- Research article
- Open Access
Mycoplasma detection by triplex real-time PCR in bronchoalveolar lavage fluid from bovine respiratory disease complex cases
BMC Veterinary Research volume 13, Article number: 97 (2017)
In this study we evaluated the RespoCheck Mycoplasma triplex real-time PCR for the detection in bronchoalveolar lavage fluid (BALF) of Mycoplasma (M.) dispar, M. bovis and M. bovirhinis, all three associated with bovine respiratory disease (BRD). Primers and probes of the RespoCheck Mycoplasma triplex real-time PCR are based on the V3/V4 region of the 16S rRNA gene of the three Mycoplasma species.
The analytical sensitivity of the RespoCheck triplex real-time PCR was, as determined by spiking experiments of the Mycoplasma strains in Phosphate Buffered Saline, 300 colony forming units (cfu)/mL for M. dispar, and 30 cfu/mL for M. bovis or M. bovirhinis. The analytical sensitivity of the RespoCheck Mycoplasma triplex real-time PCRwas, as determined on purified DNA, 10 fg DNA per assay for M. dispar and 100 fg fo rM. bovis and M. bovirhinis. The analytical specificity of the RespoCheck Mycoplasma triplex real-time PCR was, as determined by testing Mycoplasmas strains (n = 17) and other bacterial strains (n = 107), 100, 98.2 and 99.1% for M. bovis, M. dispar and M. bovirhinis respectively. The RespoCheck Mycoplasma triplex real-time PCR was compared with the PCR/DGGE analysis for M. bovis, M. dispar and M. bovirhinis respectively by testing 44 BALF samples from calves.
In conclusion, the RespoCheck PCR assay can be a valuable tool for timely and accurate detection of three Mycoplasma species associated with in bovine respiratory disease.
Bovine respiratory disease complex (BRDC) is a global problem causing severe economic losses to the cattle farming industry through mortality, loss of production, and treatment costs [1, 2]. It has a complex etiology that involves various pathogens, host factors, and environmental factors. Viruses such as bovine herpes 1 virus (BoHV-1, parainfluenza virus 3 (PBIV-3), bovine respiratory syncytial Virus (BRSV), respiratory bovine coronavirus (BoCoV) and bovine viral diarrhoea virus (BVDV) in conjunction with stress factors have been implicated as causes of respiratory tract infections of cattle by immunosuppression and damage to the respiratory epithelium . A primary viral infection can be followed by an opportunistic secondary infection with bacteria like Mannheimia haemolytica, Pasteurella multocida, Histophilus somni, or Trueperella pyogenes [2, 4, 5], but these bacteria could also act as primary pathogen. In addition it has become increasingly clear that Mycoplasmas are important contributors to BRD, either as primary pathogens or in co-infection [2, 6–9]. M. bovis is the best known Mycoplasma species causing respiratory disease [4, 7], but also M. dispar and M. bovirhinis have been associated with BRD [2, 9–11]. M. bovis has not only been identified as a primary or opportunistic pathogen in BRD in beef cattle worldwide, but it has also been implicated in other clinical manifestations in cattle, such as mastitis, otitis, arthritis, and reproductive disorders . M. bovirhinis and M. dispar are regularly isolated from the nasal cavity of cattle with respiratory disease and are usually regarded as an opportunistic pathogen in respiratory diseases [7, 12].
Bacteriological, serological and histopathological examinations are important tools to detect particular animal-carriers of Mycoplasma , however, these assays are time-consuming, insensitive and can give false positive results. Bronchoalveolar lavage fluid (BALF) from calves with BRD may contain various potential pathogens, but additional antibiotic use in the affected herds can inhibit cultivation and thereby can cause false-negative test results. In BRD, differential diagnosis of these pathogens with rapid turnaround time procedure is essential to implement appropriate treatment and intervention measures in a timely manner. Rapid detection of these pathogens at the early stage of outbreak can contribute substantially to minimize the spread of infection and increase treatment efficiency. Today quick, highly sensitive and species-specific PCRs are used in the diagnosis of Mycoplasma-associated diseases for M. dispar [14, 15], M. bovis [4, 16] and M. bovirhinis  in BALF or nasal swabs. Combining a 16S Ribosomal DNA PCR with denaturing gradient gel electrophoresis fingerprinting (PCR/DGGE) enabled the simultaneous detection of mixed Mycoplasma populations, however information about the detection limit in clinical samples is limited . Additionally, a DNA microarray assay was developed for the parallel detection of 37 Mycoplasma species , in which species-specific probes derived from the 23S rRNA and tuf genes were used for species differentiation.
