Quantification of Leuconostoc populations in mixed dairy starter cultures using fluorescence in situ hybridization

AIMS: Development of a rapid method to identify and quantify Leuconostoc populations in mesophilic starter cultures. METHODS AND RESULTS: 16S rRNA-targeted oligonucleotide probes were used in a whole cell in situ hybridization assay for the identification of the genus Leuconostoc and an undescribed Leuconostoc ribospecies. The probes were fluorescently labelled and used to quantify the Leuconostoc populations in five different mixed starter cultures. CONCLUSIONS: There was a good correlation between the results obtained using fluorescence in situ hybridization (FISH) with that of standard plate counting methods. SIGNIFICANCE AND IMPACT OF THE STUDY: To develop a FISH method capable of identifying and quantifying the Leuconostoc population in starter cultures within 1 day.     

Eco-physiological characterization of fluorescence in situ hybridization probe-targeted denitrifiers in activated sludge using culture-independent methods

AIMS: This study proposes the application of a culture-independent method [fluorescence in situ hybridization (FISH)] and a bioreactor operation control strategy to characterize environmental micro-organisms according to their survival strategies in a mixed suspension culture. Eco-physiological characteristics of two 16S rRNA probe-targeted denitrifiers (DEN581 and DEN124) were investigated against the availability of two resources. METHODS AND RESULTS: Four sequencing batch reactors were operated with manipulation of the sludge retention times to enforce limited and excess availability of two nutrients, namely acetate and nitrite, to the biomass. DEN581 FISH probe-targeted denitrifiers demonstrated dominance when the ratio of either acetate or nitrite to biomass was in excess, while DEN124-targeted organisms dominated when the above were limited. CONCLUSIONS: The study demonstrated that microbial populations in mixed cultures can be selected by changing the substrate availability (Rs) to biomass (X) ratio. The manipulation of the specific resource availability (Rs/X) determined which one of the studied probe-targeted denitrifiers (DEN124 or DEN581) became dominant. Rs/X provides a basis to study the physiology of micro-organisms that cannot be isolated in pure culture from activated sludge. SIGNIFICANCE AND IMPACT OF THE STUDY: The eco-physiological characterization of micro-organisms responsible for biological nutrient removal is anticipated to assist process designers and operators to optimize a specific biological process, such as denitrification.     

A survey of the relative abundance of specific groups of cellulose degrading bacteria in anaerobic environments using fluorescence in situ hybridization

AIMS: The utility of fluorescence in situ hybridization (FISH) for detecting uncultured micro-organisms in environmental samples has been shown in numerous habitats. In this study a suite of three FISH probes for cellulolytic bacteria is described and their efficacy is demonstrated by quantifying the relative abundance of the target micro-organisms in a range of industrial biomass samples. METHODS AND RESULTS: The probes were designed from data derived from an artificial landfill leachate reactor study and 16S rRNA gene databases. The original biomass sample proved to be well described by the three probes targeting a total of 51% of the bacterial (EUBMIX targeted) cells in quantitative FISH experiments. CONCLUSIONS: Three probes were developed and applied to samples from a range of industrial digesters. The CSTG1244 probe, specific for organisms closely related to Clostridium stercorarium, were observed in the widest range of samples (7 of the 19 samples tested). The CTH216a FISH probe, specific for organisms closely related to Clostridium thermocellum, described the highest proportion of the bacterial population within any one sample (46% in an anaerobically digested sludge sample). Finally, the BCE216a probe, specific for organisms closely related to Bacteroides cellulosolvens, achieved the lowest level of hybridisation of the three probes tested. SIGNIFICANCE AND IMPACT OF THE STUDY: This study demonstrates that the three groups of anaerobic cellulolytic micro-organisms were present in different bioreactors but at variable abundances ranging from low (where other organisms would have been responsible for cellulolysis) to high. We showed the potential of using group specific FISH probes and quantitative FISH in environmental studies. The utility of using newly designed FISH probes was demonstrated by their ability to detect and quantify the target bacterial groups in samples from a range of industrial wastewater digesters.     

