Pg Of Genomic DNA Research Articles

Visualized Detection of Tobacco Anthracnose by a Recombinase Polymerase Amplification-Lateral Flow Dipstick Assay.

Anthracnose caused by Colletotrichum spp. is a widespread fungal disease that is detrimental to tobacco growth and inflicts economic damage of up to 100 million in tobacco-growing regions in China. An early diagnostic tool is vital for the accurate determination and management of anthracnose in the field. This study investigated the diversity of Colletotrichum spp. on tobacco leaves with anthracnose and developed a recombinase polymerase amplification-lateral flow dipstick (RPA-LFD) diagnostic method for the rapid and equipment-independent detection of the main Colletotrichum spp. causing tobacco anthracnose. This assay targeted the chitin synthase gene (chs1) and could be performed in a few minutes (6 to 10 min). All isolates of C. karstii, C. fructicola, and C. gloeosporioides yielded positive results in the RPA-LFD assay, and no cross-reaction occurred with other fungal species from tobacco or other hosts. The detection threshold was 1 pg of genomic DNA under optimal reaction conditions. The entire RPA-LFD assay enabled the detection of pathogen visualization within 30 min without specialized equipment by combining a polyethylene glycol-KOH method for extracting gDNA rapidly from tobacco leaves infected with C. karstii, C. fructicola, and C. gloeosporioides. Based on these results, the RPA-LFD assay is easy to operate, rapid, and equipment-independent and is promising for development as a kit to diagnose tobacco anthracnose in resource-limited settings at point-of-care.

Spore PCR and qPCR Methods for Rapid Detection of Five Colletotrichum Species Responsible for Pepper Anthracnose in Korea

Pepper anthracnose, caused by <i>Colletotrichum</i> spp., leads to a decrease in the quantity of pepper fruit production. Molecular diagnosis is crucial for rapid identification of pathogens and determination of fungicide resistance. However, the traditional process of isolating the pathogen, extracting genomic DNA, and analyzing the gene sequence is time-consuming, which delays rapid diagnosis. In this study, we introduced a method using conidia of <i>Colletotrichum</i> spp. instead of genomic DNA, eliminating the need for DNA extraction or special processing for diagnosis. To elucidate this method, sensitivity was assessed through polymerase chain reaction (PCR) and quantitative real-time PCR (qPCR) tests using internal transcribed spacer-based primer pairs. Both PCR and qPCR tests showed that detection is feasible with just one conidia, with over 1,000 conidia yielding results comparable to approximately 1 pg of genomic DNA. For amplifying the cytochrome b gene for quinone-outside inhibitor fungicide susceptibility testing, detection from a single conidium is achievable, but a stable PCR product is obtained by increasing the number of cycles to 35. Additionally, the addition of 10% grinding fresh chili pepper paste to V8-Juicea gar medium, which is known for inducing conidia rapidly from the isolates, resulted in 3.2 to 6.0 times more conidia compared to the commonly used potato dextrose agar medium, enhancing the potential for swift testing. Taken together, this study presents a direct utilization of pepper anthracnose conidia through PCR or qPCR, offering a valuable technique for amplifying target genes, such as the minimum conidial amount and barcode genes, for molecular identification of anthracnose disease in pepper through PCR and qPCR analysis.

Detection of prolong excretion of Escherichia albertii in stool specimens of a 7-year-old child by a newly developed Eacdt gene-based quantitative real-time PCR method and molecular characterization of the isolates

