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Prevalence of Coxiella burnetii in German sheep flocks and evaluation of a novel approach to detect an infection via preputial swabs at herd-level

Published online by Cambridge University Press:  16 March 2020

A. Wolf Open the ORCID record for A. Wolf [Opens in a new window] ,
T. L. Prüfer ,
C. Schoneberg ,
A. Campe ,
M. Runge ,
M. Ganter  and
B. U. Bauer
A. Wolf
Affiliation:
Clinic for Swine, Small Ruminants and Forensic Medicine, University of Veterinary Medicine Hannover, Foundation, Hannover, Germany
T. L. Prüfer
Affiliation:
Lower Saxony State Office for Consumer Protection and Food Safety (LAVES), Food and Veterinary Institute Braunschweig/Hannover, Hannover, Germany
C. Schoneberg
Affiliation:
Department of Biometry, Epidemiology and Information Processing, (IBEI), WHO Collaborating Centre for Research and Training for Health at the Human-Animal-Environment Interface, University of Veterinary Medicine Hannover, Foundation, Hannover, Germany
A. Campe
Affiliation:
Department of Biometry, Epidemiology and Information Processing, (IBEI), WHO Collaborating Centre for Research and Training for Health at the Human-Animal-Environment Interface, University of Veterinary Medicine Hannover, Foundation, Hannover, Germany
M. Runge
Affiliation:
Lower Saxony State Office for Consumer Protection and Food Safety (LAVES), Food and Veterinary Institute Braunschweig/Hannover, Hannover, Germany
M. Ganter*
Affiliation:
Clinic for Swine, Small Ruminants and Forensic Medicine, University of Veterinary Medicine Hannover, Foundation, Hannover, Germany
B. U. Bauer
Affiliation:
Clinic for Swine, Small Ruminants and Forensic Medicine, University of Veterinary Medicine Hannover, Foundation, Hannover, Germany
*
Author for correspondence: M. Ganter, E-mail: [email protected]
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Abstract

A prevalence study was conducted on German sheep flocks including goats if they cohabitated with sheep. In addition, a novel approach was applied to identify an infection at the herd-level before lambing season with preputial swabs, suspecting venereal transmission and ensuing colonisation of preputial mucosa with Coxiella (C.) burnetii. Blood samples and genital swabs were collected from breeding males and females after the mating season and were analysed by enzyme-linked immunosorbent assay (ELISA) and quantitative polymerase chain reaction (qPCR) respectively. In total, 3367 animals were sampled across 71 flocks. The true herd-level prevalence adjusted for misclassification probabilities of the applied diagnostic tests using the Rogan-Gladen estimator for the prevalence estimate and a formula by Lang and Reiczigel (2014) for the confidence limits, ranged between 31.3% and 33% (95% confidence interval [95% CI] 17.3–45.5) detected by the ELISA and/or qPCR. Overall 26–36.6% (95% CI 13–56.8) were detected by ELISA, 13.9% (95% CI 4.5–23.2) by the qPCR and 7.9–11.2% (95% CI 0.08–22.3) by both tests simultaneously. The range of results is due to data obtained from literature with different specifications for test quality for ELISA. Among eight farms with females shedding C. burnetii, three farms (37.5%) could also be identified by preputial swabs from breeding sires. This indicates less reliability of preputial swabs if used as a single diagnostic tool to detect C. burnetii infection at the herd-level.

Keywords

Coxiella burnetiismall ruminantssurveillancevenereal transmission
Type
Original Paper
Information
Epidemiology & Infection , Volume 148 , 2020 , e75
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2020. Published by Cambridge University Press

Introduction

Q fever is a zoonotic disease caused by the intracellular bacterium Coxiella burnetii. In many countries, ruminants are the main source of human epidemics [Reference Arricau-Bouvery and Rodolakis1]. However, other animals like cats and dogs can also be responsible for human Q fever infections [Reference Marrie2, Reference Buhariwalla, Cann and Marrie3]. Infected females can shed large amounts of the pathogen into the environment during abortion or even upon normal delivery through birth products. Moreover, the bacterium is also shed with milk, faeces and urine [Reference Angelakis and Raoult4]. In animals and humans alike, the main infection pathway is the inhalation of pathogen-contaminated aerosols [Reference Todkill, Fowler and Hawker5]. Aside from airborne dissemination of C. burnetii, sexual transmission has occasionally been reported in humans [Reference Miceli6]. Furthermore, transmission of the pathogen via sexual intercourse was demonstrated in mice [Reference Kruszewska and Tylewska-Wierzbanowska7]. Later on, C. burnetii was also detected in rams` semen [Reference Ruiz-Fons8]. Hence, in sheep, transmission during breeding could result either from direct contact between mucosa of the reproductive organs of rams and ewes or from semen containing C. burnetii. Different pathogens like Chlamydia spp. and Brucella spp. were detected in samples taken from the preputial mucosa in rams [Reference Xavier9, Reference Keplan10]. But this sampling method has rarely been used to diagnose C. burnetii infection in small ruminants [Reference Debeljak11].

