Development and evaluation of a loop‐mediated isothermal amplification assay for rapid detection of chicken anaemia virus

Aim: Chicken anaemia virus (CAV) causes an economically important viral disease in chickens worldwide. The main aim of this study was to establish a rapid, sensitive and specific loop‐mediated isothermal amplification (LAMP) assay for detecting CAV infection. Methods and Results: A set of four specific LAMP primers were designed based on the nucleotide sequence of the CAV VP2 gene, which encodes a nonstructural protein. These were used for the amplification of a specific target region of the VP2 gene. LAMP amplicons were successfully amplified and detected by DNA electrophoresis and by direct naked eye SYBR Green I visualization. A sensitivity test systematically demonstrated that the LAMP assay was superior to a conventional PCR assay with a minimum concentration limit of 100 fg compared to 10 ng for the conventional PCR. The specificity of the LAMP assay for CAV detection is consistent with conventional PCR. Using this established LAMP assay, infected and uninfected clinical samples obtained from an experimental farm were fully verified. Conclusions: A novel nucleic acid‐based approach of LAMP assay was successfully developed for detecting CAV infection. Significance and Impact of the Study: In this study, these results indicate that the developed LAMP assay herein for CAV detection is a time‐effective, simple, sensitive and specific test that can be used as an alternative approach in the future for large‐scaled diagnosis on the farm of CAV infection.     

Development of a loop-mediated isothermal amplification assay for porcine circovirus type 2

In this study,the loop-mediated isothermal amplification(LAMP)method was used to develop a rapid and simple detection system for porcine circovirus type 2(PCV2).According to the PCV2 sequences published in GenBank,multiple LAMP primers were designed targeting conserved sequences of PCV2.Using the DNA extracted from PCV2 isolates HUN-09 and SD-09 as the template,LAMP reactions in a PCV2 LAMP system was performed,the amplification products were detected by adding SYBR Green I and could be observed directly by the naked eye.The results showed highly-efficient and specific amplification in 30 min at 63℃ with a LAMP real-time turbidimeter.Furthermore,PCV2 DNA templates,with a detection limit of 5.5×10-5ng of nucleic acid,indicated that this assay was highly sensitive.The results obtained with the naked eye after SYBR Green I staining were consistent with those detected by the real-time turbidimeter,showing the potential simplicity of interpretation of the assay results.The LAMP assay appeared to have greater accuracy than PCR and virus isolation for the analysis of 18 clinical samples.In addition it offers higher specificity and sensitivity,shorter reaction times and simpler procedures than the currently available methods of PCV2 detection.It is therefore a promising tool for the effective and efficient detection of PCV2.     

Loop-mediated Isothermal Amplification (LAMP) test for detection of Trypanosoma evansi strain B

Camel Trypanosomiasis (Surra) is mainly caused by Trypanosoma evansi strains that express variable surface glycoprotein (VSG) RoTat 1.2. However, in Kenya a second causative strain that does not express RoTat 1.2 VSG (T. evansi type B) has been identified. The prevalence of T. evansi type B largely remains unknown due to inadequate diagnostic assay. This work reports the development of a sensitive and specific diagnostic assay capable of detecting T. evansi type B based on the strategy of Loop-mediated Isothermal Amplification (LAMP) of DNA. The test is rapid and amplification is achieved within 20-25 min at 63 °C using a real time PCR machine. Restriction enzyme AluI digestion of the amplicon gave the predicted 83 bp and 89 bp sized bands and the LAMP product melt curves showed consistent melting temperature (T_m) of ∼89 °C. The assay analytical sensitivity is ∼0.1 tryps/ml while that of classical PCR test targeting the same gene is ∼10 tryps/ml. There was a 100% agreement in detection of the LAMP amplification product in real time, gel electrophoresis, on addition of SYBR Green I, and when using chromatographic Lateral Flow Dipstick (LFD) format. The use of the LAMP test revealed nine more T. evansi type B DNA samples that were not initially detected through PCR. The robustness and higher sensitivity of the T. evansi type B LAMP assay coupled with the visual detection of the amplification product indicate that the technique has strong potential as a point-of-use test in surra endemic areas.     