Escherichia albertii is an emerging zoonotic foodborne pathogen. The clinical significance of this bacterium has increasingly been recognized worldwide. However, diagnostic method has not yet been established and its clinical manifestations are not fully understood. Here, we show that an Eacdt gene-based quantitative real-time PCR (qRT-PCR) developed in this study is 100% specific and sensitive when tested with 39 E. albertii and 36 non-E. albertii strains, respectively. Detection limit of the real-time PCR was 10 colony forming unit (CFU) and 1 pg of genomic DNA per PCR tube. When E. albertii was spiked with 4 × 100–106 CFU per mL to stool of healthy person, detection limit was 4.0 × 103 and 4.0 CFU per mL before and after enrichment culture, respectively. Moreover, the qRT-PCR was able to detect E. albertii in five children out of 246 (2%) but none from 142 adults suffering from gastroenteritis. All five E. albertii strains isolated carried eae and paa genes, however, only one strain harbored stx2f genes. Long-term shedding of stx2f gene-positive E. albertii in a child stool could be detected because of the qRT-PCR developed in this study which might have been missed if only conventional PCR and culture methods were employed. Furthermore, E. albertii isolated from siblings with diarrhea showed clonality by PFGE analysis. Taken together, these data suggest that the Eacdt gene-based qRT-PCR developed for the detection of E. albertii is useful and will assist in determining the real burden and clinical manifestation of E. albertii infections.

A Cost-Effective and Labor-Saving Method for Detecting Human Leukocyte Antigen B27 Status via Sequence-Encoded Fluorescence Amplification Assay

Identification of human leukocyte antigen B27 (HLA-B27) by flow cytometry (FCM) has been widely applied in clinical practice for auxiliary diagnosis of ankylosing spondylitis (AS). However, FCM requires freshly prepared samples and relies on expensive equipment, reagents, and an experienced operator. To provide a cheaper and more convenient method for HLA-B27 detection, we proposed a new method termed sequence-encoded fluorescence amplification assay (SEFA), which specially recognized sequences of HLA-B27 gene (HLA-B∗27) covering current common subtypes in a single closed tube. SEFA could detect as low as 10 pg (equal to 3 copies) genomic DNA per reaction and distinguish HLA-B∗27 from other HLA-B alleles with highly similar sequences. A total of 288 clinical samples were tested by SEFA, including 181 patients with AS and 107 healthy controls. Compared with the detection results from FCM, two controversial samples of patients with AS were obtained and further confirmed to be consistent with SEFA by Sanger sequencing, indicating that this method was more accurate than FCM. Moreover, SEFA could detect HLA-B27 status by using supernatant from crude extract of 10-μL blood without commercial reagents. Overall, SEFA has the potential to be an alternative for HLA-B27 identification with the advantage of convenience and low cost, especially suitable for early diagnosis of AS in areas with limited medical resources.

Development of a TaqMan Real-Time PCR for Early and Accurate Detection of Anthracnose Pathogen Colletotrichum siamense in Pachira glabra.

Anthracnose, caused by Colletotrichum siamense, is a destructive disease of Pachira glabra in southern China. Early and proper monitoring and quantification of C. siamense is of importance for disease control. A calmodulin (CAL) gene-based TaqMan real-time PCR assay was developed for efficient detection and quantification of C. siamense, which reliably detected as low as 5 pg of genomic DNA and 12.8 fg (5800 copies) of target DNA. This method could specifically recognize all tested C. siamense isolates, while no amplification was observed in other closely related Colletotrichum species. The assay could still detect C. siamense in plant mixes, of which only 0.01% of the tissue was infected. A dynamic change in the amount of C. siamense population was observed during infection, suggesting that this real-time PCR assay can be used to monitor the fungal growth progression in the whole disease process. Moreover, the method enabled the detection of C. siamense in naturally infected and symptomless leaves of P. glabra trees in fields. Taken together, this specific TaqMan real-time PCR provides a rapid and accurate method for detection and quantification of C. siamense colonization in P. glabra, and will be useful for prediction of the disease to reduce the epidemic risk.

Ultrasensitive and visual detection of genetically modified crops using two primers-induced cascade exponential amplification assay

The increased global cultivation area of genetically modified (GM) crops has caused severe controversies over potential health and environmental risks worldwide. There is an urgent need to verify even trace amount of a particular GM material in products. Herein, a two primers-induced cascade exponential amplification reaction combined with cationic conjugated polymers (CCPs)-based visual detection method is developed for rapid and ultrasensitive detection of GM crops. This method only uses two primers to specifically recognize the four regions of the target gene, which is easier for primer design and probably more suitable for the detection of shorter targets. By integrating the two exponential amplification reactions, as low as 5 pg genomic DNA from GM maize can be accurately detected, which is more sensitive than the single amplification-based methods. Taking advantage of the efficient fluorescence resonance energy transfer (FRET) between CCPs and the commercial fluorescent dye SYBR Green I (SG), our method can differentiate as low as 0.01 % GM maize from a large amount of non-GM maize, which is the most accurate method so far. By changing the two primers according to target gene, our method can be modified to the detection of any other GM materials, indicating that our method is promising to be applied in other GM materials-related testing and screening system.

