Loop-mediated Isothermal Amplification Reaction Research Articles

Streamlined boiling lysis DNA extraction for Gram-positive aquaculture pathogen Streptococcus agalactiae.

Accurate genetic analysis is essential for the detection of pathogens as it necessitates suitable DNA extraction methods tailored to specific microorganisms such as Gram-positive bacteria. This study examined several commercial and simplified DNA extraction methods for their suitability in isothermal downstream applications. Extracted DNA was assessed using spectrophotometry, electrophoresis, polymerase chain reaction (PCR) and loop-mediated isothermal amplification (LAMP) while its stability was inspected after five months of storage. The findings revealed variations in DNA yield, purity and integrity among the extraction methods. While extraction kits demonstrated high yield and purity, the in-house extraction techniques showed incoherent correlation between yield and purity, yet showed promise for a streamlined extraction process. The DNA acquired from all methods yielded positive amplification in PCR and LAMP. DNA extracted by kits exhibits prolonged stability than those obtained via boiling lysis. Both methods offer distinct advantages, with commercial kits providing longer stability and high-quality DNA while boiling lysis stands out for its simplicity, with shorter handling and processing periods. This study emphasizes selecting ideal extraction methods for Streptococcus agalactiae, in the prospect of aquaculture settings. In particular, successful LAMP reaction suggests that boiled extracts are feasible enough for detection, and suited for point-of-care (POC) testing where prompt detection of aquatic pathogens is often critical. Ultimately, the choice of method should be contemplated on a case-by-case basis such as the study goals, intended settings, and type of samples.

Sex identification of sun conure (Aratinga solstitialis) using loop-mediated isothermal amplification of W and Z spindlin chromosomes.

The sun conure (Aratinga solstitialis), a bird belonging to the Psittaciformes family, is a popular pet because of its bright color and beautiful appearance. The sun conure is a monomorphic bird with similar appearances between males and females, making sex identification difficult by observing the external morphology. Therefore, molecular techniques are utilized. Loop-mediated isothermal amplification (LAMP) is a molecular technique that is often applied for sex identification in birds and is a quick and simple method that can be used in the field. This study used the LAMP technique to improve sex identification in sun conures by observing the color change of hydroxy naphthol blue. Two primer sets, SunSpin-W and SunSpin-Z, were designed for sex identification in sun conures using the LAMP technique specific to the spindlin gene. The developed LAMP reaction was tested for optimal conditions, sensitivity, and specificity compared with the polymerase chain reaction (PCR) technique. The SunSpin-W primer set amplified only female birds, whereas the SunSpin-Z primer set amplified DNA from both male and female birds. The primer sets were optimized at 62°C for 45 min. A positive result was visible to the naked eye from the color change of the reaction. In the LAMP assay, the lowest detectable concentration was 10 pg/μL and in the PCR assay, it was 1 ng/μL, while a 100% accuracy rate in sex identification was observed when comparing the LAMP assay results with the PCR assay. This study successfully developed a LAMP technique for sex identification of sun conure, which took 45 min to complete and can be expanded for use in the field.

Integrating loop-mediated isothermal amplification with lateral flow assay to achieve a highly sensitive method for detecting Streptococcus suis Genome in raw pork

Streptococcus suis (S.suis), a zoonotic foodborne pathogen prevalent in Southeast Asia, poses a substantial threat to human and animal health because of its ability to cause severe and life-threatening illnesses. To address this challenge, a rapid and highly sensitive detection platform for S. suis in raw pork was developed by integrating loop-mediated isothermal amplification (LAMP) and a lateral flow assay (LFA), S. suis LAMP-LFA. LAMP reactions targeting the S. suis glutamate dehydrogenase (gdh) gene were optimized for specific detection of S. suis within 45 min at an isothermal temperature of 65 °C. The assay exhibited marked sensitivity, with a detection limit of 100 fg for genomic DNA extracted from S. suis cultures. Notably, this method showed no cross-reactivity with other bacterial contaminants commonly found in raw pork. The resulting LAMP amplicons were effectively detected using LFA, with a test limit of 101 CFU per 25 g of raw pork. S. suis LAMP-LFA proved to be highly specific and reliable, with no false-positives detected in spiked pork samples or pork samples containing other bacterial contaminants. Due to its high sensitivity, specificity, and rapid turnaround time, the proposed technique has immense potential as a field-deployable screening test for S. suis detection in raw pork, contributing to enhanced food safety and public health protection.

