Characterization and validation of a chemiluminescent assay based on a 1,2-dioxetane for rapid detection of enterococci in contaminated water and comparison with standard methods and qPCR

Aims: To evaluate the potential for using a novel chemiluminescence‐based enzyme assay for rapid detection of enterococci in water contaminated with faecal waste. Methods and Results: The novel assay (EntLight) was based on the enzymatic hydrolysis of the chemiluminescent 1,2‐dioxetane [(4‐methoxy‐4(3‐β‐d ‐glucoside‐4‐chlorophenyl)]spiro[1,2‐dioxetane‐3‐1,3‐tricyclo[7·3·1·0^2,7]tridec‐2,7‐ene] specific for β‐d ‐glucosidase. The specificity of the proposed EntLight assay was characterized using 26 different Enterococcus strains and 10 bacterial genera other than Enterococcus. With an analysis time of ≤8 h, the assay was found to be sensitive and specific. Validation experiments were carried out using water samples contaminated with raw municipal wastewater in comparison with qPCR and ISO standard methods. EntLight was successfully applied to detect enterococci in contaminated water within ≤8 h, and the proposed assay correlated well with both qPCR and ISO standard methods (R² > 0·776). Conclusions: EntLight can be applied to rapid and simple detection of viable enterococci in water contaminated with faecal matter. Significance and Impact of the Study: The novel EntLight assay and qPCR have the potential to be used as methods for early warning (1–7 h) of faecal pollutions in different water types.     

Rapid quantification of viable legionellae in water and biofilm using ethidium monoazide coupled with real‐time quantitative PCR

Aims: To optimize ethidium monoazide (EMA) coupled with real‐time quantitative PCR (qPCR) and to evaluate its environmental applicability on quantifying viable legionellae in water and biofilm of cooling towers and hot water systems. Methods and Results: EMA (0·9–45·5 μg ml^?1) and propidium monoazide (PMA, 0·9 and 2·3 μg ml^?1) combined with qPCR (i.e. EMA‐qPCR and PMA‐qPCR, respectively) were applied to unheated and heated (70°C for 30 min) Legionella pneumophila to quantify viable cells, which was also simultaneously determined by BacLight Bacterial Viability kit with epifluorogenic microscopic enumeration (BacLight‐EM). The effects of nontarget microflora and sample matrix on the performance of EMA‐qPCR were also evaluated. In comparison with BacLight‐EM results, qPCR with EMA at 2·3 μg ml^?1 was determined as the optimal EMA‐qPCR assay, which performed equally well as PMA‐qPCR for unheated Leg. pneumophila but better than PMA‐qPCR for heated Leg. pneumophila (P < 0·05). Moreover, qPCR with EMA at 2·3 μg ml^?1 accurately quantified viable Leg. pneumophila, Legionella anisa and Legionella‐like amoebal pathogens 6 (LLAP 6) without interferences by heated legionellae, unheated nonlegionellae cells and cooling tower water matrix (P > 0·05). As for water and biofilm samples collected from cooling towers and hot water systems, the viable legionellae counts determined by EMA‐qPCR were mostly greater than the culturable counts by culture assay but consistently lower than the total cell counts quantified by qPCR. Conclusions: The qPCR with EMA at 2·3 μg ml^?1 may accurately quantify viable legionellae (including fastidious LLAP 6) and Leg. pneumophila pretreated with superheating and is applicable for water and biofilm samples obtained from cooling towers and hot water systems. Significance and Impact of the Study: The EMA‐qPCR assay may be useful in environmental surveillance for viable legionellae and in evaluation of superheating efficacy against legionellae.     

