Low DNA Concentrations Research Articles

An all-in-one strategy for bisulfite-free DNA methylation detection by temperature-programmed enzymatic reactions

The fragmentation and low concentration of cell-free DNA (cfDNA) pose higher challenges for the cfDNA methylation detection technologies. Conventional bisulfite conversion-based methods are inadequate for cfDNA methylation analysis due to cumbersome operation and exacerbating cfDNA degradation. Herein, we proposed temperature-programmed enzymatic reactions for cfDNA methylation analysis in a single tube. Endonuclease was used to mildly recognize DNA methylation to avoid the degradation of cfDNA. And two stages of amplification reactions significantly improved the detection sensitivity for GC-rich sequence. With vimentin as the target, the detection sensitivity was 10 copies of methylated DNA. Meanwhile, the proposed method can accurately quantify the methylation level of target sequence from 1000-fold of unmethylated DNA background. Further, the methylated vimentin gene in 20 clinical plasma samples was successfully detected. The results shown significant differences in methylation levels of the vimentin gene between healthy volunteers and colorectal cancer patients. These results lead us to believe that the proposed method has great application potential for DNA methylation analysis as a complement to bisulfite conversion-based methods.

Multiplex ddPCR: A Promising Diagnostic Assay for Early Detection and Drug Monitoring in Bovine Theileriosis

Accurate quantification based on nucleic acid amplification is necessary to avoid the spread of pathogens, making early diagnosis essential. Droplet digital PCR (ddPCR) stands out for absolute parasite quantification because it combines microfluidics with the TaqMan test. This helps deliver maximum accuracy without needing a reference curve. This study assessed the efficacy of ddPCR as a detection tool for the bovine theileriosis (BT) caused by Theileria parasites. We developed and validated a duplex ddPCR method that detects and quantifies the Theileria genus (18S rRNA) and identifies clinically significant Theileria annulata parasites (TaSP) in experimental and clinical samples. ddPCR was shown to be as effective as qPCR throughout a 10-fold sample dilution range. However, ddPCR was more sensitive than qPCR at lower parasite DNA concentrations and reliably assessed up to 8.5 copies/µL of the TaSP gene in the infected DNA (0.01 ng) samples. The ddPCR was very accurate and reproducible, and it could follow therapeutic success in clinical cases of theileriosis. In conclusion, our ddPCR assays were highly sensitive and precise, providing a valuable resource for the study of absolute parasite quantification, drug treatment monitoring, epidemiological research, large-scale screening, and the identification of asymptomatic parasite reservoirs in the pursuit of BT eradication.

Nanoplate digital PCR assays for detection and quantification of Xylella fastidiosa

Xylella fastidiosa is a fastidious Gram-negative bacterium that is associated with several important plant diseases, and is regulated as a quarantine pest in many countries where strategies are implemented to prevent its introduction and spread. To enact efficient quarantine measures, effective and early detection of the pathogen are essential, especially because global trade of goods increases the risks of introduction of alien pathogens. this study aimed to adapt two qPCR-based diagnostic methods (SYBR Green and Probe based qPCR), already in use to detect X. fastidiosa, for use with a nanoplate based digital PCR assay. Detection of the pathogen using the two digital PCR assays (EvaGreen- and Probe-based) was similar to standard qPCR, giving 100% sensitivity, specificity, and accuracy, while providing accurate absolute quantification of the pathogen when using experimental samples that had low concentrations of host DNA. Using undiluted plant DNA added with low concentrations of X. fastidiosa, only the TaqMan method maintained satisfactory performance and quantification, and is therefore preferred. These results are a first step demonstrating the usefulness of nanoplate-based digital PCR for detection of plant pathogens, which allows greater throughput than qPCR, reducing the time and cost of diagnostic assays.