Germany has a long history of C. burnetii infections. In 1947, the pathogen was first diagnosed within the context of a human outbreak in the federal state of Baden-Wuerttemberg [Reference Heni and Germer12]. Most human Q fever cases occurred in southern Germany, but reports from central and northern regions increased with occasional larger outbreaks and mainly associated with lambing sheep [Reference Porten13Reference Hellenbrand, Breuer and Petersen15]. Despite the awareness of C. burnetii infection in the German sheep population, only poor data, especially in the northern federal states, are available. Therefore, the first aim of this study was to assess the actual prevalence of C. burnetii in German sheep flocks. For this purpose, a cross-sectional study encompassing five federal states with high numbers of sheep was conducted. In addition, we hypothesised that transmission of C. burnetii occurs during sexual intercourse of small ruminants and that the pathogen may be localised in the prepuce of infected rams. Therefore, preputial swabs of breeding sires were examined after the mating season in order to substantiate this assumption. As a consequence of C. burnetii recognition at an early stage of infection, measures such as pre-lambing treatments could be performed in order to reduce abortion and shedding of the pathogen to minimise the risk for human infection. Overall, conclusive results could contribute to develop a monitoring and surveillance system (MOSS) identifying C. burnetii in small ruminant flocks.

Material and methods

Animals and sample collection

Basic data on small ruminant populations in Germany were sourced from the Genesis-Online Database of the German Federal Statistical Office from 1st March 2016 and used to calculate the number of samples [16]. Applied statistical methods for calculating the number of samples were performed according to the STROBE Statement below [Reference Sargeant and O'Connor17]. Due to reasons of time and costs a maximum of 71 herds could be investigated in the five selected federal states during the study. Considering a herd-level prevalence of 10% [Reference Runge18] and a 95% confidence interval, this resulted in a maximum precision of ±7% [PASS 16 Power Analysis and Sample Size Software (2018). NCSS, LLC. Kaysville, Utah, USA, ncss.com/software/pass].

To represent the distribution of sheep farms between the federal states, the following number of farms (calculated proportion of the federal states in the sample according to the Genesis-Online Database of the German Federal Statistical Office from 1st March 2016 [16]) were included into the study: Schleswig-Holstein 12 (16.7%), Lower Saxony 11 (13.6%), North Rhine-Westphalia 12 (16.7%), Baden-Wuerttemberg 14 (19.7%) and Bavaria 22 (33.3%). These states have the largest sheep populations within Germany. Therefore, the estimation of C. burnetii occurrence in these states is important for further risk assessments. Moreover, other federal states have smaller numbers of sheep and especially in eastern parts of Germany, examinations concerning C. burnetii infection in sheep have been conducted in recent years [Reference Hilbert19, Reference Moog, Henning and Horner20]. The participating farms were selected based on the respective owners' willingness to contribute to the study. Hence, this study was based on a convenient sampling.

The number of samples required from each flock to estimate the positivity rate independently of a clinical disease was calculated on the assumption of 3% expected prevalence [Reference Runge18], 95% confidence interval, 80% power and 5% precision. A maximum of 44 animals per herd had to be sampled. If goats were kept on the same farm, their sample size was calculated under the same assumptions, independently of the number of sheep sampled. Genital swabs (Sarstedt, Nürmbrecht, Germany) from breeding males and females in combination with blood samples (Kabe Labortechnik, Nürmbrecht-Elsenroth, Germany) were collected. Blood samples were centrifuged within 6 h of sampling. The genital swabs and serum samples were stored at −18 °C until laboratory examination. Aside from their species, the sex and the reproductive status of the females (gimmer or adult ewe) were recorded. The flocks were visited between November 2017 and June 2018, after or during the mating season when breeding sires were introduced into the flock for at least 6 weeks. Farms vaccinating against C. burnetii were excluded.

Detection methods

C. burnetii-specific DNA in the genital swabs was detected by amplificating IS1111 elements with a quantitative polymerase chain reaction (qPCR) (LSI VetMAX™Coxiella burnetii, Thermo Fisher Scientific, Germany). The manufacturer indicates Cycle Threshold (C t) values ⩽ 45 as positive and C t values > 45 as negative. A sensitivity of 95–100% and a specificity of 100% were assumed according to the manufacturers validation report from 8th December 2014.

