Compositions and methods for identifying and using cis-regulatory and decoy sequences are disclosed.

Compositions and methods for identifying and using cis-regulatory and decoy sequences are disclosed.

The present invention provides compositions, kits and methods for the selective hybridization and capture of a specific target nucleic acid. The specific target nucleic acid may be present in a heterogeneous mixture of nucleic acids. Selective hybridization and capture provides a target nucleic acid that is substantially free of non-target and/or contaminating nucleic acids. Target nucleic acids that have been selectively hybridized and captured using the current invention are then used in subsequent analysis, wherein the presence of non-target and/or contaminating nucleic acids that interfere with said subsequent analysis have been substantially reduced or eliminated, thereby providing improved analysis results. The invention offers the further advantage of requiring less stringent purification and/or sterility efforts than conventionally needed in order to ensure that enzymes and other reagents used in subsequent analysis, or present in the environment in which an assay is performed, are free of bacterial or other contaminating nucleic acids.

The present invention provides compositions, kits and methods for the selective hybridization and capture of a specific target nucleic acid. The specific target nucleic acid may be present in a heterogeneous mixture of nucleic acids. Selective hybridization and capture provides a target nucleic acid that is substantially free of non-target and/or contaminating nucleic acids. Target nucleic acids that have been selectively hybridized and captured using the current invention are then used in subsequent analysis, wherein the presence of non-target and/or contaminating nucleic acids that interfere with said subsequent analysis have been substantially reduced or eliminated, thereby providing improved analysis results. The invention offers the further advantage of requiring less stringent purification and/or sterility efforts than conventionally needed in order to ensure that enzymes and other reagents used in subsequent analysis, or present in the environment in which an assay is performed, are free of bacterial or other contaminating nucleic acids.

Provided herein are oligomers, compositions, kits, and methods for capturing target polynucleotides, e.g., for downstream applications such as amplification, library preparation, or sequencing. In some embodiments, a capture oligomer is provided or used that comprises a capture sequence that is annealed to a complement that prevents capture until the complement is displaced in a target-polynucleotide dependent manner. In some embodiments, an amount of target polynucleotide is captured that is less than or equal to a predetermined amount.

Provided herein are oligomers, compositions, kits, and methods for capturing target polynucleotides, e.g., for downstream applications such as amplification, library preparation, or sequencing. In some embodiments, a capture oligomer is provided or used that comprises a capture sequence that is annealed to a complement that prevents capture until the complement is displaced in a target-polynucleotide dependent manner. In some embodiments, an amount of target polynucleotide is captured that is less than or equal to a predetermined amount.

Provided herein are methods for labeling input DNA with oligonucleotide barcode sequences, and selective PCR amplification of DNA sequence variants across the targeted regions for variant quantitation.

Provided herein are methods for labeling input DNA with oligonucleotide barcode sequences, and selective PCR amplification of DNA sequence variants across the targeted regions for variant quantitation.

The invention pertains to construction of next-generation DNA sequencing (NGS) libraries for whole genome sequencing, targeted resequencing, sequencing-based screening assays, metagenomics, or any other application requiring sample preparation for NGS.

The invention pertains to construction of next-generation DNA sequencing (NGS) libraries for whole genome sequencing, targeted resequencing, sequencing-based screening assays, metagenomics, or any other application requiring sample preparation for NGS.