Multiplex real-time PCR could be a promising and practical approach to speed up the differential diagnosis from 1 to 2 weeks for traditional culture to 24 h, with limited expenses. This will make diagnostic testing more accessible for veterinary practitioners and thereby improve BRD diagnosis. This report describes the RespoCheck triplex PCR developed by Central Veterinary Institute (CVI, Lelystad, The Netherlands) for detection of three Mycoplasma species.
Strains and growth conditions
M. bovis (ATCC 25025) and M. bovirhinis (ATCC 5189985) were purchased from the ATCC (United Kingdom (U.K.), Guernsey, Ireland, Jersey and Liechtenstein) and cultured in Heart Infusion Broth Medium (Difco, Detroit, Mich.). All isolates were grown at 37 °C and 5% CO2 for seven days in a modified standard mycoplasma broth medium  containing 19 g of Heart Infusion Broth, 50 mL of liquid yeast extract (10% [vol/vol]; Oxoid, London, United Kingdom), 2 × 106 U of penicillin G (Hoechst, Frankfurt, Germany), and 200 mL of heat-inactivated (56 °C, 30 min) horse serum per liter. Stocks of each isolate were prepared by freezing 1 mL portions of a 10 mL logarithmic-phase broth culture with 15% glycerol at −80 °C. Cultures were titrated on Heart Infusion Agar and were shown to contain 7 × 106 cfu/mL for M. bovis and 4 × 105 cfu/mL for M. bovirhinis. M. dispar NCTC 10125) was provided by Helena Windsor (Mycoplasma Experience LTD, Bletchingley, UK) with a titre of 1.6 × 107 cfu/mL. In addition, DNA from 14 Mycoplasma strains (Table 1) were provided by Prof. Konrad Sachse (Friedrich-Loeffler-Institut, Federal Research Institute for Animal Health, Bundesforschungsinstitut für Tiergesundheit, Jena, Germany).
Hundred and seven bacterial isolates, representing 39 different species, were used to evaluate of specificity of the RespoCheck Mycoplasma triplex real-time PCR assay (Table 2). These included isolates associated with BRD and isolates associated with other bovine diseases. Prior to testing by PCR, the identity of the isolates was confirmed using MALDI-TOF mass spectrometry (MS Bruker MALDI Biotyper Microflex, version 3.1 with the reference database version 3.1.66 Bruker Daltonics GmbH, Germany).
Field samples and isolation of DNA
Calves (n = 44) with or without BRD (increased respiratory rate and/or dyspnoea) were sampled for diagnostic purposes. Sampling of the calves was granted an exemption from requiring ethics approval by the institutional Animal Experiment Commission “Dier Experimenten Commissie (DEC) Lelystad (2013111.b)” because sampling was performed for diagnostic purposes. BAL samples were obtained as described . Approximately 35–75 ml BAL was obtained from each calf after instillation of 100 ml PBS with 10% Fetal Calf serum (FCS). Foam, large purulent exudates and blood clots were removed from the BALF samples under aseptic conditions. BALF (25 mL) was centrifuged (4600×g, 10 min, 4 °C). Sediment was resuspended in 0.5 mL Dulbecco’s minimal essential medium (DMEM) with 5% FCS, carefully added to 1 mL freeze medium (DMEM, 50% FCS and 20% DMSO) and frozen at −80 °C. The BALF supernatants were also stored at −80 °C.
For testing the influence of centrifugation of BALF samples (4600×g, 10 min, 4 °C) on the PCR results we tested three variants of BALF samples: without centrifugation, supernatant and pellet obtained after centrifugation (50 times concentrated). DNA was extracted from 200 μL aliquots of BALF samples. We used the MagNA Pure LC Total Nucleic Acid Isolation Kit (Roche Applied Science), with the Total NA External_lysis” protocol (Version 2.11). With the MagNA Pure LC Total Nucleic Acid Isolation Kit) 32 samples can processed per run. In all runs a positive control (a mix of 1.4 × 106 cfu/mL M. bovis, 0.5 × 107 cfu/mL M dispar and 1.3 × 105 cfu/mL M. bovirhinis) and a negative water control (NTC) was included.
RespoCheck primers and probes
To enable testing of testing for BRD associated pathogens in a routine setting, real-time PCRs for detection of viral, bacterial and mycoplasma pathogens in bronchoalveolar lavage fluid (BALF) of calves have been set up by the Central Veterinary Institute (Lelystad, The Netherlands) under the name RespoCheck. Primers and probes specific for the bacterial 16S, V3 and V4 regions were based on the Full length, bacterial 16S sequences (50,000 in July 2012) were used from the nuccore database at the National Center for Biotechnology Information (NCBI, USA, http://0-www.ncbi.nlm.nih.gov.brum.beds.ac.uk/nuccore). For M. bovirhinis and M. dispar the nearly full length 16S sequences were used. These sequences and their taxonomic information were used to build an Insignia-based database  from which pathogen-specific sequence regions were extracted with special interest for the V3 and V4 region because these sequences are often targeted for metagenomic next-generation sequencing (NGS) . Using the identified regions, primers and probes were designed with AlleleID 7.8. (Premier Biosoft, palo Alto, USA). The resulting triplex PCR was designated RespoCheck Mycoplasma triplex real-time PCR The specificity of the Mycoplasma primers and probes was also verified against V3-V4 partial sequences of M. flocculare, M. ovipneumonia and M. hyopneumonia.