Fungal Metabarcoding Data for Two Grapevine Varieties (Regent and Vitis vinifera ‘Cabernet-Sauvignon’) Inoculated with Powdery Mildew (Erysiphe necator) Under Drought Conditions

Fungal Metabarcoding Data for Two Grapevine Varieties (Regent and <i>Vitis vinifera</i> ‘Cabernet-Sauvignon’) Inoculated with Powdery Mildew (<i>Erysiphe necator</i>) Under Drought Conditions

Detection of Highly Poisonous Nerium oleander Using Quantitative Real-Time PCR with Specific Primers.

Nerium oleander is one of the most poisonous plants, and its accidental ingestion has frequently occurred in humans and livestock. It is vital to develop a rapid and accurate identification method for the timely rescue of oleander-poisoned patients and the investigation of poisoning cases. In this study, a specific and highly sensitive quantitative real-time PCR (qPCR)-based method was developed to identify oleander in mixture systems and simulated forensic specimens (SFS). First, a new pair of oleander-specific primers, JZT-BF/BR, was designed and validated. Then, a qPCR method was developed using the primers, and its detective sensitivity was examined. The results showed that JZT-BF/BR could specifically identify oleander in forage and food mixtures, and qPCR was capable of accurate authentication even at a low DNA concentration of 0.001 ng/μL. This method was further applied to the analysis of SFS containing different ratios of N. oleander. The method was confirmed to be applicable to digested samples, and the detection limit reached 0.1% (w/w) oleander in mixture systems. Thus, this study undoubtedly provides strong support for the detection of highly toxic oleander and the diagnosis of food poisoning in humans and animals.

Robust detection of cow and female buffalo DNA through Real-Time PCR assay

Cow, Bos taurus, and female buffalo, Bubalus bubalis, are considered sacred animals that are a part of rural livelihood in India. The purity of products from these bovine species has significant sentimental implications in the dairy and meat industry. Therefore, the mitochondrial DNA and the sex origin, targeting the X and Y chromosomes from these bovine species, were selected to design three multiplex real-time probe PCR assays: Hi-PCR® Cow Detection Kit (MBPCR184), Hi-PCR® Buffalo Detection Kit (MBPCR185) and Hi-PCR® Cattle Sex Determination Kit (MBPCR186). Scientific Working Group on DNA Analysis Methods (SWGDAM) guidelines were followed to perform different studies using reference control DNAs. An Internal Reagent Control (IRC) was part of every assay, thus ensuring a successful reaction. The assays were 100% specific, with no cross-amplification of the two bovine species. The amplification of the X chromosomal target was observed for male and female DNAs, whereas Y chromosome amplification was observed only for the male DNA. The assays were 100% specific to the target genes in these organisms with no non-specificity towards any other targets or organisms. The limit of detection for sex determination was 0.01 ng/µl, whereas the differential capability of the assay was 3 copies/µl and 30 copies/µl for Bos taurus and Bubalus bubalis, respectively. The assays were reproducible at 1 ng/µl genomic DNA with 95% CI. The assays are open and compatible with other brands of Real-Time PCR systems used in forensic labs. The experiments presented here verify that the developed real-time PCR assays are robust, produce reliable and reproducible results for detection and differentiation of Bos taurus and Bubalus bubalis and their sex even at low DNA concentrations.

Probabilistic SNP genotyping at low DNA concentrations

We present a statistical method for biallelic SNP genotyping that reduces the risk of wrong SNP calls and gives fewer no-calls. The method uses a symmetric multinomial logistic regression model with an intuitive graphical interpretation. Its probabilistic nature gives the user control over the accepted risk through the estimated genotype probabilities. We compared the performance of our method with the HID SNP Genotyper v.4.3.1 plug-in (HSG) (Thermo Fisher Scientific) and the additional criteria of the University of Copenhagen (UCPH) through a series of six DNA dilutions from 500 pg to 16 pg DNA. The HSG method made wrong calls from 62.5 pg DNA and below, while the UCPH method made wrong calls at 16 pg DNA. Our method allowed SNP genotyping of 16 pg DNA without making wrong calls. Depending on the DNA dilution, our method also reduced the number of no-calls by 70–96 % compared to UCPH method and 59–69 % compared to the HSG method. Our method can be used for any biallelic genotyping.

