Abstract:
Assay methods and apparatus for the analysis of biopolymers are disclosed. The assays employ nicking endonucleases to enable the generation of flaps on target biomolecules which are detected in nanopore or fluidic channel devices. Identification of flap locations enables a map of the target biomolecule to be derived.

Description:
CROSS REFERENCE TO RELATED APPLICATION 
       [0001]    This application is a continuation of U.S. patent application Ser. No. 12/891,343 filed Sep. 27, 2010, which is hereby incorporated by reference in its entirety. 
     
    
     SEQUENCE LISTING 
       [0002]    The instant application contains a Sequence Listing which has been submitted in ASCII format via EFS-Web and is hereby incorporated by reference in its entirety. Said ASCII copy, created on Nov. 8, 2010, is named NAB-011.txt and is 2,432 bytes in size. 
       FIELD OF INVENTION 
       [0003]    The present invention relates generally to assay methods and devices for the analysis of biopolymers. Mapping of such biopolymers is contemplated herein. 
       BACKGROUND 
       [0004]    Identifying the composition and sequence of various biomolecules, such as human DNA, with accuracy and specificity is of great interest. Mapping and sequencing technology, however, is time consuming and expensive to develop and implement. For example, sequencing the DNA of a single individual for the Human Genome Project required over $3 billion of funding. 
         [0005]    It is estimated that each person&#39;s DNA varies from one another by approximately 1 base in 1000. Knowledge of such genetic variations among human populations may allow the scientific community to identify genetic trends that are related to various medical predispositions, conditions, or diseases, and may lead to the realization of truly personalized medicine where treatments are customized for a given individual based on that individual&#39;s DNA. A reduction in the time and cost of DNA mapping and sequencing is needed to develop such knowledge and to tailor medical diagnostics and treatments based on the genetic makeup of individual patients. 
         [0006]    New DNA sequencing technologies produce many short reads (lengths of sequenced DNA) that are then used to assemble the sequence of the entire sample. These “short-read” technologies have sequenced read lengths of from 25 bases to 400 bases. For genomes of modest size or complexity, these short reads are incapable of correctly assembling the sequence of the sample because of the appearance of repeats in the sequence. DNA mapping may be used to guide the assembly. For instance, restriction maps may be used to aid in the assembly of short-read data. More rapid and higher density maps would be useful to enable short-read technologies to assemble data. 
         [0007]    Hybridization Assisted Nanopore Sequencing (HANS) is a nanopore-based method for sequencing genomic lengths of DNA and other biomolecules. The method relies on detecting the position of hybridization of probes on specific portions of the biomolecule to be sequenced or characterized. 
         [0008]    In this method, two reservoirs of solution are separated by a nanometer-sized hole, or nanopore, that serves as a fluidic constriction of known dimensions. The application of a constant DC voltage between the two reservoirs results in a baseline ionic current that is measured. If an analyte is introduced into a reservoir, it may pass through the fluidic channel and change the observed current, due to a difference in conductivity between the electrolyte solution and analyte. The magnitude of the change in current depends on the volume of electrolyte displaced by the analyte while it is in the fluidic channel. The duration of the current change is related to the amount of time that the analyte takes to pass through the nanopore constriction. The current signals are used in determining the position of the probes on the biomolecule. Measurement of the probe positions allows for accurate reconstruction of the biomolecule sequence using computer algorithms. A need exists for efficient methods and devices capable of rapid and accurate nucleic acid mapping and sequencing for de novo assembly of human genomes. It is desirable to have long read lengths and to use as little nucleic acid template as possible. 
         [0009]    Mapping and sequencing may also be achieved using fluidic nano-channel and micro-channel based devices. In these systems, the analyte is caused to transit through a nano- or micro-channel, and its passage is detected by electrodes positioned along the length of the channel. In one embodiment, described in co-pending U.S. patent application Ser. No. 12/789,817, filed May 28, 2010, and the teachings of which are incorporated herein by reference in its entirety, a first pair of electrodes is positioned longitudinally along the channel to provide a reference voltage between them. A second pair of electrodes is positioned across the channel to define a detection volume. As an analyte passes through the detection volume, it causes a detectable change in an electrical property, for example, a change in the reference voltage. Probes that are hybridized to the analyte cause a further change in the electrical property when they enter the detection volume. Thus, it is possible to detect when the analyte is present in the detection volume, as well as the absolute or relative position of hybridized probes as they enter the detection volume. 