RespoCheck triplex and single real-time PCR
The QuantiFast triplex Kit Real Time-PCR kit (Qiagen) was used for the RespoCheck Mycoplasma triplex real-time PCR. The assays were conducted in a 20 μl reaction mix containing 5 μl of the nucleic acid sample, 250 nM of each primer, 100 nM of each MGB probe, 1× QuantiFast triplex Real Time-PCR Master Mix and sterile deionised water. All reactions were conducted with an ABI-7500 with the following cycling parameters: 95 °C for 15 min, followed by 40 cycles of 94 °C for 15 s and 60 °C for 60 s. The machine was set to acquire fluorescence on the FAM, VIC, and NED channels for respectively M. bovis, M. dispar and M. bovirhinis All primers and probes were obtained from Life Technologies Europe BV (Bleiswijk, the Netherlands). The final results were analysed using ABI-7500 software (Version 1.4). Samples with a Ct of 40 cycles or less were considered to be positive.
Evaluation of the analytical sensitivity and the analytical specificity
The analytical sensitivity of the RespoCheck triplex PCR was defined as the ability to detect the lowest concentration of M. bovis, M. dispar and M. bovirhinis expressed as a concentration (cfu/mL) . The analytical sensitivity of the single and triplex PCRs for M. bovis, M. dispar and M. bovirhinis was determined with DNA isolated from 200 μL culture (M. bovis, M. dispar and M. bovirhinis strain) in a volume of 200 μL elution buffer at a final DNA concentration of 10 ng/ μL. This DNA preparation was tested in seven 10-fold serial dilutions (5 μL per assay) in PBS, resulting in a range with 10 ng down to 1 fg Mycoplasma DNA per assay. The Ct was determined for each sample by single and RespoCheck triplex real-time PCR with a threshold of 50% of the Delta Rn value (log). The threshold was manually set at 0.04 in the linear phase of the amplification plot, whereby the Slope and Correlation Coefficient values were 3.22 and 99.99% respectively.
The analytical sensitivity of the M. bovis, M. dispar and M. bovirhinis single and RespoCheck triplex real-time PCR, was also determined by testing a mixture of M. bovis (3 × 106 cfu/mL), M. dispar (3 × 106 cfu/mL) and M. bovirhinis (3 × 105 cfu/mL) in seven 10-fold serial dilutions in BALF of specific pathogen free (SPF) calves of 3–4 weeks old. Dilution resulted in a series of M. bovis, M. dispar and M. bovirhinis spiked BALF samples, ranging from 3 × 106 cfu/mL down to 0.3 cfu/mL. Total DNA was isolated from each 200 μl sample with the MAGNA pure isolation kit and the Ct was determined for each sample (5 μl) by both the single and RespoCheck triplex PCR assays. The slope of the curve, the efficiency and the detection limit (for DNA ng/μl; for cells cfu/mL) for each PCR was determined. To determine the analytical specificity of the designed RespoCheck triplex PCR, 17 Mycoplasma isolates and 107 bacterial strains (Table 2) were tested.
Diagnostic sensitivity and specificity in BALF samples from calves.
For determining the diagnostic specificity, BALF samples were analysed with the PCR/DGGE method by the Animal and Plant Health Agency (APHA, Mycoplasma Team, Addlestone Surrey, UK) as earlier described [18, 25]. To determine the analytical sensitivity of the PCR/DGGE analysis, four 10-fold serial dilutions of M. bovis (7 × 104 cfu/mL), M. dispar (16 × 104 cfu/mL), and M. bovirhinis (0.5 × 104 cfu/mL), were prepared in PBS. Samples were sent to the APHA and analysed using the PCR/DGGE method.
16S rDNA PCR-sequencing was used for confirmation of the results of RespoCheck Mycoplasma triplex real-time PCR. 16S rDNA of the DGGE positive /PCR positive (n = 5) and DGGE negative /PCR positive (n = 5) was amplified using the specific Mycoplasma primers of the RespoCheck Mycoplasma triplex real-time PCR. DNA was sequenced by BaseClear (Leiden, the Netherlands) by an automated DNA sequencer. The nucleotide sequences were compared with GenBank sequences using the Basic Local-Alignment Search Tool(BLAST) of the NCBI-NIH for homology . Pair-wise sequence alignments were performed using the Clustal algorithm implemented in the program DNA star (DNASTAR Inc., Madison, WI).