The C. burnetii-specific antibody levels in the serum samples were determined by enzyme-linked immunosorbent assay (ELISA), detecting phase unspecific IgG antibodies (Q Fever Antibody Test Kit, IDEXX, Switzerland). The manufacturers specified samples with S/P (%) > 40 as positive, values with a percentage <30 as negative. Results with values between 30% and 40% were considered inconclusive and were scored as negative in the present study. A sensitivity of 70.1%, 84% and 98.6% and a specificity of 96.2%, 99% and 97.1% were assumed according to Muleme et al., Paul et al. and Horigan et al. [Reference Muleme21Reference Horigan23], taking into account that data were provided under different study designs and for different species.

Statistical analysis

Occurrence of C. burnetii in German sheep flocks

Both diagnostic tests (ELISA and qPCR) were considered for the estimation of herd-level prevalence and the proportion of C. burnetii infected adults within the farms. The results were divided into the following test combinations: ELISA+, qPCR+, ELISA and qPCR+, ELISA and/or qPCR+. After sampling on the selected farms, the selections were checked to determine whether the sample survey was representative. For all calculations, we used the statistical software SAS (SAS Institute Inc., Cary, NC, USA).

Herd-level prevalence

A farm was considered positive if at least one sampled animal yielded a positive test result. The herd-level prevalence was assessed across the five selected federal states. To determine the true herd-level prevalence, the apparent prevalence was corrected for misclassification probabilities (sensitivity and specificity of the diagnostic tests) using the Rogan-Gladen estimator [Reference Rogan and Gladen24] for the prevalence estimate and a formula by Lang and Reiczigel for the confidence limits [Reference Lang and Reiczigel25]. Although not substantiated by the sample size, the results were analysed for a possible impact of federal state and management systems of the farm on the occurrence of C. burnetii.

Proportion of C. burnetii infected adults within the farms

An animal was considered positive if at least qPCR or ELISA presented a positive test result. The results for the proportion of infected adults within the farms were corrected for misclassification probabilities as well.

Results

Occurrence of C. burnetii in German sheep flocks

Samples from 3367 animals (2920 sheep and 447 goats) belonging to 71 flocks (41 sheep and 30 mixed flocks) were examined (Fig. 1). The included federal states have the highest number of sheep within Germany and represent 61.3% (1 123 877/1 834 275) of the entire German sheep population [16]. The distribution of the examined farms in the federal states was compared to calculated data sourced from the Federal Statistical Office for total numbers of farms in each federal state. Bavaria is slightly underrepresented (31%) and Lower Saxony overrepresented (15.5%). In addition, we verified whether the ratio of pure sheep farms (57.8%) to mixed sheep and goat farms (42.3%) in the present survey corresponds to the actual distribution within federal states. The proportion of mixed farms is overrepresented comparing the data from the State Statistical Office of Lower Saxony for sheep farms (80.9%) and for mixed farms (19.1%) [26]. This bias must be taken into account when interpreting the results.

Fig. 1. Distribution of the 71 sampled farms in the five selected German federal states. Districts with grey background indicating location of the participating farms. Federal states: SH = Schleswig-Holstein; LS = Lower Saxony; NRW = North Rhine-Westphalia; BAV = Bavaria; BW = Baden-Wuerttemberg.

Herd-level prevalence

Overall, the apparent prevalence of C. burnetii infections (ELISA and/or qPCR) at the herd-level was 33.8% (n = 24) (Table 1). The true herd-level prevalence adjusted for misclassification probabilities of the applied diagnostic tests using the Rogan-Gladen estimator for the prevalence estimate [Reference Rogan and Gladen24] and a formula by Lang and Reiczigel for the confidence limits [Reference Lang and Reiczigel25] is presented in Table 2. Assuming the test quality according to Muleme et al. [Reference Muleme21], the true herd-level prevalence was 31.3%, according to Paul et al. [Reference Paul22] or Horigan et al. [Reference Horigan23], the true prevalence results in 33% and 31.4% respectively.

Table 1. Percentage of C. burnetii positive farms by federal state and apparent herd-level prevalence of all examined farms (for four different definitions of positive herd status)

Federal states: SH = Schleswig-Holstein; LS = Lower Saxony; NRW = North Rhine-Westphalia; BAV = Bavaria; BW = Baden-Wuerttemberg.