Diagnostic assay for molecular detection of Bipolaris maydis and Stenocarpella maydis for safe exchange and long-term conservation of maize germplasm

Maize is a versatile multi-purpose crop used as a feed and food crop and is one of the most extensively grown and traded crops globally. The maize cultivation is greatly influenced by several seed-borne fungal pathogens including Bipolaris maydis and Stenocarpella maydis. Keeping the potential risks associated with movement of seeds, a conventional and qPCR based reliable and sensitive method for detection of B. maydis and S. maydis was developed. Four sets of specific primers derived from kilbournase gene were developed for detection and quantification of S. maydis, whereas, six sets of specific primers were developed from internal transcribed spacer (ITS) region for detection of B. maydis. The specificity and sensitivity of the primers developed for both the fungal pathogens were tested and the primers were found specific to the target pathogens and are able to detect up to 0.1 pg of genomic DNA. A duplex PCR assay for simultaneous detection of these fungal pathogens was successfully established using highly specific and sensitive primer sets, BmayITS1F&5R specific to B. maydis and DMKB4F&4R specific to S. maydis. The primers produced specific size of amplicons in duplex as well as individually for respective target pathogens. The developed protocol in the present study could be utilized effectively for detection and quantification of these pathogens to facilitate the quick quarantine processing, monitor seed health and seed certification thereby preventing infected maize from entering into food and feed chain and also to facilitate their long-term safe conservation.

Development and Sensitivity Determination of 18S rRNA Gene-specific Fast Loop-mediated Isothermal Amplification (LAMP) Assay for Rapid Detection of Acanthamoeba.

Acanthamoeba, one of the free-living amoeba, has been detected in many environmental samples, mainly in water, soil and air. Acanthamoeba keratitis and granulomatous amoebic encephalitis are among the most important clinical manifestations caused by Acanthamoeba. In this study, it was aimed to determine the sensitivity of the rapid loop mediated isothermal amplification (LAMP) test designed with primers specific to Acanthamoeba 18S rRNA gene to detect more rapidly the presence of Acanthamoeba in clinical and environmental samples. Acanthamoeba strain grown in culture was diluted in 200 μL as 1x106 trophozoites and DNA was isolated, and the amount of DNA was determined by Nano-Drop Spectrophotometer. The purified DNAs were diluted from 1000 pg to 0.001 pg and used in colorimetric and fluorescence-based LAMP reactions. The LAMP reaction mixture was incubated for 60 minutes at 63 °C in a total volume of 25 μL. To determine the sensitivity of the test, positivity of Acanthamoeba genomic DNA was observed at 1, 10, 100 and 1000 pg/reaction in both colorimetric and fluorescence-based LAMP tests. The lowest analytical sensitivity of both calorimetric and fluorescent LAMP assay was determined as 1 pg/reaction. In addition, as a result of LAMP reaction applied with other parasite DNAs to evaluate the specificity of the test, no LAMP product was detected in calorimetric and 1% agarose gel electrophoresis, except for positive control, and the specificity of the test was determined as 100%. It has been demonstrated that the LAMP assay designed by targeting 18S rRNA gene of Acanthamoeba has a detection limit of 1 pg of genomic DNA. It is promising that LAMP test is more sensitive and faster than culture method, as well as simple, inexpensive and highly sensitive. For this reason, it is thought that developed test can be applied in the diagnosis of Acanthamoeba in environmental and clinical samples.