Analyses of sensitivity and specificity
The analytical sensitivity of the RespoCheck triplex PCR was determined by its ability to detect a low concentration of M. bovis, M. dispar and M. bovirhinis and therefore expressed as a concentration (ng/assay and cfu/mL) . The analytical specificity of the assay was calculated for each target microorganism using the following definition for specificity as the percentage of true negative samples/ the number of true negative samples and the number of false positive samples .
Calculation of diagnostic sensitivity, specificity and Cohen’s Kappa Coefficient was performed as described . We therefore used the results of the PCR/DGGE analysis as reference standard.
Differences in PCR results were analysed for statistical significance by the non-parametric Mann–Whitney U test in the GraphPad Prism version 5.0 software, with P < 0.05 considered significant.
Analytical sensitivity and linear detection range of the RespoCheck triplex
The linearity of quantification of the RespoCheck triplex Mycoplasma real-time PCR was established through a linear regression plot by plotting the Ct-values against the values of log10 DNA concentration tested per reaction. The M. dispar single and RespoCheck triplex real-time PCR showed a linear detection range from 10 ng to 10 fg DNA per assay with a linear correlation (R2) value of 0.999 (Table 3; Fig. 1.). The M. bovis and M. bovirhinis single and RespoCheck real-time PCR showed a linear detection range from from 1 ng to 100 fg DNA per assay, with a R2 value of 0.999 (Table 3; Fig. 1). In BALF spiked samples, the detection limit of the RespoCheck triplex real-time PCR was 300 cfu/mL for M. dispar, and 30 cfu/mL for M. bovis or M. bovirhinis (Table 3; Fig. 2). In the RespoCheck Mycoplasma real-time PCR, 5 μL was tested and the analytical sensitivity was therefore 1–15 cfu/assay. A good linear correlation (R2 > 0.96) was found between the values of BALF spiked samples and the Ct-values in the RespoCheck Mycoplasma triplex or singleplex real-time PCR for the three Mycoplasmas (Table 3).
Analytical specificity of the RespoCheck triplex PCR
RespoCheck Mycoplasma triplex PCR in silico BLAST searchs (http://blast.ncbi.nlm.nih.gov/Blast.cgi) for the specificity of the M. dispar amplicon revealed a 100% identity (E-value 1E−46) for 2 hits for M. dispar complete genome sequence. The in silico BLAST search for amplicon of M. bovis we found a 99–100% identity (E-values 4E−43 - 6E−45) to 31 complete genome or 16S ribosomal partial sequence, and for the amplicon of M. bovirhinis we found a 99–100% identity (E-values 5E−50 - 1E-51.) For the M. bovirhinis amplicon a 97% identity (3E-40) was found for 11 hits for Mycoplasma canis (Taxid:29,555).
Seventeen Mycoplasma strains (Table 1) and 107 bacterial strains (Table 2) were used to calculate the analytical specificity of the RespoCheck Mycoplasma triplex PCR. The RespoCheck Mycoplasma triplex real-time assay for detecting M. bovis, M. dispar and M. bovirhinis possessed an analytical specificity of 100% (0 FP), 98.2% (2 FP) and 99.1% (1 FP), respectively. No cross-reactivity in the RespoCheck Mycoplasma triplex real-time assay was observed with any of the 107 bacterial strains. The M. dispar PCR did however cross-react with Acholeplasma axanthum S743 and M. alkalescens PG 31/D 12. In silico sequence data analyses from the 16S V3 genomic DNA region showed no similarity of M. dispar specific sequences with the A. axanthum S743 and M. alkalescens PG 31/D 12 isolates. The M. bovirhinis RespoCheck triplex PCR cross-reacted with M. canis with a Ct-value of 20.4. In the M. bovis RespoCheck triplex PCR we found a cross-reaction with M. agalactiae. Based on the almost 100% similarity of M. canis PG14 16S rRNA gene and the M. bovirhinis16S rRNA, it is not possible to prevent for this cross-reaction.
Diagnostic sensitivity and specificity of the RespoCheck triplex compared with DGGE
To study the influence of centrifugation of the BALF samples on the PCR results we compared the PCR results from the BALF samples before and after centrifugation (10 min at 4600×g). A significant lower Ct-value (P < 0.05; non-parametric Wilcoxon statistics) in the RespoCheck Mycoplasma triplex real-time PCR was found for M. bovis and M. dispar in the pellet of the centrifuged BALF samples. Several M. bovis, M. bovirhinis and M. dispar mix-infections could be detected in one BALF sample with a difference of 10 Ct-values between the three species and were in accordance with the PCR/DGGE analysis (Fig 3). Therefore we used the pellet of the centrifuged BALF samples (50× concentrated) to determine the presence of the three Mycoplasma species in 44 BALF samples by real-time PCR.