         [0010]    Despite the foregoing, there remains a need for improved methods and devices for the analysis of biopolymers, including improved assay methods for mapping and sequencing such biopolymers. 
       SUMMARY 
       [0011]    The embodiments of the invention relate to assay methods for preparing target analyte samples suitable for mapping using nanopore, micro-channel or nano-channel analysis devices. 
         [0012]    In one embodiment, the method includes the steps of a) providing a double-stranded DNA template having first and second DNA strands, each strand having a 5′ end and a 3′ end, b) contacting the double-stranded DNA template with a nicking endonuclease to form a nick at a sequence-specific nicking location on the first DNA strand, c) conducting a base extension reaction on the first DNA strand along the corresponding region of the second DNA strand, the reaction starting at the nick and progressing toward the 3′ end of the first DNA strand to thereby form a single-stranded flap on the template adjacent to the nicking location, and d) coating the double-stranded DNA template with a binding moiety that enhances electrical detection of the template and the single-stranded flap, to thereby prepare the target analyte. 
         [0013]    In another embodiment, the method includes the steps of a) providing a double-stranded DNA template having first and second DNA strands, each strand having a 5′ end and a 3′ end, b) contacting the template with a nicking endonuclease to form nicks at sequence-specific locations on the first DNA strand, c) conducting a first base extension reaction on the first DNA strand along the corresponding region of the second DNA strand, the reaction starting at each nick and progressing toward the 3′ end of the first DNA strand to thereby form single-stranded flap regions on the double-stranded DNA template adjacent to the sequence specific nicking locations, and d) conducting a second base extension reaction on at least one flap region to form at least one double-stranded flap, to thereby prepare the target analyte. In this embodiment, all or a portion of the resulting analyte may be coated with a binding moiety. Thus, in this embodiment, an additional step of coating the double-stranded flap, as well as the double-stranded DNA template, with a binding moiety may be employed. 
         [0014]    In still another embodiment, the method includes the steps of a) providing a double-stranded DNA template having a first and a second DNA strand, each DNA strand having a 5′ end and a 3′ end, b) contacting the double-stranded DNA template with a nicking endonuclease to form a nick at a sequence-specific nicking location on the first DNA strand, c) conducting a base extension reaction on the first DNA strand along a corresponding region of the second DNA strand, the reaction starting at the nick and progressing toward the 3′ end of the first DNA strand to thereby form a single-stranded flap on the double-stranded DNA template adjacent to the sequence-specific nicking location, and d) coating the single-stranded flap with a binding moiety that selectively binds with single-stranded DNA to enhance electrical detection of the single-stranded flap, to thereby prepare the target analyte. 
         [0015]    In another embodiment, the method includes the steps of a) providing a double-stranded DNA template having first and second DNA strands, each strand having a 5′ end and a 3′ end, b) contacting the template with a nicking endonuclease to form nicks at sequence-specific locations on the first DNA strand, c) conducting a first base extension reaction on the first DNA strand along the corresponding region of the second DNA strand, the reaction starting at each nick and progressing toward the 3′ end of the first DNA strand to thereby form single-stranded flap regions on the double-stranded DNA template adjacent to the sequence-specific nicking locations, d) conducting a second base extension reaction on at least one single-stranded flap region to form at least one double-stranded flap, e) adding a single-stranded extension to the double-stranded flap, and f) hybridizing one or more probes to the single-stranded extension, to thereby prepare the target analyte. The single stranded extension may be at least 100 bases in length, and may comprise a polyT or polyA polymers. The extension may be added to the double-stranded flap using a terminal transferase. The probes may be tagged with gold particles and may comprise polyA oligomers (in the case of a polyT extension), or polyT oligomers (in the case of a polyA extension). 