Design and 3D printing of an electrochemical sensor for Listeria monocytogenes detection based on loop mediated isothermal amplification

The aim of this work is the design and 3D printing of a new electrochemical sensor for the detection of Listeria monocytogenes based on loop mediated isothermal amplification (LAMP). The food related diseases involve a serious health issue all over the world. Listeria monocytogenes is one of the major problems of contaminated food, this pathogen causes a disease called listeriosis with a high rate of hospitalization and mortality. Having a fast, sensitive and specific detection method for food quality control is a must in the food industry to avoid the presence of this pathogen in the food chain (raw materials, facilities and products). A point-of-care biosensor based in LAMP and electrochemical detection is one of the best options to detect the bacteria on site and in a very short period of time. With the numerical analysis of different geometries and flow rates during sample injection in order to avoid bubbles, an optimized design of the microfluidic biosensor chamber was selected for 3D-printing and experimental analysis.For the electrochemical detection, a novel custom gold concentric-3-electrode consisting in a working electrode, reference electrode and a counter electrode was designed and placed in the bottom of the chamber. The LAMP reaction was optimized specifically for a primers set with a limit of detection of 1.25 pg of genomic DNA per reaction and 100% specific for detecting all 12 Listeria monocytogenes serotypes and no other Listeria species or food-related bacteria. The methylene blue redox-active molecule was tested as the electrochemical transducer and shown to be compatible with the LAMP reaction and very clearly distinguished negative from positive food samples when the reaction is measured at the end-point inside the biosensor.

Quantitative PCR Assays for the Strain-Specific Identification and Enumeration of Probiotic Strain Lacticaseibacillus rhamnosus X253.

Probiotics are universally recognized for their health benefits, despite the fact that their effects depend on the strain. Identification and enumeration of probiotic strains are required prior to evaluating their effectiveness. Lacticaseibacillus rhamnosus X253 is a potential probiotic strain with antioxidant capacity. Comparative genomics and single nucleotide polymorphisms (SNPs) were used to identify a strain-specific locus within the holA gene for strain X253 that was distinct in 30 different L. rhamnosus strains. Using quantitative PCR, the primers and probe designed for the locus were able to distinguish L. rhamnosus X253 from the other 20 probiotic strains. The chosen locus remained stable over 19 generations. The sensitivity of the assay was 0.2 pg genomic DNA of L. rhamnosus X253, or 103 cfu/mL bacteria of this strain. In terms of repeatability and reproducibility, relative standard deviations (RSD) were less than 1% and 3%, respectively. Additionally, this assay achieved accurate enumerations of L. rhamnosus X253 in spiked milk and complex powder samples. The strain-specific assay could be used for quality control and compliance assessment of dairy products.

Development of loop mediated isothermal amplification for rapid species detection of Armillaria ostoyae using assimilating probe

We introduced here the first loop mediated isothermal amplification (LAMP) assay for the identification of honey fungus, Armillaria ostoyae, a basidiomycote playing an important role in spruce declines in the Palaearctic region. In total, 101 isolates, representing three Armillaria species, were used to develop a new LAMP assay to determine species specific identification. We have here described LAMP primers enhanced with fluorescent dye that are able to amplify A. ostoyae DNA and detect fungi in a fast single step reaction. The detection limit of LAMP was 1 pg of genomic DNA per reaction. We optimized a new LAMP assay for the rapid detection of A. ostoyae using the translation elongation factor 1-α (tef1) marker and fluorescence labelled oligonucleotide assimilating probe. The LAMP assay does not require any specialized equipment, hence it can be used in the field for the rapid detection of A. ostoyae even using the portable and mobile device. The specificity of the assay was confirmed by the use of A. ostoyae strains and Armillaria cepistipes and Armillaria gallica strains, respectively. In conclusion, the assay could be a rapid, specific, sensitive and low-cost tool for identification of A. ostoyae as well as the first step for expansion of this method in practical applications.