Improvement of ciliate identification and quantification: a new protocol for fluorescence in situ hybridization (FISH) in combination with silver stain techniques

A new protocol for taxon specific probe based fluorescent in situ hybridization was developed for the identification and quantification of ciliates in microbial communities. Various fixatives and experimental parameters were evaluated and optimized with respect to cell permeability and morphological preservation. Optimum results were adaption by obatined of a modified fixation method using Bouin's solution. Furthermore, conventional staining procedures such as different Protargol stain techniques and a silver nitrate impregnation method were modified and can now be applied in combination with fluorescence in situ hybridization. The new protocol allows a rapid and reliable identification as well as quantification of ciliates based upon classical morphological aspects and rRNA based phylogenetic relationships performed in one experiment. Furthermore, a set of specific probes targeting different regions of the 18S rRNA was designed for Glaucoma scintillans Ehrenberg, 1830 and tested by applying this new approach of combining in situ cell hybridization with conventional staining techniques.     

Identification of waterborne bacteria by the analysis of 16S-23S rRNA intergenic spacer region

AIM: In this study, we evaluated, the use of universal primers, specific for the 16S-23S rRNA intergenic region, to detect and identify nine species that are of high interest for the microbiological control of water. METHODS AND RESULTS: The analysis of the fragments was carried out using a High Resolution acrylamide/bisacrylamide gels in a fluorescent automated DNA sequencer. The results showed specific profiles for each of the nine species but this technique failed to detect simultaneously micro-organisms in samples containing a mixed population. CONCLUSION: Nevertheless, the electrophoretic profiles obtained provided a very useful tool for the rapid and specific identification of water isolates. SIGNIFICANCE AND IMPACT OF THE STUDY: A possible new methodology for a rapid identification of pathogens in water.     

Quantification of Microthrix parvicella in activated sludge bacterial communities by real-time PCR

AIMS: This study was to develop a simple and reliable method for quantifying Microthrix parvicella 16S rRNA gene copies and its application to activated sludge samples collected from wastewater treatment plants (WWTP) with and without foaming problems. METHODS AND RESULTS: The relative frequency of M. parvicella was determined by combining real-time PCR assays for quantification of total bacterial 16S rRNA gene copies and M. parvicella 16S rRNA gene copies. The developed method was applied to analyse 32 activated sludge samples obtained from German WWTP. The level of M. parvicella 16S rRNA gene copies in the 18 nonfoaming samples was below 3% of the total number of 16S rRNA gene copies and in the range of 0-18% for the 14 foaming samples. CONCLUSIONS: The described method allows reliable monitoring of the amount of M. parvicella in activated sludge samples. SIGNIFICANCE AND IMPACT OF THE STUDY: The described method may become an important component of a warning system for forthcoming bulking and foaming episodes.     

Filter-based PNA in situ hybridization for rapid detection, identification and enumeration of specific micro-organisms

AIMS: A method for rapid and simultaneous detection, identification and enumeration of specific micro-organisms using Peptide Nucleic Acid (PNA) probes is presented. METHODS AND RESULTS: The method is based on a membrane filtration technique. The membrane filter was incubated for a short period of time. The microcolonies were analysed by in situ hybridization, using peroxidase-labelled PNA probes targeting a species-specific rRNA sequence, and visualized by a chemiluminescent reaction. Microcolonies were observed as small spots of light on film, thereby providing simultaneous detection, identification and enumeration. The method showed 95-100% correlation to standard plate counts along with definitive identification due to the specificity of the probe. CONCLUSION: Using the same protocol, results were generated approximately three times faster than culture methods for Gram-positive and -negative bacterial species and yeast species. SIGNIFICANCE AND IMPACT OF THE STUDY: The method is an improvement on the current membrane filtration technique, providing rapid determination of the level of specific pathogens, spoilage or indicator micro-organisms.     