Covalently linked immunomagnetic separation/adenosine triphosphate technique (Cov‐IMS/ATP) enables rapid,in‐field detection and quantification of Escherichia coli and Enterococcus spp. in freshwater and marine environments

Aims: Developing a rapid method for detection of faecal pollution is among the critical goals set forth by the Environmental Protection Agency in its revision of water quality criteria. The purpose of this study is to devise and test covalently linked antibody–bead complexes for faecal indicator bacteria (FIB), specifically Escherichia coli or Enterococcus spp., in measuring water quality in freshwater and marine systems. Methods and Results: Covalently linked complexes were 58–89% more robust than antibody–bead complexes used in previous studies. Freshwater and marine water samples analysed using covalently linked immunomagnetic separation/adenosine triphosphate quantification technique (Cov‐IMS/ATP) and culture‐based methods yielded good correlations for E. coli (R = 0·87) and Enterococcus spp. (R = 0·94), with method detection limits below EPA recreational water quality health standards for single standard exceedances (E. coli– 38 cells per 100 ml; Enterococcus spp. – 25 cells per 100 ml). Cov‐IMS/ATP correctly classified 87% of E. coli and 94% of Enterococcus spp. samples based on these water quality standards. Cov‐IMS/ATP was also used as a field method to rapidly distinguish differential loading of E. coli between two stream channels to their confluence. Conclusions: Cov‐IMS/ATP is a robust, in‐field detection method for determining water quality of both fresh and marine water systems as well as differential loading of FIB from two converging channels. Significance and Impact of the Study: To our knowledge, this is the first work to present a viable rapid, in‐field assay for measuring FIB concentrations in marine water environments. Cov‐IMS/ATP is a potential alternative detection method, particularly in areas with limited laboratory support and resources, because of its increased economy and portability.     

Evaluation of methodology for detection of human adenoviruses in wastewater,drinking water,stream water and recreational waters

Aims: This study evaluates dialysis filtration and a range of PCR detection methods for identification and quantification of human adenoviruses in a range of environmental waters. Methods and Results: Adenovirus was concentrated from large volumes (50–200 l) of environmental and potable water by hollow fibre microfiltration using commercial dialysis filters. By this method, an acceptable recovery of a seeded control bacteriophage MS2 from seawater (median 95·5%, range 36–98%, n = 5), stream water (median 84·7%, range 23–94%, n = 5) and storm water (median 59·5%, range 6·3–112%, n = 5) was achieved. Adenovirus detection using integrated cell culture PCR (ICC‐PCR), direct PCR, nested PCR, real‐time quantitative PCR (qPCR) and adenovirus group F‐specific direct PCR was tested with PCR products sequenced for confirmation. Adenovirus was routinely detected from all water types by most methods, with ICC‐PCR more sensitive than direct‐nested PCR or qPCR. Group F adenovirus dominated in wastewater samples but was detected very infrequently in environmental waters. Conclusions and Implications: Human adenoviruses (HAdv) proved relatively common in environmental and potable waters when assessed using an efficient concentration method and sensitive detection method. ICC‐PCR proved most sensitive, could be used semiquantitatively and demonstrated virus infectivity but was time consuming and expensive. qPCR provided quantitative results but was c. ten‐fold less sensitive than the best methods.     

An international trial of quantitative PCR for monitoring Legionella in artificial water systems

Aims: To perform an international trial to derive alert and action levels for the use of quantitative PCR (qPCR) in the monitoring of Legionella to determine the effectiveness of control measures against legionellae. Methods and Results: Laboratories (7) participated from six countries. Legionellae were determined by culture and qPCR methods with comparable detection limits. Systems were monitored over ≥10 weeks. For cooling towers (232 samples), there was a significant difference between the log mean difference between qPCR (GU l^?1) and culture (CFU l^?1) for Legionella pneumophila (0·71) and for Legionella spp. (2·03). In hot and cold water (506 samples), the differences were less, 0·62 for Leg. pneumophila and 1·05 for Legionella spp. Results for individual systems depended on the nature of the system and its treatment. In cooling towers, Legionella spp. GU l^?1 always exceeded CFU l^?1, and usually Legionella spp. were detected by qPCR when absent by culture. The pattern of results by qPCR for Leg. pneumophila followed the culture trend. In hot and cold water, culture and qPCR gave similar results, particularly for Leg. pneumophila. There were some marked exceptions with temperatures ≥50°C, or in the presence of supplementary biocides. Action and alert levels for qPCR were derived that gave results comparable to the application of the European Guidelines based on culture. Algorithms are proposed for the use of qPCR for routine monitoring. Conclusions: Action and alert levels for qPCR can be adjusted to ensure public health is protected with the benefit that remedial actions can be validated earlier with only a small increase in the frequency of action being required. Significance and Impact of the Study: This study confirms it is possible to derive guidelines on the use of qPCR for monitoring the control of legionellae with consequent improvement to response and public health protection.     

