Abstract: Methods of analyzing nucleic acids of a cell are provided.

Abstract: A method and a kit for detecting Mycobacterium tuberculosis are provided. The method includes a step of performing a nested qPCR assay to a specimen. The nested qPCR assay includes a first round of amplification using external primers and a second round of amplification using internal primers and a probe. The external primers have sequences of SEQ ID NOs. 1 and 2, and the internal primers and the probe have sequences of SEQ ID NOs. 3 to 5.

Abstract: Methods for analyzing DNA-containing samples are provided. The methods can comprise isolating a single genomic equivalent of DNA from the DNA-containing sample to provide a single isolated DNA molecule. The single isolated DNA molecule can be subjected to amplification conditions in the presence of one or more sets of unique molecularly tagged primers to provide one or more amplicons. Any spurious allelic sequences generated during the amplification process are tagged with an identical molecular tag. The methods can also include a step of determining the sequence of the one or more amplicons, in which the majority sequence for each code is selected as the sequence of the single original encapsulated target. The DNA-containing sample can be a forensic sample (e.g., mixed contributor sample), a fetal genetic screening sample, or a biological cell.

Abstract: The present specification discloses a method for detecting an aneuploid of a Brassica oleracea plant, including: performing real-time PCR using DNA extracted from a sample derived from a Brassica oleracea plant to be tested as a template and DNA markers specific to each of two or more chromosomes of Brassica oleracea plant; and detecting chromosomal aneuploidy from a relative difference in amplification amount between the obtained DNA markers. According to one embodiment of the present invention, it is possible to simply, accurately, and rapidly detect an off-type (chromosomal aneuploid) that may occur in Brassica oleracea varieties, in a laboratory equipped with a general molecular biological equipment in the course of seed quality control and breeding research.

Abstract: Provided herein is a method for detecting the presence of clade variants in the COVID-19 virus in a human sample and/or an environmental sample. Samples are processed to obtain total RNA. The RNA is used as a template in a combined reverse transcription and amplification reaction to obtain fluorescent COVID-19 virus amplicons. These amplicons are hybridized on a microarray with nucleic acid probes having sequences that discriminate among the various clade variants. The microarray is imaged to detect the clade variant. Also provided is a method of distinguishing each clade variant from others by generating an intensity distribution profile from the image, which is unique to each of the clade variants.

Abstract: In traditional plant breeding approaches, chemical mutagenesis may be utilized to introduce nucleotide substitutions at random in the genome of a plant, i.e. without possibilities to control the sites of nucleotide changes. Because of genome complexities, the statistical probability is extremely little when it comes to finding a predetermined nucleotide substitution. The present invention, however, demonstrates how a novel, alternative use of digital polymerase chain reaction (dPCR), preferably droplet dPCR (ddPCR), is developed to exploit finding of specific nucleotide substitutions in mutated genes. The entire platform comprises a screening method with a library of mutagenized organisms, digital PCR-based systems and a set-up to propagate and analyze identified, mutated organisms.

Abstract: The present invention relates to nucleic acids encoding for proteins correlated with the resistance of the Sm1 locus in wheat and uses of these nucleic acids, in particular for conferring or improving resistance to orange wheat blossom midge (OWBM) in a plant.

Abstract: The present invention relates to the field of molecular biology, and more specifically to methods for reducing the complexity of a nucleic acid sample.

Abstract: The present disclosure generally relates to the field of microbial pathogen detection and identification utilizing genomic sequence recognition.

Abstract: A method and system for normalizing a polymerase chain reaction (PCR) amplification process for a plurality of samples containing DNA. Cycle data for performing the PCR amplification process is identified for the plurality of samples. The cycle data includes a corresponding cycle count for each sample of the plurality of samples. The plurality of samples is sorted into a plurality of bins based on the cycle data such that cycle count variation between bins of the plurality of bins is reduced. A bin cycle count is assigned to each bin of the plurality of bins. The bin cycle count is unique to each bin of the plurality of bins. Identification information is generated for the bins. An output for performing a PCR amplification of the plurality of samples is generated using the bins and the bin cycle count for each bin of the plurality of bins.

Abstract: The present invention provides a multiplex PCR detection kit of Listeria monocytogenes serotype 4h. The kit includes a gene Imo1210 detection primer and a gene xysn_1693 detection primer. The present invention establishes a multiplex PCR method for rapidly detecting Listeria monocytogenes serotype 4h by using two pairs of primers.

