Data collection

The serological data on brucellosis were collected through a cross-sectional field study conducted in the Arusha and Manyara regions of northern Tanzania in 2002–2003. Within five districts in these regions, a multi-stage cluster sampling strategy was used to identify and randomize the selection of villages, sub-villages, ten cell units and livestock keeping households. Data collection at the 86 selected households included blood sample collection from randomly selected sheep and goats (combined as caprids), cattle and humans. The number of cattle and/or caprids sampled at each household was based on the number required to estimate the within-herd prevalence given the size of the household herd. This was calculated for an expected prevalence of 5%, with 80% power and 95% confidence (Martin et al. Reference Martin, Meek and Willeberg1987). All humans present at the household were invited to participate in the study. Serum samples from all species were tested for antibodies against Brucella species at the Animal and Plant Health Agency (APHA) using a competitive ELISA (McGiven et al. Reference McGiven, Tucker, Perrett, Stack, Brew and MacMillan2003; Perrett et al. Reference Perrett, McGiven, Brew and Stack2010). A cut-off of 60% inhibition was used to define sample status for all species tested. This dataset is a subset of data described previously (Shirima, Reference Shirima2005; Kunda, Reference Kunda2006). Figure 2c shows the number of cattle and caprids sampled in each household and Fig. 3a shows the seroprevalence of Brucella sp. in humans, cattle and caprids in this dataset. No genetic-typing data of the Brucella species were available in this field study.

Fig. 3. Serology sampling strategy. The continuous bold line shows the relationship between the number of animals present at each household and the number sampled. The dotted line shows the number of animals that would be sampled if all animals present were sampled.

Generalized linear model (GLM) analysis

GLMs were used to examine the relationship between the seroprevalence of Brucella exposure in humans and the (crudely) estimated total numbers of seropositive cattle and caprids present at each household in the Tanzanian field dataset. A GLM was used instead of a GLMM because the inclusion of random effects (e.g. household and village) did not make a difference to the results, both in terms of significance and goodness-of-fit of the model (i.e. AIC difference was less than 2; Burnham and Anderson, Reference Burnham and Anderson2002). The response variable was the proportion of humans at the household that tested seropositive, weighted by the number of humans sampled at the household. The covariates considered were estimates for the total numbers of seropositive cattle and caprids present at each household, which were calculated by multiplying the proportion seropositive in the sample by the total population size at the household for each animal group.

Bayesian serology model

A latent model was developed to quantify the contribution of different animal hosts to human infection probability from serology data. A detailed description of this model is provided in Supplementary information (SI). In essence, the model is composed of five interlinked binomial processes: the first two binomials estimate the cattle and caprid probability of being seropositive in the sampled population, the third and fourth binomials take these inferences from the sample to estimate the number of seropositive cattle and caprids in the whole population, and the fifth binomial process uses the population inferences to estimate the contribution of seropositive animals to the probability of human infection. One of the main advantages of this modelling approach is that it allows propagation of uncertainties from the inferences of the animal samples, to those of the whole animal population and finally to humans. We note that this is not a one-way propagation as the five binomials are estimated simultaneously and inform each other.

For each host [i.e. cattle c, caprids (sheep and goats) s and humans h], a binomial model (equivalent to a Bernoulli process) is implemented to describe the observation process of each individual serology test result. The likelihood of the data from an individual being classified as seropositive was based on the serological test data and a probability of misclassification. This probability of misclassification (i.e. whether the serology assay generates false positives or negatives (further details in the SI) typically incorporates pre-existing information about the performance of the test being used. For simplicity and because there is no misclassification in the simulated data, this was always set to 0. These binomials are ultimately defined by a probability of an individual testing seropositive in a household. At the household level, these are linearized through a logit transformation and described through a linear predictor (lnSer). For humans, this linear predictor is described below. For cattle (lnSer_c) and caprids (lnSer_s) these predictors are described as a function of the number of cattle [Ncattle(i)] and caprids [Ncaprids(i)] in each household (i):