Use of a Bacteroides thetaiotaomicron-specific α-1-6, mannanase quantitative PCR to detect human faecal pollution in water

Aims: The aims of this work were to develop a quantitative test, based on Bacteroides thetaiotaomicron, for human faecal pollution in water and to evaluate test performance. Methods and Results: qPCR primers, based on the complete genomic sequence of B. thetaiotaomicron VPI 5482, were designed and tested. The single-copy putative mannanase homologue, α-1-6 mannanase, was selected as the particular target and sequences within this gene chosen as the qPCR primers by Blast search for specificity to B. thetaiotaomicron. The average concentration of B. thetaiotaomicron in human faeces was 1·39 × 10⁸ cells per gram faeces and the detection limit was 9·3 B. thetaiotaomicron copies per qPCR procedure. Comparison of B. thetaiotaomicron content in sewage vs pooled nonhuman faecal samples indicated that the current assay is specific for sewage. Conclusion: The subject assay is potentially useful for quantification of sewage pollution in water. Significance and Impact of the Study: Bacteroides-associated markers, proposed for faecal source tracking, have exclusively been based on gene sequences related to generally classified and uncultured bacteria. However, genes associated with host-microbe interaction have been suggested as more specific markers. The present assay targets such a gene of B. thetaiotaomicron which is considered to be a symbiont in the human gut.     

Comparison of quantitative PCR assays for Escherichia coli targeting ribosomal RNA and single copy genes

Aims: Compare specificity and sensitivity of quantitative PCR (qPCR) assays targeting single and multi‐copy gene regions of Escherichia coli. Methods and Results: A previously reported assay targeting the uidA gene (uidA405) was used as the basis for comparing the taxonomic specificity and sensitivity of qPCR assays targeting the rodA gene (rodA984) and two regions of the multi‐copy 23S ribosomal RNA gene (EC23S and EC23S857). Experimental analyses of 28 culture collection strains representing E. coli and 21 related non‐target species indicated that the uidA405 and rodA984 assays were both 100% specific for E. coli while the EC23S assay was only 29% specific. The EC23S857 assay was only 95% specific due to detection of E. fergusonii. The uidA405, rodA984, EC23S and EC23S857 assays were 85%, 85%, 100% and 86% sensitive, respectively, in detecting 175 presumptive E. coli culture isolates from fresh, marine and waste water samples. In analyses of DNA extracts from 32 fresh, marine and waste water samples, the rodA984, EC23S and EC23S857 assays detected mean densities of target sequences at ratios of approximately 1 : 1, 243 : 1 and 6 : 1 compared with the mean densities detected by the uidA405 assay. Conclusions: The EC23S assay was less specific for E. coli, whereas the rodA984 and EC23S857 assay taxonomic specificities and sensitivities were similar to those of the uidA405 gene assay. Significance and Impact: The EC23S857 assay has a lower limit of detection for E. coli cells than the uidA405 and rodA984 assays due to its multi‐copy gene target and therefore provides greater analytical sensitivity in monitoring for these faecal pollution indicators in environmental waters by qPCR methods.     