Table 2. True herd-level prevalence of all examined farms adjusted for sensitivity and specificity of the applied test systems ELISA and qPCR (for four different definitions of positive herd status) according to the literature with reliable estimation for test quality for ELISA and the manufacturer`s validation report for the qPCR

Federal states

The southern states Bavaria (31.8%; 7/22) and Baden-Wuerttemberg (78.6%; 11/14) had the highest proportion of positive farms with Baden-Wuerttemberg on the top of all states (Table 1). Overall, positive farms were detected more by serology (83.3%; 20/24) than with the qPCR technique (41.7%; 10/24).

Flock type

The proportion of mixed flocks (sheep and goats) and sheep flocks within positive farms is shown in Figure 2.

Fig. 2. Numbers of C. burnetii positive and negative farms by farm type (farms keeping only sheep and farms keeping sheep and goats). Federal states: SH = Schleswig-Holstein; LS = Lower Saxony; NRW = North Rhine-Westphalia; BAV = Bavaria; BW = Baden-Wuerttemberg.

Proportion of C. burnetii infected adults within positive farms

The apparent proportion of C. burnetii infected adults within the positive farms is shown in Figure 3. The true mean proportion of infected adults detected by ELISA was 13% (95% CI 3–22) among 12 positive farms, 9% (95% CI 3–14) among 20 farms and 8% (95% CI 2–13) among 15 farms according to test quality specifications by Muleme et al., Paul et al. and Horigan et al. respectively [Reference Muleme21Reference Horigan23]. Within 10 positive farms, 18% (95% CI 0–39) were detected by the qPCR. The mean proportion was 37% (95% CI 0–100) (Muleme et al.), 31% (95% CI 0–100) (Paul et al.) and 26% (95% CI 0–100) (Horigan et al.) among two positive farms detected by ELISA and qPCR simultaneously [Reference Muleme21Reference Horigan23]. Overall, the true mean proportion of C. burnetii infected adults within the positive farms was 12% (95% CI 1–22), 11% (95% CI 3–20) and 12% (95% CI 2–22) within 19, 24 and 20 positive farms detected by the ELISA and/or qPCR.

Fig. 3. The apparent proportion of C. burnetii infected adults within the positive farms. Number in brackets = farms tested positive on the individual animal level of infection status. Infection status on the individual animal level acquired by four different definitions according to PCR and ELISA test results.

Evaluation of preputial swabs as detection matrix for an infection with C. burnetii at herd-level

C. burnetii was detected in preputial swabs obtained from sires of five (7%) out of 71 examined farms. This corresponds to 50% of the qPCR positive farms (n = 10). On these five farms, females were detected as positive either by the qPCR (vaginal swabs) (n = 2), or ELISA (n = 2), or with both detection methods (n = 1) (Table 3). Within three of the five positive farms, in which C. burnetii was detected with vaginal and preputial swabs by the qPCR simultaneously, the females presented C tvalues from 11 to 42 with the qPCR and the proportion of infected adults presented a range between 10.4% and 97.4% (median = 15%). The C tvalues and the proportion of infected adults within the five farms detected by the qPCR exclusively with vaginal swabs presented a range between 34 and 42 and 1.3% to 18.5% (median = 15.6%) respectively.

Table 3. Distribution of percentage and number of the 24 positive farms based on sex and test system ELISA and qPCR (for four different definitions of positive herd status)

Discussion

Occurrence of C. burnetii in German sheep flocks

In this study, the occurrence of C. burnetii was determined in 71 farms located in five federal states of Germany. First of all, the results obtained depended on the selection of the farms/animals and the test systems used (ELISA and qPCR). According to Greiner and Gardener [Reference Greiner and Gardner27], the variability of the results is caused by the sampling strategy and the estimates for the diagnostic sensitivity and specificity may vary among populations and/or subpopulations of animals. The results in this study provide an estimation of the actual distribution of C. burnetii in small ruminant populations within the five federal states. The selection of other farms and animals may lead to different results. It has to be taken into account that we investigated a convenient sample, which was obviously biased as compared to the target population. This could be shown regarding the ratio of pure sheep and mixed farms, at least. Hence, the prevalence estimations presented here, have to be handled cautiously when generalising the results of this study. Nevertheless, this study is the first nationwide approach to estimate the herd- and intra-herd prevalence in Germany. In addition, the results depended on misclassification probabilities of the test systems (ELISA and qPCR) used. To determine the true prevalence in this particular population study, a latent class analysis could be performed. This method has the advantage of estimating the true prevalence and the misclassification errors simultaneously [Reference Rindskopf and Rindskopf28]. However, to run a latent class analysis, there are at least three different tests needed, which test the same infection status. This was not feasible in this study.