The calculated diagnostic sensitivity and specificity the RespoCheck triplex PCR is reported in Table 4. As the diagnostic specificity is very low (0.1944, 0.739, 0.3889 for M. dispar, M. bovis and M. bovirhinis respectively) we analysed the sequence of the produced amplicon of five DGGE negative /PCR positive and five DGGE positive PCR positive samples. The sequence of both products was confirmed as M. bovis, M. dispar or M. bovirhinis, as all sequences had a high E-value (3e-44) and 100% Query cover (100%) against the homologue sequence using the BLAST of the NCBI-NIH. Comparison of the Ct-values of PCR positive/ DGGE negative and the PCR positive/ DGGE positive samples with a non-parametric Mann Whitney test, showed that the Ct values of M. dispar and M. bovis were significantly lower, p = 0.0026 and 0.0282, respectively. In the M. bovis and M. dispar PCR, the difference in Ct value between PCR positive/ DGGE positive and PCR positive/ DGGE negative samples is at least 3.2, which indicates a factor of 10 difference in concentration of M. bovis and M. dispar DNA between these two groups (Fig. 4). As a consequence the diagnostic specificity of the RespoCheck triplex PCR is undervalued by this method. We compared the results of the M. bovis, M. dispar and M. bovirhinis RespoCheck triplex PCR with the results of the PCR/DGGE analysis. The detection limit of the M. bovis, M. dispar and M. bovirhinis PCR/DGGE analysis was, as determined by APHA, 0.7 × 103 cfu/mL, 16 × 103 cfu/mL and 0.5 × 103 cfu/mL, respectively (Fig. 5).
PCR assays for the detection of Mycoplasmas generally target sequences on the 16S rRNA gene [29, 30]. In this study we used the highly conserved 16S rRNA sequence to set up the RespoCheck Mycoplasma triplex real-time PCR assay for the specific detection of M. bovis, M. dispar and M. bovirhinis in BALF samples of calves.
The lowest concentration of M. dispar which could be detected with the RespoCheck triplex PCR assay is around 300 cfu/mL. With a copy number of 16S rRNA of one or two (https://rrndb.umms.med.umich.edu/) and with a test volume of 5 μl the lowest concentration which could be detected is around 1–2 cfu/assay. The lowest concentration of M. bovis and M. bovirhinis which could be detected with the RespoCheck triplex for M. bovis, and M. bovirhinis is around 0.5 cfu/assay. From the calculated analytical sensitivity of the M. bovis, M dispar and M. bovirhinis RespoCheck triplex PCR (0.5–2 cfu/assay) we conclude that the RespoCheck triplex PCR has a good analytical sensitivity. It was shown that the use of a pellet from 25 mL BALF after centrifugation instead of not-centrifuged BALF samples increased the analytical sensitivity of the RespoCheck triplex PCR assay. In order to determine the analytical specificity of the RespoCheck triplex PCR we analysed the DNAs from panels of Mycoplasma and bacterial strains. In the M. bovis RespoCheck Mycoplasma triplex real-time PCR we found a cross-reaction with M. agalactiae. Phylogenetic analyses on 16S rRNA sequences and comparing the 16S rRNA sequences of M. bovis and M. agalactiae  at NCBI (www.ncbi.nlm.nih.gov), we found a close relationship between M. agalactiae and M. bovis, with a 99% nucleotide identity between their 16S rRNA sequences. However, M. bovis causes calf pneumonia, mastitis, and arthritis in cattle [16, 31], M. agalactiae is the causal agent of contagious agalactia in goats and sheep . Although unusual, M. agalactiae has been detected from cattle samples [33, 34]. Therefore the cross reactivity for M. agalactiae might be a problem for the intended BALF samples in the M. bovis PCR. In the M. bovirhinis RespoCheck triplex real-time PCR one false positive reaction was obtained on DNA from M. canis. M. canis can be isolated from the reproductive tract of dogs, but has not been proved to cause disease in dogs. However, it has been shown to cause clinical signs of pneumonia in experimentally challenged calves  and M. canis has been isolated from ruminants in Britain [36, 37]. Depending on the incidence of M. canis in ruminants, this may give false-positive results in the M. bovirhinis RespoCheck triplex real-time PCR. DNA samples from M. alkalescens and A. axanthun showed high Ct-values (>35) for M. dispar in the RespoCheck triplex real-time PCR, and were therefore classified as false-positive (Ct of 40 cycles or less were considered to be positive). M. alkalescens and M. bovigenitalium are important Mycoplasmas that can infect cattle and cause mastitis, arthritis and respiratory disease . However, in the sequence analyses of the PCR-positive and DGGE-negative M. dispar BALF samples, we did not find any indication for the presence of M. alkascens, underlining the high specificity for M. dispar in the RespoCheck triplex real-time PCR.