An Integrated Micro-Heating System for On-Chip Isothermal Amplification of African Swine Fever Virus Genes.

The loop-mediated isothermal amplification (LAMP) is widely used in the laboratory to facilitate rapid DNA or RNA detection with a streamlined operational process, whose properties are greatly dependent on the uniformity and rise rate of temperature in the reaction chambers and the design of the primers. This paper introduces a planar micro-heater equipped with an embedded micro-temperature sensor to realize temperature tunability at a low energy cost. Moreover, a control system, based on the Wheatstone bridge and proportional, integral, and derivative (PID) control, is designed to measure and adjust the temperature of the micro-heater. The maximum temperature rise rate of the designed micro-heater is ≈8°Cs-1, and it only takes ≈60s to reach the target temperature. Furthermore, a designed plasmid, containing the B646L gene of African Swine Fever Virus (ASFV), and a set of specific primers, are used to combine with the designed micro-heating system to implement the LAMP reaction. Finally, the lateral flow assay is used to interpret the amplification results visually. This method can achieve highly sensitive and efficient detection of ASFV within 40min. The sensitivity of this on-chip gene detection method is 8.4 copies per reaction, holding great potential for applications in DNA and RNA amplification.

Loop-Mediated Isothermal Amplification for Detecting Gly-4891-Glu and Ile-4734 Multiple Mutations of Ryanodine Receptor in the Fall Armyworm, Spodoptera frugiperda.

The key mutations, such as the Gly-4891-Glu substitution and the Ile-4734 multiple substitutions within the ryanodine receptors (RyR), are linked to diamide resistance in fall armyworm (FAW), Spodoptera frugiperda. In this study, we found that FAW remained sensitive to cyantraniliprole and chlorantraniliprole, while its sensitivity to flubendiamide was reduced. Moreover, a low level of heterozygous mutation at I4743 was observed. To facilitate the detection procedure of these mutations, a simple and efficient loop-mediated isothermal amplification (LAMP) protocol was developed for operation. The reaction for detecting the G4891E and I4743 single or multiple mutations was carried out at 68 °C for 85 min and 68 °C for 85 min or 68 °C for 65 min, respectively. These LAMP reactions can be easily observed via visualization of the color change from pink to yellow. This assay provides a simple, convenient, and effective means of detecting mutations in the RyR of FAW for pest management purposes.

A colorimetric assay for Neospora caninum utilizing the loop-mediated isothermal amplification technique

Neospora caninum (N. caninum) is a protozoan parasite that poses a serious risk to livestock by infecting various domestic and wild animals. Loop-Mediated Isothermal Amplification (LAMP) offers a cost-effective, highly sensitive, and specific method for detecting protozoan parasites. This study aims to develop a precise, rapid, and visually assessable colorimetric LAMP method, improving on traditional techniques. We employed a rigorous screening process to identify the optimal primer set for this experiment. Subsequently, we fine-tuned the LAMP reaction at 65 °C for 40 min with 270 μmol/L neutral red. We then confirmed the specificity of primers for N. caninum through experimental validation. The LAMP method demonstrated a lower detection limit compared to traditional Polymerase Chain Reaction (PCR) techniques. While LAMP offers clear advantages, the prevalence of DNA detected in 89 sheep serum and 59 bovine serum samples using the nested PCR method was 3.37 % (3/89) and 1.69 % (1/59), respectively. In contrast, when the LAMP method was employed, the prevalence of detected DNA rose to 5.61 % (5/89) for sheep and 3.38 % (2 /59) for bovine. A comparison of two molecular assays using the intragroup correlation coefficient (ICC) resulted in a value of 0.999 (95 % CI: 0.993–0.996, p < 0.001), indicating the LAMP method is in the “better” range according to James Lee's categorization. The LAMP technique, optimized with specific primers of N. caninum and neutral red dye, not only exhibited higher sensitivity but also provided convenience over conventional PCR methods, highlighting its potential for on-site applications and cost-effective field detection.