Herd-level prevalence

In this study, most of the positive farms were only seropositive. This indicates that they had contact with C. burnetii, e.g. due to previous infection. The number of farms detected by the qPCR was much lower, probably because shedding of the pathogen occurred mainly during parturition and sampling took place before the lambing season started [Reference Angelakis and Raoult4]. In general, shedding before parturition does not occur [Reference Roest29]. However, some authors postulated a possible intermitting shedding of C. burnetii especially during oestrus [Reference van den Brom30, Reference Villari, G, Arnone, Alfano, Geraci and Chiarenza31]. This can lead to misidentification of infected animals, but this assumption has to be investigated in future studies. The smallest percentage of the examined farms revealed positive results by the ELISA and qPCR simultaneously, which showed that the presence of C. burnetii did not lead inevitably to the production of detectable antibody activities and at the same time seropositivity did not prove the presence of the pathogen [Reference Joulié32]. Some females shedding C. burnetii never seroconvert [Reference Berri33].

Federal states

The proportion of infected farms and animals between the federal states seems to be different and some regions may be endemically infected with C. burnetii. This assumption would lead to a regionally adapted MOSS. Different breeding and management systems might explain the different occurrences of C. burnetii in distinct parts of Germany. In southern Germany, the main breed is Merino Landrace, which lambs all year-round, including periods in the summer when conditions for the survival and aerogenic transmission of C. burnetii are favourable. By contrast, aerogenic transmission of C. burnetii seems to be less likely in northern parts of Germany where sheep have a seasonal breeding behaviour and indoor lambing in spring is common due to the cold and humid weather conditions in this region. Therefore, transmission seems to be less likely in this area. Overall, risk factors should be identified in future studies to elucidate the difference of C. burnetii infection between northern and southern Germany.

Flock type

Several studies were conducted to determine the prevalence in sheep and goat flocks [Reference Hilbert19, Reference Moog, Henning and Horner20]. Less attention was paid to mixed sheep and goat flocks. In the present study more mixed flocks tested positive than flocks where only sheep were kept. However, the number of mixed flocks is overrepresented in the present study and most of the mixed flocks are located in southern Germany. This area is known for their endemic C. burnetii infections in small ruminants [Reference Hellenbrand, Breuer and Petersen15, Reference Sting34]. Nevertheless, Anastácio et al. [Reference Anastácio35] made a similar observation in Portugal. The seroprevalence in mixed flocks (38.5%; 95% CI 12–65) was slightly higher than in sheep flocks (37.5%; 95% CI 21–54). Later, Rizzo et al. [Reference Rizzo36] also reported a higher prevalence in Italian mixed flocks (48.5%; 95% CI 34.7–62.3) compared to sheep flocks (38.7%; 95% CI 25.5–51.9). Under the same management conditions, goats seem to be more susceptible for C. burnetii. This increases the risk for sheep situated near to goats to get infected [Reference Lambton37].

Proportion of infected adults within positive flocks

The proportion of adults shedding C. burnetii within positive flocks is higher than the proportion of seropositive animals, probably due to sampling before detectable antibodies were available during acute infection or as described above, the absence of antibodies despite the presence of the pathogen [Reference Joulié32]. Another reason could be the detection method used in this study. The sensitivity/specificity is higher for the qPCR (95–100%/100%) in comparison with the ELISA (70.1–98.6%/96.2–99%) [Reference Muleme21Reference Horigan23]. This may lead to a sensitive detection of adults shedding C. burnetii by the qPCR, while the detection of positive animals by ELISA may be lower due to misclassification probabilities. One farm in this study achieved a proportion of 97% infected animals within the flock and most of the animals showed positive results in ELISA and qPCR respectively. In this case, abortion and stillbirths were reported in the subsequent lambing season, which suggests an acute infection.