Loop-mediated isothermal amplification targeting the apxIVA gene for detection of Actinobacillus pleuropneumoniae

Loop-mediated isothermal amplification (LAMP) is a novel nucleic acid amplification method performed under isothermal conditions with high specificity and efficiency. We developed a diagnostic method based on LAMP for detection of Actinobacillus pleuropneumoniae . Using six specific primers targeting the apxIVA gene, the LAMP assay rapidly amplified the target gene within 30 min, requiring only a laboratory water bath for the reaction to occur. The resulting amplificon was visualized by adding SYBR Green I to the mixture. The results obtained from testing 15 A. pleuropneumoniae reference strains and other seven bacterial species strains showed that the LAMP was as specific as and 10 times more sensitive than nested PCR. Sixty-five tonsil samples were collected from 65 healthy pigs. All the samples were negative for A. pleuropneumoniae by immunomagnetic separation-based (IMS) bacterial isolation, nested PCR and LAMP, respectively. Meanwhile, 115 tonsil samples were also collected from 115 pigs with apparent respiratory problems. Twenty-two were positive by IMS bacterial isolation. All the samples that were positive by IMS bacterial isolation were also positive by nested PCR and LAMP. The LAMP assay demonstrated exceptionally higher sensitivity than nested PCR by picking up 14 additional positive cases (χ² test, P <0.0001); we concluded that LAMP was a highly sensitive and reliable method for detection of A. pleuropneumoniae infection.     

Loop-mediated isothermal amplification (LAMP) method for rapid detection of Trypanosoma brucei rhodesiense

Loop-mediated isothermal amplification (LAMP) of DNA is a novel technique that rapidly amplifies target DNA under isothermal conditions. In the present study, a LAMP test was designed from the serum resistance-associated (SRA) gene of Trypanosoma brucei rhodesiense, the cause of the acute form of African sleeping sickness, and used to detect parasite DNA from processed and heat-treated infected blood samples. The SRA gene is specific to T. b. rhodesiense and has been shown to confer resistance to lysis by normal human serum. The assay was performed at 62 degrees C for 1 h, using six primers that recognised eight targets. The template was varying concentrations of trypanosome DNA and supernatant from heat-treated infected blood samples. The resulting amplicons were detected using SYTO-9 fluorescence dye in a real-time thermocycler, visual observation after the addition of SYBR Green I, and gel electrophoresis. DNA amplification was detected within 35 min. The SRA LAMP test had an unequivocal detection limit of one pg of purified DNA (equivalent to 10 trypanosomes/ml) and 0.1 pg (1 trypanosome/ml) using heat-treated buffy coat, while the detection limit for conventional SRA PCR was approximately 1,000 trypanosomes/ml. The expected LAMP amplicon was confirmed through restriction enzyme RsaI digestion, identical melt curves, and sequence analysis. The reproducibility of the SRA LAMP assay using water bath and heat-processed template, and the ease in results readout show great potential for the diagnosis of T. b. rhodesiense in endemic regions.     

Development of a visual loop-mediated isothermal amplification method for rapid detection of the bacterial pathogen Pseudomonas putida of the large yellow croaker (Pseudosciaena crocea)