         [0016]    In each embodiment above, the biomolecule to be analyzed may be double-stranded DNA. The nicking endonucleases may be Nb.BbvCI, Nb.BsmI, NbBsrDI, Nb.BtsI, Nt.AlwI, Nt.BbvCI, Nt.BsmAI, Nt.BspQI, Nt.BstNBI, and Nt.CviPII, used either alone or in various combinations; however, any nicking endonuclease may be employed, either alone or in combination. Base extension reactions may be achieved by contacting a DNA strand with a polymerase, one or more nucleotides, a ligase, or any combination thereof. The binding moiety may be a protein. Examples of suitable proteins include RecA, T4 gene 32 protein, f1 geneV protein, human replication protein A, Pf3 single-stranded binding protein, adenovirus DNA binding protein, and  E. coli  single-stranded binding protein. 
         [0017]    Further embodiments of the invention relate to target analytes comprising double-stranded DNA fragments having one or more double-stranded DNA flaps, and target analytes comprising double-stranded DNA fragments having one or more single- or double-stranded DNA flaps that have been coated with a binding moiety. DNA fragments having one or more double-stranded flaps with single-stranded extensions are contemplated as well. The extensions may be hybridized with oligonucleotide probes, and the probes may include tags such as gold particles. 
         [0018]    The target analytes prepared by the methods of the present invention are configured for the detection of positional information in a nanopore system, as well as in a fluidic channel system employing nano-channels or micro-channels. As such, embodiments of the invention relate to monitoring changes in an electrical property across a nanopore or a fluidic channel as the target analytes made using the methods described above are translocated through the nanopore or fluidic channel. The monitored changes are indicative of double-stranded regions of the target analyte as well as flap regions. Further, embodiments of the invention relate to using the detected changes in the electrical property to differentiate between double-stranded and flap regions on the target analyte. The differentiation may be used to determine nick locations and thereby map at least a portion of the DNA template. 
         [0019]    Thus, in one embodiment, the present invention relates to the method of a) providing a double-stranded DNA template having first and second DNA strands, each strand having a 5′ end and a 3′ end, b) contacting the double-stranded DNA template with a nicking endonuclease to form a nick at a sequence-specific nicking location on the first DNA strand, c) conducting a base extension reaction on the first DNA strand along the corresponding region of the second DNA strand, the reaction starting at the nick and progressing toward the 3′ end of the first DNA strand to thereby form a single-stranded flap on the template adjacent to the nicking location, d) coating the double-stranded DNA template with a binding moiety that enhances electrical detection of the template and the single-stranded flap, to thereby prepare the target analyte, and e) monitoring changes in an electrical property as the target analyte is translocated through a nanopore or across a fluidic micro- or nano-channel, where the changes in the electrical property are indicative of double-stranded regions of the target analyte and of the single-stranded flap regions. The additional step of differentiating between the double-stranded template and single-stranded flap regions, based at least in part, on detected changes in the electrical property, to determine nick locations and map at least a portion of the double-stranded DNA template may be employed as well. 
         [0020]    In another embodiment, the present invention relates to the method of a) providing a double-stranded DNA template having first and second DNA strands, each strand having a 5′ end and a 3′ end, b) contacting the template with a nicking endonuclease to form nicks at sequence-specific locations on the first DNA strand, c) conducting a first base extension reaction on the first DNA strand along the corresponding region of the second DNA strand, the reaction starting at each nick and progressing toward the 3′ end of the first DNA strand to thereby form single-stranded flap regions on the double-stranded DNA template adjacent to the sequence specific nicking locations, d) conducting a second base extension reaction on at least one flap region to form at least one double-stranded flap, to thereby prepare the target analyte, and e) monitoring changes in an electrical property as the target analyte is translocated through a nanopore or across a fluidic micro- or nano-channel, where the changes in the electrical property are indicative of double-stranded regions of the target analyte and of the double-stranded flap regions. The additional step of differentiating between the double-stranded template and double-stranded flap regions, based at least in part, on detected changes in the electrical property, to determine nick locations and map at least a portion of the double-stranded DNA template may be employed as well. 
