The present invention provides for methods of epigenetic analysis. In some cases, the methods may include obtaining a sample comprising a nucleic acid sequence. In some cases, the nucleic acid sequence may comprise one or more epigenetic marks. The methods may include performing a sequencing. The methods may include distinguishing a hydroxymethylated base from a methylated base.

The present invention provides for methods of epigenetic analysis. In some cases, the methods may include obtaining a sample comprising a nucleic acid sequence. In some cases, the nucleic acid sequence may comprise one or more epigenetic marks. The methods may include performing a sequencing. The methods may include distinguishing a hydroxymethylated base from a methylated base.

The present invention provides for methods of epigenetic analysis. In some cases, the methods may include obtaining a sample comprising a nucleic acid sequence. In some cases, the nucleic acid sequence may comprise one or more epigenetic marks. The methods may include performing a sequencing. The methods may include distinguishing a hydroxymethylated base from a methylated base.

The present invention provides for methods of epigenetic analysis. In some cases, the methods may include obtaining a sample comprising a nucleic acid sequence. In some cases, the nucleic acid sequence may comprise one or more epigenetic marks. The methods may include performing a sequencing. The methods may include distinguishing a hydroxymethylated base from a methylated base.

There is described herein a method of detecting the presence of DNA from cancer cells in a subject comprising: providing a sample of cell-free DNA from a subject; subjecting the sample to library preparation to permit subsequent sequencing of the cell-free methylated DNA; optionally denaturing the sample; capturing cell-free methylated DNA using a binder selective for methylated polynucleotides; sequencing the captured cell-free methylated DNA; comparing the sequences of the captured cell-free methylated DNA to control cell-free methylated DNAs sequences from healthy and cancerous individuals; identifying the presence of DNA from cancer cells if there is a statistically significant similarity between one or more sequences of the captured cell-free methylated DNA and cell-free methylated DNAs sequences from cancerous individuals.

There is described herein a method of detecting the presence of DNA from cancer cells in a subject comprising: providing a sample of cell-free DNA from a subject; subjecting the sample to library preparation to permit subsequent sequencing of the cell-free methylated DNA; optionally denaturing the sample; capturing cell-free methylated DNA using a binder selective for methylated polynucleotides; sequencing the captured cell-free methylated DNA; comparing the sequences of the captured cell-free methylated DNA to control cell-free methylated DNAs sequences from healthy and cancerous individuals; identifying the presence of DNA from cancer cells if there is a statistically significant similarity between one or more sequences of the captured cell-free methylated DNA and cell-free methylated DNAs sequences from cancerous individuals.

Disclosed herein are methods, compositions and systems that facilitate accurate phasing of sequence data such as genomic sequence data through the segmentation and rearrangement of nucleic acid molecules in such a way as to preserve individual molecules phase or physical linkage information. This is variously accomplished by binding molecules independent of their phosphodiester backbones, cleaving the molecules, ligating, and sequencing the molecules through long-read sequencing technology to recover segment sequence information spanning at least more than one segment.

Disclosed herein are methods, compositions and systems that facilitate accurate phasing of sequence data such as genomic sequence data through the segmentation and rearrangement of nucleic acid molecules in such a way as to preserve individual molecules phase or physical linkage information. This is variously accomplished by binding molecules independent of their phosphodiester backbones, cleaving the molecules, ligating, and sequencing the molecules through long-read sequencing technology to recover segment sequence information spanning at least more than one segment.

The present invention provides a novel method for preparing a sequencing library and studying molecular interactions involving a nucleic acid. In particular, the invention relates to a method for preparing a sequencing library, the method comprising the addition of an agent binding to chromatin to a sample comprising a nucleic acid; isolating chromatin bound by said agent; addition of transposase to the isolated chromatin; isolating nucleic acid from chromatin; and obtaining a sequencing library. Moreover, the present invention relates to a method for mapping of molecular interactions involving a nucleic acid, the method comprising the addition of an agent binding to chromatin to a sample comprising a nucleic acid; isolating chromatin bound by said agent; addition of transposase to the isolated chromatin; isolating nucleic acid from chromatin; amplification of nucleic acid; sequencing of amplified nucleic acid; and identifying molecular interactions.

The present invention provides a novel method for preparing a sequencing library and studying molecular interactions involving a nucleic acid. In particular, the invention relates to a method for preparing a sequencing library, the method comprising the addition of an agent binding to chromatin to a sample comprising a nucleic acid; isolating chromatin bound by said agent; addition of transposase to the isolated chromatin; isolating nucleic acid from chromatin; and obtaining a sequencing library. Moreover, the present invention relates to a method for mapping of molecular interactions involving a nucleic acid, the method comprising the addition of an agent binding to chromatin to a sample comprising a nucleic acid; isolating chromatin bound by said agent; addition of transposase to the isolated chromatin; isolating nucleic acid from chromatin; amplification of nucleic acid; sequencing of amplified nucleic acid; and identifying molecular interactions.