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 invention disclosure relates to a next generation DNA sequencing method and use for accurate and massively parallel quantification of one or more nucleic acid targets, for example in large volumes of unpurified sample material. More particularly, the invention is related to a method and a kit comprising probes for detecting and quantifying genetic targets in complex samples. The invention includes one or more target-specific nucleic acid probes per genetic target and a bridge oligo or bridge oligo complex.

The present invention disclosure relates to a next generation DNA sequencing method and use for accurate and massively parallel quantification of one or more nucleic acid targets, for example in large volumes of unpurified sample material. More particularly, the invention is related to a method and a kit comprising probes for detecting and quantifying genetic targets in complex samples. The invention includes one or more target-specific nucleic acid probes per genetic target and a bridge oligo or bridge oligo complex.

Dumbbell-shaped DNA minimal vectors represent genetic vectors solely composed of the gene expression cassette of interest and terminal closing loop structures. Dumbbell vectors for small hairpin RNA or microRNA expression are extremely small-sized which is advantageous with regard to cellular delivery and nuclear diffusion. Conventional strategies for the generation of small RNA-expressing dumbbell vectors require cloning of a respective plasmid vector which is subsequently used for dumbbell protection. Here, we present a novel cloning-free method for the generation of small RNA-expressing dumbbell vectors which also does not require any restriction endonucleases. The method comprises the PCR amplification of a universal DNA template using primers containing the sense or antisense strand of the sequence of interest, the denaturing and refolding of the amplified product to form stem-loop structures, and the structures are covalently closed using DNA ligases to obtain dumbbell structures.

Dumbbell-shaped DNA minimal vectors represent genetic vectors solely composed of the gene expression cassette of interest and terminal closing loop structures. Dumbbell vectors for small hairpin RNA or microRNA expression are extremely small-sized which is advantageous with regard to cellular delivery and nuclear diffusion. Conventional strategies for the generation of small RNA-expressing dumbbell vectors require cloning of a respective plasmid vector which is subsequently used for dumbbell protection. Here, we present a novel cloning-free method for the generation of small RNA-expressing dumbbell vectors which also does not require any restriction endonucleases. The method comprises the PCR amplification of a universal DNA template using primers containing the sense or antisense strand of the sequence of interest, the denaturing and refolding of the amplified product to form stem-loop structures, and the structures are covalently closed using DNA ligases to obtain dumbbell structures.

The present disclosure provides methods for sequencing nucleic acid targets (e.g., both DNA and RNA co-amplified in a sample mixture, for example by using a surrogate for the RNA). Such methods can be used to determine if one or more nucleic acid targets are present in a sample.

The present disclosure provides methods for sequencing nucleic acid targets (e.g., both DNA and RNA co-amplified in a sample mixture, for example by using a surrogate for the RNA). Such methods can be used to determine if one or more nucleic acid targets are present in a sample.

Methods and compositions for the detection and quantification of nucleic acids are provided. In one embodiment, a sample is contacted with a primer and a quencher-probe complementary to a target nucleic acid. The quencher-probe is complementary to an anti-probe that comprises a reporter and is attached to a solid support. Thus, hybridized probe is cleaved with a nucleic acid polymerase having exonuclease activity to release the quencher from the probe. The presence of the target nucleic acid is then detected and/or optionally quantified by detecting an increase in signal from the fluorescent reporter on the solid support.

Methods and compositions for the detection and quantification of nucleic acids are provided. In one embodiment, a sample is contacted with a primer and a quencher-probe complementary to a target nucleic acid. The quencher-probe is complementary to an anti-probe that comprises a reporter and is attached to a solid support. Thus, hybridized probe is cleaved with a nucleic acid polymerase having exonuclease activity to release the quencher from the probe. The presence of the target nucleic acid is then detected and/or optionally quantified by detecting an increase in signal from the fluorescent reporter on the solid support.

The invention provides a method for genetic analysis in individuals that reveals both the genetic sequences and chromosomal copy number of targeted and specific genomic loci in a single assay. The present invention further provide methods for the sensitive and specific detection of target gene sequences and gene expression profiles.