Use of Ethidium Monoazide and PCR in Combination for Quantification of Viable and Dead Cells in Complex Samples

The distinction between viable and dead cells is a major issue in many aspects of biological research. The current technologies for determining viable versus dead cells cannot readily be used for quantitative differentiation of specific cells in mixed populations. This is a serious limitation. We have solved this problem by developing a new concept with the viable/dead stain ethidium monoazide (EMA) in combination with real-time PCR (EMA-PCR). A dynamic range of approximately 4 log₁₀ was obtained for the EMA-PCR viable/dead assay. Viable/dead differentiation is obtained by covalent binding of EMA to DNA in dead cells by photoactivation. EMA penetrates only dead cells with compromised membrane/cell wall systems. DNA covalently bound to EMA cannot be PCR amplified. Thus, only DNA from viable cells can be detected. We evaluated EMA-PCR with the major food-borne bacterium Campylobacter jejuni as an example. Traditional diagnosis of this bacterium is very difficult due to its specific growth requirements and because it may enter a state where it is viable but not cultivable. The conditions analyzed included detection in mixed and natural samples, survival in food, and survival after disinfection or antibiotic treatment. We obtained reliable viable/dead quantifications for all conditions tested. Comparison with standard fluorescence-based viable/dead techniques showed that the EMA-PCR has a broader dynamic range and enables quantification in mixed and complex samples. In conclusion, EMA-PCR offers a novel real-time PCR method for quantitative distinction between viable and dead cells with potentially very wide application.     

Use of ethidium monoazide and PCR in combination for quantification of viable and dead cells in complex samples

The distinction between viable and dead cells is a major issue in many aspects of biological research. The current technologies for determining viable versus dead cells cannot readily be used for quantitative differentiation of specific cells in mixed populations. This is a serious limitation. We have solved this problem by developing a new concept with the viable/dead stain ethidium monoazide (EMA) in combination with real-time PCR (EMA-PCR). A dynamic range of approximately 4 log(10) was obtained for the EMA-PCR viable/dead assay. Viable/dead differentiation is obtained by covalent binding of EMA to DNA in dead cells by photoactivation. EMA penetrates only dead cells with compromised membrane/cell wall systems. DNA covalently bound to EMA cannot be PCR amplified. Thus, only DNA from viable cells can be detected. We evaluated EMA-PCR with the major food-borne bacterium Campylobacter jejuni as an example. Traditional diagnosis of this bacterium is very difficult due to its specific growth requirements and because it may enter a state where it is viable but not cultivable. The conditions analyzed included detection in mixed and natural samples, survival in food, and survival after disinfection or antibiotic treatment. We obtained reliable viable/dead quantifications for all conditions tested. Comparison with standard fluorescence-based viable/dead techniques showed that the EMA-PCR has a broader dynamic range and enables quantification in mixed and complex samples. In conclusion, EMA-PCR offers a novel real-time PCR method for quantitative distinction between viable and dead cells with potentially very wide application.     

Viable but non-culturable Listeria monocytogenes on parsley leaves and absence of recovery to a culturable state

AIMS: To investigate the presence of viable but non-culturable Listeria monocytogenes during survival on parsley leaves under low relative humidity (RH) and to evaluate the ability of L. monocytogenes to recover from VBNC to culturable state under satured humidity. METHODS AND RESULTS: Under low RH (47-69%) on parsley leaves, the initial number of L. monocytogenes populations counted on non selective media (10(9) L. monocytogenes per leaf on TSA) was reduced by 6 log10 scales in 15 days, whereas number of viable L. monocytogenes counted under the microscope was reduced by 3-4 log10 scales, indicating the presence of VBNC cells. This was demonstrated on three L. monocytogenes strains (EGDe, Bug 1995 and LmP60). Changing from low to 100% RH permitted an increase of the culturable counts of L. monocytogenes and this growth was observed only when residual culturable cells were present. Moreover, VBNC L. monocytogenes inoculated on parsley leaves did not become culturable after incubation under 100% RH. CONCLUSIONS: Dry conditions induced VBNC L. monocytogenes on parsley leaves but these VBNC were likely unable to recover culturability after transfer to satured humidity. SIGNIFICANCE AND IMPACT OF STUDY: Enumeration on culture media presumably under-estimates the number of viable L. monocytogenes on fresh produce after exposure to low RH.     