         [0021]    In still another embodiment, the method includes the steps of a) providing a double-stranded DNA template having a first and a second DNA strand, each DNA strand having a 5′ end and a 3′ end, b) contacting the double-stranded DNA template with a nicking endonuclease to form a nick at a sequence-specific nicking location on the first DNA strand, c) conducting a base extension reaction on the first DNA strand along a corresponding region of the second DNA strand, the reaction starting at the nick and progressing toward the 3′ end of the first DNA strand to thereby form a single-stranded flap on the double-stranded DNA template adjacent to the sequence-specific nicking location, d) coating the single-stranded flap with a binding moiety that selectively binds with single-stranded DNA to enhance electrical detection of the single-stranded flap, to thereby prepare the target analyte, and e) monitoring changes in an electrical property as the target analyte is translocated through a nanopore or across a fluidic micro- or nano-channel, where the changes in the electrical property are indicative of double-stranded regions of the target analyte and of the single-stranded flap regions. The additional step of differentiating between the double-stranded template and single-stranded flap regions, based at least in part, on detected changes in the electrical property, to determine nick locations and map at least a portion of the double-stranded DNA template may be employed as well. 
         [0022]    In another embodiment, the method includes the steps of a) providing a double-stranded DNA template having first and second DNA strands, each strand having a 5′ end and a 3′ end, b) contacting the template with a nicking endonuclease to form nicks at sequence-specific locations on the first DNA strand, c) conducting a first base extension reaction on the first DNA strand along the corresponding region of the second DNA strand, the reaction starting at each nick and progressing toward the 3′ end of the first DNA strand to thereby form single-stranded flap regions on the double-stranded DNA template adjacent to the sequence-specific nicking locations, d) conducting a second base extension reaction on at least one single-stranded flap region to form at least one double-stranded flap, e) adding a single-stranded extension to the double-stranded flap, and f) hybridizing one or more probes to the single-stranded extension, to thereby prepare the target analyte. Changes in an electrical property may be monitored as the target analyte is translocated through a nanopore or across a fluidic micro- or nano-channel, where the changes in the electrical property are indicative of double-stranded regions of the target analyte and of the extended flap regions. The additional step of differentiating between the double-stranded template and extended flap regions, based at least in part, on detected changes in the electrical property, to determine nick locations and map at least a portion of the double-stranded DNA template may be employed as well. 
         [0023]    In another embodiment, the method includes the steps of a) providing a double-stranded DNA template having first and second DNA strands, each strand having a 5′ end and a 3′ end, b) contacting the double-stranded DNA template with a nicking endonuclease to form a nick at a sequence-specific nicking location on the first DNA strand, c) conducting a base extension reaction on the first DNA strand along the corresponding region of the second DNA strand, the reaction starting at the nick and progressing toward the 3′ end of the first DNA strand to thereby form a single-stranded flap on the template adjacent to the nicking location, and d) monitoring changes in an electrical property as the target analyte is translocated through a nanopore or across a fluidic micro- or nano-channel, where the changes in the electrical property are indicative of double-stranded regions of the target analyte and of the single-stranded flap regions. The additional step of differentiating between the double-stranded template and single-stranded flap regions, based at least in part, on detected changes in the electrical property, to determine nick locations and map at least a portion of the double-stranded DNA template may be employed as well. 
         [0024]    As before, in each embodiment above, the biomolecule to be analyzed may be double-stranded DNA. The nicking endonucleases may be Nb.BbvCI, Nb.BsmI, NbBsrDI, Nb.BtsI, Nt.AlwI, Nt.BbvCI, Nt.BsmAI, Nt.BspQI, Nt.BstNBI, and Nt.CviPII, used either alone or in various combinations; however, any nicking endonuclease may be employed, either alone or in combination. Base extension reactions may be achieved by contacting a DNA strand with a polymerase, one or more nucleotides, a ligase, or any combination thereof. If used, the binding moiety may be a protein. Examples of suitable proteins include RecA, T4 gene 32 protein, f1 geneV protein, human replication protein A, Pf3 single-stranded binding protein, adenovirus DNA binding protein, and  E. coli  single-stranded binding protein. 
         [0025]    In cases where a single-stranded extension is formed on a double-stranded flap region, the single stranded extension may be at least 100 bases in length, and may comprise a polyT or polyA polymers. The extension may be added to the double-stranded flap using a terminal transferase. The probes may be tagged, for example, with gold particles and may comprise polyA oligomers (in the case of a polyT extension), or polyT oligomers (in the case of a polyA extension). 
     
