Methods for enhancing specificity of an analyte binding moiety or probe oligonucleotide to an analyte are provided herein. For example, methods provided herein include blocking a capture binding domain, thereby preventing hybridization to the capture domain of the capture probe affixed to a substrate. Further methods include releasing the block from the capture binding domain, thereby allowing the capture binding domain to specifically bind to the capture domain of the capture probe on the substrate.

The present disclosure relates to a method of sequencing nascent RNA in a cell. In some embodiments, the nascent RNA is conjugated to DNA using copper-catalyzed azide-alkyne cycloaddition (CuAAC). Methods of the present disclosure can be used to generate genomic libraries of a cell and measure gene expression and enhancer and/or super-enhancer activity.

The present disclosure relates to a method of sequencing nascent RNA in a cell. In some embodiments, the nascent RNA is conjugated to DNA using copper-catalyzed azide-alkyne cycloaddition (CuAAC). Methods of the present disclosure can be used to generate genomic libraries of a cell and measure gene expression and enhancer and/or super-enhancer activity.

The present application relates to a double-stranded DNA molecule comprising a first double-stranded DNA molecule (1) connected to a second double-stranded DNA molecule (2) by at least one covalent bond which is not a phosphodiester, phosphorothioate, phosphoramidate or phosphorodiamidate bond, preferably by a tether, said tether preferably being a double-stranded DNA molecule.

The present application relates to a double-stranded DNA molecule comprising a first double-stranded DNA molecule (1) connected to a second double-stranded DNA molecule (2) by at least one covalent bond which is not a phosphodiester, phosphorothioate, phosphoramidate or phosphorodiamidate bond, preferably by a tether, said tether preferably being a double-stranded DNA molecule.

Disclosed here is a method for detecting genome rearrangement in a biological sample, comprising: obtaining a contact matrix plotted from proximity ligation sequencing data of at least one chromosome; identifying an abnormal contact pattern in the contact matrix compared to the contact matrix of a reference genome; comparing the abnormal contact pattern in the contact matrix to one or more known patterns associated with genomic rearrangement to identify a type of genomic rearrangement causing the abnormal contact pattern. Also disclosed is a method for detecting genome rearrangement in a biological sample, comprising: selecting linked chromosomal fragments from proximity ligation sequencing data of at least one chromosome, identifying an abnormal covalent bonding pattern of the linked chromosomal fragments compared to a reference genome; and comparing the abnormal covalent bonding pattern to one or more known patterns associated with genomic rearrangement to identify genomic rearrangement causing the abnormal covalent bonding pattern.

Disclosed here is a method for detecting genome rearrangement in a biological sample, comprising: obtaining a contact matrix plotted from proximity ligation sequencing data of at least one chromosome; identifying an abnormal contact pattern in the contact matrix compared to the contact matrix of a reference genome; comparing the abnormal contact pattern in the contact matrix to one or more known patterns associated with genomic rearrangement to identify a type of genomic rearrangement causing the abnormal contact pattern. Also disclosed is a method for detecting genome rearrangement in a biological sample, comprising: selecting linked chromosomal fragments from proximity ligation sequencing data of at least one chromosome, identifying an abnormal covalent bonding pattern of the linked chromosomal fragments compared to a reference genome; and comparing the abnormal covalent bonding pattern to one or more known patterns associated with genomic rearrangement to identify genomic rearrangement causing the abnormal covalent bonding pattern.

The invention relates to the amplification of specific target nucleic acids. The invention provides methods, reagents, and kits for carrying out such amplification via the autoligation chain reaction (ACR).

The invention relates to the amplification of specific target nucleic acids. The invention provides methods, reagents, and kits for carrying out such amplification via the autoligation chain reaction (ACR).

The present disclosure relates to a method of sequencing nascent RNA in a cell. In some embodiments, the nascent RNA is conjugated to DNA using copper-catalyzed azide-alkyne cycloaddition (CuAAC). Methods of the present disclosure can be used to generate genomic libraries of a cell and measure gene expression and enhancer and/or super-enhancer activity.