Robust and low-cost open-source device for detecting infectious microorganisms by loop-mediated isothermal amplification

Loop-Mediated Isothermal Amplification (LAMP) is a useful technique for detecting infectious microorganisms in human fluids since it performs similarly to conventional PCR, the results are obtained faster and no thermocyclers or complex devices are required. Since only two isothermal blocks (95 °C to lyse cells and 65 °C for DNA amplification) are needed, LAMP is particularly suited for applications in Low- and Middle-Income Countries (LMICs). To validate such assumption, we first designed and tested Arduino-controlled LAMP thermoblocks to process a considerable number of samples simultaneously with a low-energy consumption to enable routine use under worst-case conditions (no main power source and low ambient temperatures).The thermoblocks were tested when battery-powered at temperature down to 5 °C, showing high stability in well temperatures (<0.8 °C). The charge required for both thermoblocks to simultaneously achieve the target temperatures after switching on and to keep their working temperatures were 4.1 A·h and 2.4 A·h/h, respectively. Second, we implemented a low-cost viewer with LEDs and filters to detect the fluorescent LAMP reaction. All the components required for the instrument are for general purpose and readily available by e-commerce. Thus, the LAMP device allows for considerable autonomy by using a typical car battery in rural and itinerant healthcare or field hospitals in LMICs, even under difficult environmental conditions.

A Finger-Actuated Sample-Dosing Capillary-Driven Microfluidic Device for Loop-Mediated Isothermal Amplification.

Loop-mediated isothermal amplification (LAMP) has attracted significant attention for rapid and accurate point-of-care diagnostics. However, integrating sample introduction, lysis, amplification, and detection steps into an easy-to-use, disposable system has so far been challenging. This has limited the uptake of the technique in practical applications. In this study, we developed a colourimetric one-step LAMP assay that combines thermolysis and LAMP reaction, to detect the SARS-CoV-2 virus in nasopharyngeal swab samples from COVID-19-infected individuals. The limit of detection was 500 copies per reaction at 65 °C for 25 min in reaction tubes. Additionally, we developed a finger-operated capillary-driven microfluidic device with selective PVA coating. This finger-actuated microfluidic device could self-dose the required sample amount for the LAMP reaction and inhibit sample evaporation. Finally, we integrated the LAMP assay into the microfluidic device by short-term pre-storage of the LAMP master mix. Using this device, nasopharyngeal swab samples from COVID-19-infected individuals showed positive results at a reaction time of 35 min at 65 °C. This integrated device may be adapted to detect other RNA viruses of interest rapidly.

Event-specific loop-mediated isothermal amplification for living modified cotton MON88701, MON531, MON15985, MON88913, and COT102

Gossypium hirsutum L., commonly known as upland cotton, is cultivated globally for natural fiber, feed, and seed oil. To enhance agricultural productivity and quality, living modified (LM) cotton has been developed and utilized since the late 1990s. Due to environmental concerns, such as biodiversity risks associated with living modified organisms (LMOs), the Korean government, including the Ministry of Environment, has been conducting LMO natural environment monitoring and post-management projects. In this study, we developed a loop-mediated isothermal amplification (LAMP) assay to detect five specific LM cotton events (MON88701, MON531, MON15985, MON88913, and COT102), which were the most abundant volunteers observed from 2019 to 2021 in South Korea. The event-specific LAMP assays for the five LM cotton events were established with a 40-min reaction time using LAMP reaction buffer, Bst DNA polymerase, and event-specific primers. The limit of detection ranged from 0.01 to 1 ng/μL. The assays' specificity and sensitivity were validated through colorimetric changes, fluorescence intensity measurements, and conventional PCR. To demonstrate the practical application of the LAMP assays, we tested 22 LM cotton volunteers collected from the natural environment in 2021. Each LAMP assay event-specifically amplified the respective LM cotton volunteers. These results indicate that the developed LAMP assays are effective tools for the efficient management and detection of LM cotton in field surveys, supporting regulatory compliance and environmental monitoring efforts.

