The invention relates to a new method of sequencing a double stranded target polynucleotide. The two strands of the double stranded target polynucleotide are linked by a bridging moiety. The two strands of the target polynucleotide are separated using a polynucleotide binding protein and the target polynucleotide is sequenced using a transmembrane pore.

The invention relates to a new method of sequencing a double stranded target polynucleotide. The two strands of the double stranded target polynucleotide are linked by a bridging moiety. The two strands of the target polynucleotide are separated using a polynucleotide binding protein and the target polynucleotide is sequenced using a transmembrane pore.

Methods, systems, and kits with reagents for assessing genotoxicity, are disclosed herein. Genotoxicity and their mechanisms of action can be determined within a few days of a subjects exposure. Some embodiments of the technology are directed to utilizing Duplex Sequencing for assessing a genotoxic potential of a compound (e.g., a chemical compound) in an exposed subject. Other embodiments of the technology are directed to utilizing Duplex Sequencing for determining a mutation signature associated with a genotoxic agent; and/or a safe threshold level of genotoxin exposure. Additional embodiments of the technology are directed to identifying one or more genotoxic agents a subject may have been exposed to by comparing the subjects DNA mutation spectrum to the mutation spectra of known mutagenic compounds. Once a genotoxin exposure in a subject is identified, or confirmed, then a prophylactic, and/or inhibitory therapeutic course of treatment is provided.

Methods, systems, and kits with reagents for assessing genotoxicity, are disclosed herein. Genotoxicity and their mechanisms of action can be determined within a few days of a subjects exposure. Some embodiments of the technology are directed to utilizing Duplex Sequencing for assessing a genotoxic potential of a compound (e.g., a chemical compound) in an exposed subject. Other embodiments of the technology are directed to utilizing Duplex Sequencing for determining a mutation signature associated with a genotoxic agent; and/or a safe threshold level of genotoxin exposure. Additional embodiments of the technology are directed to identifying one or more genotoxic agents a subject may have been exposed to by comparing the subjects DNA mutation spectrum to the mutation spectra of known mutagenic compounds. Once a genotoxin exposure in a subject is identified, or confirmed, then a prophylactic, and/or inhibitory therapeutic course of treatment is provided.

Next Generation DNA sequencing promises to revolutionize clinical medicine and basic research. However, while this technology has the capacity to generate hundreds of billions of nucleotides of DNA sequence in a single experiment, the error rate of approximately 1% results in hundreds of millions of sequencing mistakes. These scattered errors can be tolerated in some applications but become extremely problematic when “deep sequencing” genetically heterogeneous mixtures, such as tumors or mixed microbial populations. To overcome limitations in sequencing accuracy, a method Duplex Consensus Sequencing (DCS) is provided. This approach greatly reduces errors by independently tagging and sequencing each of the two strands of a DNA duplex. As the two strands are complementary, true mutations are found at the same position in both strands. In contrast, PCR or sequencing errors will result in errors in only one strand. This method uniquely capitalizes on the redundant information stored in double-stranded DNA, thus overcoming technical limitations of prior methods utilizing data from only one of the two strands.

Next Generation DNA sequencing promises to revolutionize clinical medicine and basic research. However, while this technology has the capacity to generate hundreds of billions of nucleotides of DNA sequence in a single experiment, the error rate of approximately 1% results in hundreds of millions of sequencing mistakes. These scattered errors can be tolerated in some applications but become extremely problematic when “deep sequencing” genetically heterogeneous mixtures, such as tumors or mixed microbial populations. To overcome limitations in sequencing accuracy, a method Duplex Consensus Sequencing (DCS) is provided. This approach greatly reduces errors by independently tagging and sequencing each of the two strands of a DNA duplex. As the two strands are complementary, true mutations are found at the same position in both strands. In contrast, PCR or sequencing errors will result in errors in only one strand. This method uniquely capitalizes on the redundant information stored in double-stranded DNA, thus overcoming technical limitations of prior methods utilizing data from only one of the two strands.

Methods and associated reagents for efficient genotyping of large numbers of samples via pooling are disclosed herein. Some of the embodiments of the technology are directed utilizing Duplex Sequencing for efficient genotyping of large numbers of samples (e.g., nucleic acid samples, patient samples, tissue samples, blood samples, etc.) and associated applications. Various aspects of the present technology have many applications in both pre-clinical and clinical disease assessment, screening large sample numbers where relatively infrequent variants are being sought, and others.

Methods and associated reagents for efficient genotyping of large numbers of samples via pooling are disclosed herein. Some of the embodiments of the technology are directed utilizing Duplex Sequencing for efficient genotyping of large numbers of samples (e.g., nucleic acid samples, patient samples, tissue samples, blood samples, etc.) and associated applications. Various aspects of the present technology have many applications in both pre-clinical and clinical disease assessment, screening large sample numbers where relatively infrequent variants are being sought, and others.

The present disclosure provides compositions and methods for accurately detecting mutations by uniquely tagging double stranded nucleic acid molecules with dual cyphers such that sequence data obtained from a sense strand can be linked to sequence data obtained from an anti-sense strand when sequenced, for example, by massively parallel sequencing methods.

The present disclosure provides compositions and methods for accurately detecting mutations by uniquely tagging double stranded nucleic acid molecules with dual cyphers such that sequence data obtained from a sense strand can be linked to sequence data obtained from an anti-sense strand when sequenced, for example, by massively parallel sequencing methods.