Evaluation of preputial swabs as detection matrix for an infection with C. burnetii at herd-level

To the authors' knowledge, our study is the first attempt to monitor small ruminant flocks using preputial swabs after the mating season, in order to identify C. burnetii positive flocks before the main shedding at lambing occurs. Despite the shedding and detection of C. burnetii, which usually takes part through parturition [Reference Angelakis and Raoult4], we detected females shedding C. burnetii before the lambing season started. This indicates that the detection of C. burnetii DNA before parturition is possible according to Alsaleh et al. [Reference Alsaleh38], who detected the pathogen in flushing media from oviduct and uteri of non-pregnant goats. Furthermore, C. burnetii DNA was also detected in specimens from other non-pregnant animals, e.g. cats and hares [Reference Gonzalez-Barrio39, Reference Cairns, Brewer and Lappin40]. In this study, C. burnetii was found on five farms with preputial swabs by the qPCR. Interestingly, at an individual animal level, the eleven affected rams were serologically negative even in flocks with a high proportion of infected adults. In contrast, in five other flocks, six males were seropositive but the preputial swabs were negative. There seems to be no correlation between serological ELISA results and the presence of C. burnetii DNA on preputial mucosa. This indicates that the presence of C. burnetii does not lead inevitably to the production of detectable antibodies and vice versa [Reference Joulié32]. Nevertheless, it should be noted that intra-preputial inoculation of pathogens (e.g. Brucella ovis, Chlamydia spp.) under experimental conditions lead to a detectable immune response [Reference Halbert41, Reference Chin and Plant42]. Moreover, these rams are probably not infected but their prepuce got contaminated with C. burnetii by mating infected females.

Among eight farms in which females were shedding the pathogen, three farms (37.5%) were also detected with preputial swabs by the qPCR. Within these three farms C. burnetii was detected by vaginal and preputial swabs by the qPCR simultaneously, the C t values seemed to be lower and the proportion of infected adults to be higher than in those farms in which only vaginal swabs yielded positive results. Although these findings were not significant, the status of infection and the intra-herd prevalence may have an influence on the success for the detection of the pathogen with preputial swabs. The results indicate that preputial swabs are less reliable as a single detection matrix at the herd-level. However, further research is necessary to evaluate the epidemiological role of breeding sires and the applicability of preputial swabs for a MOSS at the herd-level. The question of sexual transmission of C. burnetii within small ruminants and the duration of colonisation on the preputial mucosa remains to be determined. In addition, the influence of duration and timing of the mating season, as well as the number of rams per ewes should be studied.

In conclusion, this study generated new data about the occurrence of C. burnetii in small ruminant flocks in Germany. The risk for an infection in sheep flocks may well depend on the farm location and the presence of goats on the farm. Further investigations are needed to clarify the risk factors for small ruminant flocks in Germany to acquire C. burnetii infection.

Financial support

This work was funded by the Federal Ministry of Education and Research (BMBF) under grant number 01KI1726B as part of the Zoonotic Infectious Diseases Research Network.

Conflict of interest

None.