In recent years, the large yellow croaker (Pseudosciaena crocea), an important marine fish farmed in the coastal areas of Zhejiang province, east China, has become severely endangered as a result of the bacterial pathogen Pseudomonas putida. This paper reports the development of a visual loop-mediated isothermal amplification (LAMP) assay for rapid detection of the pathogen. Four primers, F3, B3, FIP and BIP, were designed on the basis of DNA sequence of the rpoN gene of P. putida. After optimization of the reaction conditions, the detection limit of LAMP assay was 4.8cfu per reaction, 10-fold higher than that of conventional PCR. The assay showed high specificity to discriminate all P. putida isolates from nine other Gram-negative bacteria. The assay also successfully detected the pathogen DNA in the tissues of infected fish. For visual LAMP without cross-contamination, SYBR Green I was embedded in a microcrystalline wax capsule and preset in the reaction tubes; after the reaction the wax was melted at 85°C to release the dye and allow intercalation with the amplicons. The simple, highly sensitive, highly specific and cost-effective characteristics of visual LAMP may encourage its application in the rapid diagnosis of this pathogen.     

Loop-mediated isothermal amplification method for rapid detection of the toxic dinoflagellate Alexandrium, which causes algal blooms and poisoning of shellfish

The marine dinoflagellate genus Alexandrium includes a number of species that produce potent neurotoxins responsible for paralytic shellfish poisoning, which in humans may cause muscular paralysis, neurological symptoms and, in extreme cases, death. Because of the genetic diversity of different genera and species, molecular tools may help to detect the presence of target microorganisms in marine field samples. Here we employed a loop-mediated isothermal amplification (LAMP) method for the rapid and simple detection of toxic Alexandrium species. A set of four primers were designed based upon the conserved region of the 5.8S rRNA gene of members of the genus Alexandrium . Using this detection system, toxic Alexandrium genes were amplified and visualized as a ladder-like pattern of bands on agarose gels under isothermal condition within 60 min. The LAMP amplicons were also directly visualized by eye in the reaction tube by the addition of SYBR Green I. This LAMP assay was 10-fold more sensitive than a conventional PCR method with a detection limit of 5 cells per tube when targeting DNA from Alexandrium minutum . The LAMP assay reported here indicates the potential usefulness of the technique as a valuable simple, rapid alternative procedure for the detection of target toxic Alexandrium species during coastal water monitoring.     

单管可视化环介导等温扩增技术快速检测恶性疟原虫

目的:建立一种基于环介导等温核酸扩增技术(Loop-mediated Isothermal Amplification,LAMP)的恶性疟原虫高灵敏可视化闭管检测方法。方法:针对恶性疟原虫核糖体DNA的序列保守区设计LAMP引物,通过优化LAMP体系中的Mg2+、甜菜碱浓度和反应温度等因素,建立环介导等温扩增法;并结合蜡封反应管对产物进行检测,检测结果可直接通过肉眼观察SYBR Green I荧光显色进行判定。结果:本方法可检测到70个拷贝/管的恶性疟原虫核酸片段,并具有高特异性,可区分检测常见的血液病毒。该法具有如下优点:1、整个反应恒温进行,无需热循环仪;2、闭管检测,极大降低了扩增产物交叉污染的风险;3、检测速度快,整个检测过程只需30 min。结论:该法的建立为恶性疟原虫的现场快速筛检提供了一种简便、高灵敏、高特异的工具。     

Quantitative detection for low levels of Helicobacter pylori infection in experimentally infected mice by real-time PCR

Accurate diagnosis of Helicobacter pylori infection is important in both clinical practice and clinical research. Molecular methods are highly specific and sensitive, and various PCR-based tests have been developed to detect H. pylori in gastric biopsy specimens. We optimized a sensitive and specific quantitative SYBR Green I real-time PCR assay for detection of H. pylori based on amplification of the fragment of a 26-kDa Helicobacter species-specific antigen gene that allows for detection of 5 bacterial cells per PCR sample. Under the assay conditions, SYBR Green I real-time PCR is highly reproducible with a precise log-linear relation in the range of six orders of magnitude of bacterial DNA concentrations. For accurate comparison of H. pylori infection in different tissue samples, the amount of total host DNA in each sample is normalized by TaqMan real-time PCR of glyceraldehyde 3-phosphate dehydrogenase (GAPDH) pseudogenes. The developed method was validated in prophilactically immunized and experimentally infected mice and revealed a level of H. pylori gastric colonisation that was below the limit of detection for a rapid urease test. This new method established for a quantitative analysis of H. pylori in the host's stomach may be useful in experimental studies evaluating new anti-H. pylori drugs and vaccines.     