脱氧胆酸钠在副溶血性弧菌死活细胞叠氮溴乙锭PCR鉴别中的应用

[目的]通过将表面活性剂脱氧胆酸钠(Sodium deoxycholate,SD)与叠氮溴乙锭(Ethidium bromide monoazide,EMA)-PCR反应体系相结合,建立SD-EMA-PCR鉴别副溶血性弧菌死活细胞的检测方法.[方法]依次对加入检测体系中的脱氧胆酸钠最适浓度、EMA区分死活细胞DNA的浓度范围、EMA激活光解最佳曝光时间进行优化;确定SD-EMA-PCR方法检测副溶血性弧菌死活细胞混合体系中活细胞的最低检出限.[结果]当脱氧胆酸钠浓度≤0.5 g/L,EMA的浓度为3.2-34.0 mg/L,曝光时间为25 min时,SD-EMA-PCR检测体系仅对死细胞DNA扩增产生抑制作用.SD-EMA-PCR检测活菌细胞的最低检出限为10 CFU/mL.[结论]死活细胞混合体系的SD-EMA-PCR检测证明该方法能够明显降低EMA-PCR漏检的死菌对检测结果造成的影响,为完善食源性致病菌检测中死活菌细胞鉴别方法提供了一种有效途径.     

Detection of Listeria monocytogenes in Italian-style soft cheeses

AIMS: A rapid detection system specific for Listeria monocytogenes and based on the polymerase chain reaction (PCR) was developed. METHODS AND RESULTS: Primers annealing to the coding region of the actA gene, critically involved in virulence and capable of discrimination between two different alleles naturally occurring in L. monocytogenes, have been utilized. The procedure was applied to recover L. monocytogenes cells in artificially contaminated fresh Italian soft cheeses (mozzarella, crescenza and ricotta). Low levels of L. monocytogenes were detected in mozzarella and crescenza homogenates (0.04-0.4 and 4 CFU g(-1), respectively) whereas in ricotta the detection limit was higher (40 CFU g(-1)). CONCLUSIONS: This PCR-based assay is highly specific as primers used recognize the DNA from different L. monocytogenes strains of clinical and food origin, while no amplification products result with any other Listeria spp. strains. SIGNIFICANCE AND IMPACT OF THE STUDY: This study highlighted a low-cost and rapid procedure that can be appropriated for the detection in real time of low L. monocytogenes levels in soft cheese.     

Specific Detection of Viable Legionella Cells by Combined Use of Photoactivated Ethidium Monoazide and PCR/Real-Time PCR

Legionella organisms are prevalent in manmade water systems and cause legionellosis in humans. A rapid detection method for viable Legionella cells combining ethidium monoazide (EMA) and PCR/real-time PCR was assessed. EMA could specifically intercalate and cleave the genomic DNA of heat- and chlorine-treated dead Legionella cells. The EMA-PCR assay clearly showed an amplified fragment specific for Legionella DNA from viable cells, but it could not do so for DNA from dead cells. The number of EMA-treated dead Legionella cells estimated by real-time PCR exhibited a 10⁴- to 10⁵-fold decrease compared to the number of dead Legionella cells without EMA treatment. Conversely, no significant difference in the numbers of EMA-treated and untreated viable Legionella cells was detected by the real-time PCR assay. The combined assay was also confirmed to be useful for specific detection of culturable Legionella cells from water samples obtained from spas. Therefore, the combined use of EMA and PCR/real-time PCR detects viable Legionella cells rapidly and specifically and may be useful in environmental surveillance for Legionella.     

An advanced PCR method for the specific detection of viable total coliform bacteria in pasteurized milk

Pasteurized milk is a complex food that contains various inhibitors of polymerase chain reaction (PCR) and may contain a large number of dead bacteria, depending on the milking conditions and environment. Ethidium monoazide bromide (EMA)-PCR is occasionally used to distinguish between viable and dead bacteria in foods other than pasteurized milk. EMA is a DNA-intercalating dye that selectively permeates the compromised cell membranes of dead bacteria and cleaves DNA. Usually, EMA-PCR techniques reduce the detection of dead bacteria by up to 3.5 logs compared with techniques that do not use EMA. However, this difference may still be insufficient to suppress the amplification of DNA from dead Gram-negative bacteria (e.g., total coliform bacteria) if they are present in pasteurized milk in large numbers. Thus, false positives may result. We developed a new method that uses real-time PCR targeting of a long DNA template (16S-23S rRNA gene, principally 2,451?bp) following EMA treatment to completely suppress the amplification of DNA of up to 7?logs (10(7)?cells) of dead total coliforms. Furthermore, we found that a low dose of proteinase K (25?U/ml) removed PCR inhibitors and simultaneously increased the signal from viable coliform bacteria. In conclusion, our simple protocol specifically detects viable total coliforms in pasteurized milk at an initial count of ≥1?colony forming unit (CFU)/2.22?ml within 7.5?h of total testing time. This detection limit for viable cells complies with the requirements for the analysis of total coliforms in pasteurized milk set by the Japanese Sanitation Act (which specifies <1?CFU/2.22?ml).     