References

Arricau-Bouvery, N and Rodolakis, A (2005) Is Q fever an emerging or re-emerging zoonosis? Veterinary Research 36, 327349.CrossRefGoogle ScholarPubMed
Marrie, TJ et al. (1988) Exposure to parturient cats: a risk factor for acquisition of Q fever in Maritime Canada. The Journal of Infectious Diseases 158, 101108.CrossRefGoogle ScholarPubMed
Buhariwalla, F, Cann, B and Marrie, TJ (1996) A dog-related outbreak of Q fever. Clinical Infectious Disease 23, 753755.CrossRefGoogle ScholarPubMed
Angelakis, E and Raoult, D (2010) Q fever. Veterinary Microbiology 140, 297309.CrossRefGoogle ScholarPubMed
Todkill, D, Fowler, T and Hawker, JI (2018) Estimating the incubation period of acute Q fever, a systematic review. Epidemiology and Infection 146, 665672.CrossRefGoogle ScholarPubMed
Miceli, MH et al. (2010) A case of person-to-person transmission of Q fever from an active duty serviceman to his spouse. Vector Borne and Zoonotic Diseases 10, 539541.CrossRefGoogle ScholarPubMed
Kruszewska, D and Tylewska-Wierzbanowska, SK (1993) Coxiella burnetii penetration into the reproductive system of male mice, promoting sexual transmission of infection. Infection and Immunity 61, 41884195.CrossRefGoogle ScholarPubMed
Ruiz-Fons, F et al. (2014) Infectious pathogens potentially transmitted by semen of the black variety of the Manchega sheep breed: health constraints for conservation purposes. Animal Reproduction Science 149, 152157.CrossRefGoogle ScholarPubMed
Xavier, MN et al. (2010) Development and evaluation of a species-specific PCR assay for the detection of Brucella ovis infection in rams. Veterinary Microbiology 145, 158164.CrossRefGoogle ScholarPubMed
Keplan, N (2009) The effect of natural mating on the bacterial pollution in the endogenous ram. Al-Anbar Journal of Veterinary Science 2, 3135.Google Scholar
Debeljak, Z et al. (2018) Clinical, epidemiological and epizootic features of a Q fever outbreak in the border region between Serbia and Montenegro. The Journal of Infection in Developing Countries 12, 290296.CrossRefGoogle Scholar
Heni, E and Germer, WD (1948) Q(ueensland)-Fieber in Deutschland. Deutsche Medizinische Wochenschrift 73, 472476.CrossRefGoogle Scholar
Porten, K et al. (2006) A super-spreading ewe infects hundreds with Q fever at a farmers' market in Germany. BMC Infectious Diseases 6, 147.CrossRefGoogle Scholar
Gilsdorf, A et al. (2008) Large Q fever outbreak due to sheep farming near residential areas, Germany, 2005. Epidemiology and Infection 136, 10841087.CrossRefGoogle ScholarPubMed
Hellenbrand, W, Breuer, T and Petersen, L (2001) Changing epidemiology of Q fever in Germany, 1947–1999. Emerging Infectious Diseases 7, 789796.CrossRefGoogle Scholar
DESTATIS (2016) Viehhaltung der Betriebe-Fachserie 3 Reihe 2.1.3–2016. Landwirtschaftliche Betriebe mit Schafhaltung und Schafbestand am 1. März 2016 nach regionaler Einheit. (https://www.destatis.de/DE/Themen/Branchen-Unternehmen/Landwirtschaft-Forstwirtschaft-Fischerei/Tiere-Tierische-Erzeugung/_inhalt.html#sprg239762) dl-de/by-2-0 (https://www.govdata.de/dl-de/by-2-0). (Accessed 14 January 2017). Own calculation.Google Scholar
Sargeant, JM and O'Connor, AM (2014) Issues of reporting in observational studies in veterinary medicine. Preventive Veterinary Medicine 113, 323330.CrossRefGoogle ScholarPubMed
Runge, M et al. (2012) Investigations concerning the prevalence of Coxiella burnetii and Chlamydia abortus in sheep in correlation with management systems and abortion rate in Lower Saxony in 2004. Berliner und Münchener Tierärztliche Wochenschrift 125, 138143.Google ScholarPubMed
Hilbert, A et al. (2012) Prevalence of Coxiella burnetii in clinically healthy German sheep flocks. BMC Research Notes 5, 152.CrossRefGoogle ScholarPubMed
Moog, U, Henning, K and Horner, S (2016) Q-fever-vaccination and surveillance in Thuringea. on a conference: Annual European College of Small Ruminant Health Management in Freiburg, Germany.Google Scholar
Muleme, M et al. (2016) Bayesian validation of the indirect immunofluorescence assay and its superiority to the enzyme-linked immunosorbent assay and the complement fixation test for detecting antibodies against Coxiella burnetii in goat serum. Clinical and Vaccine Immunology 23, 507514.CrossRefGoogle ScholarPubMed
Paul, S et al. (2013) Bayesian Estimation of sensitivity and specificity of Coxiella burnetii antibody ELISA tests in bovine blood and milk. Preventive Veterinary Medicine 109, 258263.CrossRefGoogle ScholarPubMed
Horigan, MW et al. (2011) Q fever diagnosis in domestic ruminants: comparison between complement fixation and commercial enzyme-linked immunosorbent assays. Journal of Veterinary Diagnostic Investigation 23, 924931.CrossRefGoogle ScholarPubMed
Rogan, WJ and Gladen, B (1978) Estimating prevalence from the results of a screening test. American Journal of Epidemiology 107, 7176.CrossRefGoogle ScholarPubMed
Lang, Z and Reiczigel, J (2014) Confidence limits for prevalence of disease adjusted for estimated sensitivity and specificity. Preventive Veterinary Medicine 113, 1322.CrossRefGoogle ScholarPubMed