A rapid LAMP assay for the diagnosis of oak wilt with the naked eye

BackgroundOak wilt disease, caused by Bretziella fagacearum is a significant threat to oak (Quercus spp.) tree health in the United States and Eastern Canada. The disease may cause dramatic damage to natural and urban ecosystems without management. Early and accurate diagnosis followed by timely treatment increases the level of disease control success.ResultsA rapid assay based on loop mediated isothermal amplification (LAMP) was first developed with fluorescence detection of B. fagacearum after 30-minute reaction time. Six different primers were designed to specifically bind and amplify the pathogen’s DNA. To simplify the use of this assay in the field, gold nanoparticles (AuNPs) were designed to bind to the DNA amplicon obtained from the LAMP reaction. Upon inducing precipitation, the AuNP-amplicons settle as a red pellet visible to the naked eye, indicative of pathogen presence. Both infected and healthy red oak samples were tested using this visualization method. The assay was found to have high diagnostic sensitivity and specificity for the B. fagacearum isolate studied. Moreover, the developed assay was able to detect the pathogen in crude DNA extracts of diseased oak wood samples, which further reduced the time required to process samples.ConclusionsIn summary, the LAMP assay coupled with oligonucleotide-conjugated gold nanoparticle visualization is a promising method for accurate and rapid molecular-based diagnosis of B. fagacearum in field settings. The new method can be adapted to other forest and plant diseases by simply designing new primers.

Loop-Mediated Isothermal Amplification for the Diagnosis of Sporotrichosis by Sporothrix brasiliensis.

We aimed to develop and validate a Loop-mediated Isothermal Amplification (LAMP) assay to Sporothrix brasiliensis. LAMP reaction was developed using six primers designed based on calmodulin gene. In the LAMP reaction, we tested twenty isolates of S. brasiliensis from animals and humans, along with ten tissue samples extracted from the left footpad of mice that had been experimentally infected with S. brasiliensis. In addition, it included DNA samples from various other fungal species for specificity evaluation. All S. brasiliensis isolates yielded positive results in the LAMP, and the limit of DNA detection was 1ng/μL. All murine samples were positive in the test while DNA from other fungal species were all negative, resulting in 100% of sensitivity and specificity of primers. LAMP diagnosis technique is a promising alternative to sporotrichosis diagnosis, in a simple and cost-effective way. Further studies are warranted to validate this technique using animal model samples obtained from both humans and animals.

A one-pot loop-mediated isothermal amplification platform using fluorescent gold nanoclusters for rapid and naked-eye pathogen detection

Loop-mediated isothermal amplification (LAMP) is a rapid and sensitive nucleic acid testing method for pathogen detection, yet the absence of a straightforward readout strategy remains challenging. We've successfully designed polyethyleneimine-stabilized gold nanoclusters (PEI-AuNCs) as a cationic AuNCs indicator tailored for distinguishing LAMP results, enabling direct visual inspection under UV light. Positive LAMP reactions with PEI-AuNCs, in combination with magnesium pyrophosphate crystals, yield red-fluorescent bulk precipitates visible to the naked eye. To address contamination concerns, we introduced a one-pot reaction by incorporating AuNCs into the lid recess. This one-pot LAMP assay demonstrates exceptional detection capability, identifying Salmonella enterica at concentrations as low as 101 CFU/mL within approximately 50 min, excluding nucleic acid extraction. The platform's versatility, achieved through customizable primers, positions it as a promising molecular diagnostic tool for rapid and visual pathogen detection across scientific disciplines.

Development of a Colorimetric and SERS Dual-Signal Platform via dCas9-Mediated Chain Assembly of Bifunctional Au@Pt Nanozymes for Ultrasensitive and Robust Salmonella Assay.