Detection of chicken adulteration in beef via ladder-shape melting temperature isothermal amplification (LMTIA) assay

The ladder-shape melting temperature isothermal amplification (LMTIA) is a newly developed technique with advantages of simple mechanism, easy primer design, quick turn-around time, high specificity, high sensitivity and short target sequence compared to the loop-mediated isothermal amplification (LAMP) technique. The objective of this research was to establish the LMTIA assay for detection of chicken in beef. The LMTIA primers targeting the prolactin receptor gene of Gallus gallus were designed, the LMTIA reaction system was optimized, the specificity and the sensitivity of the LMTIA assay were determined. Our results showed that the LMTIA assay was able to specifically detect 100 ng genomic DNA of Gallus gallus, without detecting the 100 ng genomic DNA of Anas platyrhynchos, Felis catus, Sus scrofa, Canis lupus familiaris, Bos taurus or Capra hircus. The sensitivity of the LMTIA assay was 100 pg genomic DNA of G. gallus. Furthermore, the LMTIA assay was able to detect the chicken adulterated in beef with ≥0.1% (w/w) detection limit (LOD). This study holds a promise for facilitation of the surveillance of the commercial adulteration of chicken in beef.

A Rapid and Efficient Loop-mediated Isothermal Amplification (LAMP) Assay for the Authentication of Food Supplements Based on Maitake (Grifola Frondosa).

Grifola frondosa (“Maitake”) is an edible fungus with several nutraceutical properties, largely used in traditional medicine. The increased use of Maitake as a food supplements ingredient raised the need of accurate authentication methods since the morphological identification of G. frondosa is not feasible in formulated food supplements. We developed a diagnostic tool based on loop-mediated isothermal AMPlification (LAMP) for the detection of G. frondosa in food supplements. First, a modified CTAB protocol for DNA extraction from food supplements has been set up and it has been shown to be able to isolate amplifiable total genomic material from different types of commercial products. Subsequently, the LAMP assay confirmed high specificity and good analytical sensitivity, allowing to detect up to 0.62 pg of genomic DNA in less than 20 min. Ten related fungal species resulted negative, confirming the specificity of the assay. The presence of Maitake in commercial food supplements was confirmed, except for one, revealing a mislabeling (or a food fraud). This assay proved to be a rapid powerful tool for food authentication purposes and routine inspections at any level of the supply chain of Maitake-based products and it can be used as a model for other quality control assays of fungal food products.Supplementary InformationThe online version contains supplementary material available at 10.1007/s12161-022-02235-0.

Rapid Russula senecis identification assays using loop-mediated isothermal amplification based on real-time fluorescence and visualization.

Russula senecis, a common poisonous mushroom, is widely distributed in China. Mushroom poisoning is becoming a major threat to human health and its rate is increasing worldwide. For the first time, we developed a set of loop-mediated isothermal amplification (LAMP) assays based on a real-time fluorescence and a visualization method to detect R. senecis, and the visual LAMP reaction system was optimized to further shorten the reaction time. Both real-time LAMP and visual LAMP could detect as low as 3.2pg of genomic DNA. In addition, fried and digested mushrooms were used to validate the proposed LAMP method, and mushroom mixtures with as low as 1% of the target species could be successfully detected, indicating that the LAMP assays established in this study had good applicability and could be used for clinical sample detection and forensic identification. Furthermore, the LAMP assays were proven to be comparable to the real-time PCR method. KEY POINTS: • A set of loop-mediated isothermal amplification (LAMP) assays based on real-time fluorescence and visualization to detect Russula senecis was developed. • Both real-time LAMP and visual LAMP can be used to detect genomic DNA at concentrations as low as 3.2pg. • By simulating mushroom processing and digestion in gastric juice, LAMP assays were proved to have good applicability and could be used for clinical diagnosis and forensic analysis.

Development of Recombinase Polymerase Amplification Combined with Lateral Flow Detection Assay for Rapid and Visual Detection of Ralstonia solanacearum in Tobacco.