    
     
       BRIEF DESCRIPTION OF THE FIGURES 
         [0026]      FIG. 1  is a schematic depiction of a DNA molecule (SEQ ID NOS 5-6, respectively, in order of appearance). 
           [0027]      FIG. 2   a  is a schematic depiction of a DNA molecule (SEQ ID NOS 5-6, respectively, in order of appearance) showing the recognition and nicking site for the nicking endonuclease Nt.BbvCI. 
           [0028]      FIG. 2   b  is a schematic depiction of a DNA molecule (bottom strand is disclosed as SEQ ID NO: 6) subsequent to reaction with the nicking endonuclease Nt.BbvCI. 
           [0029]      FIG. 3  is a schematic depiction of a nicked DNA molecule (SEQ ID NOS 7 and 6, respectively, in order of appearance) subsequent to a base extension reaction beginning at the nicking site. 
           [0030]      FIG. 4   a  is a schematic depiction of the DNA molecule of  FIG. 3  subsequent to contact of the molecule with a binding moiety that binds to single- and double-stranded DNA. 
           [0031]      FIG. 4   b  is a schematic depiction of the DNA molecule of  FIG. 3  subsequent to contact of the molecule with a binding moiety that preferentially binds to single-stranded DNA. 
           [0032]      FIG. 5   a  is a schematic depiction of a DNA molecule showing a recognition and nicking site for a nicking endonuclease. 
           [0033]      FIG. 5   b  is a schematic depiction of a DNA molecule subsequent to reaction with a nicking endonuclease. 
           [0034]      FIG. 5   c  is a schematic depiction of a nicked DNA molecule subsequent to a first base extension reaction to form a flap. 
           [0035]      FIG. 5   d  is a schematic depiction of a DNA molecule subsequent to hybridization of an oligonucleotide probe to the flap. 
           [0036]      FIG. 5   e  is a schematic depiction of a DNA molecule subsequent to a second base extension reaction to form a double-stranded flap. 
           [0037]      FIG. 5   f  is a schematic depiction of a DNA molecule having a double-stranded flap. 
           [0038]      FIG. 6  is a schematic depiction of the DNA molecule of  FIG. 5   f  subsequent to contact of the molecule with a binding moiety. 
           [0039]      FIG. 7   a  is a schematic depiction of a DNA molecule having a plurality of closely-spaced recognition and nicking sites subsequent to reaction with a nicking endonuclease. 
           [0040]      FIG. 7   b  is a schematic depiction of the DNA molecule of  FIG. 7   a  subsequent to a first base extension reaction to form a plurality of flaps. 
           [0041]      FIG. 7   c  is a schematic depiction a portion of the DNA molecule of  FIG. 7   b  depicting an isolation of a single flap. 
           [0042]      FIG. 7   d  is a schematic depiction of the portion of the DNA molecule of  FIG. 7   c  subsequent to hybridization of the flap with a probe and use of a base extension reaction to convert the flap into double-stranded DNA. 
           [0043]      FIG. 7   e  is a schematic depiction of the portion of the DNA molecule (SEQ ID NO: 8) of  FIG. 7   d  subsequent to the addition of a single-stranded extension to the flap. 
           [0044]      FIG. 7   f  is a schematic depiction of the portion of the DNA molecule (SEQ ID NO: 8) of  FIG. 7   e  subsequent to hybridization of the extension with complementary oligonucleotide probes. 
           [0045]      FIG. 7   g  is a schematic depiction of the portion of the DNA molecule (SEQ ID NO: 8) of  FIG. 7   e  subsequent to hybridization of the extension with tagged complementary oligonucleotide probes. 
           [0046]      FIG. 8   a  is a schematic depiction of a DNA molecule having a flap in a nanopore apparatus. 
           [0047]      FIG. 8   b  is a schematic depiction of a current measurement waveform as a DNA molecule having a flap translocates through the nanopore apparatus of  FIG. 8   a.    
           [0048]      FIG. 9  is a schematic depiction of a fluidic channel apparatus useful for mapping the analytes of the present invention, in which the fluidic channel may be a nano-channel or a micro-channel. 
           [0049]      FIG. 10   a  is a schematic depiction of an electrical potential measurement as a DNA molecule having a flap enters a detection volume in the apparatus of  FIG. 9 . 
           [0050]      FIG. 10   b  is a schematic depiction of an electrical potential measurement as a flap on a DNA molecule enters a detection volume in the apparatus of  FIG. 9 . 
           [0051]      FIG. 10   c  is a schematic depiction of an electrical potential measurement as a flap on a DNA molecule exits a detection volume in the apparatus of  FIG. 9 . 
           [0052]      FIG. 10   d  is a schematic depiction of an electrical potential measurement as a DNA molecule having a flap exits a detection volume in the apparatus of  FIG. 9 . 
           [0053]      FIG. 11  is a schematic depiction of a nano-channel or micro-channel apparatus having multiple detection volumes. 
       