Detection and quantification of Brettanomyces bruxellensis and 'ropy' Pediococcus damnosus strains in wine by real-time polymerase chain reaction

AIMS: Brettanomyces bruxellensis is a well-known wine spoilage yeast that causes undesirable off-flavours. Likewise, glucan-producing strains of ropy Pediococcus damnosus are considered as spoilage micro-organisms because the synthesis of glucan leads to an unacceptable viscosity of wine. METHODS AND RESULTS: We developed a real-time PCR method to detect and quantify these two spoilage micro-organisms in wine. It is based on specific primer pairs for amplification of target DNA, and includes a melting-curve analysis of PCR products as a confirmatory test. CONCLUSIONS: The detection limit in wine was 10(4) CFU ml(-1) for B. bruxellensis and 40 CFU ml(-1) for ropy Pediococcus damnosus. The real-time PCR proved to be reliable for the early, sensitive detection and quantification of B. bruxellensis and ropy P. damnosus in wine. SIGNIFICANCE AND IMPACT OF THE STUDY: The real-time PCR-based method described in this study provides a new tool for monitoring spoilage micro-organisms in wine. Time-consuming culture and colony isolation steps are no longer needed, so winemakers can intervene before spoilage occurs.     

Rapid detection of Oenococcus oeni in wine by real-time quantitative PCR

AIMS: To develop a real-time polymerase chain reaction (PCR) method for rapid detection and quantification of Oenococcus oeni in wine samples for monitoring malolactic fermentation. METHODS AND RESULTS: Specific primers and fluorogenic probe targeted to the gene encoding the malolactic enzyme of O. oeni were developed and used in real-time PCR assays in order to quantify genomic DNA either from bacterial pure cultures or wine samples. Conventional CFU countings were also performed. The PCR assay confirmed to be specific for O. oeni species and significantly correlated to the conventional plating method both in pure cultures and wine samples (r = 0.902 and 0.96, respectively). CONCLUSIONS: The DNA extraction from wine and the real-time PCR quantification assay, being performed in ca 6 h and allowing several samples to be concurrently processed, provide useful tools for the rapid and direct detection of O. oeni in wine without the necessity for sample plating. SIGNIFICANCE AND IMPACT OF THE STUDY: Rapid quantification of O. oeni by a real-time PCR assay can improve the control of malolactic fermentation in wines allowing prompt corrective measures to regulate the bacterial growth.     

Simultaneous monitoring of two fungal genotypes on plant roots by single nucleotide polymorphism quantification with an innovative KASPar quantitative PCR

An innovative quantitative PCR-based method derived from the Kompetitive Allele Specific PCR Assay Reagent (KASPar) system was developed to quantify the genomic DNA from two coexisting genotypes on the same tissues of a host-plant. For this purpose, the classical end-point KASPar method was evolved to a real-time method thanks to the addition of an adapted measurement step after each PCR cycle. It was applied to the quantification of the two genotypes G1 and G2 of the Gaeumannomyces graminis var. tritici (Ggt) soilborne fungus, pathogenic on wheat roots. Specific primers targeting a single nucleotide polymorphism from the ITS sequence were used allowing simultaneous quantification of both genotypes in the same reaction. The assays were applied to quantify fungal DNA of each genotype, aside or mixed together, after DNA extraction from fungal pure cultures and from single or co-inoculated roots in artificial medium or in soil. The detection and quantification lower limits for the two genotypes were 1.25 pg and 5 pg for DNA from fungal pure cultures, and 1.8 pg and 7 pg for DNA from fungal inoculated roots. The advantages of this cost-effective method are the high levels of specificity, sensitivity and reproducibility. Moreover, the accuracy of the method is independent of the copy numbers of the target sequences. The method is the first one to adapt the non-quantitative genotyping KASPar system to a quantitative application of two known genotypes of a species simultaneously and is suitable for simultaneous genotype-specific quantification of any other organisms (fungi, bacteria, plants).     

Evaluation of group-specific, 16S rRNA-targeted scissor probes for quantitative detection of predominant bacterial populations in dairy cattle rumen

