A nucleic acid patch method for amplifying target nucleic acid sequences in circulating free DNA or residual DNA samples where the defining ends of the target nucleic acid sequences are unknown.

A nucleic acid patch method for amplifying target nucleic acid sequences in circulating free DNA or residual DNA samples where the defining ends of the target nucleic acid sequences are unknown.

A nucleic acid patch method for amplifying target nucleic acid sequences in circulating free DNA or residual DNA samples where the defining ends of the target nucleic acid sequences are unknown.

Embodiments of the disclosure encompass highly sensitive and quantitative methods for single-cell sequencing of total RNA. In particular cases, methods utilize annealing of multiple primers to RNA, polytailing of single stranded DNA reverse transcribed therefrom, and utilization of bar codes in primers for amplification of amplicons produced from second strand synthesis.

Embodiments of the disclosure encompass highly sensitive and quantitative methods for single-cell sequencing of total RNA. In particular cases, methods utilize annealing of multiple primers to RNA, polytailing of single stranded DNA reverse transcribed therefrom, and utilization of bar codes in primers for amplification of amplicons produced from second strand synthesis.

The present invention relates to a method for the highly specific, targeted capture of regions of human genomes and transcriptomes from the blood, i.e. from cell free circulating DNA, exosomes, microRNA, circulating tumor cells, or total blood cells, to allow for the highly sensitive detection of mutation, expression, copy number, translocation, alternative splicing, and methylation changes using combined nuclease, ligation, polymerase, and massively parallel sequencing reactions. The method generates a collection of different circular chimeric single-stranded nucleic acid constructs, suitable for sequencing on multiple platforms. In some embodiments, each construct of the collection comprised a first single stranded segment of original genomic DNA from a host organism and a second single stranded synthetic nucleic acid segment that is linked to the first single stranded segment and comprises a nucleotide sequence that is exogenous to the host organism. These chimeric constructs are suitable for identifying and enumerating mutations, copy changes, translocations, and methylation changes. In other embodiments, input mRNA, lncRNA, or miRNA is used to generate circular DNA products that reflect the presence and copy number of specific mRNA's, lncRNA's splice-site variants, translocations, and miRNA.

The present invention relates to a method for the highly specific, targeted capture of regions of human genomes and transcriptomes from the blood, i.e. from cell free circulating DNA, exosomes, microRNA, circulating tumor cells, or total blood cells, to allow for the highly sensitive detection of mutation, expression, copy number, translocation, alternative splicing, and methylation changes using combined nuclease, ligation, polymerase, and massively parallel sequencing reactions. The method generates a collection of different circular chimeric single-stranded nucleic acid constructs, suitable for sequencing on multiple platforms. In some embodiments, each construct of the collection comprised a first single stranded segment of original genomic DNA from a host organism and a second single stranded synthetic nucleic acid segment that is linked to the first single stranded segment and comprises a nucleotide sequence that is exogenous to the host organism. These chimeric constructs are suitable for identifying and enumerating mutations, copy changes, translocations, and methylation changes. In other embodiments, input mRNA, lncRNA, or miRNA is used to generate circular DNA products that reflect the presence and copy number of specific mRNA's, lncRNA's splice-site variants, translocations, and miRNA.

The present invention relates to the detection of a target nucleic acid sequence from a DNA or a mixture of nucleic acids by a PCE-hCTO (PTO Cleavage and Extension using hCTO) assay on a solid phase. According to the present invention, the extended duplex is formed in a liquid phase in a target-dependent manner and then its presence is detected on a solid phase. Since hCTO is not immobilized onto a solid phase, the extended duplex is more effectively formed in a liquid phase.

The present invention relates to the detection of a target nucleic acid sequence from a DNA or a mixture of nucleic acids by a PCE-hCTO (PTO Cleavage and Extension using hCTO) assay on a solid phase. According to the present invention, the extended duplex is formed in a liquid phase in a target-dependent manner and then its presence is detected on a solid phase. Since hCTO is not immobilized onto a solid phase, the extended duplex is more effectively formed in a liquid phase.

A kit for preparing a nucleic acid sample for analysis by liquid chromatography tandem mass spectrometry (LC-MS/MS) is provided, the kit comprising: a lyophilized enzyme composition comprising: micrococcal nuclease; nuclease P1; and bacterial alkaline phosphatase (BAP); and a digestion buffer. Also provided are enzyme compositions and methods of use for rapid, efficient preparation of a nucleic acid sample for analysis by LC-MS/MS, without the need for denaturation of the sample.