Türkiye'de yoncada önemli thrips türlerinin hızlı tespiti için yeni bir kapiler jel elektroforez tabanlı fragment analiz yöntemi

Thrips cause significant yield reduction in several industrial crops. Since these pests are also included in the quarantine organisms of Turkey, the rapid detection of agents is important to prevent their spread to new areas. Mitochondrial cytochrome oxidase I (COI) barcoding gene assay; one of the molecular methods is widely used in thrips identification. However, as the COI gene has a very short fragment length, it is very difficult to distinguish fragment sizes on agarose gel after PCR. In this study, a new identification method was developed by integrating the Capillary Gel Electrophoresis (CGE) system for Thrips tabaci Lideman, Frankliniella occidentalis (Pergande) and Frankliniella intonsa (Trybom) species, using primer pairs previously used by different researchers. The assay produces strong signals obtained by minimizing the margin of error in the separation of fragment lengths close to each other, especially in the short fragment length COI gene. Therefore, by eliminating the gel electrophoresis step, reliable detections could be obtained without exposure to hazardous chemicals. The novel method shortened the detection time and minimized the process mistakes on the detection of a single thrips with a low DNA concentration. Total 83 thrips individual (52 F. intonsa, 31 F. occidentalis) were able to be detected with this capillary gel electrophoresis based fragment analysis. The novel method is evaluated as unique, specific and quick for the detection of three different thrips species. It is also thought to be able to utilize for identification of different thrips species with short fragment sizes in the foreseeable future.

Molecular Detection and Genotyping of Toxoplasma gondii from Pigs for Human Consumption in Zhejiang and Jiangsu Provinces, Eastern China.

Toxoplasma gondii infections are common in humans and animals worldwide. Ingestion of raw or undercooked meat containing tissue cysts of T. gondii is one major source of transmission of this parasite. It is important to guarantee the meat quality of China since our pork industry produces about half of the world's pork. In this study, a total of 746 pig samples were collected from Zhejiang and Jiangsu provinces in eastern China, and examined for T. gondii infection by PCR amplification targeting B1 gene. In this study, we found that 57 of 746 (7.6%) pigs were positive for B1 gene, with 8.5% (48/562) in Zhejiang province and 4.9% (9/184) in Jiangsu province, respectively. The positive DNA samples were further genotyped at 11 genetic markers, including SAG1, 5'-and 3'-SAG2, alternative SAG2, SAG3, BTUB, GRA6, L358, PK1, c22-8, c29-2, and an apicoplast locus Apico through PCR-restriction fragment length polymorphism (PCR-RFLP) technology. Two genotypes (ToxoDB 9 and ToxoDB 10) of T. gondii were identified by PCR-RFLP in Zhejiang province. However, both genotypes were not determined from Jiangsu province, which is speculated on the low DNA concentration and the small number of samples. These results indicate that T. gondii infection is endemic in pigs in eastern China and may raise public food safety concerns, suggesting more interventions for T. gondii-related risks are needed in the future.

Use of hormone-specific antibody probes for differential labeling of contributor cell populations in trace DNA mixtures.