Monitoring for Mycoplasma species in BALF samples through collection and testing of BALF samples by culture is hampered by the fastidious nutritional requirements, lengthy culture of mycoplasmas, and their susceptibility to growth inhibitors. As a consequence, Mycoplasma culture is time-consuming, costly, and requires specific expertise. Moreover, Mycoplasma species may easily be overgrown by bacterial contaminants or by more rapidly growing Mollicutes, notably Acholeplasmas. The PCR/DGGE method of the APHA can differentiate 13 bovine Mycoplasma species  including the target Mycoplasmas of the RespoCheck Mycoplasma triplex real-time PCR and in contrary to the RespoCheck can differentiate between M. bovis and M. canis. Additional the PCR/DGGE is capable of detecting mixed cultures, which would have been difficult to detect by culture methods . Therefore we used this method as a reference for determining the diagnostic sensitivity and specificity of the RespoCheck Mycoplasma triplex real-time PCR.
Possibly due to the lower sensitivity of the DGGE analysis compared to the RespoCheck triplex PCR (almost factor 10) and its use as reference method to validate the RespoCheck triplex PCR, the latter test method scores 29, 6 and 22 M. dispar, M. bovis and M. bovirhinis respectively out of 44 more samples as false-positive and therefore the diagnostic specificity of the RespoCheck triplex PCR is underestimated. The transport and storage conditions or differences in DNA preparation of particularly the more diluted BALF samples for the PCR/DGGE method could have induced a lower sensitivity of the PCR/DGGE analysis. The Ct values of the M. bovis, and M. dispar PCR positive and DGGE positive samples are significant (P < 0.05 Mann Whitney test) lower than the M. bovis, and M. dispar PCR positive DGGE negative samples, which confirms the difference in the analytical sensitivity between the RespoCheck triplex PCR and DGGE analyse. In the M. bovis and M. dispar PCR, we found a 10 fold difference in the Ct values between the DGGE positive/ PCR positive and DGGE negative/ PCR positive samples, which indicates a higher diagnostic sensitivity of M. bovis and M. dispar PCR than the DGGE analyses. Results by DGGE from BALF samples with mixed infections could be reproduced by the triplex PCR, suggesting that there is no significant PCR bias when the triplex PCR is used for Mycoplasma detection in field samples. The PCR has thus a higher analytical sensitivity than the DGGE.
In conclusion, the RespoCheck Mycoplasma triplex PCR-test appears to be a sensitive and specific test for the detection of M. bovis, M. dispar and M. bovirhinis in BALF samples of calves.
Bronchoalveolar lavage fluid
Bovine respiratory disease complex
PCR with denaturing gradient gel electrophoresis fingerprinting
Poulsen KP, McGuirk SM. Respiratory disease of the bovine neonate. Vet Clin North Am Food Anim Pract. 2009;25:121–37. doi:10.1016/j.cvfa.2008.10.007.
Griffin D, Chengappa MM, Kuszak J, McVey DS. Bacterial pathogens of the bovine respiratory disease complex. Vet Clin North Am Food Anim Pract. 2010;26:381–94. doi:10.1016/j.cvfa.2010.04.004.
Srikumaran S, Kelling CL, Ambagala A. Immune evasion by pathogens of bovine respiratory disease complex. Anim Health Res Rev. 2007;8:215–29. doi:10.1017/s1466252307001326.
Bell CJ, Blackburn P, Elliott M, Patterson T, Ellison S, Lahuerta-Marin A, Ball HJ. Investigation of polymerase chain reaction assays to improve detection of bacterial involvement in bovine respiratory disease. J Vet Diagn Investig. 2014;26:631–4. doi:10.1177/1040638714540166.
Woolums AR, Ames TR, Baker JC. The bronchopneumonias (respiratory disease complex of cattle, sheep and goats). In: Smith BP, editor. Large Animal Internal Medicine. 4th ed. St Louis: Mosby, Elsevier; 2009. p. 602–43.
Nicholas RA, Ayling RD. Mycoplasma bovis: disease, diagnosis, and control. Res Vet Sci. 2003;74:105–12.
Nicholas RA. Bovine mycoplasmosis: silent and deadly. Vet Rec. 2011;168:459–62. doi:10.1136/vr.d2468.
Houghton SB, Gourlay RN. Synergism between Mycoplasma bovis and Pasteurella haemolytica in calf pneumonia. Vet Rec. 1983;113:41–2. doi:10.1136/vr.d2468.