Bacterial wilt caused by Ralstonia solanacearum is a serious soilborne disease that results in severe losses to tobacco (Nicotiana tabacum) production in China. In this study, a novel RPA-LFD assay for the rapid visual detection of R. solanacearum was established using recombinase polymerase amplification (RPA) and lateral-flow dipstick (LFD). The RPA-LFD assay was performed at 37°C in 30 min without complex equipment. Targeting the sequence of the RipTALI-9 gene, we designed RPA primers (Rs-rpa-F/R) and an LF probe (Rs-LF-probe) that showed high specificity to R. solanacearum. The sensitivity of RPA-LFD assay to R. solanacearum was the same as that in conventional PCR at 1 pg genomic DNA, 103 CFU/g artificially inoculated tobacco stems, and 104 CFU/g artificially inoculated soil. The RPA-LFD assay could also detect R. solanacearum from plant and soil samples collected from naturally infested tobacco fields. These results suggest that the RPA-LFD assay developed in this study is a rapid, accurate molecular diagnostic tool with high sensitivity for the detection of R. solanacearum.

Occurrence, Characteristics, and PCR-Based Detection of Pectobacterium polaris Causing Soft Rot of Chinese Cabbage in China.

Bacterial soft rot is an important disease of Chinese cabbage (Brassica rapa L. ssp. pekinensis) in China and many other countries. Four pectinolytic bacterial strains (WBC1, WBC6, WBC9, and WBC11) were isolated from soft-rotted Chinese cabbage in Beijing, China. Based on 16S rDNA and pmrA gene sequence analyses, multilocus sequence analysis (MLSA), and genomic average nucleotide identity (ANI) analysis, these four strains were identified as Pectobacterium polaris. This species, previously reported from potato in countries not including China, is a new soft rot pathogen of Chinese cabbage in China. Biochemical characteristics of these P. polaris strains tested by Biolog were mostly consistent with those of P. polaris NIBIO1006T. Their pathogenicity on Chinese cabbage is temperature dependent, with all four strains as well as the type strain exhibiting high pathogenicity at 23°C and 28°C. These four strains infected Lactuca sativa, Daucus carota, Solanum tuberosum, and Capsicum annuum by artificial inoculation. Specific polymerase chain reaction (PCR) and quantitative PCR (qPCR) primers for P. polaris were developed on the basis of its specific gene sequences (determined by genome comparison methods). Both PCR and qPCR detected not only genomic DNA of P. polaris but also the pathogen from diseased plant tissues even before external symptoms appeared. Their detection sensitivities were as low as 1 pg and 100 pg genomic DNA of P. polaris, respectively. To our knowledge, this study is the first to both report the emergence of P. polaris on Chinese cabbage in China and provide rapid and accurate PCR/qPCR-based detection systems specific for P. polaris.

Rapid and simultaneous detection of Campylobacter spp. and Salmonella spp. in chicken samples by duplex loop-mediated isothermal amplification coupled with a lateral flow biosensor assay.

Development of a simple, rapid and specific assay for the simultaneous detection of Campylobacter spp. and Salmonella spp. based on duplex loop-mediated isothermal amplification (d-LAMP), combined with lateral-flow biosensor (LFB) is reported herein. LAMP amplicons of both pathogens were simultaneously amplified and specifically differentiated by LFB. The specificity of the d-LAMP-LFB was evaluated using a set of 68 target and 12 non-target strains, showing 100% inclusivity and exclusivity. The assay can simultaneously detect Campylobacter and Salmonella strains as low as 1 ng and 100 pg genomic DNA per reaction, respectively. The lowest inoculated detection limits for Campylobacter and Salmonella species in artificially contaminated chicken meat samples were 103 CFU and 1 CFU per 25 grams, respectively, after enrichment for 24 h. Furthermore, compared to culture-based methods using field chicken meat samples, the sensitivity, specificity and accuracy of d-LAMP- LFB were 95.6% (95% CI, 78.0%-99.8%), 71.4% (95% CI, 29.0%-96.3%) and 90.0% (95% CI, 73.4%-97.8%), respectively. The developed d-LAMP-LFB assay herein shows great potentials for the simultaneous detection of the Campylobacter and Salmonella spp. and poses a promising alternative approach for detection of both pathogens with applications in food products.