(1) $${\rm lnSer}_{\rm c} (i) = \beta _{\rm {0,c}} + \beta _{\rm {1,c}} {\rm Ncattle} (i) + \beta _{\rm {2,c}} {\rm Ncaprids} (i)$$

(2) $${\rm lnSer}_{\rm s} (i) = \beta _{\rm {0,s}} + \beta _{\rm {1,s}} {\rm Ncattle} (i) + \beta _{\rm {2,s}} {\rm Ncaprids} (i)$$

where β _0,c and β _0,s correspond to the intercepts, β _1,c and β _2,c, and β _1,s and β _2,s, correspond to the coefficients governing the effect of the number of cattle and caprids on the probability of infection in cattle and caprids, respectively. The unobserved total numbers of infected cattle and caprids per household [Y _c(i) and Y _s(i)] are then estimated through a Binomial process using the infection probability estimated from the sampled population (pSer, which corresponds to the inverse logit of the predictor lnSer) and data on the total herd/flock size at each household:

(3) $$Y_{\rm c} (i) \sim {\rm binomial}({\rm pSer}_{\rm c} (i), {\rm Ncattle}(i))$$

(4) $$Y_{\rm s} (i) \sim {\rm binomial}({\rm pSer}_{\rm s} (i), {\rm Ncaprids}(i))$$

The estimated total numbers of positive animals [Y _c(i) and Y _s(i)] are then used as covariates in the logit linear predictor [lnSer_h(i)] of the probability of human infection:

(5) $${\rm lnSer}_{\rm h} (i) = \beta _{\rm {0,h}} + \beta _{\rm{1,h}} {Y}_{\rm c} (i) + \beta _{\rm {2,h}} {Y}_{\rm s} (i)$$

where β _0,h corresponds to the intercept, β _1,h and β _2,h correspond to the coefficients governing the effect of the number of infected cattle and caprids on the probability of human infection.

Further details of the model, including the prior distributions allocated to each coefficient and the model code for implementation in JAGS, are provided in the SI.

This model only used serology data and was implemented with the field survey data to estimate the human source of infection in the northern Tanzanian setting. This serology only model was also implemented with simulated datasets (see the subsequent section) to address our specific aim 1 and explore how different epidemiological scenarios and population structures might impact on the inferences made from serological data.

Simulation of serology & genetic typing data

We simulated datasets to illustrate the three alternative epidemiological scenarios of Brucella transmission (Fig. 1) within three distinct population structures (Fig. 2). In epidemiological scenario 1, cattle were infected with B. abortus only and caprids with B. melitensis only. Humans could acquire Brucella infection from both livestock populations, but the contribution of B. melitensis-positive caprids to human infection probability was twice as large as that of B. abortus-positive cattle. See Table S3 for simulation coefficient values. In this case, genetic-typing data were simulated only for B. abortus-positive cattle and B. melitensis-positive caprids (see below for details of the sampling mechanisms used for simulations). In epidemiological scenario 2, only B. melitensis was present. Here, cattle could be exposed to infection from caprids and seroconvert but humans could only acquire infection from caprids. This illustrates a situation where cattle do not shed the pathogen and no genetic-typing data are available. In epidemiological scenario 3, only B. melitensis was present but both caprids and cattle were infected. Genetic-typing data were simulated for B. melitensis-positive cattle and caprids and the probability of obtaining typing data from seropositive individuals in these two groups was equal. In this scenario, humans acquire infection from both hosts, but the contribution of B. melitensis-positive caprids to human infection probability is twice as large as the contribution of B. melitensis-positive cattle. We note that there is no genetic-typing data for humans, and that in all simulations the only data available for humans are serological test results. Scenarios where only B. abortus is present were not included but these would be functionally equivalent to the B. melitensis only scenarios explored in scenarios 2 and 3.

