A method for template-directed sequencing-by-synthesis of an array of target polynucleotide can include: (a) providing an array of target polynucleotides in a fluidic vessel; (b) contacting the array of polynucleotides with a solution comprising (i) polymerization complex and (ii) reversibly terminating and differently labeled A,C,G, and T/U nucleotides; (c) incorporating one of the differently labeled nucleotides, using the polymerization complex, into a chain complementary to at least one of the array of polynucleotides; (d) binding imaging tags to the differently labeled nucleotides of step (c); (e) imaging and storing the identity and position of the imaging tags of step (d); (f) reversing termination (b)-(e); (g) repeating steps (b)-(e) and assembling a sequence for each of the array of target polynucleotides from the stored identity and position of the imaging tags, optionally as a homogeneous or one pot reaction. Additional methods of sequencing target polynucleotides are described herein.

The present application relates to a method of amplifying genomic DNA of a cell, comprising: (a) providing a reaction mixture, wherein the reaction mixture comprises the genomic DNA, a first type of primer, a second type of primer, a mixture of nucleotide monomers, and a nucleic acid polymerase, wherein the first type of primer comprises, in a 5′ to 3′ orientation, a common sequence and a variable sequence, wherein the common sequence consists of three or two types of bases selected from the group consisting of four types of bases: G, A, C and T, providing that the common sequence does not comprise G and C at the same time, and wherein the second type of primer comprises the common sequence but not the variable sequence; (b) placing the reaction mixture in a first thermal cycle program such that the variable sequence of the first type of primer can pair with the genomic DNA and amplify the genomic DNA to obtain a genomic amplification product, wherein the genomic amplification product comprises the common sequence at its 5′ end and comprises complementary sequence of the common sequence at its 3′ end; (c) placing the reaction mixture obtained from step (b) in a second thermal cycle program, such that the common sequence of the second type of primer can pair with 3′ end of the genomic amplification product and amplify the genomic amplification product to obtain an expanded genomic amplification product, wherein the reaction mixture is provided prior to the step (b) and the step (c). The present application also relates to a kit for amplifying genomic DNA.

The present application relates to a method of amplifying genomic DNA of a cell, comprising: (a) providing a reaction mixture, wherein the reaction mixture comprises the genomic DNA, a first type of primer, a second type of primer, a mixture of nucleotide monomers, and a nucleic acid polymerase, wherein the first type of primer comprises, in a 5′ to 3′ orientation, a common sequence and a variable sequence, wherein the common sequence consists of three or two types of bases selected from the group consisting of four types of bases: G, A, C and T, providing that the common sequence does not comprise G and C at the same time, and wherein the second type of primer comprises the common sequence but not the variable sequence; (b) placing the reaction mixture in a first thermal cycle program such that the variable sequence of the first type of primer can pair with the genomic DNA and amplify the genomic DNA to obtain a genomic amplification product, wherein the genomic amplification product comprises the common sequence at its 5′ end and comprises complementary sequence of the common sequence at its 3′ end; (c) placing the reaction mixture obtained from step (b) in a second thermal cycle program, such that the common sequence of the second type of primer can pair with 3′ end of the genomic amplification product and amplify the genomic amplification product to obtain an expanded genomic amplification product, wherein the reaction mixture is provided prior to the step (b) and the step (c). The present application also relates to a kit for amplifying genomic DNA.

The present disclosure provides methods, kits and compositions for identifying nucleic acid agents having a desired property, e.g., a property of specifically binding to a target (such as a protein target) with high affinity. More specifically, the present disclosure provides methods, kits and compositions for identifying candidate nucleic acid agents with both high specificity and affinity for a target.

The present disclosure provides methods, kits and compositions for identifying nucleic acid agents having a desired property, e.g., a property of specifically binding to a target (such as a protein target) with high affinity. More specifically, the present disclosure provides methods, kits and compositions for identifying candidate nucleic acid agents with both high specificity and affinity for a target.

The present invention relates to a nucleic acids and variants thereof, as well as uses thereof. The present nucleic acids are useful for detecting indels (insertions and deletions) as small as 1 nucleotide in a target nucleic acid. They have a broad applicability for detecting indels following genome editing and can also be used in methods for amplifying a target nucleic acid.

The present invention relates to a nucleic acids and variants thereof, as well as uses thereof. The present nucleic acids are useful for detecting indels (insertions and deletions) as small as 1 nucleotide in a target nucleic acid. They have a broad applicability for detecting indels following genome editing and can also be used in methods for amplifying a target nucleic acid.

This disclosure provides methods, systems, compositions, and kits for the multiplexed detection of a plurality of analytes in a sample. In some examples, this disclosure provides methods, systems, compositions, and kits wherein multiple analytes may be detected in a single sample volume by acquiring a cumulative measurement or measurements of at least one quantifiable component of a signal. In some cases, additional components of a signal, or additional signals (or components thereof) are also quantified. Each signal or component of a signal may be used to construct a coding scheme which can then be used to determine the presence or absence of any analyte.

This disclosure provides methods, systems, compositions, and kits for the multiplexed detection of a plurality of analytes in a sample. In some examples, this disclosure provides methods, systems, compositions, and kits wherein multiple analytes may be detected in a single sample volume by acquiring a cumulative measurement or measurements of at least one quantifiable component of a signal. In some cases, additional components of a signal, or additional signals (or components thereof) are also quantified. Each signal or component of a signal may be used to construct a coding scheme which can then be used to determine the presence or absence of any analyte.

An aerolysin nanopore or a nanotube is used for the electrical detection of peptides, proteins separated by at least one amino acid and other macromolecules such as polysaccharides or synthetic or natural polymers present in a preparation where said nanopore or nanotube is inserted into a lipid membrane which is subjected to a difference in potential greater than −160 mV, in a reaction medium having an alkali metal halide electrolyte solution with a concentration of less than 6M and at a temperature of less than 40° C., and where said use is intended to differentiate said peptides, proteins and other molecules according to their length and their mass. Application to the sequencing of peptides and other molecules to differentiate them according to their length and mass with an amino acid-level or monomer-level resolution and to medical diagnosis.