    
    
     DETAILED DESCRIPTION 
       [0054]    As used in this description and the accompanying claims, the following terms shall have the meanings given, unless the context indicates otherwise: 
         [0055]    An “analyte” or “target” means a double-stranded DNA biomolecule. 
         [0056]    A “DNA template” means a DNA molecule that serves as a pattern for the synthesis of an additional molecular structure. 
         [0057]    A “binding moiety” means an entity, such as a protein, capable of providing a coating on an analyte. 
         [0058]    An “endonuclease” is an enzyme that cleaves the phosphodiester bond within a polynucleotide chain, in contrast with an exonuclease, which cleaves phosphodiester bonds at the end of a polynucleotide chain. 
         [0059]    A “restriction endonuclease” or “restriction enzyme” cleaves DNA at specific sites. 
         [0060]    A “nicking endonuclease” or “nickase” is a form of restriction endonuclease. Restriction endonucleases recognize specific nucleotide sequences in double-stranded DNA and generally cleave both strands. Some sequence-specific endonucleases, however, cleave only one of the strands. These endonucleases are known as nicking endonucleases. 
         [0061]    The translocation of biomolecules and biomolecule/protein complexes through a nanopore, a nano-channel or a micro-channel sequencing system may include detecting an electrical signal indicative of the passage of the biomolecule through the system, as well as an electrical signal indicative of the passage of single- or double-stranded flaps formed on the biomolecule through the system. The biomolecule and/or the flaps may be coated with a binding moiety such as a protein. The time for translocation may be indicative of the length of the biomolecule. The detection step may discriminate between coated, uncoated, or multiply coated regions, as a coated region may have a signal about ten times that of an uncoated region. Increasing the signal-to-noise ratio may increase confidence in the detection of flaps formed on the biomolecule. Positional information of flaps on the target biomolecule may be used to identify nicking sites, and thereby facilitates the mapping of the biomolecule. 
         [0062]    Referring to  FIG. 1 , a DNA molecule  10 , e.g., a double-stranded DNA template, is schematically depicted. The molecule  10  comprises two DNA strands, e.g., first and second strands  12 ,  14  positioned in anti-parallel relation to one another. The two DNA strands may also be referred to as top and bottom strands  12 ,  14 . Each of the two opposing strands  12 ,  14  may be sequentially formed from repeating groups of nucleotides  16  where each nucleotide  16  consists of a phosphate group, 2-deoxyribose sugar and one of four nitrogen-containing bases. The nitrogen-containing bases include cytosine (C), adenine (A), guanine (G) and thymine (T). Each DNA strand has a 5′ end and a 3′ end. In particular, the DNA strands  12 ,  14  are read in a particular direction, from the top (called the 5′ or “five prime” end) to the bottom (called the 3′ or “three prime” end). Similarly, RNA molecules are polynucleotide chains, which differ from those of DNA by having ribose sugar instead of deoxyribose and uracil bases (U) instead of thymine bases (T). 
         [0063]    The bases in the molecules do not share an equal affinity for one another. Thymine (T) bases favor binding with adenine (A) bases, while cytosine (C) bases favor binding with guanine (G) bases. Binding is mediated via hydrogen bonds that exist between the opposing base pairs. For example, base A binds to base T using two hydrogen bonds, while base C binds to base G using three hydrogen bonds. 
         [0064]    Nicking endonucleases useful in embodiments of the present invention include Nb.BbvCI, Nb.BsmI, NbBsrDI, Nb.BtsI, Nt.AlwI, Nt.BbvCI, Nt.BsmAI, Nt.BspQI, Nt.BstNBI, and Nt.CviPII, used either alone or in various combinations. As noted above, nickases are sequence-specific endonucleases which are characterized in that they cleave only one strand of double-stranded DNA at the recognition site. 
         [0065]    The nickase Nb.BbvCI is derived from an  E. coli  strain expressing an altered form of the BbvCI restriction genes [Ra+:Rb(E177G)] from  Bacillus brevis . It nicks at the following recognition site (with “{hacek over ( )}” specifying the nicking site and “N” representing any one of C, A, G or T): 
         [0000]    
       
         
               
               
             
           
               
                   
                 5′ . . . C C T C A G C . . . 3′ 
               
               
                   
                   
               
               
                   
                 3′ . . . G G A G T{hacek over ( )}C G . . . 5′ 
               
             
          
         
       
     
         [0066]    The nickase Nb.BsmI is derived from an  E. coli  strain that carries the cloned BsmI gene from  Bacillus stearothermophilus  NUB 36. It nicks at the following recognition site: 
         [0000]    
       
         
               
               
             
           
               
                   
                 5′ . . . G A A T G C N . . . 3′ 
               
               
                   
                   
               
               
                   
                 3′ . . . C T T A C{hacek over ( )}G N . . . 5′ 
               
             
          
         
       
     
         [0067]    The nickase Nb.BsrDI is derived from an  E. coli  strain expressing only the large subunit of the BsrDI restriction gene from  Bacillus stearothermophilus  D70. It nicks at the following recognition site: 
         [0000]    
       
         
               
               
             
           
               
                   
                 5′ . . . G C A A T G N N . . . 3′ 
               
               
                   
                   
               
               
                   
                 3′ . . . C G T T A C{hacek over ( )}N N . . . 5′ 
               
             
          
         
       
     
         [0068]    The nickase Nb.BtsI is derived from an  E. coli  strain expressing only the large subunit of the BtsI restriction gene from  Bacillus thermoglucosidasius . It nicks at the following recognition site: 
         [0000]    
       
         
               
               
             
           
               
                   
                 5′ . . . G C A G T G N N . . . 3′ 
               
               
                   
                   
               
               
                   
                 3′ . . . C G T C A C{hacek over ( )}N N . . . 5′ 
               
             
          
         
       