Each of the epidemiological scenarios was simulated for the three distinct population structures in Fig. 2. The simulated population structures included 86 households and 428 humans (identical to the household and human numbers in the field dataset). The total size of the livestock population in each household (cattle + caprids) was also as observed in the field study, but the ratio of cattle:caprids was altered for each population structure. In population structure 1, the total animal population was divided between cattle and caprids (with a probability of 0·5 of being a cow vs caprid), leading to a strong positive correlation (measured by the Pearson's correlation coefficient, r) between cattle and caprid numbers in each household (r = 0·975). In population structure 2, there is clear segregation of the cattle and caprid populations such that each household had either 90% cattle or 90% caprids (r = 0·08). In population structure 3, the number (and ratio) of cattle and caprids in each household was as observed in the field dataset (r = 0·656).

The models and parameters used to simulate the alternative datasets are based on the serology model presented above, and its extension that includes genetic-typing data presented below. In brief, animal infection probability was simulated as function of the size of the cattle and caprid populations at the household level. Human infection probability was simulated as a function of the number of animals in each of four possible infectious populations: B. abortus infected cattle, B. abortus infected caprids, B. melitensis-infected cattle and B. melitensis-infected caprids. The parameter values used for these simulations differed for the different epidemiological scenarios and the details of the values used are given in Table S3. The plausibility of the values used for the simulated datasets was ensured by keeping the number of households, the number of human and animals per household (explained above), and the prevalence values generated within realistic values (i.e. similar to those in the field dataset). Simulated prevalence values were below 10% for cattle and caprid populations and 16% for humans.

To simulate both genetic-typing and serological data, the Brucella species-specific (B. melitensis or B. abortus) infection status (infected or not) was simulated at the individual animal level. For simplicity, all genetically positive individuals were classified as seropositive, analogous to assuming that all animal infections would lead to a detectable and lasting antibody response. This is an oversimplification that assumes that there is no misclassification in serostatus and that only seropositive animals can be genetically positive. We deal with the latter issue in the model analyses by considering such samples (genetically typed positives from seronegative individuals) as missing data. This simulation strategy also meant that all seropositive animals were positive for B. melitensis and/or B. abortus, corresponding to an assumption that the Brucella species responsible for all seropositivity could be determined in all cases. The exception to this assumption is the genetic-typing data simulated for cattle in epidemiological scenario 2. Here, all cattle test negative for B. melitensis as they constitute a dead-end host and would not shed Brucella.

As complete sampling of populations is rarely achievable in field studies, we sampled individuals from these simulated datasets using a rationale analogous to the sampling strategy used in the original field study; i.e. the sample size required to estimate prevalence of 5% with 95% confidence and 90% precision (Dohoo et al. Reference Dohoo, Martin and Stryhn2003). Figure 3 illustrates the number of animals sampled from the range of population sizes. Only the data obtained from these sampled animals were considered in the model analyses.

While the determination of the serostatus of an individual is relatively straightforward, the apparently intermittent or temporally variable nature of Brucella shedding by the infected animals (World Health Organization et al. 2006; Ebrahimi et al. Reference Ebrahimi, Milan, Mahzoonieh and Khaksar2014), the potential for animals to seroconvert and recover (to a genetically negative but seropositive status) and relatively low diagnostic sensitivity of PCR-based techniques for the direct detection of Brucella, all ensure that the genetic identity of the infecting Brucella species will only ever be obtainable for a small subset of previously infected animals. To represent the sparseness of available genetic-typing data and explore the amount of typing data required to effectively identify the host and pathogen species that pose the greatest threat to human populations, we used different proportions of the genetic-typing data available for the seropositive animals sampled, i.e. 50, 10 and 5% (e.g. for the 5% situation, genetic-typing data were only available for 5% of the seropositive animals in the sampled population).