Development of a PCR-lateral flow assay for rapid detection of Yersinia pestis, the causative agent of plague

Plague is a zoonotic disease caused by Yersinia pestis, a Gram-negative, rod shaped coccobacillus, which is primarily found in rodents and can be transmitted to humans through flea bite. The disease has three major clinical forms bubonic (by flea bite), pneumonic (by respiratory droplets) and septicemic plague. Y. pestis is classified as a category ‘A’ agent by NIAID, USA due to its high mortality and easy person to person dissemination. The conventional diagnostic methods available for Y. pestis show cross-reactivity with other enteropathogenic bacteria making its detection difficult. There is a need to develop sensitive and specific molecular assay for accurate detection of Y. pestis. PCR is well suited molecular biology tool for rapid diagnosis of plague but after completion of thermal cycling steps, it requires additional time to analyze amplified product using agarose gel electrophoresis. In the present study, PCR assay coupled with lateral flow strips has been developed for rapid detection of Y. pestis. Lateral flow strips give an alternative to gel electrophoresis and permit easy and rapid detection of PCR products. The PCR was performed with 5′ 6-FAM and biotin tagged primers specific for Y. pestis, targeting yihN gene located on chromosome. The PCR product was analyzed using lateral flow strips which yielded result within 2-3 minutes. The analytical sensitivity of PCR-lateral flow (PCR-LF) assay was 1 pg genomic DNA of Y. pestis and 500 copies of target DNA sequence harboured in a recombinant plasmid. The assay could detect Y. pestis DNA extracted from spiked human blood samples containing ≥104 CFU per mL of bacteria. The assay was found to be specific and did not cross react with other closely related bacterial species. The developed assay was highly specific, sensitive and also did not require agarose gel electrophoresis for post amplification analysis.

Development of a PCR Lateral Flow Assay for Rapid Detection of Bacillus anthracis, the Causative Agent of Anthrax.

Bacillus anthracis, the causative agent of anthrax is one of the most potent listed biological warfare agents. The conventional microbiological methods of its detection are labor intensive and time consuming, whereas molecular assays are fast, sensitive and specific. PCR is one of the most reliable diagnostic tools in molecular biology. The combination of PCR with lateral flow strips can reduce the diagnostic/detection time. It gives an alternative to gel electrophoresis and offers easy and clear interpretation of results. In the present study, a PCR Lateral flow (PCR-LF) assay targeting cya gene present on pXO1 plasmid of B. anthracis has been developed. The forward and reverse primers were tagged with 6-carboxyflourescein (6-FAM) and biotin, respectively, at 5' end. The dual labeled PCR products were detected using lateral flow (LF) strips developed in this study. The PCR-LF assay could detect ≥ 5 pg of genomic DNA and ≥ 500 copies of target DNA harboured in a recombinant plasmid. The assay was able to detect as few as 103 and 10 CFU/mL of B. anthracis Sterne cells spiked in human blood after 6 and 24 h of enrichment, respectively.

A one step nested PCR method for detection of Peronospora sparsa, the downy mildew pathogen, in boysenberry (Rubus ursinus)

Downy mildew is a major disease of boysenberries in New Zealand, caused by Peronospora sparsa. Most boysenberry plant material, including tissue culture propagated plants are systemically infected and this pathogen also presents as a latent infection. The current nested PCR method to detect latent infection of P. sparsa in asymptomatic boysenberry plants is time consuming as it employs two separate PCR, with potential contamination producing false positive and/or false negative results. To overcome these issues a one step nested PCR method was developed. The method was optimised for primer concentrations, PCR cycle number and DNA concentration. DNA was extracted using a CTAB method. The one step nested PCR method could detect latent infection of P. sparsa in both dormant and active plant growth at 0.4 pg genomic DNA. The most reliable detection was achieved from crown or root tissues. For surety of the infection status, replicate plant tissues should be assessed by PCR as inconsistency between the one step nested PCR and fluorescence microscopy indicated that P. sparsa colonisation is discontinuous through the plant. This method can be recommended for screening P. sparsa latent infection in boysenberry mother plants and daughter plants in nurseries, due to high sensitivity, improved throughput, low cost, and low contamination risk.