AIMS: To develop a suite of group-specific, rRNA-targeted oligonucleotide scissor probes for the quantitative detection of the predominant bacterial groups within the ruminal microbial community with the rRNA cleavage reaction-mediated microbial quantification method. METHODS AND RESULTS: Oligonucleotides that complement the conserved sites of the 16S rRNA of phylogenetically defined groups of bacteria that significantly contribute to the anaerobic fermentation of carbohydrates in ruminal ecosystems were selected from among published probes or were newly designed. For each probe, target-specific rRNA cleavage was achieved by optimizing the formamide concentration in the reaction mixture. The set of scissor probes was then used to analyse the bacterial community in the rumen fluids of four healthy dairy cows. In the rumen fluid samples, the genera Bacteroides/Prevotella and Fibrobacter and the Clostridium coccoides-Eubacterium rectale group were detected in abundance, accounting for 44-48%, 2.9-10%, and 9.1-10% of the total 16S rRNA, respectively. The coverage with the probe set was 71-78% of the total bacterial 16S rRNA. CONCLUSIONS: The probe set coupled with the sequence-specific small-subunit rRNA cleavage method can be used to analyse the structure of a ruminal bacterial community. SIGNIFICANCE AND IMPACT OF THE STUDY: The probe set developed in this study provides a tool for comprehensive rRNA-based monitoring of the community members that dominate ruminal ecosystems. As the ruminal microbial community can be perturbed, it is important to track its dynamics by analysing microbiological profiles under specific conditions. The method described here will provide a convenient approach for such tracking.     

Advances in disinfection testing and modelling

AIMS: To develop a set of kinetic equations which more ably describe the disinfection process. METHODS AND RESULTS: A group of functions, the fat equations, based on the model used for the quantification of microbial inhibition, was produced. These functions introduce a limit to the numbers of micro-organisms capable of being disinfected. These new expressions were shown to be more general forms of currently-used (e.g. log-linear) disinfection models, and accommodate the lags and/or tails of non-linear log-survivor--time plots. An advance in the experimental procedures used to obtain disinfection data, using an optical density technique, was developed concomitantly. CONCLUSION: The methods of analyses (experimental and modelling) allow the researcher to examine, more ably, five-minute disinfection (or specific time disinfection tests) as well as the more important disinfection rate analyses. SIGNIFICANCE AND IMPACT OF THE STUDY: The fat equations are an improvement over commonly-used rate models of disinfection, which are shown to be special cases of these equations. This raises the question as to whether our current understanding of the kinetic basis of disinfection requires revision.     

Enumeration of total bacteria and bacteria with genes for proteolytic activity in pure cultures and in environmental samples by quantitative PCR mediated amplification

Real-time quantitative PCR assays were developed for the absolute quantification of different groups of bacteria in pure cultures and in environmental samples. 16S rRNA genes were used as markers for eubacteria, and genes for extracellular peptidases were used as markers for potentially proteolytic bacteria. For the designed 16S rDNA TaqMan assay, specificity of the designed primer-probe combination for eubacteria, a high amplification efficiency over a wide range of starting copy numbers and a high reproducibility is demonstrated. Cell concentrations of Bacillus cereus, B. subtilis and Pseudomonas fluorescens in liquid culture were monitored by TaqMan-PCR using the 16S rDNA target sequence of Escherichia coli as external standard for quantification. Results agree with plate counts and microscopic counts of DAPI stained cells. The significance of 16S rRNA operon multiplicity to the quantification of bacteria is discussed.Furthermore, three sets of primer pair together with probe previously designed for targeting different classes of bacterial extracellular peptidases were tested for their suitability for TaqMan-PCR based quantification of proteolytic bacteria. Since high degeneracy of the probes did not allow accurate quantification, SybrGreen was used instead of molecular probes to visualize and quantify PCR products during PCR. The correlation between fluorescence and starting copy number was of the same high quality as for the 16S rDNA TaqMan assay for all the three peptidase gene classes. The detected amount of genes for neutral metallopeptidase of B. cereus, for subtilisin of B. subtilis and for alkaline metallopeptidase of P. fluorescens corresponded exactly to the numbers of bacteria investigated by the 16S rDNA targeting assay.The developed assays were applied for the quantification of bacteria in soil samples.     