Detection of periodontal pathogen Porphyromonas gingivalis by loop-mediated isothermal amplification method

A method for nucleic acid amplification, loop-mediated isothermal amplification (LAMP) was employed to develop a rapid and simple detection system for periodontal pathogen, Porphyromonas gingivalis. A set of six primers was designed by targeting the 16S ribosomal RNA gene. By the detection system, target DNA was amplified and visualized on agarose gel within 30 min under isothermal condition at 64 degrees C with a detection limit of 20 cells of P. gingivalis. Without gel electrophoresis, the LAMP amplicon was directly visualized in the reaction tube by addition of SYBR Green I for a naked-eye inspection. The LAMP reaction was also assessed by white turbidity of magnesium pyrophosphate (a by-product of LAMP) in the tube. Detection limits of these naked-eye inspections were 20 cells and 200 cells, respectively. Although false-positive DNA amplification was observed from more than 10(7) cells of Porphyromonas endodontalis, no amplification was observed in other five related oral pathogens. Further, quantitative detection of P. gingivalis was accomplished by a real-time monitoring of the LAMP reaction using SYBR Green I with linearity over a range of 10(2)-10(6) cells. The real-time LAMP was then applied to clinical samples of dental plaque and demonstrated almost identical results to the conventional real-time PCR with an advantage of rapidity. These findings indicate the potential usefulness of LAMP for detecting and quantifying P. gingivalis, especially in its rapidity and simplicity.     

Loop-Mediated Isothermal Amplification (LAMP) Method for Rapid Detection of Trypanosoma brucei rhodesiense

Loop-mediated isothermal amplification (LAMP) of DNA is a novel technique that rapidly amplifies target DNA under isothermal conditions. In the present study, a LAMP test was designed from the serum resistance-associated (SRA) gene of Trypanosoma brucei rhodesiense, the cause of the acute form of African sleeping sickness, and used to detect parasite DNA from processed and heat-treated infected blood samples. The SRA gene is specific to T. b. rhodesiense and has been shown to confer resistance to lysis by normal human serum. The assay was performed at 62°C for 1 h, using six primers that recognised eight targets. The template was varying concentrations of trypanosome DNA and supernatant from heat-treated infected blood samples. The resulting amplicons were detected using SYTO-9 fluorescence dye in a real-time thermocycler, visual observation after the addition of SYBR Green I, and gel electrophoresis. DNA amplification was detected within 35 min. The SRA LAMP test had an unequivocal detection limit of one pg of purified DNA (equivalent to 10 trypanosomes/ml) and 0.1 pg (1 trypanosome/ml) using heat-treated buffy coat, while the detection limit for conventional SRA PCR was ∼1,000 trypanosomes/ml. The expected LAMP amplicon was confirmed through restriction enzyme RsaI digestion, identical melt curves, and sequence analysis. The reproducibility of the SRA LAMP assay using water bath and heat-processed template, and the ease in results readout show great potential for the diagnosis of T. b. rhodesiense in endemic regions.     

African trypanosomiasis: sensitive and rapid detection of the sub-genus Trypanozoon by loop-mediated isothermal amplification (LAMP) of parasite DNA