Use of ethidium bromide monoazide for quantification of viable and dead mixed bacterial flora from fish fillets by polymerase chain reaction

Ethidium bromide monoazide (EMA) was utilized to selectively allow conventional PCR amplification of target DNA from viable but not dead cells from a broth culture of bacterial mixed flora derived from cod fillets. The universal primers designated DG74 and RW01 that amplify a 370-bp sequence of a highly conserved region of all eubacterial 16S rDNA were used for the PCR. The use of 10 microg/ml or less of EMA did not inhibit the PCR amplification of DNA derived from viable bacteria. The minimum amount of EMA to completely inhibit the PCR amplification of DNA derived from dead bacterial cells was 0.8 microg/ml. Amplification of target DNA from only viable cells in a suspension with dead cells was selectively accomplished by first treating the cells with 1 microg/ml of EMA. A standard curve was generated relating the intensity of fluorescence of DNA bands to the log of CFU of mixed bacterial cultures for rapidly assessing the number of genomic targets per PCR derived from the number of CFU. A linear range of DNA amplification was exhibited from 1 x 10(2) to 1 x 10(5) genomic targets per PCR. The viable/dead cell discrimination with the EMA-PCR method was evaluated by comparison with plate counts following freezing and thawing. Thawing frozen cell suspensions initially containing 1 x 10(5) CFU/ml at 4, 20, and 37 degrees C yielded a 0.8 log reduction in the number of viable cells determined by both plate counts and EMA-PCR. In contrast, thawing for 5 min at 70 degrees C resulted in a 5 log reduction in CFU derived from plate counts (no CFU detected) whereas the EMA-PCR procedure resulted in only a 2.8 log reduction in genomic targets, possibly reflecting greater damage to enzymes or ribosomes at 70 degrees C to a minority of the mixed population compared to membrane damage.     

A novel real-time PCR-based method for the detection of Listeria monocytogenes in food

AIMS: A new real-time PCR-based method was developed for the detection of Listeria monocytogenes in food. METHODS AND RESULTS: A two-step enrichment involving a 24-h incubation in half-Fraser broth followed by a 6-h subculture in Fraser broth was used, followed by cell lysis and real-time PCR with primers and a TaqMan probe previously developed in our laboratory. When the method was evaluated with 144 naturally contaminated food samples, 44 were detected as positive by the PCR-based method and 42 by the standard method EN ISO 11290-1. With 61 food samples artificially contaminated at a level of 10(0) CFU per 25 g, 61 and 58 positive samples were detected by the respective methods. CONCLUSIONS: The developed real-time PCR-based method facilitated the detection of L. monocytogenes in food on the next day after the sample reception, with a reduction of false-positive results because of dead bacterial cells and false-negative results because of PCR inhibitors. SIGNIFICANCE AND IMPACT OF THE STUDY: The method can be used for L. monocytogenes detection in food as a faster alternative to current methods.     

Use of ethidium bromide monoazide for quantification of viable and dead mixed bacterial flora from fish fillets by polymerase chain reaction

Ethidium bromide monoazide (EMA) was utilized to selectively allow conventional PCR amplification of target DNA from viable but not dead cells from a broth culture of bacterial mixed flora derived from cod fillets. The universal primers designated DG74 and RW01 that amplify a 370-bp sequence of a highly conserved region of all eubacterial 16S rDNA were used for the PCR. The use of 10 μg/ml or less of EMA did not inhibit the PCR amplification of DNA derived from viable bacteria. The minimum amount of EMA to completely inhibit the PCR amplification of DNA derived from dead bacterial cells was 0.8 μg/ml. Amplification of target DNA from only viable cells in a suspension with dead cells was selectively accomplished by first treating the cells with 1 μg/ml of EMA. A standard curve was generated relating the intensity of fluorescence of DNA bands to the log of CFU of mixed bacterial cultures for rapidly assessing the number of genomic targets per PCR derived from the number of CFU. A linear range of DNA amplification was exhibited from 1 × 10² to 1 × 10⁵ genomic targets per PCR. The viable/dead cell discrimination with the EMA-PCR method was evaluated by comparison with plate counts following freezing and thawing. Thawing frozen cell suspensions initially containing 1 × 10⁵ CFU/ml at 4, 20, and 37 °C yielded a 0.8 log reduction in the number of viable cells determined by both plate counts and EMA-PCR. In contrast, thawing for 5 min at 70 °C resulted in a 5 log reduction in CFU derived from plate counts (no CFU detected) whereas the EMA-PCR procedure resulted in only a 2.8 log reduction in genomic targets, possibly reflecting greater damage to enzymes or ribosomes at 70 °C to a minority of the mixed population compared to membrane damage.     