Caswell JL, Archambault M. Mycoplasma bovis pneumonia in cattle. Anim Health Res Rev. 2007;8:161–86. doi:10.1017/s1466252307001351.
Panciera RJ, Confer AW. Pathogenesis and pathology of bovine pneumonia. Vet Clin North Am Food Anim Pract. 2010;26:191–214. doi:10.1016/j.cvfa.2010.04.001.
Angen O, Thomsen J, Larsen LE, Larsen J, Kokotovic B, Heegaard PM, Enemark JM. Respiratory disease in calves: microbiological investigations on trans-tracheally aspirated bronchoalveolar fluid and acute phase protein response. Vet Microbiol. 2009;137:165–71. doi:10.1016/j.vetmic.2008.12.024.
Hirose K, Kobayashi H, Ito N, Kawasaki Y, Zako M, Kotani K, Ogawa H, Sato H. Isolation of Mycoplasmas from nasal swabs of calves affected with respiratory diseases and antimicrobial susceptibility of their isolates. J Vet Med B Infect Dis Vet Public Health. 2003;50:347–51.
Gabinaitiene A, Siugzdaite J, Zilinskas H. Laboratory diagnosis of Mycoplasma infection in young cattle. Pol J Vet Sci. 2011;14:87–93.
Marques LM, Buzinhani M, Yamaguti M, Oliveira RC, Ferreira JB, Mettifogo E, Timenetsky J. Use of a polymerase chain reaction for detection of Mycoplasma dispar in the nasal mucus of calves. J Vet Diagn Investig. 2007;19:103–6.
Miles K, McAuliffe L, Ayling RD, Nicholas RA. Rapid detection of Mycoplasma dispar and M. Bovirhinis using allele specific polymerase chain reaction protocols. FEMS Microbiol Lett. 2004;241:103–7. doi:10.1016/j.femsle.2004.10.010.
Sachse K, Salam HS, Diller R, Schubert E, Hoffmann B, Hotzel H. Use of a novel real-time PCR technique to monitor and quantitate Mycoplasma bovis infection in cattle herds with mastitis and respiratory disease. Vet J. 2010;186:299–303. doi:10.1016/j.tvjl.2009.10.008.
Kobayashi H, Hirose K, Worarach A, Paugtes P, Ito N, Morozumi T, Yamamoto K. In vitro amplification of the 16S rRNA genes from Mycoplasma bovirhinis, Mycoplasma alkalescens and Mycoplasma bovigenitalium by PCR. J Vet Med Sci. 1998;60:1299–303.
McAuliffe L, Ellis RJ, Lawes JR, Ayling RD. Nicholas RA 16S rDNA PCR and denaturing gradient gel electrophoresis; a single generic test for detecting and differentiating Mycoplasma species. J Med Microbiol. 2005;54:731–9. doi:10.1099/jmm.0.46058-0.
Schnee C, Schulsse S, Hotzel H, Ayling RD, Nicholas RA, Schubert E, Heller M, Ehricht R, Sachse K. A novel rapid DNA microarray assay enables identification of 37 Mycoplasma species and highlights multiple Mycoplasma infections. PLoS One. 2012;7:e33237. doi:10.1371/journal.pone.0033237.
Aluotto BB, Wittier RG, Williams CO, Faber JE. Standardized bacteriologic techniques for the characterization of mycoplasma species. Int J Syst Bacteriol. 1970;20:35–58.
Fogarty U, Quinn PJ, Hannan J. Bronchopulmonary lavage in the calf: a new technique. Ir Vet J. 1983;37(2):35–8.
Phillippy AM, Mason JA, Ayanbule K, Sommer DD, Taviani E, Huq A, Colwell RR, Knight IT, Salzberg SL. Comprehensive DNA signature discovery and validation. PLoS Comput Biol. 2007;3:e98. doi:10.1371/journal.pcbi.0030098.
Peer Y van de, Chapelle S, de Wachter S. A quantitative map of nucleotide substitution rates in bacterial RNA. NAR 1996; 24:3381-3391.
Saah AJ, Hoover DR. “Sensitivity” and “specificity” reconsidered: the meaning of these terms in analytical and diagnostic settings. Ann Intern Med. 1997;126:91–4.
Pettersson B, Uhlén M, Johansson KE. Phylogeny of some mycoplasmas from ruminants based on 16S rRNA sequences and definition of a new cluster within the hominis group. Int J Syst Bacteriol. 1996;46:1093–8. doi:10.1099/00207713-46-4-1093.
Altschul SF, Gish W, Miller W, Myers EW, Lipman DJ. Basic local alignment search tool. Mol Biol. 1990;215:403–10. doi:10.1016/s0022-2836(05)80360-2.
Martin SW. Estimating disease prevalence and the interpretation of screening test results. Prev Vet Med. 1984;2:463–72.
