The present disclosure provides methods and compositions for molecular tagging of complex populations of nucleic acid molecules. The disclosure provides methods and compositions to obtain phase information of tagged nucleic acid molecules from high-throughput nucleic acid sequencing data.

The present disclosure provides methods and compositions for molecular tagging of complex populations of nucleic acid molecules. The disclosure provides methods and compositions to obtain phase information of tagged nucleic acid molecules from high-throughput nucleic acid sequencing data.

Disclosed herein are compositions for detecting the presence of one or more target(s) of interest, wherein the composition comprises a first hairpin initiator molecule and a second initiator molecule. Also disclosed herein are methods of using the same.

Disclosed herein are compositions for detecting the presence of one or more target(s) of interest, wherein the composition comprises a first hairpin initiator molecule and a second initiator molecule. Also disclosed herein are methods of using the same.

Sequencing adaptors and methods are provided for preparation of polynucleotides for sequencing. The sequencing adaptors contain a portion of a recognition sequence for a methyl-dependent endonuclease. Unwanted adaptor dimers that form during ligation of adaptors to target polynucleotides produce a complete restriction sequence and are cleaved by the endonuclease, followed by exonuclease digestion, thereby removing the dimers.

Sequencing adaptors and methods are provided for preparation of polynucleotides for sequencing. The sequencing adaptors contain a portion of a recognition sequence for a methyl-dependent endonuclease. Unwanted adaptor dimers that form during ligation of adaptors to target polynucleotides produce a complete restriction sequence and are cleaved by the endonuclease, followed by exonuclease digestion, thereby removing the dimers.

The invention relates to methods of detecting and/or quantifying analytes in a sample, as well as methods of detecting mutations and/or polymorphisms in nucleic acid molecules. The methods include: providing at least one carrier nucleic acid molecule comprising at least one single-stranded region; providing at least one detection element comprising: at least one fluorophore, at least one fluorescence quencher that quenches spectroscopic detection of the fluorophore; at least one analyte-binding moiety; and at least one nucleic acid moiety that binds to a single stranded region on the carrier nucleic acid molecule; wherein the detection element is configured such that in the absence of the analyte the fluorophore is quenched by the fluorescence quencher and upon analyte binding to the analyte-binding moiety fluorescence is restored; binding these with an analyte to form a complex; translocating the complex through a nanopore via voltage-driven translocation and monitoring time-dependent current response; irradiating the nanopore with radiation that excites the fluorophore and monitoring radiation emissions of the fluorophore over time; and comparing the signals from time-dependent current response and emission over time.

The invention relates to methods of detecting and/or quantifying analytes in a sample, as well as methods of detecting mutations and/or polymorphisms in nucleic acid molecules. The methods include: providing at least one carrier nucleic acid molecule comprising at least one single-stranded region; providing at least one detection element comprising: at least one fluorophore, at least one fluorescence quencher that quenches spectroscopic detection of the fluorophore; at least one analyte-binding moiety; and at least one nucleic acid moiety that binds to a single stranded region on the carrier nucleic acid molecule; wherein the detection element is configured such that in the absence of the analyte the fluorophore is quenched by the fluorescence quencher and upon analyte binding to the analyte-binding moiety fluorescence is restored; binding these with an analyte to form a complex; translocating the complex through a nanopore via voltage-driven translocation and monitoring time-dependent current response; irradiating the nanopore with radiation that excites the fluorophore and monitoring radiation emissions of the fluorophore over time; and comparing the signals from time-dependent current response and emission over time.

Disclosed are compositions and methods that enable loop-mediated isothermal amplification (LAMP) of one or more nucleic acid targets without the need for conventional LAMP primer design customized to each target. A transduction reaction is performed upstream from the LAMP reaction. The transduction reaction generates a single stranded DNA (ssDNA) oligonucleotide when the target nucleic acid is present in the sample. The ssDNA generated in the transduction reaction functions as a required LAMP primer for a universal LAMP template. The ssDNA thus promotes the LAMP reaction. Analysis of the LAMP products can determine the presence of the one or more nucleic acid targets.

Disclosed are compositions and methods that enable loop-mediated isothermal amplification (LAMP) of one or more nucleic acid targets without the need for conventional LAMP primer design customized to each target. A transduction reaction is performed upstream from the LAMP reaction. The transduction reaction generates a single stranded DNA (ssDNA) oligonucleotide when the target nucleic acid is present in the sample. The ssDNA generated in the transduction reaction functions as a required LAMP primer for a universal LAMP template. The ssDNA thus promotes the LAMP reaction. Analysis of the LAMP products can determine the presence of the one or more nucleic acid targets.