Development of a method to detect and quantify <Emphasis Type="Italic">Aspergillus fumigatus</Emphasis> conidia by quantitative PCR for environmental air samples

Exposure to Aspergillus fumigatus is linked with respiratory diseases such as asthma, invasive aspergillosis, hypersensitivity pneumonitis, and allergic bronchopulmonary aspergillosis. Molecular methods using quantitative PCR (qPCR) offer advantages over culture and optical methods for estimating human exposures to microbiological agents such as fungi. We describe an assay that uses lyticase to digest A. fumigatus conidia followed by TaqMan™ qPCR to quantify released DNA. This method will allow analysis of airborne A. fumigatus samples collected over extended time periods and provide a more representative assessment of chronic exposure. The method was optimized for environmental samples and incorporates: single tube sample preparation to reduce sample loss, maintain simplicity, and avoid contamination; hot start amplification to reduce non-specific primer/probe annealing; and uracil-N-glycosylase to prevent carryover contamination. An A. fumigatus internal standard was developed and used to detect PCR inhibitors potentially found in air samples. The assay detected fewer than 10 A. fumigatus conidia per qPCR reaction and quantified conidia over a 4−log₁₀ range with high linearity (R ² > 0.99) and low variability among replicate standards (CV=2.0%) in less than 4 h. The sensitivity and linearity of qPCR for conidia deposited on filters was equivalent to conidia calibration standards. A. fumigatus DNA from 8 isolates was consistently quantified using this method, while non-specific DNA from 14 common environmental fungi, including 6 other Aspergillus species, was not detected. This method provides a means of analyzing long term air samples collected on filters which may enable investigators to correlate airborne environmental A. fumigatus conidia concentrations with adverse health effects.     

A rapid and simple PCR method for identifying isolates of the genus Azospirillum within populations of rhizosphere bacteria

Aims: Escherichia coli is the pre‐eminent microbiological indicator used to assess safety of drinking water globally. The cost and equipment requirements for processing samples by standard methods may limit the scale of water quality testing in technologically less developed countries and other resource‐limited settings, however. We evaluate here the use of ambient‐temperature incubation in detection of E. coli in drinking water samples as a potential cost‐saving and convenience measure with applications in regions with high (>25°C) mean ambient temperatures. Methods and Results: This study includes data from three separate water quality assessments: two in Cambodia and one in the Dominican Republic. Field samples of household drinking water were processed in duplicate by membrane filtration (Cambodia), Petrifilm? (Cambodia) or Colilert^® (Dominican Republic) on selective media at both standard incubation temperature (35–37°C) and ambient temperature, using up to three dilutions and three replicates at each dilution. Matched sample sets were well correlated with 80% of samples (n = 1037) within risk‐based microbial count strata (E. coli CFU 100 ml^?1 counts of <1, 1–10, 11–100, 101–1000, >1000), and a pooled coefficient of variation of 17% (95% CI 15–20%) for paired sample sets across all methods. Conclusions: These results suggest that ambient‐temperature incubation of E. coli in at least some settings may yield sufficiently robust data for water safety monitoring where laboratory or incubator access is limited. Significance and Impact of the Study: Ambient‐temperature incubation of E. coli may be a promising option for reducing the complexity and costs associated with water safety monitoring for faecal indicator bacteria such as E. coli in a field context in resource‐limited settings, as are often encountered in developing countries and after disasters.     

Application of EMA-qPCR as a complementary tool for the detection and monitoring of <Emphasis Type="Italic">Legionella</Emphasis> in different water systems

Legionella are prevalent in human-made water systems and cause legionellosis in humans. Conventional culturing and polymerase chain reaction (PCR) techniques are not sufficiently accurate for the quantitative analysis of live Legionella bacteria in water samples because of the presence of viable but nonculturable cells and dead cells. Here, we report a rapid detection method for viable Legionella that combines ethidium monoazide (EMA) with quantitative real-time PCR (qPCR) and apply this method to detect Legionella in a large number of water samples from different sources. Results yielded that samples treated with 5 μg/ml EMA for 10 min and subsequently exposed to light irradiation for 5 min were optimal for detecting Legionella. EMA treatment before qPCR could block the signal from approximately 4 log₁₀ of dead cells. When investigating environmental water samples, the percent-positive rate obtained by EMA-qPCR was significantly higher than conventional PCR and culture methods, and slightly lower than qPCR. The bacterial count of Legionella determined by EMA-qPCR were mostly greater than those determined by culture assays and lower than those determined by qPCR. Acceptable correlations were found between the EMA-qPCR and qPCR results for cooling towers, piped water and hot spring water samples (r = 0.849, P < 0.001) and also found between the EMA-qPCR and culture results for hot spring water samples (r = 0.698, P < 0.001). The results indicate that EMA-qPCR could be used as a complementary tool for the detection and monitoring of Legionella in water systems, especially in hot spring water samples.     

