Described herein is a method of sequencing a template that comprises a direct repeat, comprising: (a) in the same reaction, hybridizing a primer to a first site that is upstream of the first repeat sequence and hybridizing a primer to a second site that is upstream of the second repeat sequence, wherein the first and second sites are: (i) upstream of the first and second repeat sequences, respectively, and (ii) equidistant from the first and second repeat sequences; and (b) subjecting the hybridization product of (a) to a sequencing-by-synthesis sequencing reaction to produce a sequence read that comprises a combination of the first and second repeat sequences.

Described herein is a method of sequencing a template that comprises a direct repeat, comprising: (a) in the same reaction, hybridizing a primer to a first site that is upstream of the first repeat sequence and hybridizing a primer to a second site that is upstream of the second repeat sequence, wherein the first and second sites are: (i) upstream of the first and second repeat sequences, respectively, and (ii) equidistant from the first and second repeat sequences; and (b) subjecting the hybridization product of (a) to a sequencing-by-synthesis sequencing reaction to produce a sequence read that comprises a combination of the first and second repeat sequences.

The present invention relates to the field of pharmacogenomics and in particular to detecting the presence or absence of hypermethylated DNA. The detection of CpG methylation in marker DNA is useful for the diagnosis of cancers and the invention provides improved methods for this purpose. These improved methods allow in particular for a more sensitive detection of methylated marker DNA with high backgrounds of unmethylated marker DNA.

The present invention relates to the field of pharmacogenomics and in particular to detecting the presence or absence of hypermethylated DNA. The detection of CpG methylation in marker DNA is useful for the diagnosis of cancers and the invention provides improved methods for this purpose. These improved methods allow in particular for a more sensitive detection of methylated marker DNA with high backgrounds of unmethylated marker DNA.

A method of labelling a nucleic acid of interest (NAOI) is provided. In some embodiments, the method may comprise contacting a sample comprising the nucleic acid of interest with a pool of oligonucleotides, the pool comprising oligonucleotides having at least 5 different lengths; and attaching an oligonucleotide from the pool on to one or each end of the nucleic acid of interest, wherein attachment of an oligonucleotide moves the read start and/or stop coordinate when the labelled NAOI is sequenced.

A method of labelling a nucleic acid of interest (NAOI) is provided. In some embodiments, the method may comprise contacting a sample comprising the nucleic acid of interest with a pool of oligonucleotides, the pool comprising oligonucleotides having at least 5 different lengths; and attaching an oligonucleotide from the pool on to one or each end of the nucleic acid of interest, wherein attachment of an oligonucleotide moves the read start and/or stop coordinate when the labelled NAOI is sequenced.

Disclosed are methods and systems for detecting RNA and sequencing RNA in a wide range of samples such as samples with low concentrations of nucleic acid, samples with degraded nucleic acid, samples that would not otherwise be amenable to conventional sequencing or RNA detection methods, poor quality samples, high quality samples in which rare mutations are sought, formalin-fixed paraffin-embedded samples, blood samples, etc. The methods of the present invention may use paired, large panels of primers to amplify many short fragments that overlap between but not within each panel. Each panel's amplicon set may fill the gaps between those of the opposing panel, thereby providing complete gene or genomic coverage. A preliminary, multiplex amplification step amplifies target nucleic acid for all downstream reactions such as Sanger sequencing, cloning, and Next Generation Sequencing (NGS).

Disclosed are methods and systems for detecting RNA and sequencing RNA in a wide range of samples such as samples with low concentrations of nucleic acid, samples with degraded nucleic acid, samples that would not otherwise be amenable to conventional sequencing or RNA detection methods, poor quality samples, high quality samples in which rare mutations are sought, formalin-fixed paraffin-embedded samples, blood samples, etc. The methods of the present invention may use paired, large panels of primers to amplify many short fragments that overlap between but not within each panel. Each panel's amplicon set may fill the gaps between those of the opposing panel, thereby providing complete gene or genomic coverage. A preliminary, multiplex amplification step amplifies target nucleic acid for all downstream reactions such as Sanger sequencing, cloning, and Next Generation Sequencing (NGS).

This invention provides a method of quantifying chimeric DNA in a cell-free DNA sample.

This invention provides a method of quantifying chimeric DNA in a cell-free DNA sample.