Model extension to integrate serology with genetics

In order to integrate genetic-typing data, we extended the serology model described above to include the influence of different pathogen and animal host combinations upon the probability of human infection. In this extended model, we replace lnSer_h(i) by lnType_h(i) and define this linear predictor as:

(6) $$\eqalign{{\rm lnType}_{\rm h}(i) & = \alpha _{\rm {0,h}} + \alpha _{\rm {1,h}} {Y}_{\rm {c,a}}(i) + \alpha _{\rm {2,h}} {Y}_{\rm {s,a}}(i) \cr & \quad+ \alpha _{\rm {3,h}} {Y}_{\rm {c,m}}(i) + \alpha _{\rm {4,h}} {Y}_{\rm {s,m}}(i)}$$

where α _0,h corresponds to the intercept, α _1,h and α _2,h correspond to the coefficients governing the effect of the number of B. abortus infected cattle and caprids (Y _c,a and Y _s,a), respectively, and α _3,h and α _4,h correspond to the coefficients governing the effect of the number of B. melitensis infected cattle and caprids (Y _c,m and Y _s,m), respectively, on the probability of human infection. The main difference between the extended model and the serology only model is in the way the ‘true’ number of infected cattle and caprids in each household are estimated [i.e. four Y's from equation (6) compared with the two Y's from equation (5)]. In this extended model, the number of B. abortus and B. melitensis-infected cattle and caprids were estimated from Binomial processes in which the probability of being infected with a pathogen/host combination (pType) is weighted by the probability of the host being seropositive (pSer), which was estimated from the serology only model. It is in this step that the integration between serology and genetic-typing data occurs:

(7) $$\eqalign{{Y}_{\rm {c,a}} (i) \sim & {\rm binomial}({\rm pType}_{\rm {c,a}} (i) \cr & \times {\rm pSer}_{\rm c} (i), {\rm Ncattle}(i))}$$

(8) $$\eqalign{{Y}_{\rm {c,m}} (i) \sim & {\rm binomial}({\rm pType}_{\rm {c,m}} (i) \cr & \times {\rm pSer}_{\rm c} (i), {\rm Ncattle}(i))}$$

(9) $$\eqalign{{Y}_{\rm {s,a}} (i) \sim & {\rm binomial}({\rm pType}_{\rm {s,a}} (i) \cr & \times {\rm pSer}_{\rm s} (i), {\rm Ncaprids}(i))}$$

(10) $$\eqalign{{Y}_{\rm {s,m}} (i) \sim & {\rm binomial}({\rm pType}_{\rm {s,m}} (i) \cr & \times {\rm pSer}_{\rm s} (i), {\rm Ncaprids}(i))}$$

The remaining components of this model are equivalent to those of the serology only model. However, the probability of being genetically positive (pType) comes from the binomial likelihood of the data [e.g. for B. abortus in cattle ~binomial(pType_c,a(i), Ncattle(i))], rather than being a Bernoulli trial, as we assume that the misclassification associated with genetic typing is negligible (e.g. there are no incorrectly typed individuals by PCR-based diagnostics). This probability pType is finally linearized (lnType) through a logit transformation and described as a function of the number of animals in the household. For cattle with B. abortus [lnType_c,a(i)]:

(11) $$\eqalign{{\rm lnType}_{\rm {c,a}} (i) = & {\alpha} _{\rm {0,c,a}} + {\alpha} _{\rm {1,c,a}} {\rm Ncattle}(i) \cr & + {\alpha} _{\rm {2,c,a}} {\rm Ncaprids}(i)}$$

The parameter α _0,c,a corresponds to the intercept, α _1,c,a and α _2,c,a correspond to the coefficients governing the effect of the number of cattle and caprids in the household. Further details of the model, including the full linear predictors for the remaining sources of infection (e.g. B. abortus infected caprids, B. melitensis infected cattle and B. melitensis-infected caprids), are given in the SI.

Although the model is a stochastic one, the model formulation matches the process of data simulation. Consequently, it should allow us to retrieve the coefficient values used to generate the contributions of the different infected animal populations to the probability of human infection. In addition, to verifying that we could retrieve the coefficient values used for simulations, we further determine the goodness-of-fit by evaluating its fit to the data, confirming that we can recover the generated animal population sizes and prevalence values, and by checking convergence of the model. Further details are given in the SI.