Selective PCR detection of viable Enterobacter sakazakii cells utilizing propidium monoazide or ethidium bromide monoazide

Aims: The detection of viable Enterobacter sakazakii cells is important due to the association of this pathogen with outbreaks of life-threatening neonatal infections. The aim of this study was to optimize a PCR-based method for selective detection of only viable Ent. sakazakii cells in the presence of dead cells, utilizing propidium monoazide (PMA) or ethidium bromide monoazide (EMA). Methods and Results: PMA or EMA was added to suspensions of viable and/or dead Ent. sakazakii cells at varying concentrations (10, 50 or 100 μg ml⁻¹) prior to DNA isolation and PCR with Ent. sakazakii-specific primers. At concentrations of 50 and 100 μg ml⁻¹, PMA completely inhibited PCR amplification from dead cells, while causing no significant inhibition of the amplification from viable cells. PMA was also effective in allowing selective PCR detection of only viable cells in mixtures of varying ratios of viable and dead cells. EMA was equally effective in preventing amplification from dead cells, however, it also inhibited DNA amplification from viable cells. Conclusions: This study demonstrated the efficiency of PMA for viable and dead differentiation of Ent. sakazakii, as well as the lack of selectivity of EMA for this purpose. Significance and Impact of the Study: PMA-PCR, in particular, will be useful for monitoring the resistance, survival strategies and stress responses of Ent. sakazakii in foods and the environment.     

Quantification of Campylobacter spp. in chicken rinse samples by using flotation prior to real-time PCR

Real-time PCR is fast, sensitive, specific, and can deliver quantitative data; however, two disadvantages are that this technology is sensitive to inhibition by food and that it does not distinguish between DNA originating from viable, viable nonculturable (VNC), and dead cells. For this reason, real-time PCR has been combined with a novel discontinuous buoyant density gradient method, called flotation, in order to allow detection of only viable and VNC cells of thermotolerant campylobacters in chicken rinse samples. Studying the buoyant densities of different Campylobacter spp. showed that densities changed at different time points during growth; however, all varied between 1.065 and 1.109 g/ml. These data were then used to develop a flotation assay. Results showed that after flotation and real-time PCR, cell concentrations as low as 8.6 x 10(2) CFU/ml could be detected without culture enrichment and amounts as low as 2.6 x 10(3) CFU/ml could be quantified. Furthermore, subjecting viable cells and dead cells to flotation showed that viable cells were recovered after flotation treatment but that dead cells and/or their DNA was not detected. Also, when samples containing VNC cells mixed with dead cells were treated with flotation after storage at 4 or 20 degrees C for 21 days, a similar percentage resembling the VNC cell fraction was detected using real-time PCR and 5-cyano-2,3-ditolyl tetrazolium chloride-4',6'-diamidino-2-phenylindole staining (20% +/- 9% and 23% +/- 4%, respectively, at 4 degrees C; 11% +/- 4% and 10% +/- 2%, respectively, at 20 degrees C). This indicated that viable and VNC Campylobacter cells could be positively selected and quantified using the flotation method.     

