Abstract: The present invention features compositions and methods for quantifying detection of a target oligonucleotide in a sample in real time. These methods are compatible with target oligonucleotides amplified using a NEAR reaction.

Abstract: A method for amplification of nucleic acids in which substantially use is made of the fact that a pre-defined nucleic acid chain (target sequence) can be multiplied/amplified in the presence of a target sequence-specific activator oligonucleotide. The target sequence-specific activator oligonucleotide causes the separation of re-synthesized complementary primer extension products by strand displacement, so that a new primer oligonucleotide can attach to the respective template strand. The thus formed complex of a primer oligonucleotide and a template strand can initiate a new primer extension reaction. The thus formed primer extension products in turn function as templates, so that an exponential amplification reaction results. Amplification of a particular target sequence takes place more efficiently in case of perfect match complementary base pair formation between the activator oligonucleotide and the corresponding target sequence.

Abstract: Methods for the detection of components from biological samples are provided. In certain aspects, the methods may be used to detect and/or quantify specific components in a biological sample, such as tumor cells (e.g., circulating tumor cells). Systems and devices for practicing the subject methods are also provided.

Abstract: Methods for performing multiplex PCR-based enrichment of a target substrate are provided. Systems and methods for generating a sequencing library are also provided.

Abstract: The invention provides methods for isolating RNA from the soluble fraction of urine. The methods can be used for detecting the presence or absence of an RNA, or quantifying the amount of an RNA. The methods are useful for diagnosing an individual suspected of having a disease by detecting the level of RNA associated with the disease in the soluble fraction of urine. The methods are also useful for prognosing an individual diagnosed with a disease by detecting the level of RNA associated with the disease in the soluble fraction of urine.

Abstract: A method for identifying a nucleic acid template that includes (a) providing a plurality of primer-template hybrids, wherein a first hybrid of the plurality includes a first template hybridized to a first primer, and wherein a second hybrid of the plurality includes a second template hybridized to a second primer, the second primer having a ternary complex inhibitor moiety at the 3? end; (b) delivering polymerases and nucleotides to the plurality, whereby the first hybrid binds a polymerase and nucleotide to form a stabilized ternary complex and whereby the second hybrid does not bind a polymerase and nucleotide to form a stabilized ternary complex; and (c) detecting the stabilized ternary complex to identify the first template.

Abstract: The present invention provides methods for analyzing polynucleotides such as genomic DNA. In some embodiments, the disclosure provides a method for preparing and amplifying a genomic DNA library in situ in a fixed biological sample. The method comprises treating a fixed biological sample with an insertional enzyme complex to produce tagged fragments of genomic DNA. The method further comprises circularizing the tagged fragments of genomic DNA. The method further comprises amplifying the tagged fragments of genomic DNA.

Abstract: Disclosed are systems and methods for simultaneous detection of DNA and RNA genetic alterations comprising gene splicing variants, mutations, indel, copy number changes, fusion and combination thereof, in a biofluid sample from the patient without physically separating RNA from DNA. The systems and methods are similarly applicable to the simultaneous detection of DNA and RNA genetic alterations in solid tissues comprising gene splicing variants, mutations, indel, copy number changes, fusion and combination thereof. The present method utilized a barcoding method for analysis. The streamlined methods improve the simplicity, quantification accuracy and detection sensitivity and specificity of non-invasive detections of biomarkers.

Abstract: Disclosed are processes and kits for rapid nucleic acid extraction from a nucleic acid-containing material, such as a bone, tooth or semen sample. For bone and tooth process involves providing the nucleic acid-containing material in a form suitable for nucleic acid extraction, adding a lysis buffer to the nucleic acid-containing material to obtain a mixture, mixing the mixture in a manner equivalent for about 30 seconds or longer and separating the mixture by centrifugation to obtain a liquid supernatant. The liquid supernatant contains the extracted nucleic acids which can be used for analysis including STR profiling by conventional or rapid DNA analysis. For semen the processes and kits involve applying an appropriate amount of sperm disruptive agent.

Abstract: The invention is a novel method of making and using a template for nucleic acid sequencing. The templates include circular and linear templates with symmetric and asymmetric adaptors. The methods include utilizing the templates in an asymmetric fashion.

Abstract: Methods for performing multiplex PCR-based enrichment of a target substrate are provided. Systems and methods for generating a sequencing library are also provided.

Abstract: Provided herein are methods and compositions for single cell characterization using affinity-oligonucleotide conjugates. In some aspects, such methods may comprise attaching a first vessel barcoded polynucleotide to an oligonucleotide portion of an affinity-oligonucleotide conjugate, which binds to a target antigen expressed by a single cell that is isolated in a single vessel. In some aspects, the oligonucleotide portion of the affinity-oligonucleotide conjugate may comprise an antigen identification sequence (AID). In some aspects, the oligonucleotide portion of the affinity-oligonucleotide conjugate may further comprise an affinity molecular barcode (AMB) sequence. In some aspects, such methods may further comprise lysing the single cell and attaching a second vessel barcoded polynucleotide to a cell polynucleotide from the single cell.