Abstract: Methods of profiling the nucleic acid composition of single cells and tools for same. The methods can include isolating a single cell in a liquid droplet, lysing the single cell in the liquid droplet to release template nucleic acid from the cell, amplifying the template nucleic acid in the liquid droplet to generate amplified nucleic acid, and detecting the amplified nucleic acid in the liquid droplet. The methods can be useful for profiling expression patterns and/or detecting genetic characteristics such as single nucleotide polymorphisms. The tools include nucleic acid logic gates, including polymerase-dependent logic gates. The logic gates can perform logical operations such as YES, NOT, AND, OR, AND-NOT, NOT-AND, NOT-OR, EXCLUSIVE-OR, EXCLUSIVE-NOR, and IMPLY. The tools also include microfluidic systems for performing the methods.

Abstract: Disclosed are nucleic acid oligomers, including amplification oligomers, capture probes, and detection probes, for detection of Zika virus nucleic acid. Also disclosed are methods of specific nucleic acid amplification and detection using the disclosed oligomers, as well as corresponding reaction mixtures and kits.

Abstract: According to an aspect of the present disclosure, there is provided a polymerase chain reaction (PCR) patch which is provided as a gel type having a net-like structure forming micro-cavities, wherein at least a part of a plurality of reagents used in a PCR are contained in the micro-cavities, and when the patch contacts with an external region, the reagents contained in the micro-cavities move to at least a portion of the external region, and a PCR of a target DNA included in a sample located in the external region is performed.

Abstract: A heating mechanism for use in DNA applications such as DNA amplification, extraction and sterilization is provided. Nanoparticles having photo-thermal properties are put in contact with a reaction mixture and irradiated with an activation light beam to activate these photo-thermal properties, thereby releasing heat. Nanoparticles of several types may be used. Use of the same nanoparticles or of different one to monitor the reaction using a different light beam is also presented.

Abstract: Methods for rapidly concentrating a food sample for efficient detection of bacteria are disclosed. A microfiltration approach followed by centrifugation was used to concentrate the cells with an enzyme (e.g., a protease) added at the beginning of the process to facilitate more efficient micro-filtering. The enzyme was found to have no significant effect on cell viability.

Abstract: Provided is a PCR primer pair, comprising: a first primer and a second primer, wherein the first primer comprises a first specific sequence and a first random sequence; the first specific sequence is located on 3? end of the first primer, and the first random sequence is located on 5? end of the first primer; the second primer comprises a second specific sequence and a second random sequence, the second specific sequence is located on 3? end of the second primer, and the second random sequence is located on 5? end of the second primer; moreover, the first specific sequence and the second specific sequence are an upstream primer and a downstream primer directed to a target sequence respectively, and the first random sequence and the second random sequence are inverse complementary.

Abstract: The present disclosure provides methods and materials for determining if antibiotic resistant H. pylori is present in a sample. The methods may comprise obtaining a threshold level of H. pylori DNA from the sample, amplifying a region of the H. pylori DNA to generate multiple copies of the region of the H. pylori DNA, sequencing the multiple copies of the region of the H. pylori DNA, comparing sequences of multiple copies of the region of the H. pylori DNA to a reference sequence, identifying the presence of a mutation in multiple copies of the region of the H. pylori DNA, and determining a number of the multiple copies of the region of the H. pylori DNA with the mutation, wherein antibiotic resistant H. pylori is present in the sample when the number of the multiple copies of the region of the H. pylori DNA with the mutation is above a predetermined amount.

Abstract: Methods of isolating cell free RNA from individual's bodily fluid and reliably obtain cell free RNA data are presented, preferably by use of high-stability portions and/or use of targeted small amplicons on the cell free RNA.

Abstract: Provided herein is a method for detecting the presence of clade variants in the COVID-19 virus in a human sample and/or an environmental sample. Samples are processed to obtain total RNA. The RNA is used as a template in a combined reverse transcription and amplification reaction to obtain fluorescent COVID-19 virus amplicons. These amplicons are hybridized on a microarray with nucleic acid probes having sequences that discriminate among the various clade variants. The microarray is imaged to detect the clade variant and each clade variant is distinguished from others by generating an intensity distribution profile from the image, which is unique to each of the clade variants.