Rapid detection and quantification of five periodontopathic bacteria by real-time PCR

The quantity of periodontopathic bacteria in plaque samples is an important determinant for understanding the etiologic role of bacteria. The real-time PCR method was used to detect and quantify periodontopathic bacteria, such as Actinobacillus actinomycetemcomitans, Bacteroides forsythus, Porphyromonas gingivalis, Treponema denticola, and Treponema socranskii, in saliva and subgingival plaque samples. There was good agreement between the results of conventional PCR and real-time PCR methods. Using the LightCycler system we were able to determine the amount of periodontopathic bacteria within an hour. The real-time PCR method was linear for samples containing from 10(3) to more than 10(8) cells (r2 = 0.999). The application of the real-time PCR method should be useful in the rapid detection and quantification of periodontopathic bacteria in clinical samples.     

Development of a real-time PCR assay for detection and quantification of Rhizobium leguminosarum bacteria and discrimination between different biovars in zinc-contaminated soil

Primers were designed to target 16S rRNA and nodD genes of Rhizobium leguminosarum from DNA extracted from two different soil types contaminated with Zn applied in sewage sludge. Numbers of rhizobia estimated using 16S rRNA gene copy number showed higher abundance than those estimated by both nodD and the most-probable-number (MPN) enumeration method using a plant trap host. Both 16S rRNA gene copies and the MPN rhizobia declined with increased levels of Zn contamination, as did the abundance of the functional gene nodD, providing compelling evidence of a toxic effect of Zn on R. leguminosarum populations in the soil. Regression analysis suggested the total Zn concentration in soil as a better predictor of rhizobial numbers than both NH4NO3-extractable and soil solution Zn. R. leguminosarum bv. viciae nodD gene copies were generally less sensitive to Zn than R. leguminosarum bv. trifolii nodD. The latter were generally below detection limits at Zn levels of >250 mg kg(-1). Although there were differences in the actual numbers estimated by each approach, the response to Zn was broadly similar across all methods. These differences were likely to result from the fact that the molecular approaches assess the potential for nodulation while the MPN approach assesses actual nodulation. The results demonstrate that the use of targeted gene probes for assessing environmental perturbations of indigenous soil rhizobial populations may be more sensitive than the conventional plant bioassay and MPN methods.     

Highly sensitive direct detection and quantification of Burkholderia pseudomallei bacteria in environmental soil samples by using real-time PCR

The soil bacterium and potential biothreat agent Burkholderia pseudomallei causes the infectious disease melioidosis, which is naturally acquired through environmental contact with the bacterium. Environmental detection of B. pseudomallei represents the basis for the development of a geographical risk map for humans and livestock. The aim of the present study was to develop a highly sensitive, culture-independent, DNA-based method that allows direct quantification of B. pseudomallei from soil. We established a protocol for B. pseudomallei soil DNA isolation, purification, and quantification by quantitative PCR (qPCR) targeting a type three secretion system 1 single-copy gene. This assay was validated using 40 soil samples from Northeast Thailand that underwent parallel bacteriological culture. All 26 samples that were B. pseudomallei positive by direct culture were B. pseudomallei qPCR positive, with a median of 1.84 × 10(4) genome equivalents (range, 3.65 × 10(2) to 7.85 × 10(5)) per gram of soil, assuming complete recovery of DNA. This was 10.6-fold (geometric mean; range, 1.1- to 151.3-fold) higher than the bacterial count defined by direct culture. Moreover, the qPCR detected B. pseudomallei in seven samples (median, 36.9 genome equivalents per g of soil; range, 9.4 to 47.3) which were negative by direct culture. These seven positive results were reproduced using a nested PCR targeting a second, independent B. pseudomallei-specific sequence. Two samples were direct culture and qPCR negative but nested PCR positive. Five samples were negative by both PCR methods and culture. In conclusion, our PCR-based system provides a highly specific and sensitive tool for the quantitative environmental surveillance of B. pseudomallei.     