A significant proportion of casework analyzed by forensic science laboratories is often "touch" or trace forensic DNA evidence, which is deposited through physical contact and is comprised of sloughed epidermal cells. These samples can be challenging to analyze due to low DNA concentrations, frequent degradation, and the presence of cells from multiple individuals in the same sample. To address these challenges, we investigated a new approach for characterizing trace evidence prior to DNA profiling that labels epidermal cells with antibody probes targeting hormone molecules testosterone and dihydrotestosterone (DHT). The goal was to test whether cell populations derived from separate individuals showed different binding efficiencies to hormone probes and, thus, could be used to detect the presence of multiple cell populations. Additionally, we investigated whether antibody probes could be used to isolate contributor cell populations from an epidermal cell mixture and facilitate deconvolution of mixed DNA profiles recovered from touch/trace evidence. Results showed that cell populations from some individuals could differentiated in trace samples based on fluorescence histograms following probe labeling. However, certain pairs of contributors showed largely or completely overlapping histogram profiles and could not be resolved. Preliminary efforts to separate cell populations that could be differentiated with hormone probes with fluorescence-activated cell sorting (FACS) coupled to DNA profiling and probabilistic modeling indicated that it is possible to enrich contributor cell populations from touch/trace samples and produce more probative DNA profiles compared to the original mixture sample. The variability in labeling, differentiation, and physical separation of cell populations may be impacted by similarities in biochemical profiles across some contributors as well as imbalance of contributor DNA quantities in certain mixtures as is typical in casework involving touch/trace evidence. Ultimately, screening and separation of trace DNA samples with this approach may be presumptive and constrained by sample-specific parameters of the original mixture.

Airborne fungal and bacterial microbiome in classrooms of elementary schools during the COVID-19 pandemic period: Effects of school disinfection and other environmental factors.

The aim of the study was to examine the effects of environmental factors including disinfection on airborne microbiome during the coronavirus disease 2019 pandemic, we evaluated indoor and outdoor air collected from 19 classrooms regularly disinfected. Extracted bacterial and fungal DNA samples were sequenced using the Illumina MiSeq™ platform. Using bacterial DNA copy number concentrations from qPCR analysis, multiple linear regressions including environmental factors as predictors were performed. Microbial diversity and community composition were evaluated. Classrooms disinfected with spray ≤1 week before sampling had lower bacterial DNA concentration (3116 DNA copies/m3) than those >1 week (5003 copies/m3) (p‐values = 0.06). The bacterial DNA copy number concentration increased with temperature and was higher in classrooms in coastal than inland cities (p‐values <0.01). Bacterial diversity in outdoor air was higher in coastal than inland cities while outdoor fungal diversity was higher in inland than coastal cities. These outdoor microbiomes affected classroom microbial diversity but bacterial community composition at the genus level in occupied classrooms were similar between coastal and inland cities. Our findings emphasize that environmental conditions including disinfection, climate, and school location are important factors in shaping classroom microbiota. Yet, further research is needed to understand the effects of modified microbiome by disinfection on occupants' health.

The Effect of DNA from Escherichia Coli at High and Low CO2 Concentrations on the Shape and Form of Crystal-line Silica-Carbonates of Barium (II)

The synthesis of nucleic acids in the Precambrian era marked the start of life, with DNA being the molecule in which the genetic information has been conserved ever since. After studying the DNA of different organisms for several decades, we now know that cell size and cellular differentiation are influenced by DNA concentration and environmental conditions. However, we still need to find out the minimum required concentration of DNA in the pioneer cell to control the resulting morphology. In order to do this, the present research aims to evaluate the influence of the DNA concentration on the morphology adopted by biomorphs (barium silica-carbonates) under two synthesis conditions: one emulating the Precambrian era and one emulating the present era. The morphology of the synthetized biomorphs was assessed through scanning electron microscopy (SEM). The chemical composition and the crystalline structure were determined through Raman and IR spectroscopy. Our results showed that DNA, even at relatively low levels, affects the morphology of the biomorph structure. They also indicated that, even at the low DNA concentration prevailing during the synthesis of the first DNA biomolecules existing in the primitive era, these biomolecules influenced the morphology of the inorganic structure that lodged it. On the other hand, this also allows us to infer that, once the DNA was synthetized in the Precambrian era, it was definitely responsible for generating, conserving, and directing the morphology of all organisms up to the present day.