Environmental monitoring of the biocontrol agent Pantoea agglomerans CPA‐2 applied to citrus fruit at preharvest

The aim of this study was to evaluate the environmental fate and behaviour of the biocontrol product based on Pantoea agglomerans CPA‐2 cells after its release into the field. Three different methods, dilution plating, quantitative real‐time PCR (qPCR) and propidium monoazide combined with qPCR (PMA‐qPCR) were used to track the CPA‐2 population. Populations quantified by qPCR were statistically different compared with those by the PMA‐qPCR and dilution plating methods. In addition, the spray dispersion of the CPA‐2 treatment was evaluated using water‐sensitive papers. A lack of dispersion of the CPA‐2 treatment was observed at distances of 2.5 ± 0.5 m. The presence and persistence of CPA‐2 in the environment were monitored in different areas, by dilution plating and confirmed by conventional PCR. The results showed that CPA‐2 can survive but not proliferate on weed and leaves. The persistence on inert surfaces, such as motorised backpack sprayer, gloves and working clothes, was less than 7 days. In conclusion, PMA‐qPCR was a potential tool for fast and specific monitoring of viable populations of CPA‐2 and it gave valuable information on population behaviour. Moreover, the results demonstrate that CPA‐2 would not present a risk for the environment because of its low establishment, survival and dispersion.     

Enterococcus species distribution among human and animal hosts using multiplex PCR

Aims: This study evaluated the use of Enterococcus species differentiation as a tool for microbial source tracking (MST) in recreational waters. Methods and Results: Avian, mammalian and human faecal samples were screened for the occurrence of Enterococcus avium, Enterococcus casseliflavus, Enterococcus durans, Enterococcus gallinarum, Enterococcus faecium, Enterococcus faecalis, Enterococcus hirae and Enterococcus saccharolyticus using multiplex PCR. Host‐specific patterns of Enterococcus species presence were observed only when data for multiple Enterococcus species were considered in aggregate. Conclusions: The results suggest that no single Enterococcus species is a reliable indicator of the host faecal source. However, Enterococcus species composite ‘fingerprints’ may offer auxiliary evidence for bacterial source identification. Significance and Impact of Study: This study presents novel information on the enterococci species assemblages present in avian and mammalian hosts proximate to the nearshore ocean. These data will aid the development of appropriate MST strategies, and the approach used in this study could potentially assist in the identification of faecal pollution sources.     

The Applicability of TaqMan-Based Quantitative Real-Time PCR Assays for Detecting and Enumerating Cryptosporidium spp. Oocysts in the Environment

Quantitative real-time polymerase chain reaction (qPCR) assays to detect Cryptosporidium oocysts in clinical samples are increasingly being used to diagnose human cryptosporidiosis, but a parallel approach for detecting and identifying Cryptosporidium oocyst contamination in surface water sources has yet to be established for current drinking water quality monitoring practices. It has been proposed that Cryptosporidium qPCR-based assays could be used as viable alternatives to current microscopic-based detection methods to quantify levels of oocysts in drinking water sources; however, data on specificity, analytical sensitivity, and the ability to accurately quantify low levels of oocysts are limited. The purpose of this study was to provide a comprehensive evaluation of TaqMan-based qPCR assays, which were developed for either clinical or environmental investigations, for detecting Cryptosporidium oocyst contamination in water. Ten different qPCR assays, six previously published and four developed in this study were analyzed for specificity and analytical sensitivity. Specificity varied between all ten assays, and in one particular assay, which targeted the Cryptosporidium 18S rRNA gene, successfully detected all Cryptosporidium spp. tested, but also cross-amplified T. gondii, fungi, algae, and dinoflagellates. When evaluating the analytical sensitivity of these qPCR assays, results showed that eight of the assays could reliably detect ten flow-sorted oocysts in reagent water or environmental matrix. This study revealed that while a qPCR-based detection assay can be useful for detecting and differentiating different Cryptosporidium species in environmental samples, it cannot accurately measure low levels of oocysts that are typically found in drinking water sources.     