Evaluation of real-time PCR for the detection and quantification of bacteria in chronic obstructive pulmonary disease

Chronic obstructive pulmonary disease (COPD) embraces a number of pathological processes including chronic bronchitis, chronic bronchiolitis and emphysema. The chronic and progressive course of COPD is often aggravated by short periods of increasing symptoms. Respiratory tract infections (RTIs) are the most common causes of COPD exacerbations. Detection and enumeration of respiratory bacteria are important techniques in diagnosing RTIs and in the validation of new treatment methods. We describe here the development and evaluation of real-time PCR assays for the simultaneous direct detection and quantification of a range of respiratory bacteria in individuals with COPD during stable periods and during acute exacerbations of the disease. Sputum samples from 30 subjects in a COPD study were analysed, and results compared with the current gold standard of culture. Real-time PCR assays proved highly sensitive, with no cross-reactivity with other species. The prevalence of bacteria detected by real-time PCR compared with that by culture was substantially higher for Streptococcus pneumoniae, Staphylococcus aureus, Haemophilus spp. and Moraxella catarrhalis. Multiple pathogens were also found with real-time PCR but were not detected by culture. This study demonstrates the potential of such methods in the detection and enumeration of respiratory bacteria.     

Specific and sensitive detection of Ralstonia solanacearum in soil with quantitative, real-time PCR assays

Aims:  The aim of this study was to develop a sensitive and an effective method suitable for large-scale detection and quantification of Ralstonia solanacearum in soil.
Methods and Results:  Based on the specific sequence of R. solanacearum strain G1000, the primer pair R.sol1-R.sol2 and the TaqMan probe Rs-pro were designed, and specific and sensitive PCR detection methods were successfully established. The detection limit was 100 fg μl⁻¹ DNA in conventional PCR and 1·2 fg μl⁻¹ in real-time PCR. By combining real-time PCR with the modified protocols to extract DNA from soil, it was possible to achieve real-time detection of R. solanacearum in soil, and the degree of sensitivity was 100 fg μl⁻¹. To detect inhibition in soil samples, an exogenous internal positive control (IPC) was included preventing false negative results, and IPC was successfully amplified from all samples tested. The methodology developed was used to detect the presence of R. solanacearum in tobacco fields in China.
Conclusions:  The real-time PCR combined with the protocol to extract DNA from soil led to the development of a specific, sensitive and rapid detection method for R. solanacearum in soil.
Significance and Impact of the Study:  The real-time PCR improves the detection sensitivity and specificity and provides an important tool for routine detection of R. solanacearum in soil samples and for epidemiological and ecological studies.     

Rapid specific detection and quantification of bacteria and archaea involved in mineral sulfide bioleaching using real-time PCR

A SybrGreen real-time PCR assay was developed to detect and quantify both total and selected 16S rDNA species of bacteria and archaea involved in the bioleaching of metals from sulfide ores. A set of specific and universal primers based on 16S rDNA sequences was designed and validated for specific detection and quantification of DNA isolated from representative strains of Acidianus brierleyi, Sulfolobus sp., Sulfobacillus thermosulfidooxidans, Sulfobacillus acidophilus, Acidithiobacillus caldus, and Leptospirillum ferrooxidans. An artificial sequence based on 16S rDNA was constructed to quantify total 16S rDNA in mixed DNA samples. The real-time PCR assay was further validated using a mixture of 16S rDNA amplicons derived from the six different species, each added at a known amount. Finally, the real-time PCR assay was used to monitor the change of 16S rDNA copies of four bioleaching strains inoculated into chalcopyrite airlift column reactors operated at different temperatures. The growth dynamics of these strains correlated well with the expected effects of temperature in the chalcopyrite-leaching environment. The suitability of this method for monitoring microbial populations in industrial bioleaching environments is discussed.     

Development of real-time PCR assay for detection and quantification of Sinorhizobium meliloti in soil and plant tissue

Aims:  Sinorhizobium meliloti is a nitrogen-fixing alpha-proteobacterium present in soil and symbiotically associated with root nodules of leguminous plants. To date, estimation of bacterial titres in soil is achieved by most-probable-number assays based on the number of nodules on the roots of test plants. Here, we report the development of two real-time PCR (qPCR) assays to detect the presence of S. meliloti in soil and plant tissues by targeting, in a species-specific fashion, the chromosomal gene rpo E1 and the pSymA gene nod C.
Methods and Results:  rpo E1 and nod C primer pairs were tested on DNA extracted from soil samples unspiked and spiked with known titres of S. meliloti and from plant root samples nodulated with S. meliloti . Results obtained were well in agreement with viable titres of S. meliloti cells estimated in the same samples.
Conclusions:  The developed qPCR assays appear to be enough sensitive, precise and species-specific to be used as a complementary tool for S. meliloti titre estimation.
Significance and Impact of the Study:  These two novel markers offer the possibility of quick and reliable estimation of S. meliloti titres in soil and plant roots contributing new tools to explore S. meliloti biology and ecology including viable but nonculturable fraction.     