Recognition of HIV-1 capsid by PQBP1 licenses an innate immune sensing of nascent HIV-1 DNA

We have previously described polyglutamine-binding protein 1 (PQBP1) as an adapter required for the cyclic GMP-AMP synthase (cGAS)-mediated innate response to the human immunodeficiency virus 1 (HIV-1) and other lentiviruses. Cytoplasmic HIV-1 DNA is a transient and low-abundance pathogen-associated molecular pattern (PAMP), and the mechanism for its detection and verification is not fully understood. Here, we show a two-factor authentication strategy by the innate surveillance machinery to selectively respond to the low concentration of HIV-1 DNA, while distinguishing these species from extranuclear DNA molecules. We find that, upon HIV-1 infection, PQBP1 decorates the intact viral capsid, and this serves as a primary verification step for the viral nucleic acid cargo. As reverse transcription and capsid disassembly initiate, cGAS is recruited to the capsid in a PQBP1-dependent manner. This positions cGAS at the site of PAMP generation and sanctions its response to a low-abundance DNA PAMP.

A New TaqMan Real-Time PCR Assay for Detecting the Blueberry Pathogen Monilinia vaccinii-corymbosi.

Monilinia vaccinii-corymbosi (Mvc) is an important fungal pathogen of blueberry, causing mummy berry disease. While the symptoms of the advanced stages of the disease can be obvious, diagnosing its early stages can be challenging. To facilitate fast and sensitive screening of asymptomatic or latently infected plant material for Mvc, we developed a specific TaqMan real-time PCR assay targeting the internal transcribed spacer (ITS) region. The assay was shown to be specific to Mvc and did not cross react with any of the other tested Monilinia species or other blueberry pathogens. Using the multicopy ITS region ensured high analytical sensitivity, enabling very low concentrations of Mvc DNA (0.1 pg) to be detected both in water and host DNA matrix. Comparable results were obtained in interlaboratory testing, showing that the assay is robust, and can be effectively used in other laboratories. Assay sensitivity was also confirmed on infected plant tissue, showing that it is effective in detecting the pathogen in infected asymptomatic stem tissue, as well as infected tissue that was mixed with healthy tissue at a ratio of 1:10 by weight. The assay was duplexed with a plant internal control (cytochrome oxidase gene) for simultaneous amplification of the pathogen and plant internal control in a single reaction. This new diagnostic tool can be used for sensitive and rapid screening of blueberry plants for the presence of Mvc in many different settings, e.g., for breeding programs, research, or biosecurity diagnostics.

Direct comparison of eDNA capture and extraction methods through measuring recovery of synthetic DNA cloned into living cells

AbstractBefore eDNA surveys can be deployed, the methods used to capture and extract DNA need to be determined. Multiple widely used eDNA capture and DNA extraction methods are available, and the effectiveness of these methods has been assessed in the literature. These studies used raw estimates of target cells captured from mesocosms and tanks, or already extracted DNA, which are not reflective of environmental DNA or precise enough to accurately compare eDNA capture and DNA extraction methods. Here, using qPCR quantification, we compared two eDNA capture and extraction methods using low and high concentrations of DNA cloned into living cells. By cloning target DNA into living cells, we can control the quantity of our starting copy number to directly compare the efficiency and effectiveness of each method throughout the process of eDNA handling and data analysis. This approach is useful for determining which capture and extraction method is suitable for the target species and sampling location of interest before full‐scale deployment. Although our target species DNA is consistently and accurately detected (even at low concentrations), stochasticity is a significant factor in our ability to consistently recover all the starting material by the end of sample processing. By recognizing that stochasticity is important for eDNA recovery, more accurate sampling models and eDNA processing protocols can be developed to increase eDNA detection sensitivity.