Timely screening for harmful pathogens is a great challenge in emergencies where traditional culture methods suffer from long assay time and alternative methods are limited by poor accuracy and low robustness. Herein, we present a dCas9-mediated colorimetric and surface-enhanced Raman scattering (SERS) dual-signal platform (dCas9-CSD) to address this challenge. Strategically, the platform used dCas9 to accurately recognize the repetitive sequences in amplicons produced by loop-mediated isothermal amplification (LAMP), forming nucleic acid frameworks that assemble numerous bifunctional gold-platinum (Au@Pt) nanozymes into chains on the surface of streptavidin-magnetic beads (SA-MB). The collected Au@Pt converted colorless 3,3',5,5'-tetramethylbenzidine (TMB) to blue oxidized TMB (oxTMB) via its Pt shell and then enhanced the Raman signal of oxTMB by its Au core. Therefore, the presence of Salmonella could be dexterously converted into cross-validated colorimetric and SERS signals, providing more reliable conclusions. Notably, dCas9-mediated secondary recognition of amplicons reduced background signal caused by nontarget amplification, and two-round signal amplification consisting of LAMP reaction and Au@Pt catalysis greatly improved the sensitivity. With this design, Salmonella as low as 1 CFU/mL could be detected within 50 min by colorimetric and SERS modes. The robustness of dCas9-CSD was further confirmed by various real samples such as lake water, cabbage, milk, orange juice, beer, and eggs. This work provides a promising point-of-need tool for pathogen detection.

Rapid cyprinid herpesvirus 3 detection using loop-mediated isothermal amplification (LAMP) combined with gold nanoprobes and SYBR safe

As an etiological agent of a notifiable and emerging disease, Cyprinid herpesvirus 3 (CyHV-3 or koi herpesvirus, KHV) is a highly risky factor that affects koi and common carp yield through increasing the mortality rates. In the current study, a highly rapid and sensitive technique was established to detect CyHV-3 with the help of loop-mediated isothermal amplification (LAMP) method with dual visualizing indicators (SYBR safe and gold nanoparticle probes; AuNP-probes). Six specific primers were used to amplify the thymidine kinase (TK) of CyHV-3 using a LAMP reaction of 45 min at 65 °C along with detecting the products through visual inspection via hybridization at 65 °C for 20 min with a functionalized thiol-AuNP probe. A closed-tube LAMP-SYBR safe assay was also developed under the same condition without AuNP probe. The amplification of KHV-LAMP products were evaluated by the naked eye, through fluorescent emission of LAMP-SYBR safe dye-complex and colorimetric aggregate of LAMP product in the presence of AuNP probe. Furthermore, quantitative measurement was applied to the LAMP-AuNPs assay, using the spectral shift assay. The detection limit was 1.25 fentograms DNA which can compete the latest techniques available. The proposed technique yielded negative outcomes with DNA template from other viruses such as CyHV-1 and CEV. The LAMP-SYBR safe and LAMP-AuNPs assays introduced in this article were very sensitive, fast, and reliable diagnostic tools for the detection of CyHV-3.

Advancements and applications of loop-mediated isothermal amplification technology: a comprehensive overview.

Loop-mediated isothermal amplification (LAMP) is a novel method for nucleic acid detection known for its isothermal properties, high efficiency, sensitivity, and specificity. LAMP employs 4 to 6 primers targeting 6 to 8 regions of the desired sequence, allowing for amplification at temperatures between 60 and 65°C and the production of up to 109 copies within a single hour. The product can be monitored by various methods such as turbidimetry, fluorometry, and colorimetry. However, it faces limitations such as the risk of non-specific amplification, challenges in primer design, unsuitability for short gene sequences, and difficulty in multiplexing. Recent advancements in polymerase and primer design have enhanced the speed and convenience of the LAMP reaction. Additionally, integrating LAMP with technologies like rolling circle amplification (RCA), recombinase polymerase amplification (RPA), and CRISPR-Cas systems has enhanced its efficiency. The combination of LAMP with various biosensors has enabled real-time analysis, broadening its application in point-of-care testing (POCT). Microfluidic technology has further facilitated the automation and miniaturization of LAMP assays, allowing for the simultaneous detection of multiple targets and preventing contamination. This review highlights advancements in LAMP, focusing on primer design, polymerase engineering, and its integration with other technologies. Continuous improvements and integration of LAMP with complementary technologies have significantly enhanced its diagnostic capabilities, making it a robust tool for rapid, sensitive, and specific nucleic acid detection with promising implications for healthcare, agriculture, and environmental monitoring.