Detection of recombinant Pseudomonas putida in the wheat rhizosphere by fluorescence in situ hybridization targeting mRNA and rRNA

A method was developed to detect a specific strain of bacteria in wheat root rhizoplane using fluorescence in situ hybridization and confocal microscopy. Probes targeting both 23S rRNA and messenger RNA were used simultaneously to achieve detection of recombinant Pseudomonas putida (TOM20) expressing toluene o-monooxygenase (tom) genes and synthetic phytochelatin (EC20). The probe specific to P. putida 23S rRNA sequences was labeled with Cy3 fluor, and the probe specific to the tom genes was labeled with Alexa647 fluor. Probe specificity was first determined, and hybridization temperature was optimized using three rhizosphere bacteria pure cultures as controls, along with the P. putida TOM20 strain. The probes were highly specific to the respective targets, with minimal non-specific binding. The recombinant strain was inoculated into wheat seedling rhizosphere. Colonization of P. putida TOM20 was confirmed by extraction of root biofilm and growth of colonies on selective agar medium. Confocal microscopy of hybridized root biofilm detected P. putida TOM20 cells emitting both Cy3 and Alexa647 fluorescence signals.     

Multiple competitive PCR-DGGE as a tool for quantifying and profiling defined mixed cultures of lactic acid bacteria during production of probiotics from complex polysaccharides

AIMS: To apply a denaturing gradient gel electrophoretic (DGGE) method to quantify and profile individual strains during a mixed culture fermentation. METHODS AND RESULTS: DNA was extracted during the culture of lactic acid bacteria (LAB) and amplified in a multiple competitive PCR (cPCR) using general primers targeting 16S rDNA and DNA from Streptococcus salivarius as competitive DNA. Subsequently the 200-kb amplified fragments were separated by DGGE. The method was validated in pure cultures and used to profile a mixture of three LAB grown on glucose, soluble starch and glycogen from mussel processing waste. The inclusion of a starch- and glycogen-degrading strain (Lactobacillus plantarum) and a weakly amylotic nisin-resistant strain (Lact. paracasei) allowed proliferation of the nisin producing Lactococcus lactis which in itself is unable to grow on complex carbohydrates. cPCR-DGGE permitted the monitoring of a different strain succession on the different carbohydrates, related to amylolytic activity and substrate consumption, acid production and nisin production. CONCLUSIONS: cPCR-DGGE is a useful tool for profiling defined mixed cultures of bacteria and hence allows their interaction to be studied. SIGNIFICANCE AND IMPACT OF THE STUDY: Provided validation of the method for each specific case, it may be appropriate to monitor and control the reproducibility of any defined mixed culture of bacteria, with the advantage that an increase in the strain numbers to be monitored does not yield an increase in the labour of the procedure.     

The molecular diversity of the methanogenic community in a hypereutrophic freshwater lake determined by PCR-RFLP

AIMS: To combine database-held sequence information with a programme of experimental molecular ecology to define the methanogenic community of a hypereutrophic lake by a PCR-restriction fragment length polymorphism (RFLP) analysis. METHODS AND RESULTS: Methanogen diversity in a hypereutrophic freshwater lake was analysed using 16S rDNA PCR-RFLP. Database-held 16S rRNA gene sequences for 76 diverse methanogens were analysed for specific restriction sites that permitted unequivocal differentiation of methanogens. Restriction digestion and agarose gel electrophoresis of the 16S rDNA from selected methanogen pure cultures generated observed restriction profiles that corroborated the expected patterns. This method was then tested by analysing methanogen diversity in samples obtained over 1 year from sediment and water samples taken from the same sampling site. CONCLUSIONS: Restriction analysis of the 16S rRNA gene sequences from 157 methanogen clones generated from lakewater and sediment samples showed that over 50% were similar to Methanoculleus spp. Furthermore, a total of 16 RFLP types (1-16) were identified, eight of which contained no cultured representative archaeal 16S rRNA gene sequences. SIGNIFICANCE AND IMPACT OF THE STUDY: This RFLP strategy provides a robust and reliable means to rapidly identify methanogens in the environment.     

DETECTION OF THE TOXIC DINOFLAGELLATE ALEXANDRIUM FUNDYENSE (DINOPHYCEAE) WITH OLIGONUCLEOTIDE AND ANTIBODY PROBES: VARIABILITY IN LABELING INTENSITY WITH PHYSIOLOGICAL CONDITION

