The current document is directed to methods and compositions that enable simplified, sensitive, and accurate quantification of nucleic acids. Some methods enable highly parallel measurement of multiple targeted ribonucleic acids from multiple samples. Additional methods enable highly sensitive measurement of low-abundance nucleic acid variants from a complex mixture of nucleic acid molecules.

The present invention relates to, among other things, probes, compositions, methods, and kits for simultaneous, multiplexed detection and quantification of protein and/or nucleic acid expression in a user-defined region of a tissue, user-defined cell, and/or user-defined subcellular structure within a cell.

The present invention relates to, among other things, probes, compositions, methods, and kits for simultaneous, multiplexed detection and quantification of protein and/or nucleic acid expression in a user-defined region of a tissue, user-defined cell, and/or user-defined subcellular structure within a cell.

Methods of coupling adaptors to a target nucleic acid include coupling a first adaptor to a first end of the target nucleic acid to form a coupled first adaptor. A portion of a second adaptor is hybridized to a portion of the coupled first adaptor to form a hybridized second adaptor having a single-stranded 3′-end. The hybridized second adaptor is coupled to a second end of the target nucleic acid to form an adaptor-flanked product having at least a part of the first adaptor coupled to the first end of the target nucleic acid and at least a part of the second adaptor coupled to the second end of the target nucleic acid. These methods can minimize the formation of adaptor-dimers that may be problematic in subsequent complementary nucleic acid strand synthesis, amplification, and sequencing.

Methods of coupling adaptors to a target nucleic acid include coupling a first adaptor to a first end of the target nucleic acid to form a coupled first adaptor. A portion of a second adaptor is hybridized to a portion of the coupled first adaptor to form a hybridized second adaptor having a single-stranded 3′-end. The hybridized second adaptor is coupled to a second end of the target nucleic acid to form an adaptor-flanked product having at least a part of the first adaptor coupled to the first end of the target nucleic acid and at least a part of the second adaptor coupled to the second end of the target nucleic acid. These methods can minimize the formation of adaptor-dimers that may be problematic in subsequent complementary nucleic acid strand synthesis, amplification, and sequencing.

This application provides a bead with a covalently attached chemical compound and a covalently attached DNA barcode and methods for using such beads. The bead has many substantially identical copies of the chemical compound and many substantially identical copies of the DNA barcode. The compound consists of one or more chemical monomers, where the DNA barcode takes the form of barcode modules, where each module corresponds to and allows identification of a corresponding chemical monomer. The nucleic acid barcode can have a concatenated structure or an orthogonal structure. Provided are method for sequencing the bead-bound nucleic acid barcode, for cleaving the compound from the bead, and for assessing biological activity of the released compound.

This application provides a bead with a covalently attached chemical compound and a covalently attached DNA barcode and methods for using such beads. The bead has many substantially identical copies of the chemical compound and many substantially identical copies of the DNA barcode. The compound consists of one or more chemical monomers, where the DNA barcode takes the form of barcode modules, where each module corresponds to and allows identification of a corresponding chemical monomer. The nucleic acid barcode can have a concatenated structure or an orthogonal structure. Provided are method for sequencing the bead-bound nucleic acid barcode, for cleaving the compound from the bead, and for assessing biological activity of the released compound.

Kits and methods of using the kits for analyzing macromolecules, including peptides, polypeptides, and proteins, employing nucleic acid encoding are disclosed. The sample analysis kits employ nucleic acid encoding and/or nucleic acid recording of a molecular interaction and/or reaction, such as recognition events (e.g., between an antigen and an antibody, between a modified terminal amino acid residue, or between a small molecule or peptide therapeutic and a target, etc.). Additional barcoding reagents, such as those for cycle-specific barcoding (e.g., “clocking”), compartment barcoding, combinatorial barcoding, spatial barcoding, or any combination thereof, may be included in the kits. The sample may comprise macromolecules, including peptides, polypeptides, and proteins, and the recording may generate molecular interaction and/or reaction information, and/or polypeptide sequence information. The kits may be used in high-throughput, multiplexed, and/or automated analysis, and are suitable for analysis of a proteome or subset thereof.

Kits and methods of using the kits for analyzing macromolecules, including peptides, polypeptides, and proteins, employing nucleic acid encoding are disclosed. The sample analysis kits employ nucleic acid encoding and/or nucleic acid recording of a molecular interaction and/or reaction, such as recognition events (e.g., between an antigen and an antibody, between a modified terminal amino acid residue, or between a small molecule or peptide therapeutic and a target, etc.). Additional barcoding reagents, such as those for cycle-specific barcoding (e.g., “clocking”), compartment barcoding, combinatorial barcoding, spatial barcoding, or any combination thereof, may be included in the kits. The sample may comprise macromolecules, including peptides, polypeptides, and proteins, and the recording may generate molecular interaction and/or reaction information, and/or polypeptide sequence information. The kits may be used in high-throughput, multiplexed, and/or automated analysis, and are suitable for analysis of a proteome or subset thereof.

Disclosed herein are methods, compositions and systems for the interrogation of macromolecules, more particularly for preparation of isolated single macromolecules for subsequent processing of specific regions of interest within said macromolecule based on an analysis of the molecule's physical map. The disclosure is further related to the controlled segmentation of long nucleic acid parent molecules into smaller child molecules in a targeted manner such that further processing on said children may be performed with the knowledge of their origin within the parent, in a controlled environment enabled by purposefully designed microfluidic devices. Also disclosed is binding of regional specific barcodes along the length of a long nucleic acid molecule such that upon cleavage of said molecule into child molecules, the regional origin of the children can be tracked, in a controlled environment enabled by purposefully designed microfluidic devices. Finally, the disclosure is further related to droplet devices and method to control the encapsulation of long nucleic acid molecules or specific subregions thereof into a droplet, and further tracking said droplets with their contents.