Integrated Droplet-Based Digital Loop-Mediated Isothermal Amplification Microfluidic Chip with Droplet Generation, Incubation, and Continuous Fluorescence Detection.

This study integrated sample partition, incubation, and continuous fluorescence detection on a single microfluidic chip for droplet-based digital Loop-Mediated Isothermal Amplification (LAMP) of nucleic acids. This integration eliminated the need to transfer reactions between different platforms, avoiding sample contamination and loss. Prior to the reaction, filling the channels with an oil phase and adding a glass cover slip on top of the chip overcame the problem of bubble generation in the channels during the LAMP reaction due to heating. Additionally, using two fluorescence intensity thresholds enabled simultaneous detection and counting of positive and negative droplets within a single fluorescence detection channel. The chip can partition approximately 6000 droplets from a 5 µL sample within 10 min, with a droplet diameter of around 110 µm and a coefficient of variation (CV) value of 0.82%. Staphylococcus aureus was quantified via the proposed platform. The results demonstrated a highly accurate correlation coefficient (R = 0.9998), and the detection limit reached a concentration of 1.7 × 102 copies/µL. The entire process of the droplet digital LAMP reaction, from droplet generation to incubation to quantitative results, took a maximum of 70 min.

Point-of-Care Molecular Testing with tinto rangTM: A Food Grade Safe Fluorophore for Colorimetric LAMP Assays at Low Resource Settings

LAMP (loop-mediated isothermal amplification) has proven to be a highly robust, sensitive, and cost-effective method for detecting specific target nucleic acid sequences in a single-tube reaction without the need for sophisticated instruments. Traditionally, pH-sensitive dyes, DNA-binding dyes like Ethidium Bromide(EtBr), and SYBR have been employed to detect amplified products. However, these dyes present several drawbacks, limiting the widespread adoption of LAMP in diagnostic applications. To address this limitation, a novel dye called tinto rangTM has been introduced with promising applications in nucleic acid analysis. In this study, we present an evaluation of tinto rangTM's performance in comparison to commercially available dyes commonly used in LAMP assays. One of the unique advantages of tinto rangTM is its capability to facilitate the analysis of amplified nucleic acid products through three distinct methods: visual color change, changes in relative fluorescence, and turbidity. In addition to assessing tinto rangTM's performance, we also investigated various approaches to tackle the issue of non-specific amplification, which has been a common challenge in LAMP reactions. The experimental results unequivocally demonstrate that tinto rangTM outperforms pH-indicating and other DNA-binding dyes used in LAMP assays, making it a superior alternative. This study paves the way for the broader adoption of tinto rangTM in various applications, including point-of-care diagnostics, disease monitoring, and molecular biology research.

Loop-mediated isothermal amplification (LAMP) assay coupled with gold nanoparticles for colorimetric detection of Trichoderma spp. in Agaricus bisporus cultivation substrates

One of the significant challenges in organic cultivation of edible mushrooms is the control of invasive Trichoderma species that can hinder the mushroom production and lead to economic losses. Here, we present a novel loop-mediated isothermal amplification (LAMP) assay coupled with gold nanoparticles (AuNPs) for rapid colorimetric detection of Trichoderma spp. The specificity of LAMP primers designed on the tef1 gene was validated in silico and through gel-electrophoresis on Trichoderma harzianum and non-target soil-borne fungal and bacterial strains. LAMP amplification of genomic DNA templates was performed at 65 °C for only 30 min. The results were rapidly visualized in a microplate format within less than 5 min. The assay is based on salt-induced aggregation of AuNPs that is being prevented by the amplicons produced in case of positive LAMP reaction. As the solution color changes from red to violet upon nanoparticle aggregation can be observed with the naked eye, the developed LAMP-AuNPs assay can be easily operated to provide a simple initial screening for the rapid detection of Trichoderma in button mushroom cultivation substrate.

