Disclosed is a hybridisation capture method based on the pyrophosphorolysis reaction. According to the present invention, there is provided a method for increasing the ratio of a first nucleic add sequence to second nucleic add sequence in a sample.

This invention relates to methods, compositions and kits for extending a polynucleotide and for preparing sequencing library of polynucleotides involving generating modified target polynucleotide on an adaptor template oligonucleotide and tagging one or two strands of a target sequence. The sequencing library is suitable for massive parallel sequencing and comprises a plurality of double-stranded nucleic acid molecules.

This invention relates to methods, compositions and kits for extending a polynucleotide and for preparing sequencing library of polynucleotides involving generating modified target polynucleotide on an adaptor template oligonucleotide and tagging one or two strands of a target sequence. The sequencing library is suitable for massive parallel sequencing and comprises a plurality of double-stranded nucleic acid molecules.

The present disclosure provides compositions comprising nucleic acid molecules coupled to supports and comprising one or more cleavable or excisable moieties. Methods of enriching and sequencing nucleic acid molecules are also provided.

The present disclosure provides compositions comprising nucleic acid molecules coupled to supports and comprising one or more cleavable or excisable moieties. Methods of enriching and sequencing nucleic acid molecules are also provided.

Disclosed is a preparation method for a DNA next-generation sequencing library, including steps: digestion, end repair, and A-tailing of genomic DNA; adapter ligation of DNA fragments; bead purification of product after adapter ligation; PCR amplification of DNA fragments; and selection and purification of PCR product fragments. The preparation method for the DNA next-generation sequencing library includes steps: fractionating by VVN and T7 through a single-step reaction process with double digestion and end repair, blunting a 5′-overhang under the polymerization action of a Taq DNA polymerase, adding an A (adenine) to a 3′-end, and achieving the preparation of the DNA next-generation sequencing library under an integrated single-step reaction. After the single-step reaction ends, bead purification isn't required, so that the preparation process is simple. In the preparation process, there is no preference for two restriction enzymes, which achieves the sequencing of target fragments.

Disclosed is a preparation method for a DNA next-generation sequencing library, including steps: digestion, end repair, and A-tailing of genomic DNA; adapter ligation of DNA fragments; bead purification of product after adapter ligation; PCR amplification of DNA fragments; and selection and purification of PCR product fragments. The preparation method for the DNA next-generation sequencing library includes steps: fractionating by VVN and T7 through a single-step reaction process with double digestion and end repair, blunting a 5′-overhang under the polymerization action of a Taq DNA polymerase, adding an A (adenine) to a 3′-end, and achieving the preparation of the DNA next-generation sequencing library under an integrated single-step reaction. After the single-step reaction ends, bead purification isn't required, so that the preparation process is simple. In the preparation process, there is no preference for two restriction enzymes, which achieves the sequencing of target fragments.

An example method includes reacting a first solution and a different, second solution on a flow cell by flowing the first solution over amplification sites on the flow cell and subsequently flowing the second solution over the amplification sites. The first solution includes target nucleic acids and a first reagent mixture that comprises nucleoside triphosphates and replication enzymes. The target nucleic acids in the first solution transport to and bind to the amplification sites at a transport rate. The first reagent mixture amplifies the target nucleic acids that are bound to the amplification sites to produce clonal populations of amplicons originating from corresponding target nucleic acids. The amplicons are produced at an amplification rate that exceeds the transport rate. The second solution includes a second reagent mixture and lacks the target nucleic acids. The second solution is to increase a number of the amplicons at the amplification sites.

An example method includes reacting a first solution and a different, second solution on a flow cell by flowing the first solution over amplification sites on the flow cell and subsequently flowing the second solution over the amplification sites. The first solution includes target nucleic acids and a first reagent mixture that comprises nucleoside triphosphates and replication enzymes. The target nucleic acids in the first solution transport to and bind to the amplification sites at a transport rate. The first reagent mixture amplifies the target nucleic acids that are bound to the amplification sites to produce clonal populations of amplicons originating from corresponding target nucleic acids. The amplicons are produced at an amplification rate that exceeds the transport rate. The second solution includes a second reagent mixture and lacks the target nucleic acids. The second solution is to increase a number of the amplicons at the amplification sites.

A method, in particular an in vitro method, for the circularization of a double stranded DNA nucleic acid. Also, a circularized double stranded DNA nucleic acid obtainable by the method. Another aspect pertains to a host cell comprising a circularized double stranded DNA nucleic acid obtainable by the method. Further, therapeutic and non-therapeutic uses of a circularized double stranded DNA nucleic acid obtainable by the method. Finally, a kit for the circularization of a double stranded DNA nucleic acid.