An example of a kit includes a flow cell, a primer fluid, and a cleaving fluid. The flow cell includes at least one surface functionalized with a polymeric hydrogel including azide functional groups or amine functional groups. The primer fluid includes a plurality of alkyne-containing primers, each alkyne-containing primer having an amino cleavable group attaching a primer sequence of the alkyne-containing primer to an alkyne-containing moiety of the alkyne-containing primer. The cleaving fluid includes a substance that is reactive with the amino cleavable group.

An example of a kit includes a flow cell, a primer fluid, and a cleaving fluid. The flow cell includes at least one surface functionalized with a polymeric hydrogel including azide functional groups or amine functional groups. The primer fluid includes a plurality of alkyne-containing primers, each alkyne-containing primer having an amino cleavable group attaching a primer sequence of the alkyne-containing primer to an alkyne-containing moiety of the alkyne-containing primer. The cleaving fluid includes a substance that is reactive with the amino cleavable group.

The present disclosure relates, in part, to improved methods of making single-stranded DNA (ssDNA) from double-stranded DNA (dsDNA), as well as use of the resulting ssDNA for genome engineering. The disclosure also relates, in part, to improved methods of genetic modification using single stranded DNA binding proteins.

The present disclosure relates, in part, to improved methods of making single-stranded DNA (ssDNA) from double-stranded DNA (dsDNA), as well as use of the resulting ssDNA for genome engineering. The disclosure also relates, in part, to improved methods of genetic modification using single stranded DNA binding proteins.

A nucleic acid amplification method using a solid-phase carrier according to the present invention comprises: capturing a target nucleic acid comprising mRNA on a solid-phase carrier; carrying out complementary-strand synthesis on the solid phase; carrying out exonuclease treatment to degrade and remove unreacted target- capturing nucleic acid on the solid phase; and then carrying out mRNA degradation and homopolymer addition by TdT reaction in the presence of a chain-terminating nucleotide triphosphate. According to the method of the present invention, cDNA can be stably and highly efficiently amplified even from a small amount of sample even in cases where the ratio of the amount of enzyme to the DNA substrate on the solid phase is excessive, where the reaction time is excessive, and/or where reagents show lot-to-lot variation. Further, the amplification method of the present invention can broaden the range of applications of techniques in which analysis using a specific-binding molecule labeled with an oligonucleic acid such as a DNA-labeled antibody and analysis of transcripts are carried out simultaneously.

A nucleic acid amplification method using a solid-phase carrier according to the present invention comprises: capturing a target nucleic acid comprising mRNA on a solid-phase carrier; carrying out complementary-strand synthesis on the solid phase; carrying out exonuclease treatment to degrade and remove unreacted target- capturing nucleic acid on the solid phase; and then carrying out mRNA degradation and homopolymer addition by TdT reaction in the presence of a chain-terminating nucleotide triphosphate. According to the method of the present invention, cDNA can be stably and highly efficiently amplified even from a small amount of sample even in cases where the ratio of the amount of enzyme to the DNA substrate on the solid phase is excessive, where the reaction time is excessive, and/or where reagents show lot-to-lot variation. Further, the amplification method of the present invention can broaden the range of applications of techniques in which analysis using a specific-binding molecule labeled with an oligonucleic acid such as a DNA-labeled antibody and analysis of transcripts are carried out simultaneously.

The present invention relates to a method for the highly specific, targeted capture of regions of human genomes and transcriptomes from the blood, i.e. from cell free circulating DNA, exosomes, microRNA, circulating tumor cells, or total blood cells, to allow for the highly sensitive detection of mutation, expression, copy number, translocation, alternative splicing, and methylation changes using combined nuclease, ligation, polymerase, and massively parallel sequencing reactions. The method generates a collection of different circular chimeric single-stranded nucleic acid constructs, suitable for sequencing on multiple platforms. In some embodiments, each construct of the collection comprised a first single stranded segment of original genomic DNA from a host organism and a second single stranded synthetic nucleic acid segment that is linked to the first single stranded segment and comprises a nucleotide sequence that is exogenous to the host organism. These chimeric constructs are suitable for identifying and enumerating mutations, copy changes, translocations, and methylation changes. In other embodiments, input mRNA, lncRNA, or miRNA is used to generate circular DNA products that reflect the presence and copy number of specific mRNA's, lncRNA's splice-site variants, translocations, and miRNA.

The present invention relates to a method for the highly specific, targeted capture of regions of human genomes and transcriptomes from the blood, i.e. from cell free circulating DNA, exosomes, microRNA, circulating tumor cells, or total blood cells, to allow for the highly sensitive detection of mutation, expression, copy number, translocation, alternative splicing, and methylation changes using combined nuclease, ligation, polymerase, and massively parallel sequencing reactions. The method generates a collection of different circular chimeric single-stranded nucleic acid constructs, suitable for sequencing on multiple platforms. In some embodiments, each construct of the collection comprised a first single stranded segment of original genomic DNA from a host organism and a second single stranded synthetic nucleic acid segment that is linked to the first single stranded segment and comprises a nucleotide sequence that is exogenous to the host organism. These chimeric constructs are suitable for identifying and enumerating mutations, copy changes, translocations, and methylation changes. In other embodiments, input mRNA, lncRNA, or miRNA is used to generate circular DNA products that reflect the presence and copy number of specific mRNA's, lncRNA's splice-site variants, translocations, and miRNA.

The present invention relates to a method for analysis of methylation of ribonucleic acid (RNA) comprising the steps: (i) contacting RNA with one or more antibodies which binds to methylated site(s) of RNA; wherein the methylated site(s) comprise at least one ribonucleotide base modified by one or more methyl groups; (ii) photo-crosslinking the one or more antibodies to crosslink individual antibodies to the RNA molecule(s) to form RNA-antibody conjugates; (iii) immunoprecipitating to separate the RNA-antibody conjugates; (iv) treating the RNA-antibody conjugates with at least one exonuclease; (v) removing the crosslinked antibodies from the RNA-antibody conjugates to release RNA; and (vi) analysing the released RNA.

The present invention relates to a method for analysis of methylation of ribonucleic acid (RNA) comprising the steps: (i) contacting RNA with one or more antibodies which binds to methylated site(s) of RNA; wherein the methylated site(s) comprise at least one ribonucleotide base modified by one or more methyl groups; (ii) photo-crosslinking the one or more antibodies to crosslink individual antibodies to the RNA molecule(s) to form RNA-antibody conjugates; (iii) immunoprecipitating to separate the RNA-antibody conjugates; (iv) treating the RNA-antibody conjugates with at least one exonuclease; (v) removing the crosslinked antibodies from the RNA-antibody conjugates to release RNA; and (vi) analysing the released RNA.