EMA-LAMP方法快速检测鉴别副溶血性弧菌

建立将DNA染料EMA(ethidium bromide monoazide)结合环介导等温扩增技术(loop-mediated isother-mal amplification,LAMP)的方法(EMA-LAMP),用于检测鉴别副溶血性弧菌(Vibrio parahaemolyticus)死/活菌细胞。针对副溶血性弧菌不耐热溶血素基因tlh(thermolabile hemolysin)特异性序列的6个位点设计4条引物及2条环引物,进行检测。结果表明,浓度为8.0μg/mL或更高浓度的EMA,至少经25 min的曝光处理,能够有效抑制浓度为1×108cfu/mL的副溶血性弧菌死细胞的扩增,而对用相同浓度EMA处理的副溶血性弧菌活细胞扩增没有影响。经EMA处理,含有不同比例的副溶血弧菌死细胞和活细胞的混合液中,活菌的最小检测限为1.0×102cfu/mL。EMA-LAMP方法比EMA-PCR方法区分死活细胞中的活细胞更为有效,是一种能够快速、灵敏且更为有效鉴别副溶血性弧菌死活细胞的新方法。     

基于EMA-qPCR的茄科青枯菌活体检测技术的建立

【目的】利用特异性核酸染料叠氮溴乙锭(Ethidium monoazide bromide, EMA)与实时荧光定量PCR技术相结合, 建立一种能有效区分青枯菌死活细胞的检测方法。【方法】样品DNA制备前经EMA渗透预处理, 再进行实时荧光定量PCR特异扩增菌体DNA。【结果】终浓度为2.0 mg/L的EMA能有效排除1.0×107 CFU/mL灭活青枯菌细胞DNA的扩增, 对活细胞和不可培养状态(Viable but non-culturable, VBNC)活菌的DNA扩增均没有影响。当每个定量PCR反应体系中的活细胞在5.0×100?5.0×104 CFU范围内时, 扩增Ct值与定量PCR反应体系中活细胞CFU对数值呈良好的负相关性(R2=0.992 5)。比较EMA-qPCR法和平板计数法对经过不同温度短期保存的青枯菌检测结果发现, 待检样品可在24 °C与4 °C冷藏条件下短期保存。【结论】本研究建立的EMA-qPCR方法能有效检测青枯菌VBNC细胞和有效区分死活菌, 避免或减少青枯菌PCR检测的假阳性和假阴性。     

Real-time PCR methodology for selective detection of viable Escherichia coli O157:H7 cells by targeting Z3276 as a genetic marker

The goal of this study was to develop a sensitive, specific, and accurate method for the selective detection of viable Escherichia coli O157:H7 cells in foods. A unique open reading frame (ORF), Z3276, was identified as a specific genetic marker for the detection of E. coli O157:H7. We developed a real-time PCR assay with primers and probe targeting ORF Z3276 and confirmed that this assay was sensitive and specific for E. coli O157:H7 strains (n = 298). Using this assay, we can detect amounts of genomic DNA of E. coli O157:H7 as low as a few CFU equivalents. Moreover, we have developed a new propidium monoazide (PMA)-real-time PCR protocol that allows for the clear differentiation of viable from dead cells. In addition, the protocol was adapted to a 96-well plate format for easy and consistent handling of a large number of samples. Amplification of DNA from PMA-treated dead cells was almost completely inhibited, in contrast to the virtually unaffected amplification of DNA from PMA-treated viable cells. With beef spiked simultaneously with 8 × 10(7) dead cells/g and 80 CFU viable cells/g, we were able to selectively detect viable E. coli O157:H7 cells with an 8-h enrichment. In conclusion, this PMA-real-time PCR assay offers a sensitive and specific means to selectively detect viable E. coli O157:H7 cells in spiked beef. It also has the potential for high-throughput selective detection of viable E. coli O157:H7 cells in other food matrices and, thus, will have an impact on the accurate microbiological and epidemiological monitoring of food safety and environmental sources.     

Assessment of the dynamics of the physiological states of Lactococcus lactis ssp. cremoris SK11 during growth by flow cytometry

AIMS: The aim of this study was to improve knowledge about the dynamics of the physiological states of Lactococcus lactis ssp. cremoris SK11, a chain-forming bacterium, during growth, and to evaluate whether flow cytometry (FCM) combined with fluorescent probes can assess these different physiological states. METHODS AND RESULTS: Cellular viability was assessed using double labelling with carboxyfluorescein diacetate and propidium iodide. FCM makes it possible to discriminate between three cell populations: viable cells, dead cells and cells in an intermediate physiological state. During exponential and stationary phases, the cells in the intermediate physiological state were culturable, whereas this population was no longer culturable at the end of the stationary phase. CONCLUSIONS, AND IMPACT OF THE STUDY: We introduced a new parameter, the ratio of the means of the fluorescence cytometric index to discriminate between viable culturable and viable nonculturable cells. Finally, this work confirms the relevance of FCM combined with two fluorescent stains to evaluate the physiological states of L. lactis SK11 cells during their growth and to distinguish viable cells from viable but not culturable cells.     