The toxic dinoflagellate Alexandrium fundyense Balech was grown under temperature- and nutrient-limited conditions, and changes in labeling intensity on intact cells were determined for two probe types: an oligonucleotide probe targeting rRNA and a monoclonal antibody (MAb) targeting a cell surface protein. In nutrient-replete batch culture, labeling with the rRNA probe was up to 400% brighter during exponential phase than during stationary phase, whereas MAb labeling did not change significantly with growth stage at the optimal growth temperature. In cultures grown at suboptimal, low temperatures, there was a significant difference between labeling intensity in stationary versus exponential phase for both probe types, with exponential cells labeling brighter with the rRNA probe and slightly weaker with the MAb. The decrease in rRNA probe labeling with increasing culture age was likely due to lower abundance of the target nucleic acid, as extracted RNA varied in a similar manner. With the MAb and the rRNA probes, slower growing cultures at low, nonoptimal temperature labeled 35% and 50% brighter than cells growing faster at warmer temperatures. Some differences in labeling intensity per cell disappeared when the data were normalized to surface area or volume, which indicated that the number of target antigens or rRNA molecules was relatively constant per unit area or volume, respectively. Slow growth accompanying phosphorus and nitrogen limitation resulted in up to a 400% decrease in labeling intensity with the rRNA probe compared to nutrient-replete levels, whereas the MAb labeling intensity increased by a maximum of 60%. With both probes, labeling was more intense under phosphorus limitation than under nitrogen limitation, and for all conditions tested, labeling intensity was from 600% to 3600% brighter with the MAb than with the rRNA probe. Thus, it is clear that significant levels of variability in labeling intensity can be expected with both probe types because of the influence of environmental conditions and growth stage on cellular biochemistry, cell size,rRNA levels, and the number or accessibility of cell surface proteins. Of the two probes tested, the rRNA probe was the most variable, suggesting that in automated, whole-cell assays, it can be used only in a semiquantitative manner. For manual counts, the human eye will likely accommodate the labeling differences. The MAb probe was less variable, and thus should be amenable to both manual and automated counts.     

Usefulness of a TaqMan-based polymerase chain reaction assay for the detection of the fish pathogen Flavobacterium psychrophilum

AIMS: This study developed a new diagnostic method for the bacterium Flavobacterium psychrophilum based on a TaqMan polymerase chain reaction (PCR) assay. METHODS AND RESULTS: Based on reported and newly designed PCR probes, a rapid procedure, that requires no post-PCR processing, was developed for the detection of F. psychrophilum by measuring the fluorescence produced during PCR amplification. Primers were designed to amplify a 971-bp fragment of the 16S rRNA as the target. When different F. psychrophilum strains and other bacterial species, that are taxonomically and ecologically related, were assayed the fluorogenic test was 100% specific in identifying all of the F. psychrophilum strains. The sensitivity of the assay was found to be 1.1 pg DNA and the assay was linear over a range of 0.1 pg-11.2 ng. With pure cultures of F. psychrophilum, the assay was linear over the range 0.4-4.7 x 104 cfu and was able to detect 4.7 cfu per reaction. The analysis was reproducible using either extracted DNA or pure culture. Results using artificially infected fish and diseased fry from natural fish farm outbreaks showed that the assay was useful for diagnosis. CONCLUSIONS: The data showed that the assay was as specific, sensitive, reproducible and rapid but less toxic than the PCR assays described and so very useful for the diagnosis of these micro-organisms. SIGNIFICANCE AND IMPACT OF THE STUDY: This new approach permits a rapid, easy and safe routine laboratory diagnosis of F. psychrophilum.     

Evaluating rRNA as an indicator of microbial activity in environmental communities: limitations and uses

Microbes exist in a range of metabolic states (for example, dormant, active and growing) and analysis of ribosomal RNA (rRNA) is frequently employed to identify the ‘active'' fraction of microbes in environmental samples. While rRNA analyses are no longer commonly used to quantify a population''s growth rate in mixed communities, due to rRNA concentration not scaling linearly with growth rate uniformly across taxa, rRNA analyses are still frequently used toward the more conservative goal of identifying populations that are currently active in a mixed community. Yet, evidence indicates that the general use of rRNA as a reliable indicator of metabolic state in microbial assemblages has serious limitations. This report highlights the complex and often contradictory relationships between rRNA, growth and activity. Potential mechanisms for confounding rRNA patterns are discussed, including differences in life histories, life strategies and non-growth activities. Ways in which rRNA data can be used for useful characterization of microbial assemblages are presented, along with questions to be addressed in future studies.