Inhibitors of LAMP used to detect Tenacibaculum sp. strain Pbs-1 associated with black-spot shell disease in Akoya pearl oysters, and additives to reduce the effect of the inhibitors

Black-spot shell disease is an unresolved disease that decreases pearl quality and threatens pearl oyster survival. In previous studies, the bacterium Tenacibaculum sp. strain Pbs-1 was isolated from diseased Akoya pearl oysters Pinctada fucata, and a rapid, specific, and sensitive loop-mediated isothermal amplification (LAMP) assay for detecting this pathogen was established. This technology has considerable potential for routine diagnosis of strain Pbs-1 in oyster hatcheries and/or pearl farms; therefore, it is vital to identify substances in environmental samples that might inhibit LAMP and to find additives that can reduce the inhibition. In this study, we investigated the effects of six chemicals or proteins, otherwise known as conventional PCR inhibitors, on LAMP, using the DNA of strain Pbs-1 as template: humic acid, urea, iron (III) chloride hexahydrate, melanin, myoglobin, and Ethylenediamine-N,N,N′,N′-tetraacetic acid, disodium salt, dihydrate (EDTA; pH 6.5). Next, to reduce the effects of identified inhibitors, we tested the addition of bovine serum albumin (BSA) or T4 gene 32 protein (gp32) to the LAMP assay. When 50 ng of DNA template was used, 4 ng/μL of humic acid, 0.05% melanin, and 10 mM of EDTA (pH 6.5) inhibited the LAMP reaction, whereas myoglobin, urea, and FeCl3 had no effect. When 50 pg of DNA template was used, 4 ng/μL of humic acid, 0.05% melanin, 4 μg/μL of myoglobin, 10 μg/μL of urea, and 10 mM of EDTA inhibited the LAMP reaction. Thus, it was shown that the gene-amplification inhibitory effect of melanin, humic acid, and urea could be reduced by adding BSA or gp32 to the LAMP reaction mixture. This technique could be applied as part of a protocol to prevent mass mortalities of pearl oysters; moreover, the results enhance our knowledge about substances that inhibit LAMP and methods to reduce the inhibition, which have rarely been reported.

Rapid and quantitative detection of Aspergillus niger Van Tieghem using loop-mediated isothermal amplification assay

AbstractPeanut (Arachis hypogaea L.) crown rot and root rot are common diseases caused by Aspergillus niger Van Tieghem. Early and accurate detection of A. niger is key to disease management. In this study, the design of two to five sets of loop-mediated isothermal amplification (LAMP) primers was based on the EglA, GOD, Tub, NRPS, Tan, CbhA, and CbhB genes of A. niger. Of these, primer set GOD-91 was selected for optimization of the three-factor LAMP system: the Bst DNA polymerase concentration, the concentration ratio of the inner and outer primers, and the concentration of Mg2+. In addition, the optimized LAMP reaction system for A. niger detection was validated for specificity, sensitivity, and on-site feasibility. The specificity test showed that A. niger could be specifically detected with the proposed method without cross-amplification of other pathogenic fungi DNA. Moreover, based on the sensitivity test, the lowest detection limit of this reaction system was 5.1 × 10−7 ng/µL pAN01 plasmid DNA, after which a standard curve was generated for the quantitative detection of A. niger. The LAMP method was further applied for field sample assessment before and after A. niger infection, successfully detecting A. niger presence in the samples collected in the field. This study yielded a sensitive, specific, and reproducible LAMP system that can be used to assess on-site samples within 45 min. It is an effective approach for the rapid and quantitative detection of A. niger.