Abstract: Disclosed herein in are methods and systems for determining genetic variants (e.g., copy number variation) in a polynucleotide sample. A method for determining copy number variations includes tagging double-stranded polynucleotides with duplex tags, sequencing polynucleotides from the sample and estimating total number of polynucleotides mapping to selected genetic loci. The estimate of total number of polynucleotides can involve estimating the number of double-stranded polynucleotides in the original sample for which no sequence reads are generated. This number can be generated using the number of polynucleotides for which reads for both complementary strands are detected and reads for which only one of the two complementary strands is detected.

Abstract: Disclosed herein in are methods and systems for determining genetic variants (e.g., copy number variation) in a polynucleotide sample. A method for determining copy number variations includes tagging double-stranded polynucleotides with duplex tags, sequencing polynucleotides from the sample and estimating total number of polynucleotides mapping to selected genetic loci. The estimate of total number of polynucleotides can involve estimating the number of double-stranded polynucleotides in the original sample for which no sequence reads are generated. This number can be generated using the number of polynucleotides for which reads for both complementary strands are detected and reads for which only one of the two complementary strands is detected.

Abstract: Presented are methods and compositions for preparing samples for amplification and sequencing. Particular embodiments relate to methods of preparing nucleic acid-continuing cellular samples for library amplification, wherein the methods include lysing cells of the sample to form a lysate, amplifying the nucleic acids from the lysed samples, exposing the amplified nucleic acids to a solid surface, and clonally amplifying the amplified nucleic acids to generate clusters.

Abstract: It is intended to provide a method for determining a tumor. The method for determining a tumor comprises: (1) treating genomic DNA prepared from a subject tissue or cell with bisulfite (the subject tissue or cell is derived from a patient who is affected by a tumor and is determined as (i) having MSI-H of the tumor in MSI examination and/or no or reduced expression of MLH1 in the tumor in immunohistochemical examination, and (ii) having no mutation in MLH1 in genetic examination); 2) amplifying, by PCR, DNA comprising a portion or the whole of MLH1 promoter region from the bisulfite-treated DNA; 3) subjecting the PCR amplification product to ion exchange chromatography to obtain a detection signal; 4) determining whether or not the peak of the detection signal is a peak indicating highly methylated DNA; and 5) determining the tumor as a tumor derived from a patient without Lynch syndrome when the peak is determined as a peak indicating highly methylated DNA.

Abstract: A serum microRNA (miRNA) marker suitable for early screening and diagnosis of ossification of posterior longitudinal ligament (OPLL) and its application in the diagnostic reagent or kit for the OPLL. Biomarker miRNA-563, miRNA-196b, miRNA-10a and miRNA-129 have high diagnostic value for OPLL, and the development and application of the related serum miRNA biomarker detection reagent kit. It can be applied in the screening of ossification of posterior longitudinal ligament disease, supporting the diagnosis of OPLL more quickly and accurately, evaluate the patient's ossification condition, and may lay down the foundation for improving clinical therapeutic effect.

Abstract: A kit for simultaneously detecting HSV1 and HSV2 includes a forward primer and a reverse primer specific to HSV1, and a forward primer and a reverse primer specific to HSV2. The forward primer specific to HSV1 has a sequence of SEQ ID NO: 1 or SEQ ID NO: 4, and the reverse primer specific to HSV1 has a sequence of SEQ ID NO: 2 or SEQ ID NO: 7. The forward primer specific to HSV2 has a sequence of SEQ ID NO: 6, and the reverse primer specific to HSV2 has a sequence of SEQ ID NO: 7.

Abstract: Provided herein are methods and composition for immune repertoire sequencing and single cell barcoding. In some aspects, such methods may comprise steps of: (a) forming a plurality of first vessels each comprising: (i) a single cell, and (ii) a single solid support; (b) copying onto the single solid support: (i) a first copy of a first cell polynucleotide from the single cell, and (ii) a second copy of a second cell polynucleotide from the single cell; (c) forming a plurality of second vessels each comprising (i) a single solid support from the plurality of first vessels, and (ii) a barcoded polynucleotide; and (d) amplifying (i) the first copy and the second copy with a first primer set, and (ii) the barcode with a second primer set, wherein a primer of the first primer set is complementary to a primer of the second set; and (e) forming first and second single cell barcoded sequences.

Abstract: Disclosed herein in are methods and systems for determining genetic variants (e.g., copy number variation) in a polynucleotide sample. A method for determining copy number variations includes tagging double-stranded polynucleotides with duplex tags, sequencing polynucleotides from the sample and estimating total number of polynucleotides mapping to selected genetic loci. The estimate of total number of polynucleotides can involve estimating the number of double-stranded polynucleotides in the original sample for which no sequence reads are generated. This number can be generated using the number of polynucleotides for which reads for both complementary strands are detected and reads for which only one of the two complementary strands is detected.