The present disclosure relates to compositions and methods of RNA analysis. In particular, the present disclosure provides a method of RNA analysis that includes obtaining a sample, applying one or more multi-partite probes to the sample, where each of the one or more multi-partite probes includes at least two sub-probes, annealing at least one of the applied one or more multi-partite probes to at least one target nucleic acid within the sample, and ligating the at least two sub-probes associated with the at least one annealed multi-partite probe to create a target nucleic acid proxy that can be detected.

Disclosed is a method for detecting the presence of a DNA adduct in DNA. The method involves the pre-labeling of an adducted nucleotide in the DNA with a quaternary ammonium compound.

Disclosed is a method for detecting the presence of a DNA adduct in DNA. The method involves the pre-labeling of an adducted nucleotide in the DNA with a quaternary ammonium compound.

Technology provided herein relates in part to methods, processes and apparatuses for non-invasive assessment of genetic variations.

Nucleic acid sequencing methods and systems, the systems including nanochannel chip including: a nanochannel formed in an upper surface of the nanochannel chip and; a roof covering the nanochannel and comprising nanopores and a field enhancement structure; and a barrier disposed in the nanochannel. The method including: introducing a buffer solution including long-chain nucleic acids to the nanochannel chip; applying a voltage potential across the nanochannel chip to drive the nucleic acids through the nanochannel, towards the barrier, and to translocate the nucleic acids through nanopores adjacent to the barrier, such that bases of each of the nucleic acids pass through the field enhancement structure one base at a time and emerge onto an upper surface of the roof; detecting the Raman spectra of the bases of the nucleic acids as each base passes through the electromagnetic-field enhancement structure; and sequencing the nucleic acids based on the detected Raman spectra.

Nucleic acid sequencing methods and systems, the systems including nanochannel chip including: a nanochannel formed in an upper surface of the nanochannel chip and; a roof covering the nanochannel and comprising nanopores and a field enhancement structure; and a barrier disposed in the nanochannel. The method including: introducing a buffer solution including long-chain nucleic acids to the nanochannel chip; applying a voltage potential across the nanochannel chip to drive the nucleic acids through the nanochannel, towards the barrier, and to translocate the nucleic acids through nanopores adjacent to the barrier, such that bases of each of the nucleic acids pass through the field enhancement structure one base at a time and emerge onto an upper surface of the roof; detecting the Raman spectra of the bases of the nucleic acids as each base passes through the electromagnetic-field enhancement structure; and sequencing the nucleic acids based on the detected Raman spectra.

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.

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.

The present disclosure provides methods for direct sequencing of RNA, including but not limited to any coding RNA and non-coding RNA such as tRNA, rRNA, mRNA, short or long non-coding RNA as well as any of their modified forms/versions, without the need for generation of a cDNA intermediate and/or intensive sample preparation.

The present disclosure provides methods for direct sequencing of RNA, including but not limited to any coding RNA and non-coding RNA such as tRNA, rRNA, mRNA, short or long non-coding RNA as well as any of their modified forms/versions, without the need for generation of a cDNA intermediate and/or intensive sample preparation.