Species distribution and antimicrobial resistance of enterococci isolated from surface and ocean water

Aims: The species identification and antimicrobial resistance profiles were determined for enterococci isolated from Southern California surface and ocean waters. Methods and Results: Species identification was determined for 1413 presumptive Enterococcus isolates from urban runoff, bay, ocean and sewage water samples. The most frequently isolated species were Enterococcus faecalis, Enterococcus faecium, Enterococcus hirae, Enterococcus casseliflavus and Enterococcus mundtii. All five of these species were isolated from ocean and bay water with a frequency ranging from 7% to 36%. Enterococcus casseliflavus was the most frequently isolated species in urban runoff making up 36–65% of isolates while E. faecium was the most frequently isolated species in sewage making up 53–78% of isolates. The similar distribution of species in urban runoff and receiving water suggests that urban runoff may be the source of Enterococcus. No vancomycin or high level gentamycin resistance was detected in E. faecalis and E. faecium isolates. Conclusions: Enterococcus faecalis, E. faecium, E. casseliflavus and E. mundtii are the most commonly isolated Enterococcus species from urban runoff and receiving waters in Southern California. Significance and Impact of the Study: Determination of the Enterococcus species isolated from receiving waters and potential pollution sources may assist in determining the sources of pollution.     

Quantitative real‐time PCR detection of a harmful unarmoured dinoflagellate,Karlodinium australe (Dinophyceae)

We investigated a harmful algal bloom (HAB) associated with the massive fish kills in Johor Strait, Malaysia, which recurred a year after the first incident in 2014. This incident has urged for the need to have a rapid and precise method in HAB monitoring. In this study, we develop a SYBR green‐based real‐time PCR (qPCR) to detect the culpable dinoflagellate species, Karlodinium australe. Species‐specific qPCR primers were designed in the gene region of the second internal transcribed spacer of the ribosomal RNA gene (rDNA). The species specificity of the primers designed was evaluated by screening on the non‐target species (Karlodinium veneficum, Takayama spp., and Karenia spp.) and no cross‐detection was observed. The extractable gene copies per cell of K. australe determined in this study were 19 998 ± 505 (P < 0.0001). Estimation of cell densities by qPCR in the experimental spiked samples showed high correlation with data determined microscopically (R² = 0.93). Using the qPCR assay developed in this study, we successfully detected the 2015 bloom species as K. australe. Single‐cell PCR and rDNA sequencing from the field samples further confirmed the finding. With the sensitivity as low as five cells, the qPCR assay developed in this study could effectively and rapidly detect cells of K. australe in the environmental samples for monitoring purpose.     

Automated dead-end ultrafiltration of large volume water samples to enable detection of low-level targets and reduce sample variability

Aims

A Portable Multi‐use Automated Concentration System (PMACS) concentrates micro‐organisms from large volumes of water through automated dead‐end ultrafiltration and backflushing. The ability to detect microbial targets from ground, surface and cooling tower waters collected using standard methods was compared with samples from the PMACS in this study.

