Provided herein is a method of moving a double-stranded polynucleotide with respect to a nanopore using a motor protein. The method allows a portion of the polynucleotide to be interrogated by the pore multiple times. Also provided are polynucleotide adapters and kits comprising such adapters. The methods find use in characterising polynucleotides, for example in sequencing.

Provided herein is a method of moving a double-stranded polynucleotide with respect to a nanopore using a motor protein. The method allows a portion of the polynucleotide to be interrogated by the pore multiple times. Also provided are polynucleotide adapters and kits comprising such adapters. The methods find use in characterising polynucleotides, for example in sequencing.

Provided herein is a method of characterising a target polynucleotide as it moves with respect to a nanopore using a motor protein. Also provided are polynucleotide adapters and kits comprising such adapters. The methods, kits and adapters find use in characterising polynucleotides, for example in sequencing.

Provided herein is a method of characterising a target polynucleotide as it moves with respect to a nanopore using a motor protein. Also provided are polynucleotide adapters and kits comprising such adapters. The methods, kits and adapters find use in characterising polynucleotides, for example in sequencing.

Provided herein are oligomers, compositions, kits, and methods for capturing target polynucleotides, e.g., for downstream applications such as amplification, library preparation, or sequencing. In some embodiments, a capture oligomer is provided or used that comprises a capture sequence that is annealed to a complement that prevents capture until the complement is displaced in a target-polynucleotide dependent manner. In some embodiments, an amount of target polynucleotide is captured that is less than or equal to a predetermined amount.

Provided herein are oligomers, compositions, kits, and methods for capturing target polynucleotides, e.g., for downstream applications such as amplification, library preparation, or sequencing. In some embodiments, a capture oligomer is provided or used that comprises a capture sequence that is annealed to a complement that prevents capture until the complement is displaced in a target-polynucleotide dependent manner. In some embodiments, an amount of target polynucleotide is captured that is less than or equal to a predetermined amount.

Methods for the high-throughput analysis of transgenic events are herein disclosed. The methods use libraries of sheared genomic DNA ligated to specialized adapters and pooled for sequence analysis and comparison to known genomic and insert sequence. The method finds use in detecting characterizing insertion site, transgene integrity, and transgene copy number.

Methods for the high-throughput analysis of transgenic events are herein disclosed. The methods use libraries of sheared genomic DNA ligated to specialized adapters and pooled for sequence analysis and comparison to known genomic and insert sequence. The method finds use in detecting characterizing insertion site, transgene integrity, and transgene copy number.

The present invention discloses a sequencing library comprising a nucleotide sequence. The sequence comprises a linker sequence and two target sequences. Two ends of the linker sequence are respectively linked to the target sequences and the two target sequences are direct repeat sequences. The present invention further discloses preparation and use of the sequencing library. The present invention overcomes the high error rate problem of current DNA sequencing technologies, especially in a way of very low coverage bias, and can be used to detect low frequency mutations in different kinds of samples.

The present invention discloses a sequencing library comprising a nucleotide sequence. The sequence comprises a linker sequence and two target sequences. Two ends of the linker sequence are respectively linked to the target sequences and the two target sequences are direct repeat sequences. The present invention further discloses preparation and use of the sequencing library. The present invention overcomes the high error rate problem of current DNA sequencing technologies, especially in a way of very low coverage bias, and can be used to detect low frequency mutations in different kinds of samples.