     
         [0069]    The nickase Nt.AlwI is an engineered derivative of AlwI which catalyzes a single-strand break four bases beyond the 3′ end of the recognition sequence on the top strand. It is derived from an  E. coli  strain containing a chimeric gene encoding the DNA recognition domain of AlwI and the cleavage/dimerization domain of Nt.BstNBI. It nicks at the following recognition site: 
         [0000]    
       
         
               
               
             
           
               
                   
                 (SEQ ID NO: 1) 
               
               
                   
                 5′ . . . G G A T C N N N N{hacek over ( )}N . . . 3′ 
               
               
                   
                   
               
               
                   
                 (SEQ ID NO: 2) 
               
               
                   
                 3′ . . . C C T A G N N N N N . . . 5′ 
               
             
          
         
       
     
         [0070]    The nickase Nt.BbvCI is derived from an  E. coli  strain expressing an altered form of the BbvCI restriction genes [Ra(K169E):Rb+] from  Bacillus brevis . It nicks at the following recognition site: 
         [0000]    
       
         
               
               
             
           
               
                   
                 5′ . . . C C{hacek over ( )}T C A G C . . . 3′ 
               
               
                   
                   
               
               
                   
                 3′ . . . G G A G T C G . . . 5′ 
               
             
          
         
       
     
         [0071]    The nickase Nt.BsmAI is derived from an  E. coli  strain expressing an altered form of the BsmAI restriction genes from  Bacillus stearothermophilus  A664. It nicks at the following recognition site: 
         [0000]    
       
         
               
               
             
           
               
                   
                 5′ . . . G T C T C N{hacek over ( )}N . . . 3′ 
               
               
                   
                   
               
               
                   
                 3′ . . . C A G A G N N . . . 5′ 
               
             
          
         
       
     
         [0072]    The nickase Nt.BspQI is derived from an  E. coli  strain expressing an engineered BspQI variant from BspQI restriction enzyme. It nicks at the following recognition site: 
         [0000]    
       
         
               
               
             
           
               
                   
                 5′ . . . G C T C T T C N{hacek over ( )} . . . 3′ 
               
               
                   
                   
               
               
                   
                 3′ . . . C G A G A A G N . . . 5′ 
               
             
          
         
       
     
         [0073]    The nickase Nt.BstNBI catalyzes a single strand break four bases beyond the 3′ side of the recognition sequence. It is derived from an  E. coli  strain that carries the cloned Nt.BstNBI gene from  Bacillus stereothermophilus  33M. It nicks at the following recognition site: 
         [0000]    
       
         
               
               
             
           
               
                   
                 (SEQ ID NO: 3) 
               
               
                   
                 5′ . . . G A G T C N N N N{hacek over ( )}N . . . 3′ 
               
               
                   
                   
               
               
                   
                 (SEQ ID NO: 4) 
               
               
                   
                 3′ . . . C T C A G N N N N N . . . 5′ 
               
             
          
         
       
     
         [0074]    The nickase Nt.CviPII cleaves one strand of DNA of a double-stranded DNA substrate. The final product on pUC19 (a plasmid cloning vector) is an array of bands from 25 to 200 base pairs. CCT is cut less efficiently than CCG and CCA, and some of the CCT sites remain uncleaved. It is derived from an  E. coli  strain that expresses a fusion of Mxe GyrA intein, chitin-binding domain and a truncated form of the Nt.CviPII nicking endonuclease gene from Chlorella virus NYs-1. It nicks at the following recognition site: 
         [0000]    
       
         
               
               
             
           
               
                   
                 5′ . . . {hacek over ( )}C C D . . . 3′ 
               
               
                   
                   
               
               
                   
                 3′ . . . G G H . . . 5′ 
               
             
          
         
       