State Statistical Office of Lower Saxony (2016) Agrarstrukturerhebung, Landwirtschaftliche Betriebe mit Schaf- und Ziegenhaltung am 01. März 2016 nach Tierarten und Bundesländern. (Accessed 17 January 2017) Own calculation.Google Scholar
Greiner, M and Gardner, IA (2000) Epidemiologic issues in the validation of veterinary diagnostic tests. Preventive Veterinary Medicine 45, 322.CrossRefGoogle ScholarPubMed
Rindskopf, D and Rindskopf, W (1986) The value of latent class analysis in medical diagnosis. Statistics in Medicine 5, 2127.CrossRefGoogle ScholarPubMed
Roest, HIJ et al. (2013) Q fever in pregnant goats: humoral and cellular immune responses. Veterinary Research 44, 67.CrossRefGoogle ScholarPubMed
van den Brom, R et al. (2013) Detection of Coxiella burnetii in the bulk tank milk from a farm with vaccinated goats, by using a specific PCR technique. Small Ruminant Research 110, 150154.CrossRefGoogle Scholar
Villari, S, G, P, Arnone, M, Alfano, M, Geraci, F and Chiarenza, G (2018) Seroprevalence of Coxiella burnetii infection (Q fever) in sheep farms located in Sicily (Southern Italy) and related risk factors. Small Ruminant Research 164, 8286.CrossRefGoogle Scholar
Joulié, A et al. (2017) Coxiella burnetii circulation in a naturally infected flock of sheep: individual follow-up of antibodies in serum and milk. Applied and Environmental Microbiology 83, e00222-17. Published online: 16 June 2017. doi: 10.1128/AEM.00222-17CrossRefGoogle Scholar
Berri, M et al. (2001) Relationships between the shedding of Coxiella burnetii, clinical signs and serological responses of 34 sheep. The Veterinary Record 148, 502505.CrossRefGoogle ScholarPubMed
Sting, R et al. (2004) The occurrence of Coxiella burnetii in sheep and ticks of the genus Dermacentor in Baden-Wuerttemberg. Deutsche Tierärztliche Wochenschrift 111, 390394.Google ScholarPubMed
Anastácio, S et al. (2013) Serological evidence of exposure to Coxiella burnetii in sheep and goats in central Portugal. Veterinary Microbiology 167, 500505.CrossRefGoogle ScholarPubMed
Rizzo, F et al. (2016) Q fever seroprevalence and risk factors in sheep and goats in northwest Italy. Preventive Veterinary Medicine 130, 1017.CrossRefGoogle ScholarPubMed
Lambton, SL et al. (2016) Serological survey using ELISA to determine the prevalence of Coxiella burnetii infection (Q fever) in sheep and goats in Great Britain. Epidemiology and Infection 144, 1924.CrossRefGoogle ScholarPubMed
Alsaleh, A et al. (2011) Detection of Coxiella burnetii, the agent of Q fever, in oviducts and uterine flushing media and in genital tract tissues of the non-pregnant goat. Comparative Immunology, Microbiology and Infectious Diseases 34, 355360.CrossRefGoogle ScholarPubMed
Gonzalez-Barrio, D et al. (2015) European rabbits as reservoir for Coxiella burnetii. Emerging Infectious Diseases 21, 10551058.CrossRefGoogle ScholarPubMed
Cairns, K, Brewer, M and Lappin, MR (2007) Prevalence of Coxiella burnetii DNA in vaginal and uterine samples from healthy cats of north-central Colorado. Journal of Feline Medicine and Surgery 9, 196201.CrossRefGoogle ScholarPubMed
Halbert, GW (1998) Evaluation of acute and chronic infection with Chlamydia psittaci in ewes and a model for veneral infection of rams (thesis). Guelph, Canada: University of Guelph; 138 pp.Google Scholar
Chin, JC and Plant, JW (1989) Temporal ELISA response of rams to Brucella ovis following experimental infection or vaccination. Research of Veterinary Science 46, 7378.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Distribution of the 71 sampled farms in the five selected German federal states. Districts with grey background indicating location of the participating farms. Federal states: SH = Schleswig-Holstein; LS = Lower Saxony; NRW = North Rhine-Westphalia; BAV = Bavaria; BW = Baden-Wuerttemberg.

Figure 1

Table 1. Percentage of C. burnetii positive farms by federal state and apparent herd-level prevalence of all examined farms (for four different definitions of positive herd status)

Figure 2

Table 2. True herd-level prevalence of all examined farms adjusted for sensitivity and specificity of the applied test systems ELISA and qPCR (for four different definitions of positive herd status) according to the literature with reliable estimation for test quality for ELISA and the manufacturer`s validation report for the qPCR

Figure 3

Fig. 2. Numbers of C. burnetii positive and negative farms by farm type (farms keeping only sheep and farms keeping sheep and goats). Federal states: SH = Schleswig-Holstein; LS = Lower Saxony; NRW = North Rhine-Westphalia; BAV = Bavaria; BW = Baden-Wuerttemberg.

Figure 4

Fig. 3. The apparent proportion of C. burnetii infected adults within the positive farms. Number in brackets = farms tested positive on the individual animal level of infection status. Infection status on the individual animal level acquired by four different definitions according to PCR and ELISA test results.

Figure 5

Table 3. Distribution of percentage and number of the 24 positive farms based on sex and test system ELISA and qPCR (for four different definitions of positive herd status)