Control of human African trypanosomiasis (HAT) is dependent on accurate diagnosis and treatment of infected patients. However, sensitivities of tests in routine use are unsatisfactory, due to the characteristically low parasitaemias in naturally infected individuals. We have identified a conserved sequence in the repetitive insertion mobile element (RIME) of the sub-genus Trypanozoon and used it to design primers for a highly specific loop-mediated isothermal amplification (LAMP) test. The test was used to analyse Trypanozoon isolates and clinical samples from HAT patients. The RIME LAMP assay was performed at 62 degrees C using real-time PCR and a water bath. DNA amplification was detectable within 25min. All positive samples detected by gel electrophoresis or in real-time using SYTO-9 fluorescence dye could also be detected visually by addition of SYBR Green I to the product. The amplicon was unequivocally confirmed through restriction enzyme NdeI digestion, analysis of melt curves and sequencing. The analytical sensitivity of the RIME LAMP assay was equivalent to 0.001 trypanosomes/ml while that of classical PCR tests ranged from 0.1 to 1000 trypanosomes/ml. LAMP detected all 75 Trypanozoon isolates while TBR1 and two primers (specific for sub-genus Trypanozoon) showed a sensitivity of 86.9%. The SRA gene PCR detected 21 out of 40 Trypanosoma brucei rhodesiense isolates while Trypanosoma gambiense-specific glycoprotein primers (TgsGP) detected 11 out of 13 T. b. gambiense isolates. Using clinical samples, the LAMP test detected parasite DNA in 18 out of 20 samples which included using supernatant prepared from boiled blood, CSF and direct native serum. The sensitivity and reproducibility of the LAMP assay coupled with the ability to detect the results visually without the need for sophisticated equipment indicate that the technique has strong potential for detection of HAT in clinical settings. Since the LAMP test shows a high tolerance to different biological substances, determination of the appropriate protocols for processing the template to make it a user-friendly technique, prior to large scale evaluation, is needed.     

Real-time quantitative PCR detection of Mycobacterium avium subsp. paratuberculosis and differentiation from other mycobacteria using SYBR Green and TaqMan assays

Sensitive real-time sequence detection methods based on two different chemistries were developed for Mycobacterium avium subsp. paratuberculosis (Map), the causative agent of Johne's disease in cattle. One is based on the detection of SYBR Green bound to PCR products and the second method is more specific, detecting the cleavage of a fluorogenic (TaqMan) probe bound to a target sequence during primer extension phase. Novel primers and probes that amplify small fragments (<80 bp) of the Map specific insertion sequence, IS900 were designed. Both the SYBR Green and TaqMan assays are sensitive, able to detect 4 fg of DNA extracted from Map strain ATCC19698. This amount of DNA corresponds to the detection of 0.8 cells. Map cells were quantified directly from 7H9 broth using the SYBR Green assay and compared to dilutions of DNA extracted from an equivalent number of cells. The SYBR Green assay of 7H9 broth resulted in a minimum detectable limit of 0.07 cells (equivalent to 0.34 fg of DNA). Media ingredients were not observed to interfere with the assay. Since no extraction step was necessary in the direct cell measurements, direct detection was ten-fold more sensitive than detection of extracted DNA. Both SYBR Green and TaqMan assays are highly specific for the detection of Map. They did not detect any closely related members of the avium complex, other species of mycobacteria, or related genera that are likely to be present in environmental samples. No reporter signal was detected during TaqMan assays performed with 100 pg of template DNA from the non-Map organisms.     

基于SYBR Green I的双链DNA定量方法

摘要 基于SYBR Green I荧光染料与双链DNA（dsDNA）结合产生荧光的原理,建立一种高精度、高通量的双链DNA 定量方法。将梯度稀释后的基因组DNA及已知浓度的?DNA与等体积的SYBR Green I（4×）充分混合后,利用荧光定量PCR仪采集荧光信号,以ROX（1×）作为校正染料进行定量分析;同时利用紫外分光光度计对样品进行平行测定,比较该方法与紫外分光光度法的检测限与准确度。紫外分光光度法的检测限为2 ng/?l,而SYBR Green I荧光定量法的检测限可达到0.015 ng/?l,并且在0.015~2 ng/?l范围内,SYBR Green I荧光强度与?DNA浓度呈线性关系（R2=0.9999）,比紫外分光光度法灵敏100倍以上,并可准确定量低纯度的DNA样品。此方法具有重复性好、高通量的特点,仅需少量的生物样本即可满足定量要求,为分子生物学研究及临床检验等多个领域提供了一种可靠的dsDNA定量方法。     

