Provided herein are specially modified blocking nucleotides allowing for the sensitive detection of low copies of variant sequences, while significantly reducing signals from non-variant sequences that are similar but not identical to the variant sequence. These nucleotides can be used to detect rare variants in a sample mixture, as described in the present methods.

Provided herein are specially modified blocking nucleotides allowing for the sensitive detection of low copies of variant sequences, while significantly reducing signals from non-variant sequences that are similar but not identical to the variant sequence. These nucleotides can be used to detect rare variants in a sample mixture, as described in the present methods.

The present disclosure relates to compositions and methods based on polypeptide-tagged nucleotide, and the use of such polypeptide-tagged nucleotides in nanopore devices and methods.

The present disclosure relates to compositions and methods based on polypeptide-tagged nucleotide, and the use of such polypeptide-tagged nucleotides in nanopore devices and methods.

The present invention provides methods, compositions, and systems for distributing single polymerase molecules into array regions. In particular, the methods, compositions, and systems of the present invention result in a distribution of single polymerase molecules into array regions at a percentage that is larger than the percentage expected to be occupied under a Poisson distribution.

The present invention provides methods, compositions, and systems for distributing single polymerase molecules into array regions. In particular, the methods, compositions, and systems of the present invention result in a distribution of single polymerase molecules into array regions at a percentage that is larger than the percentage expected to be occupied under a Poisson distribution.

The present disclosure provides variant OmpG polypeptides, compositions comprising the OmpG variant polypeptides, and methods for using the variant OmpG polypeptides as nanopores for determining the sequence of single stranded nucleic acids. The variant OmpG nanopores reduce the ionic current noise versus the parental OmpG polypeptide from which they are derived and thereby enable sequencing of polynucleotides with single nucleotide resolution. The reduced ionic current noise also provides for the use of these OmpG nanopore variants in other single molecule sensing applications, e.g., protein sequencing.

The present disclosure provides variant OmpG polypeptides, compositions comprising the OmpG variant polypeptides, and methods for using the variant OmpG polypeptides as nanopores for determining the sequence of single stranded nucleic acids. The variant OmpG nanopores reduce the ionic current noise versus the parental OmpG polypeptide from which they are derived and thereby enable sequencing of polynucleotides with single nucleotide resolution. The reduced ionic current noise also provides for the use of these OmpG nanopore variants in other single molecule sensing applications, e.g., protein sequencing.

The present disclosure provides nucleic acid-based nanoswitch catenanes and methods of use. A nanoswitch catenane may include a single-stranded nucleic acid comprising a first and second terminal domain linked to each other to form a host ring by one of a first, second or third switchable bridges, wherein the first switchable bridge is formed in the presence of a reaction agent through the reaction of two cognate functional groups, each linked to a terminal domain of the single-stranded nucleic acid, wherein the second switchable bridge is formed in the presence of a biomolecule of interest through binding of the bio-molecule of interest to two cognate antibodies, each linked to a terminal domain of the single stranded nucleic acid, and wherein the third switchable bridge is a link between two cognate functional groups that breaks in the presence of a dissociation agent. A nanoswitch catenane may also include a circular nucleic acid guest ring catenated with the host ring.

The present disclosure provides nucleic acid-based nanoswitch catenanes and methods of use. A nanoswitch catenane may include a single-stranded nucleic acid comprising a first and second terminal domain linked to each other to form a host ring by one of a first, second or third switchable bridges, wherein the first switchable bridge is formed in the presence of a reaction agent through the reaction of two cognate functional groups, each linked to a terminal domain of the single-stranded nucleic acid, wherein the second switchable bridge is formed in the presence of a biomolecule of interest through binding of the bio-molecule of interest to two cognate antibodies, each linked to a terminal domain of the single stranded nucleic acid, and wherein the third switchable bridge is a link between two cognate functional groups that breaks in the presence of a dissociation agent. A nanoswitch catenane may also include a circular nucleic acid guest ring catenated with the host ring.