Survival of Listeria monocytogenes and Enterococcus faecium in sludge evaluated by real-time PCR and culture methods

AIMS: This study evaluates the behaviour in spiked sludge of a pathogenic bacteria, Listeria monocytogenes, by cultural and molecular techniques, and compares its survival with the one of a faecal indicator, Enterococcus faecium. METHODS AND RESULTS: Listeria monocytogenes strain Scott A and E. faecium(T) were followed for 17 days after inoculation in sludge. Kinetics of survival depended on the bacteria and on the technique used [most probable number method, direct plate count or real-time quantitative PCR (qPCR)]. The concentration of L. monocytogenes decreased rapidly regardless of the technique, but the decrease was much more dramatic with culture techniques than with qPCR. On the contrary, the concentrations of culturable E. faecium(T) were stable. CONCLUSIONS: The results suggest that the cells of L. monocytogenes strain Scott A might have entered a viable, but nonculturable (VBNC) status, whereas cells of the indicator bacteria, E. faecium(T), maintained themselves better and stayed culturable. SIGNIFICANCE AND IMPACT OF THE STUDY: The difference of survival kinetics in the sludge of a faecal indicator (E. faecium) and a pathogenic bacterium (L. monocytogenes) may be linked to the fact that they either enter or do not enter into a VBNC status.     

Rapid quantitative detection of Listeria monocytogenes in meat products by real-time PCR

We describe a quick and simple method for the quantitative detection of Listeria monocytogenes in meat products. This method is based on filtration, Chelex-100-based DNA purification, and real-time PCR. It can detect as few as 100 CFU/g and quantify as few as 1,000 CFU/g, with excellent accuracy compared to that of the plate count method. Therefore, it is a promising alternative for the detection of L. monocytogenes in meat products.     

Quantification of Campylobacter spp. in Chicken Rinse Samples by Using Flotation prior to Real-Time PCR

Real-time PCR is fast, sensitive, specific, and can deliver quantitative data; however, two disadvantages are that this technology is sensitive to inhibition by food and that it does not distinguish between DNA originating from viable, viable nonculturable (VNC), and dead cells. For this reason, real-time PCR has been combined with a novel discontinuous buoyant density gradient method, called flotation, in order to allow detection of only viable and VNC cells of thermotolerant campylobacters in chicken rinse samples. Studying the buoyant densities of different Campylobacter spp. showed that densities changed at different time points during growth; however, all varied between 1.065 and 1.109 g/ml. These data were then used to develop a flotation assay. Results showed that after flotation and real-time PCR, cell concentrations as low as 8.6 × 10² CFU/ml could be detected without culture enrichment and amounts as low as 2.6 × 10³ CFU/ml could be quantified. Furthermore, subjecting viable cells and dead cells to flotation showed that viable cells were recovered after flotation treatment but that dead cells and/or their DNA was not detected. Also, when samples containing VNC cells mixed with dead cells were treated with flotation after storage at 4 or 20°C for 21 days, a similar percentage resembling the VNC cell fraction was detected using real-time PCR and 5-cyano-2,3-ditolyl tetrazolium chloride-4′,6′-diamidino-2-phenylindole staining (20% ± 9% and 23% ± 4%, respectively, at 4°C; 11% ± 4% and 10% ± 2%, respectively, at 20°C). This indicated that viable and VNC Campylobacter cells could be positively selected and quantified using the flotation method.     

Comparison of primers for the detection of Salmonella enterica serovars using real-time PCR

AIMS: To evaluate the specificity and sensitivity of PCR primers for the detection of Salmonella enterica in a real-time PCR assay using pure cultures. METHODS AND RESULTS: Unenriched whole cells in sterile water were used as template for each PCR. SYBR Green dye was used for the nonspecific detection of dsDNA. The real-time PCR detection limits of five previously published primer sets used in conventional PCR applications were not below 3 x 10(3) CFU per reaction (rxn). A new primer set, Sen, was designed, which detected Salm. enterica Newport down to 6 CFU rxn(-1) in one case, and gave an average detection limit of 35 CFU rxn(-1) over three separate runs. CONCLUSIONS: Primers originally designed for end-point PCR did not have adequate specificity or sensitivity compared with those specifically designed for real-time PCR. SIGNIFICANCE AND IMPACT OF THE STUDY: This study emphasizes the importance of evaluating real-time PCR primer sets in pure cultures prior to testing in field samples. This study will benefit other researchers in selecting an appropriate primer set for real-time PCR detection of Salm. enterica.