Novel root nodule bacteria belonging to the genus Caulobacter

Aims: Aim of this study is to determine the genetic variation of rhizobia associated with horse gram [Macrotyloma uniflorum (Lam.) Verdc.] plants grown in different regions of Andhra Pradesh, India. Methods and Results: Four representative isolates having most representative characters from the previous characterization were selected for 16S rRNA sequence. The sequences were submitted to the NCBI GenBank and Ribosomal Database Project (RDP). The isolates HGR‐4, 6 and 13 showed more than 99% homology between them and they were grouped with Rhizobium reference strains where as the isolate HGR‐25 showed 87·1, 87·4 and 87·2% homology with the isolates HGR‐4, 6 and 13, respectively, and were grouped with reference strains for Caulobacter. The nodulation ability of these isolates on horse gram was confirmed by inoculation tests. Conclusions: The isolate HGR‐25 was identified as Caulobacter isolated from the plants growing in soil samples collected from Khareemnagar district, Andhra Pradesh, India. Inoculation tests revealed that Caulobacter formed nodules on horse gram. It was also confirmed by RDP. Significance and Impact of the Study: This is the first report that a legume was nodulated by a member of the genus Caulobacter, which belongs to the family Caulobacteriaceae in the order Caulobacterales of Alphaproteobacteria.     

Nitric oxide reductase-targeted real-time PCR quantification of denitrifier populations in soil

The quantification of denitrifying bacteria is a component in the further understanding of denitrification processes in the environment. Real-time PCR primers were designed to target two segments of the denitrifier population (cnorB(P) [Pseudomonas mandelii and closely related strains] and cnorB(B) [Bosea, Bradyrhizobium, and Ensifer spp.]) in agricultural soils based on functional cnorB (nitric oxide reductase) gene sequences. Total population numbers were measured using 16S rRNA gene real-time PCR. Two soil microcosm experiments were conducted. Experiment 1 examined the response of the indigenous soil microbial population to the addition of 500 mg/kg glucose-C daily over 7 days in soil microcosms. Changes in the total population were correlated (r = 0.83) between 16S rRNA gene copy numbers and microbial biomass carbon estimates. Members of the cnorB(P) population of denitrifiers showed typical r-strategy by being able to increase their proportion in the total population from starting levels of <0.1% to around 2.4% after a daily addition of 500 mg/kg glucose-C. The cnorB(B) guild was not able to increase its relative percentage of the total population in response to the addition of glucose-C, instead increasing copy numbers only in proportion with the total population measured by 16S rRNA genes. Experiment 2 measured population dynamics in soil after the addition of various amounts of glucose-C (0 to 500 mg/kg) and incubation under denitrifying conditions. cnorB(P) populations increased proportionally with the amount of glucose-C added (from 0 to 500 mg/kg). In soil microcosms, denitrification rates, respiration, and cnorB(P) population densities increased significantly with increasing rates of glucose addition. cnorB(B) guild densities did not increase significantly under denitrifying conditions in response to increasing C additions.     

Quantification of ammonia-oxidizing bacteria in arable soil by real-time PCR

Real-time PCR was used to quantify populations of ammonia-oxidizing bacteria representing the beta subdivision of the class Proteobacteria in samples of arable soil, both nitrogen fertilized and unfertilized, from Mellby, Sweden. Primers and probes targeting a 16S ribosomal DNA region of the ammonia-oxidizing bacteria were designed and used. In the fertilized soil there were approximately 6.2 x 10(7) ammonia-oxidizing bacteria per g of soil, three times more than the number of bacteria in the unfertilized soil. The lytic efficiency of bead beating in these soils was investigated by using populations of free or loosely attached bacteria, bacteria tightly bound to particles, and bacteria in nonfractionated samples. The shapes of the curves generated in these tests showed that the concentration of template DNA released at various times remained constant after 10 to 100 s of bead beating.     

Enumeration and detection of acetic acid bacteria by real-time PCR and nested PCR

Acetic acid bacteria play a negative role in wine making because they increase the volatile acidity of wines. They can survive in the various phases of alcoholic fermentation and it is very important to control their presence and ulterior development. The main objective of the present work is to test fast, sensitive and reliable techniques such as real-time PCR (rt-PCR) and nested PCR for enumerating and detecting the presence of this bacterial group without plating. Primers were designed on the basis of the available 16S rRNA gene sequences and tested successfully with reference acetic acid bacteria strains. The usefulness of rt-PCR was demonstrated by comparing the results with traditional techniques (colony and microscope counting). The results were similar with all the techniques. Optimized rt-PCR enabled numbers between 10(7) and 10(1) cells mL(-1) to be enumerated, while nested PCR detected less than 10 cells mL(-1). Although this latter technique cannot be used for enumeration, it has several advantages in routine laboratory analysis.     

