Disclosed herein, inter alia, are compositions and methods providing sequencing-efficient solutions for detecting genetic features and aberrations.

Disclosed herein, inter alia, are compositions and methods providing sequencing-efficient solutions for detecting genetic features and aberrations.

A method for specifically and efficiently quantifying the expression of targeted RNA variants with specific terminal sequences suitable to identify multiple isoforms bearing complex heterogeneity in terminal sequences by hybridizing a 5′-Dbs-adapter to the 5′-end of target RNAs, wherein the 5′-Dbs-adapter has a stem-loop structure whose protruding 5′-end base-pairs with the 5′-end of target RNAs, and wherein the loop region of 5′-Dbs-adapter contains a base-lacking spacer which will terminate reverse transcription in a subsequent step; hybridizing a 3′Db-adapter to the 3′-end of target RNAs, wherein the 3′-Db-adapter has a stem-loop structure whose protruding 3′-end base-pairs with the 3′-end of target RNAs; ligating both adapters with target RNAs by RN12 ligation to form a “dumbbell-like” structure; and, amplifying and quantifying the ligation product by RT-PCR.

A method for specifically and efficiently quantifying the expression of targeted RNA variants with specific terminal sequences suitable to identify multiple isoforms bearing complex heterogeneity in terminal sequences by hybridizing a 5′-Dbs-adapter to the 5′-end of target RNAs, wherein the 5′-Dbs-adapter has a stem-loop structure whose protruding 5′-end base-pairs with the 5′-end of target RNAs, and wherein the loop region of 5′-Dbs-adapter contains a base-lacking spacer which will terminate reverse transcription in a subsequent step; hybridizing a 3′Db-adapter to the 3′-end of target RNAs, wherein the 3′-Db-adapter has a stem-loop structure whose protruding 3′-end base-pairs with the 3′-end of target RNAs; ligating both adapters with target RNAs by RN12 ligation to form a “dumbbell-like” structure; and, amplifying and quantifying the ligation product by RT-PCR.

The present disclosure relates in some aspects to methods, probes, kits, and compositions for analysis of a target nucleic acid, such as in situ generation of a circular probe for detection of a target nucleic acid in a tissue sample.

The present disclosure relates in some aspects to methods, probes, kits, and compositions for analysis of a target nucleic acid, such as in situ generation of a circular probe for detection of a target nucleic acid in a tissue sample.

The present invention provides methods, compositions, and systems for distributing molecules and complexes into reaction sites. In particular, the methods, compositions, and systems of the present invention result in an active loading of molecules and complexes into reaction sites with improved efficiency over loading by passive diffusion methods alone.

The present invention provides methods, compositions, and systems for distributing molecules and complexes into reaction sites. In particular, the methods, compositions, and systems of the present invention result in an active loading of molecules and complexes into reaction sites with improved efficiency over loading by passive diffusion methods alone.

Provided herein is a circular proximity ligation assay in which proximity-probes are employed as bridges to connect two free oligonucleotides via a dual ligation event, resulting in the formation of a circle. The circles are then quantified by, e.g., qPCR. The addition of an extra oligonucleotide is believed to enhance specificity by decreasing the probability of random background ligation events. In addition, circle formation may have selective advantages, as uncircularized DNA can be removed by a simple exonuclease treatment and it has streamlined the workflow by eliminating preamplification prior to qPCR.

Provided herein is a circular proximity ligation assay in which proximity-probes are employed as bridges to connect two free oligonucleotides via a dual ligation event, resulting in the formation of a circle. The circles are then quantified by, e.g., qPCR. The addition of an extra oligonucleotide is believed to enhance specificity by decreasing the probability of random background ligation events. In addition, circle formation may have selective advantages, as uncircularized DNA can be removed by a simple exonuclease treatment and it has streamlined the workflow by eliminating preamplification prior to qPCR.