A membrane-spanning nanopore is provided that comprises: i. at least one scaffold polynucleotide strand; ii. a plurality of staple polynucleotide strands; and iii. at least one hydrophobically-modified polynucleotide strand, wherein the at least one hydrophobically-modified polynucleotide strand comprises a polynucleotide strand and a hydrophobic moiety; wherein each of the plurality of staple polynucleotide strands hybridises to the at least one scaffold polynucleotide strand to form the three-dimensional structure of the membrane-spanning nanopore, and wherein the at least one hydrophobically-modified polynucleotide strand hybridises to a portion of the at least one scaffold polynucleotide strand, the membrane-spanning nanopore defining a central channel with a minimum internal width of at least about 5 nm. Membranes comprising the membrane-spanning nanopore and applications of those membranes are also provided.

The present disclosure relates, in some embodiments, to isolated nucleic acids (also referred to as cap guides) and methods of use thereof for RNA mapping. The disclosure is based, in part, on guide RNAs that bind to a position that is at least 7 nucleotides downstream of the first nucleotide of an mRNA molecule.

The present disclosure relates, in some embodiments, to isolated nucleic acids (also referred to as cap guides) and methods of use thereof for RNA mapping. The disclosure is based, in part, on guide RNAs that bind to a position that is at least 7 nucleotides downstream of the first nucleotide of an mRNA molecule.

The present invention relates to a method for detecting a target nucleic acid, which induces any surrogate target to be amplified in the presence of the target nucleic acid and is useful for molecular diagnosis, prenatal diagnosis, early diagnosis, cancer diagnosis, genetic related diagnosis, genetic trait diagnosis, diagnosis of infectious bacteria, identification of drug-resistant bacteria, forensic medicine, species identification of organisms, and the like.

A membrane-spanning nanopore is provided that comprises: i. at least one scaffold polynucleotide strand; ii. a plurality of staple polynucleotide strands; and iii. at least one hydrophobically-modified polynucleotide strand, wherein the at least one hydrophobically-modified polynucleotide strand comprises a polynucleotide strand and a hydrophobic moiety; wherein each of the plurality of staple polynucleotide strands hybridises to the at least one scaffold polynucleotide strand to form the three-dimensional structure of the membrane-spanning nanopore, and wherein the at least one hydrophobically-modified polynucleotide strand hybridises to a portion of the at least one scaffold polynucleotide strand, the membrane-spanning nanopore defining a central channel with a minimum internal width of at least about 5 nm.

A membrane-spanning nanopore is provided that comprises: i. at least one scaffold polynucleotide strand; ii. a plurality of staple polynucleotide strands; and iii. at least one hydrophobically-modified polynucleotide strand, wherein the at least one hydrophobically-modified polynucleotide strand comprises a polynucleotide strand and a hydrophobic moiety; wherein each of the plurality of staple polynucleotide strands hybridises to the at least one scaffold polynucleotide strand to form the three-dimensional structure of the membrane-spanning nanopore, and wherein the at least one hydrophobically-modified polynucleotide strand hybridises to a portion of the at least one scaffold polynucleotide strand, the membrane-spanning nanopore defining a central channel with a minimum internal width of at least about 5 nm.

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 disclosure, in some aspects, is directed to methods of nucleic acid enrichment using high affinity capture probes comprising one or more nucleotide analogs and uses thereof. For example, in another aspect, provided herein are methods of enriching a target nucleic acid if present in a sample. In another aspect, provided herein are methods of detecting if a target nucleic acid is in a sample. In another aspect, the present disclosure is directed to uses, kits, and compositions of the methods described herein.

The present disclosure, in some aspects, is directed to methods of nucleic acid enrichment using high affinity capture probes comprising one or more nucleotide analogs and uses thereof. For example, in another aspect, provided herein are methods of enriching a target nucleic acid if present in a sample. In another aspect, provided herein are methods of detecting if a target nucleic acid is in a sample. In another aspect, the present disclosure is directed to uses, kits, and compositions of the methods described herein.