Comparison of different real-time PCR chemistries and their suitability for detection and quantification of genetically modified organisms

Background

The real-time polymerase chain reaction is currently the method of choice for quantifying nucleic acids in different DNA based quantification applications. It is widely used also for detecting and quantifying genetically modified components in food and feed, predominantly employing TaqMan^® and SYBR^® Green real-time PCR chemistries. In our study four alternative chemistries: Lux?, Plexor?, Cycling Probe Technology and LNA^® were extensively evaluated and compared using TaqMan^® chemistry as a reference system.

Results

Amplicons were designed on the maize invertase gene and the 5'-junction of inserted transgene and plant genomic DNA in MON 810 event. Real-time assays were subsequently compared for their efficiency in PCR amplification, limits of detection and quantification, repeatability and accuracy to test the performance of the assays. Additionally, the specificity of established assays was checked on various transgenic and non-transgenic plant species. The overall applicability of the designed assays was evaluated, adding practicability and costs issues to the performance characteristics.

Conclusion

Although none of the chemistries significantly outperformed the others, there are certain characteristics that suggest that LNA^® technology is an alternative to TaqMan^® when designing assays for quantitative analysis. Because LNA^® probes are much shorter they might be especially appropriate when high specificity is required and where the design of a common TaqMan^® probe is difficult or even impossible due to sequence characteristics. Plexor? on the other hand might be a method of choice for qualitative analysis when sensitivity, low cost and simplicity of use prevail.

     

Specific molecular detection of Phytophthora sojae using conventional and real-time PCR

Phytophthora rot, caused by Phytophthora sojae, is one of the most damaging diseases of soybean (Glycine max) worldwide. This disease can be difficult to diagnose and other Phytophthora species can infect soybean. Accurate diagnosis is important for management of Phytophthora rot. The objective of this study was to evaluate polymerase chain reaction (PCR) methods for rapid and specific detection of P. sojae and diagnosis of Phytophthora rot. PCR assays using two sets of primers (PS and PSOJ) that target the ITS region were evaluated for specificity and sensitivity to P. sojae. Genomic DNA extracted from 11 species of Phytophthora and 19 other species of fungal and oomycete pathogens were used to test the specificity of each primer set. The previously published PS primers amplified DNA from P.?sojae and from four other Phytophthora species using conventional PCR, indicating they are not specific for P. sojae. The new PSOJ primers amplified DNA only from P. sojae using conventional and real-time PCR and not from Phytophthora sansomeana, which has been found in soybean production areas, indicating that they are specific for P. sojae. The PSOJ primers were also used to detect P. sojae in diseased soybean tissue and infested soil. The PCR assays based on the PSOJ primers are specific, rapid, and sensitive tools for the detection of P. sojae.     

Non-invasive detection and quantification of the parasitic ciliate Ichthyophthirius multifiliis by real-time PCR

The main parasitic threat to freshwater fish is the ciliate Ichthyophthirius multifiliis. We developed a real-time PCR assay using SYBR Green intercalating fluorescent dye for rapid detection and quantification of I. multifiliis. This non-invasive assay was based on the quantification of I. multifiliis free-swimming stages from filtered water samples, and thus made it possible to preserve host individuals. An alignment of 18S rDNA sequences of I. multifiliis and related species of the ciliate order Hymenostomatida was used to design amplification primers specifically targeting the I. multifiliis 18S rDNA gene. Different standard curves consisting of 2-fold serial dilutions of DNA extracted from 20, 60, 100 and 1000 I. multifiliis cells were constructed. The assay was able to detect less than 0.5 cell equivalent and showed a strong linearity (R2 = 0.984). Water samples were collected from 2 tanks containing heavily infected and apparently uninfected Carassius auratus specimens and were used to test this technique. Positive signals were obtained from water samples collected from both tanks, with a deduced concentration ranging from 3 to 58 I. multifiliis cells l(-1). The assay can detect low concentrations of the parasite in water, presumably corresponding to an early phase of the disease. It may, thus, be a valuable tool in assisting in the monitoring and control of ichthyophthiriasis in aquaculture.     