Collaborative swab performance comparison and the impact of sampling solution volumes on DNA recovery

The collection of DNA traces marks the first step determining the success of genetic analysis. This study aimed to identify and validate a suitable alternative to the currently used ForensiX Evidence Collection Kit containing a cardboard box for swab storage. This box has to be folded at the crime scene, which is time-consuming and carries the risk of potential contamination and handling difficulties.A collaboration study involving three police departments and one laboratory for forensic genetics was performed to compare the currently used swab against three challenger swabs: ForensiX SafeDry, Copan 4N6FLOQSwab™ Genetics and Copan 4N6FLOQSwab™ Crime Scene. Mock samples consisted mainly of touch DNA, but also blood, saliva and semen were applied to twelve items with different surfaces. Every organisation contributed with three DNA collectors, whose individual collection efficiencies were investigated. The challenge of preparing homogenous traces, especially touch DNA, was addressed by enhancing hand contact frequency and sampling area. As a further part of the swab comparison study, we describe for the first time the influence of different swabbing solution volumes on the sampling efficiency of the different swabs.The application of touch DNA was also tested for a further swab type, the Sarstedt Forensic Swab, which yielded such low DNA concentrations that it was excluded from the collaboration study. The Copan Genetics and Copan Crime Scene swabs yielded significantly lower DNA concentrations than the currently used ForensiX Evidence Collection Kit and ForensiX SafeDry swab. The inter-individual performance results of the operators revealed significant differences in sampling skills. Comparing different swabbing solution volumes showed higher DNA yields or no significant difference for the ForensiX Evidence Collection Kit and ForensiX SafeDry than the Copan Genetics, depending on the item or trace type swabbed.Our results highlight the importance of validating first-step components that are decisive to the success of DNA typing in the context of specific sampling procedures and laboratory methods. Also, the significance of individuals' securing variations, principally unknown for crime scene investigation and laboratory teams, is emphasised for the first time, offering a practical approach for improving and training DNA collecting activities and ensuring the optimal securing evidence process. These findings increase the knowledge of impacts on DNA collection and, thus, benefit other laboratories and forensic services, particularly when using the same extraction methods.

Identification and poisoning diagnosis of Aconitum materials using a genus-specific nucleotide signature

Aconitum genus generally contains hypertoxic alkaloids. Poisoning incidents due to the improper ingestion of Aconitum materials frequently occur around the world. DNA barcoding is considered as a powerful tool for species identification, but complete sequences of conventional DNA barcodes are sometimes unattainable from food and highly processed products due to severe DNA degradation. Therefore, a shorter molecular marker will be more profitable for the authentication and poisoning diagnosis of Aconitum materials. In this study, 1246 psbA-trnH sequences and chloroplast genomes representing 183 taxa of Aconitum were collected, and a 23-bp nucleotide signature unique to Aconitum genus (5′-TATATGAGTCATTGAAGTTGCAG-3′) was developed. The nucleotide signature was conserved and universal within Aconitum while divergent among other genera. The specific molecular signature was then successfully applied to the detection of processed Aconitum ingredients. To further evaluate the application potential of nucleotide signature in completely unknown mixture samples, boiled food mixtures, containing different ratios of Aconitum materials, were sequenced by high-throughput sequencing technology. The results showed that the nucleotide signature sequence could be directly extracted from raw sequencing data, even at a low DNA concentration of 0.2 ng/µl. Consequently, the 23-bp genus-specific nucleotide signature represents a significant step forward in the use of DNA barcoding to identify processed samples and food mixtures with degraded DNA. This study undoubtedly provides a new perspective and strong support for the identification and detection of Aconitum-containing products, which can be further introduced to the diagnosis of food poisoning.

