and community protective factors with risk/maintenance variables that include animal movements and densities, co‐infection and super‐shedders. We finally consider how current interventions should seek to consider and explore heterogeneity in order to tackle potential limitations for diagnosis and control programmes, simultaneously increasing their efficacy.

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Disease management at the wildlife‐livestock interface: Using whole‐genome sequencing to study the role of elk in Mycobacterium bovis transmission in Michigan, USA

Cited by 60 publications

References 76 publications

Identifying likely transmission pairs with pathogen sequence data using Kolmogorov Forward Equations; an application toM.bovisin cattle and badgers

Identifying likely transmission pairs with pathogen sequence data using Kolmogorov Forward Equations; an application toM.bovisin cattle and badgers

Mycobacterium bovis genomics reveals transmission of infection between cattle and deer in Ireland

Animal tuberculosis: impact of disease heterogeneity in transmission, diagnosis, and control

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