Direct quantification of fungal DNA from soil substrate using real-time PCR

Detection and quantification of genomic DNA from two ecologically different fungi, the plant pathogen Fusarium solani f. sp. phaseoli and the arbuscular mycorrhizal fungus Glomus intraradices, was achieved from soil substrate. Specific primers targeting a 362-bp fragment from the SSU rRNA gene region of G. intraradices and a 562-bp fragment from the F. solani f. sp. phaseoli translation elongation factor 1 alpha gene were used in real-time polymerase chain reaction (PCR) assays conjugated with the fluorescent SYBR(R) Green I dye. Standard curves showed a linear relation (r(2)=0.999) between log values of fungal genomic DNA of each species and real-time PCR threshold cycles and were quantitative over 4-5 orders of magnitude. Real-time PCR assays were applied to in vitro-produced fungal structures and sterile and non-sterile soil substrate seeded with known propagule numbers of either fungi. Detection and genomic DNA quantification was obtained from the different treatments, while no amplicon was detected from non-seeded non-sterile soil samples, confirming the absence of cross-reactivity with the soil microflora DNA. A significant correlation (P<0.0001) was obtained between the amount of genomic DNA of F. solani f. sp. phaseoli or G. intraradices detected and the number of fungal propagules present in seeded soil substrate. The DNA extraction protocol and real-time PCR quantification assay can be performed in less than 2 h and is adaptable to detect and quantify genomic DNA from other soilborne fungi.     

Highly sensitive real-time PCR for specific detection and quantification of Coxiella burnetii

Background  

Coxiella burnetii, the bacterium causing Q fever, is an obligate intracellular biosafety level 3 agent. Detection and quantification of these bacteria with conventional methods is time consuming and dangerous. During the last years, several PCR based diagnostic assays were developed to detect C. burnetii DNA in cell cultures and clinical samples. We developed and evaluated TaqMan-based real-time PCR assays that targeted the singular icd (isocitrate dehydrogenase) gene and the transposase of the IS1111a element present in multiple copies in the C. burnetii genome.     

A real-time PCR assay for detection and quantification of Mycoplasma agalactiae DNA

AIMS: The aim of this study was to develop a rapid, sensitive, specific tool for detection and quantification of Mycoplasma agalactiae DNA in sheep milk samples. METHODS AND RESULTS: A real-time polymerase chain reaction (PCR) assay targeting the membrane-protein 81 gene of M. agalactiae was developed. The assay specifically detected M. agalactiae DNA without cross-amplification of other mycoplasmas and common pathogens of small ruminants. The method was reproducible and highly sensitive, providing precise quantification of M. agalactiae DNA over a range of nine orders of magnitude. Compared with an established PCR assay, the real-time PCR was one-log more sensitive, detecting as few as 10(1) DNA copies per 10 microl of plasmid template and 6.5x10(0) colour changing units of reference strain Ba/2. CONCLUSIONS: The real-time PCR assay is a reliable method for the detection and quantification of M. agalactiae DNA in sheep milk samples. The assay is more sensitive than gel-based PCR protocols and provides quantification of the M. agalactiae DNA contained in milk samples. The assay is also quicker than traditional culture methods (2-3 h compared with at least 1 week). SIGNIFICANCE AND IMPACT OF THE STUDY: The established real-time PCR assay will help study the patterns of shedding of M. agalactiae in milk, aiding pathogenesis and vaccine efficacy studies.     

Genetic diversity and biogeography of haloalkaliphilic sulphur-oxidizing bacteria belonging to the genus Thioalkalivibrio

A group of 85 isolates of haloalkaliphilic obligately chemolithoautotrophic sulphur-oxidizing bacteria belonging to the genus Thioalkalivibrio were recently obtained from soda lakes in Mongolia, Kenya, California, Egypt and Siberia. They have been analyzed by repetitive extragenic palindromic (rep)-PCR genomic fingerprinting technique with BOX- and (GTG)5-primer set. Cluster analysis was performed using combined fingerprint profiles and a dendrogram similarity value (r) of 0.8 was used to define the same genotype. Fifty-six genotypes were found among the isolates, revealing a high genetic diversity. The strains can be divided into two major clusters, including isolates from the Asiatic (Siberia and Mongolia) and the African (Kenya and Egypt) continents, respectively. The majority (85.9%) of the genotypes were found in only one area, suggesting an endemic character of the Thioalkalivibrio strains. Furthermore, a correlation between fingerprint clustering, geographic origin and the characteristics of the lake of origin was found.