Novel hybridization- and tag-based error-corrected method for sensitive ctDNA mutation detection using ion semiconductor sequencing

Circulating tumor DNA (ctDNA) analysis has emerged as a clinically useful tool for cancer diagnostics and treatment monitoring. However, ctDNA detection is complicated by low DNA concentrations and technical challenges. Here we describe our newly developed sensitive method for ctDNA detection on the Ion Torrent sequencing platform, which we call HYbridization- and Tag-based Error-Corrected sequencing (HYTEC-seq). This method combines hybridization-based capture with molecular tags, and the novel variant caller PlasmaMutationDetector2 to eliminate background errors. We describe the validation of HYTEC-seq using control samples with known mutations, demonstrating an analytical sensitivity down to 0.1% at > 99.99% specificity. Furthermore, to demonstrate the utility of this method in a clinical setting, we analyzed plasma samples from 44 patients with advanced pancreatic cancer, revealing mutations in 57% of the patients at allele frequencies as low as 0.23%.

Single-step measurement of cell-free DNA for sepsis prognosis using a thread-based microfluidic device.

Cell-free DNA (cfDNA) content in plasma has been studied as a biomarker for sepsis. Recent publications show that the cfDNA content in sepsis patients entering intensive care unit who were likely to survive had a total cfDNA concentration of 1.16 ± 0.13μg/mL compared to 4.65 ± 0.48μg/mL of non-survivors. Current methods for measuring cfDNA content in plasma were designed to amplify and measure low concentrations of specific DNA, making them unsuitable for low-cost measurement of total cfDNA content in plasma. Here, we have developed a point of care (POC) device that uses a thread silicone device as a medium to store a fluorescent dye which eliminates the need for preparatory steps, external aliquoting and dispensing of reagents, preconcentration, and external mixing while reducing the detection cost. The device was paired with a portable imaging system with an excitation filter at 472 ± 10nm and an emission filter of 520 ± 10nm that can be operated with just 100mA current supply. The device was demonstrated for use in the quantification of buffered cfDNA samples in a range 1-6μg/mL with a sensitivity of 5.72 AU/μg/mL and with cfDNA spiked in plasma with a range of 1-3μg/mL and a sensitivity of 5.43 AU/μg/mL. The results showed that the device could be used as a low-cost, rapid, and portable POC device for differentiating between survivors and non-survivors of sepsis within 20min.

Development of a Loop-Mediated Isothermal Amplification Assay Coupled With a Lateral Flow Dipstick Test for Detection of Myosin Binding Protein C3 A31P Mutation in Maine Coon Cats.

BackgroundMyosin-binding protein C3 A31P (MYBPC3-A31P) missense mutation is a genetic deviation associated with the development of hypertrophic cardiomyopathy (HCM) in Maine Coon cats. The standard detection of the MYBPC3-A31P mutation is complicated, time-consuming, and expensive. Currently, there has been a focus on the speed and reliability of diagnostic tools. Therefore, this study aimed to develop a loop-mediated isothermal amplification assay (LAMP) coupled with a lateral flow dipstick (LFD) test to detect MYBPC3-A31P mutations in Maine Coon cats.Materials and MethodsFifty-five Maine Coon cats were enrolled in this study, and blood samples were collected. MYBPC3-A31P was genotyped by DNA sequencing. Primers for LAMP with a LFD test were designed. The optimal conditions were determined, including temperature and time to completion for the reaction. The sensitivity of A31P-LAMP detection was compared between agarose gel electrophoresis (the standard method) and the LFD test. The A31P-LAMP-LFD test was randomly performed on seven cats (four with the A31P mutation and three wild-type cats).ResultsThe A31P-LAMP procedure was able to distinguish between cats with MYBPC3-A31P wild-type cats and MYBPC3-A31P mutant cats. The LAMP reactions were able to be completed in 60 min at a single temperature of 64◦C. Moreover, this study demonstrated that A31P-LAMP coupled with the LFD test allowed for A31P genotype detection at a lower DNA concentration than agarose gel electrophoresis.DiscussionsThis new A31P-LAMP with a LFD test is a successful and reliable assay with a rapid method, cost-effectiveness, and low requirements for sophisticated equipment for the detection of MYBPC3-A31P mutations. Thus, this assay has excellent potential and can be recognized as a novel screening test for hypertrophic cardiomyopathy associated with MYBPC3-A31P mutations in felines.