Loop‐mediated isothermal amplification method for rapid detection of Vibrio alginolyticus,the causative agent of vibriosis in mariculture fish

Aims: The purpose of this study was to develop a loop‐mediated isothermal amplification (LAMP) method for the rapid, sensitive and simple detection of Vibrio alginolyticus in mariculture fish. Methods and Results: LAMP primers were designed by targeting the gyrB gene. With Bst DNA polymerase, the target DNA can be clearly amplified for 60 min at 64°C in a simple water bath. The detection sensitivity of the LAMP assay for the detection of V. alginolyticus is about 3·7 × 10² CFU ml^?1 (3·7 CFU per reaction). LAMP products could be judged with agar gel or naked eye after the addition of SYBR Green I. There were no cross‐reactions with other bacterial strains indicating a high specificity of the LAMP. The LAMP method was applied to detect V. alginolyticus‐infected fish tissues effectively. Conclusions: The LAMP established in this study is a simple, sensitive, specific, inexpensive and rapid protocol for the detection of V. alginolyticus. Significance and Impact of the Study: This LAMP method provides an important diagnostic tool for the detection of V. alginolyticus infection both in the laboratory and field.     

Effects of ethidium bromide and SYBR Green I on different polymerase chain reaction systems

In an in-gel polymerase chain reaction (PCR), the generation of a 1750-bp yeast DNA fragment was inhibited when yeast DNA gel-stabs or gel-slices stained with ethidium bromide (EtBr) or SYBR Green I were used. Similar inhibition occurred to a varying degree in the reamplification of PCR fragments in prokaryotic systems. Inclusion of the dyes in PCR resulted in an inhibition at about 10 microg/ml EtBr and at 10,000-20,000-fold dilution of SYBR Green I in all systems. The effect remained unchanged despite increasing the PCR cycles to 40. However, increasing the magnesium chloride concentration did reverse the inhibitory actions, although the PCR specificity was lost. In an unusual observation, we find that, at higher dye concentrations (50 microg/ml EtBr, or thousand fold dilution of SYBR Green I), the input yeast DNA electrophoretic profile is maintained following 25 PCR cycles (despite a denaturation temperature of 94 degrees C). It varied significantly in different DNA systems and was readily reversed by high Mg++ concentrations. It is concluded that, at low Mg++ concentrations, different PCR systems are inhibited to varying extents by intercalating dyes and, in some PCR systems, intercalating dyes at unusually high concentrations maintain input DNA electrophoretic profile.     

A quantitative fluorescence-based microplate assay for the determination of double-stranded DNA using SYBR Green I and a standard ultraviolet transilluminator gel imaging system

Various assays are available for quantification of DNA in solution, but none has been described that is both sensitive and specific for double-stranded (ds) DNA and features practical properties such as low dye and equipment costs, speed, and highly parallel microplate formats. Here we show that quantitative and sensitive measurement of ds DNA in solution is achieved using a 96-well microplate SYBR Green I assay and a standard uv transillumination-based gel-imaging system for detection. Specific detection of ds DNA was obtained over a broad concentration range of 0.5-500 ng using a single low dye concentration of up to 1/6250. Measured SYBR Green I fluorescence was not significantly affected by pH variation (4-10), assay volume (50-250 microliter l), and time (4-15 min), and measurements were appreciably compatile with commonly encountered concentrations of contaminating salts, organics, detergents, and other substances. ds DNA yielded up to 13-fold higher fluorescence compared to single-stranded DNA or RNA, but this ratio was dependent somewhat on GC content and fragment size. Of note, linear ds DNA fluoresced significantly stronger than supercoiled plasmid DNA. Our method should be broadly applicable for sensitive, rapid, and inexpensive ds DNA quantification in the average molecular biology laboratory.