The present disclosure provides methods of analysing the nucleotide read sequences of a nucleic acid sample of interest using high throughput bidirectional sequencing. The methods of the present disclosure are designed to work even where bidirectional sequencing produces forward and reverse reads that are not of a sufficient read length to be paired via the complementary hybridisation of overlapping sequences at the 3° end of the sequence reads. The disclosure further provides computer-implemented methods, computer-readable storage mediums and devices that implement a method for preparing nucleic acid sequence results for analysis from non-overlapping sequence reads for screening a nucleic acid sample of interest for the expression of one or more target nucleotide sequences.

The present disclosure provides methods of analysing the nucleotide read sequences of a nucleic acid sample of interest using high throughput bidirectional sequencing. The methods of the present disclosure are designed to work even where bidirectional sequencing produces forward and reverse reads that are not of a sufficient read length to be paired via the complementary hybridisation of overlapping sequences at the 3° end of the sequence reads. The disclosure further provides computer-implemented methods, computer-readable storage mediums and devices that implement a method for preparing nucleic acid sequence results for analysis from non-overlapping sequence reads for screening a nucleic acid sample of interest for the expression of one or more target nucleotide sequences.

The present invention relates to a method for removing free adapters in a DNA library using a double-stranded nucleic acid molecule and a restriction enzyme, and more specifically, to a method for removing free adapters in a DNA library for next generation sequencing (NGS) using a double-stranded nucleic acid molecule including a type IIs restriction enzyme recognition site and a complementary sequence thereof, and a type IIs restriction enzyme.

The present invention relates to a method for removing free adapters in a DNA library using a double-stranded nucleic acid molecule and a restriction enzyme, and more specifically, to a method for removing free adapters in a DNA library for next generation sequencing (NGS) using a double-stranded nucleic acid molecule including a type IIs restriction enzyme recognition site and a complementary sequence thereof, and a type IIs restriction enzyme.

Provided herein are methods and compositions for creating a sequencing library comprising a target nucleic acid. Methods herein can comprise: contacting a nucleic acid sample to a first population of primers, a polymerase, dNTPs, and labeled ddNTPs; performing an extension reaction thereby creating an labeled extension product; contacting the extension product to a second population of primers to create a double stranded extension product comprising the target nucleic acid; contacting the double stranded extension product to a target specific enzyme under conditions allowing cleavage of at least a subset of the double stranded extension product thereby creating a cleaved target nucleic acid; and isolating the cleaved target nucleic acid.

Provided herein are methods and compositions for creating a sequencing library comprising a target nucleic acid. Methods herein can comprise: contacting a nucleic acid sample to a first population of primers, a polymerase, dNTPs, and labeled ddNTPs; performing an extension reaction thereby creating an labeled extension product; contacting the extension product to a second population of primers to create a double stranded extension product comprising the target nucleic acid; contacting the double stranded extension product to a target specific enzyme under conditions allowing cleavage of at least a subset of the double stranded extension product thereby creating a cleaved target nucleic acid; and isolating the cleaved target nucleic acid.

The present disclosure is directed to a single-end sequencing method for improved detection of genomic rearrangements such as deletions, insertions, inversions, and translocations that are present in a polynucleotide. A first priming event allows for sequencing of a target sequence, and a second priming event on an adapter allows for identification of the sequences amplified and tagged by selective amplification. The combination of priming events in the same direction facilitates read alignment and the identification of any genomic rearrangements.

The present disclosure is directed to a single-end sequencing method for improved detection of genomic rearrangements such as deletions, insertions, inversions, and translocations that are present in a polynucleotide. A first priming event allows for sequencing of a target sequence, and a second priming event on an adapter allows for identification of the sequences amplified and tagged by selective amplification. The combination of priming events in the same direction facilitates read alignment and the identification of any genomic rearrangements.

Methods are disclosed for adding adapters to fragmented nucleic acids for next generation sequencing, including providing numerical codes based on variable adapter molecular barcode lengths on both sides of the fragmented nucleic acids and identifying reads from the same fragment based on both barcodes. The methods and products allow for the amplification of the fragmented nucleic acids when there is a low yield of isolated fragmented nucleic acids and also for efficient and reliable detection of low-frequency mutations including in subpopulations of cells within a subject.

Methods are disclosed for adding adapters to fragmented nucleic acids for next generation sequencing, including providing numerical codes based on variable adapter molecular barcode lengths on both sides of the fragmented nucleic acids and identifying reads from the same fragment based on both barcodes. The methods and products allow for the amplification of the fragmented nucleic acids when there is a low yield of isolated fragmented nucleic acids and also for efficient and reliable detection of low-frequency mutations including in subpopulations of cells within a subject.