Mackinnon A. A spreadsheet for the calculation of comprehensive statistics for the assessment of diagnostic tests and inter-rater agreement. Comput Biol Med. 2000;30:127–34.
Chávez González YR, Ros Bascuñana C, Bölske G, Mattsson JG, Fernández Molina C, Johansson KE. In vitro amplification of the 16S rRNA genes from Mycoplasma bovis and Mycoplasma agalactiae by PCR. Vet Microbiol. 1995;47:183–90.
van Kuppeveld FJ, van der Logt JT, Angulo AF, van Zoest MJ, Quint WG, Niesters HG, Galama JM, Melchers WJ. Genus and species-specific identification of mycoplasmas by 16S rRNA amplification. Appl Environ Microbiol. 1993;59:655.
Pfützner H, Sachse K. Mycoplasma bovis as an agent of mastitis, pneumonia, arthritis and genital disorders in cattle. Rev Sci Tech. 1996;15:1477–94.
Lambert M. Contagious agalactia of sheep and goats. Rev Sci Technol Off Int Epizoot. 1987;6:6677–711.
Catania S, Gobbo F, Schiavon E, Nicholas RAJ. Severe otitis and pneumonia in adult cattle with mixed infection of Mycoplasma bovis and Mycoplasma agalactiae. Vet Rec Case Rep. 2016;4:e000366. doi:10.1136/vetreccr-2016-000366.
Bashiruddin JB, Frey J, Königsson MH, Johansson KE, Hotzel H, Diller R, de Santis P, Botelho A, Ayling RD, Nicholas RA, Thiaucourt F, Sachse K. Evaluation of PCR systems for the identification and differentiation of Mycoplasma agalactiae and Mycoplasma bovis: a collaborative trial. Vet J. 2005;169:268–75.
Nicholas R, Baker S, Ayling R, Stipkovits L. Mycoplasma infections in growing cattle. Cattle Practice. 2000;8:115–8.
Megid R, Nicholas RA, Miles RJ. Biochemical characterization of Mycoplasma bovirhinis, Mycoplasma dispar and recent bovine isolates of Mycoplasma canis. Vet Res Commun. 2001;25:1–12.
Ayling RD, Bashiruddin SE, Nicholas RA. Mycoplasma species and related organisms isolated from ruminants in Britain between 1990 and 2000. Vet Rec. 2004;155:413–6.
The authors thank Prof. Konrad Sachse (Friedrich-Loeffler-Institut, Federal Research Institute for Animal Health, Jena, Germany) for providing us with DNA from 14 Mycoplasma isolates. The authors thank also The Mycoplasma Team (APHA Woodham Lane Addlestone, Surrey, UK) for performing the PCR/DGGE analysis.
This research was part of the project “Development and application of diagnostics” within the public-private partnership “One Health for Food” in The Netherlands.
The research was funded by the Dutch Ministry of Economic Affairs, Productschap Vee en Vlees / Stichting Brancheorganisatie Kalversector (SBK) and supported by the Van Drie Group, MSD Animal Health and Denkavit.
Availability of data and material
The datasets used and/or analysed during the current study are available from the corresponding author on reasonable request.
JC authored the manuscript, designed the study, performed the qPCR and analysed the data. AB and FB build an Insignia-based database from which pathogen-specific sequence regions were extracted, designed the oligonucleotide primers and probes and assisted in drafting and editing the manuscript. HW and FW assisted in study design, interpretation of data and editing the manuscript. MK was involved in the microbiological analyses of the samples and participated in the drafting of the manuscript. AA designed and coordinated the field study for the collection of BALF samples and also helped to draft this manuscript. BS conducted and coordinated the field sample collection, performed microbiological analysis of samples and managing the database with results. BK participated in the design of the study and helped in the interpretation of the triplex PCR data. All authors read and critically revised and approved the final manuscript.
The authors declare that they have no competing interests.
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Ethics approval and consent to participate
Sampling of the calves was granted an exemption from requiring ethics approval by the institutional Animal Experiment Commission “Dier Experimenten Commissie (DEC) Lelystad (2013111.b)” because sampling was performed for diagnostic purposes. Ethics approval is not applicable. Animal handling, including BALF sample collection, was performed or supervised by approved veterinarians Consent was obtained from the farmers for the samples collected at their farm.
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Cornelissen, J.B.W.J., Bree, F.M., Wal, F.J. et al. Mycoplasma detection by triplex real-time PCR in bronchoalveolar lavage fluid from bovine respiratory disease complex cases. BMC Vet Res 13, 97 (2017) doi:10.1186/s12917-017-1023-6
- Bovine Mycoplasma
- M. dispar
- M. bovis
- M. bovirhinis
- Triplex PCR
- Bovine respiratory disease