Methods and Results

PMACS (100 l) and standard grab samples (100–500 ml) were collected from sites in Florida and South Carolina, USA. Samples were analysed for the presence of faecal indicator bacteria (FIB; ground and surface water) or Legionella pneumophila (Lp; cooling tower water). FIB were enumerated by growth on selective media following membrane filtration or in IDEXX defined substrate media. Lp cells were detected by direct fluorescence immunoassay using FITC‐labelled monoclonal antibodies targeting serogroups 1, 2, 4 and 6. FIB were found in PMACS samples from ground and surface waters when their concentrations were below detection limits in grab samples. The concentrations of Lp in cooling tower samples collected over 5 months were more consistent in PMACS samples than grab samples.

Conclusions

These data demonstrate that PMACS concentration is advantageous for water monitoring. FIB were detected in PMACS samples when their concentrations were below the detection limits of the standard methods used. PMACS processing provided more representative samples of cooling tower waters reducing sample variability during long‐term monitoring.

Significance and Impact of the Study

This study highlights the utility of PMACS processing for enhanced monitoring of water for low‐level microbial targets and for reducing sample variability in long‐term monitoring programmes.     

Evaluation of real‐time PCR methods for quantification of Acanthamoeba in anthropogenic water and biofilms

Aims: To assess two real‐time PCR methods (the Riviere and Qvarnstrom assays) for environmental Acanthamoeba. Methods and Results: DNA extracted from Acanthamoeba castellanii taken from water and biofilms of cooling towers was analysed by the Riviere and Qvarnstrom assays. To quantify environmental Acanthamoeba, the calibration curves (DNA quantity vs cell number) were constructed with samples spiked with A. castellanii. The calibration curves for both quantitative PCR assays showed low variation (coefficient of variation of C_t≤ 5·7%) and high linearity (R² ≥ 0·99) over six orders of magnitudes with detection limit of three cells per water sample. DNA quantity determined by Qvarnstrom assay was equivalent between trophozoites and cysts (P = 0·49), whereas a significant difference was observed with Riviere assay (P < 0·0001). Riviere assay failed to detect Acanthamoeba in 21% (15/71) of the environmental samples which were positively detected by Qvarnstrom assay, while one sample (1·4%) was shown positive by Riviere assay but negative by Qvarnstrom assay. Moreover, Acanthamoeba counts by Qvarnstrom assay were greater than those by Riviere assay (P < 0·0001). Conclusions: Qvarnstrom assay performs better than Riviere assay for detection and quantification of Acanthamoeba in anthropogenic water and biofilms. Significance and Impact of the Study: Qvarnstrom assay may significantly contribute to a better knowledge about the distribution and abundance of Acanthamoeba in environments.     

Evaluation of Molecular Methods To Improve the Detection of Burkholderia pseudomallei in Soil and Water Samples from Laos

Burkholderia pseudomallei is the cause of melioidosis, a severe and potentially fatal disease of humans and animals. It is endemic in northern Australia and Southeast Asia and is found in soil and surface water. The environmental distribution of B. pseudomallei worldwide and within countries where it is endemic, such as the Lao People''s Democratic Republic (Laos), remains unclear. However, this knowledge is important to our understanding of the ecology and epidemiology of B. pseudomallei and to facilitate public health interventions. Sensitive and specific methods to detect B. pseudomallei in environmental samples are therefore needed. The aim of this study was to compare molecular and culture-based methods for the detection of B. pseudomallei in soil and surface water in order to identify the optimal approach for future environmental studies in Laos. Molecular detection by quantitative real-time PCR (qPCR) was attempted after DNA extraction directly from soil or water samples or after an overnight enrichment step. The positivity rates obtained by qPCR were compared to those obtained by different culture techniques. The rate of detection from soil samples by qPCR following culture enrichment was significantly higher (84/100) than that by individual culture methods and all culture methods combined (44/100; P < 0.001). Similarly, qPCR following enrichment was the most sensitive method for filtered river water compared with the sensitivity of the individual methods and all individual methods combined. In conclusion, molecular detection following an enrichment step has proven to be a sensitive and reliable approach for B. pseudomallei detection in Lao environmental samples and is recommended as the preferred method for future surveys.