Disclosed herein are methods and compositions for detection of one or more specific sequences of polynucleotides in a solution using a nanopore. In some embodiments, methods and compositions for identifying a polynucleotide in a sample or for target sequence detection of a polynucleotide are disclosed herein.

Disclosed herein are methods and compositions for detection of one or more specific sequences of polynucleotides in a solution using a nanopore. In some embodiments, methods and compositions for identifying a polynucleotide in a sample or for target sequence detection of a polynucleotide are disclosed herein.

The present invention relates to the field of analysis of the three-dimensional structure of the genome, i.e., for genome architecture mapping (GAM). The invention provides a method of determining spatial proximity of a plurality of nucleic acid loci in a compartment such as the cell nucleus, by exploiting their co-segregation amongst fractions of that compartment, identified upon separation of the nucleic acid loci from each other depending on their localization in the compartment to obtain a collection of fractions, e.g., by cryo-sectioning or cryo-milling the compartment; determining the presence or absence of the plurality of loci in said fractions; and determining the co-segregation of said plurality of loci. Co-segregation may then be analysed with statistical methods to determine spatial proximity. The method can be used e.g., for determining physical distance between a plurality of loci; and mapping loci and/or genome architecture, e.g., in the nucleus; identification of regulatory regions directing expression of a specific gene through spatial contacts; identifying the nuclear position of an exogenous nucleic acid in the nucleus and/or diagnosing a disease associated with a disturbed co-segregation of loci.

The present invention relates to the field of analysis of the three-dimensional structure of the genome, i.e., for genome architecture mapping (GAM). The invention provides a method of determining spatial proximity of a plurality of nucleic acid loci in a compartment such as the cell nucleus, by exploiting their co-segregation amongst fractions of that compartment, identified upon separation of the nucleic acid loci from each other depending on their localization in the compartment to obtain a collection of fractions, e.g., by cryo-sectioning or cryo-milling the compartment; determining the presence or absence of the plurality of loci in said fractions; and determining the co-segregation of said plurality of loci. Co-segregation may then be analysed with statistical methods to determine spatial proximity. The method can be used e.g., for determining physical distance between a plurality of loci; and mapping loci and/or genome architecture, e.g., in the nucleus; identification of regulatory regions directing expression of a specific gene through spatial contacts; identifying the nuclear position of an exogenous nucleic acid in the nucleus and/or diagnosing a disease associated with a disturbed co-segregation of loci.

The present invention relates to the field of molecular biology and more in particular to DNA technology. The invention relates to strategies for assessing structural integrity of DNA sequences of a genomic region of interest, which has clinical applications in diagnostics and personalized cancer therapy. In particular, the invention provides a method of detecting a chromosomal rearrangement involving a genomic region of interest.

The present invention relates to the field of molecular biology and more in particular to DNA technology. The invention relates to strategies for assessing structural integrity of DNA sequences of a genomic region of interest, which has clinical applications in diagnostics and personalized cancer therapy. In particular, the invention provides a method of detecting a chromosomal rearrangement involving a genomic region of interest.

An analyte [25] in a matrix is sensed using a sensing device having a detection probe [21] conjugated to a mediator-receptor [22] that is not a binder for the analyte. The sensor device is provided with mediators [23] conjugated to analyte-receptors [24], where the mediators are selected to bind to the mediator-receptors, and where the analyte-receptors are selected to bind to the analyte. In some embodiments, the mediators are bound to the detection probe by a tether molecule, or tether molecule fragment, or tether domain. In other embodiments, the mediators are not bound to the detection probe. The presence of the analyte is detected by optically or electrically detecting changes of distance between the mediators and the mediator-receptor, indicative of association and/or dissociation events between mediators and mediator-receptor, the characteristics of which are affected by whether the analyte is bound to the analyte-receptor.

An analyte [25] in a matrix is sensed using a sensing device having a detection probe [21] conjugated to a mediator-receptor [22] that is not a binder for the analyte. The sensor device is provided with mediators [23] conjugated to analyte-receptors [24], where the mediators are selected to bind to the mediator-receptors, and where the analyte-receptors are selected to bind to the analyte. In some embodiments, the mediators are bound to the detection probe by a tether molecule, or tether molecule fragment, or tether domain. In other embodiments, the mediators are not bound to the detection probe. The presence of the analyte is detected by optically or electrically detecting changes of distance between the mediators and the mediator-receptor, indicative of association and/or dissociation events between mediators and mediator-receptor, the characteristics of which are affected by whether the analyte is bound to the analyte-receptor.

Provided are methods and systems for detecting formation of nucleotide-specific ternary complexes comprising a DNA polymerase, a nucleic acid, and a nucleotide complementary to the templated base of the primed template nucleic acid. The methods and systems facilitate determination of the next correct nucleotide without requiring chemical incorporation of the nucleotide into the primer. These results can even be achieved in procedures employing unlabeled, native nucleotides.

Provided are methods and systems for detecting formation of nucleotide-specific ternary complexes comprising a DNA polymerase, a nucleic acid, and a nucleotide complementary to the templated base of the primed template nucleic acid. The methods and systems facilitate determination of the next correct nucleotide without requiring chemical incorporation of the nucleotide into the primer. These results can even be achieved in procedures employing unlabeled, native nucleotides.