     
         [0075]    Each of the restriction endonucleases described above is available from New England Biolabs of Ipswich, Mass. 
         [0076]    It should be understood that the invention is not intended to be limited to the nicking endonucleases described above; rather, it is anticipated that any endonuclease capable of providing a nick in a double-stranded DNA molecule may be used in accordance with the methods of the present invention. 
         [0077]    One embodiment of the present invention is depicted in  FIGS. 2   a - 4   a  or  4   b . In  FIG. 2   a , the DNA molecule  10  of  FIG. 1  is shown. The recognition sequence of the nicking endonuclease Nt.BbvCI is indicated by the boxed area  18 , and the specific nicking site  20  of that nicking endonuclease is identified. The double-stranded DNA template is contacted with the nicking endonuclease. In  FIG. 2   b , the nicking endonuclease Nt.BbvCI has cleaved the top strand of the DNA molecule leaving a nick  20 ′ at a sequence-specific nicking location on the top DNA strand  12 . 
         [0078]    As shown in  FIG. 3 , a base extension reaction  22 , such as a primer extension reaction, utilizing for example, a polymerase, one or more nucleotides, a ligase, or any combination thereof is carried out beginning at the nick site (indicated by a dot). The base extension reaction is conducted on the top DNA strand along (and pursuant to) the corresponding region of the bottom DNA strand. In such reactions, that form a nucleic acid complementary to a nucleic acid template, a primer complementary to a single-stranded DNA template is typically employed. Starting at the primer, a DNA polymerase may be used to add mononucleotides complementary to the template at the 3′ end of the primer. Various base extension reactions will be familiar to those of ordinary skill in the art. As the base extension reaction progresses toward the 3′ end of the top strand, a flap  24  of single-stranded DNA is formed from the original top strand of the DNA molecule. The flap  24  is single-stranded, and is adjacent to the sequence-specific nicking location. The base extension reaction is allowed to proceed until the flap  24  has reached a desired length, resulting in the formation of a target analyte including the double-stranded DNA molecule and a flap. the presence of the flap aids in the detection via, for example, HANS, or other nanopore-, nanochannel-, or microchannel-based detection techniques. In one embodiment, it is preferred that the flap  24  be at least one hundred (100) bases in length, however, the invention is not intended to be limited as such. 
         [0079]    Finally, as shown in  FIGS. 4   a  and  4   b , a binding moiety may be used to coat the DNA molecule or portions thereof. In  FIG. 4   a , the binding moiety  30  has been used to coat both strands  12 ,  14  of the DNA molecule as well as the single-stranded flap  24 . Alternatively, as shown in  FIG. 4   b , a binding moiety  30 ′ having a preference for single-stranded DNA has been used to coat only the single-stranded flap formed on the DNA molecule via the method described above. 
         [0080]    The binding moiety  30  may include or consist essentially of a protein or other composition which binds to single- and/or double-stranded DNA. In one embodiment, the binding moiety is the protein RecA. The binding moiety may enhance electrical detection of the double-stranded DNA template and flap via, for example, HANS, or other nanopore-, nanochannel-, or microchannel-based detection techniques. 
         [0081]    Protein RecA from  E. coli  typically binds single- or double-stranded DNA in a cooperative fashion to form filaments containing the DNA in a core and an external sheath of protein (McEntee, K.; Weinstock, G. M.; Lehman, I. R. Binding of the RecA Protein of  Escherichia coli  to Single- and Double-Stranded DNA.  J. Biol. Chem.  1981, 256, 8835, incorporated by reference herein in its entirety). DNA has a diameter of about 2 nm, while DNA coated with RecA has a diameter of about 10 nm. The persistence length of the DNA increases to around 950 nm, in contrast to 0.75 nm for single-stranded DNA or 50 nm for double-stranded DNA. T4 gene 32 protein is known to cooperatively bind single-stranded DNA (Alberts, B. M.; Frey, L. T4 Bacteriophage Gene32: A Structural Protein in the Replication and Recombination of DNA.  Nature,  1970, 227, 1313-1318, incorporated by reference herein in its entirety).  E. coli  single-stranded binding protein binds single-stranded DNA in several forms depending on salt and magnesium concentrations (Lohman, T. M.; Ferrari, M. E.  Escherichia Coli  Single-Stranded DNA-Binding Protein: Multiple DNA-Binding Modes and Cooperativities.  Ann. Rev. Biochem.  1994, 63, 527-570, incorporated by reference herein in its entirety). The  E. coli  single-stranded binding protein may form a varied coating on the biomolecule. The f1 geneV protein is known to coat single-stranded DNA (Terwilliger, T. C. Gene V Protein Dimerization and Cooperativity of Binding of poly(dA).  Biochemistry  1996, 35, 16652, incorporated by reference herein in its entirety), as is human replication protein A (Kim, C.; Snyder, R. O.; Wold, M. S. Binding properties of replication protein A from human and yeast cells.  Mol. Cell Biol.  1992, 12, 3050, incorporated by reference herein in its entirety), Pf3 single-stranded binding protein (Powell, M. D.; Gray, D. M. Characterization of the Pf3 single-strand DNA binding protein by circular dichroism spectroscopy.  Biochemistry  1993, 32, 12538, incorporated by reference herein in its entirety), and adenovirus DNA binding protein (Tucker, P. A.; Tsernoglou, D.; Tucker, A. D.; Coenjaerts, F. E. J.; Leenders, H.; Vliet, P. C. Crystal structure of the adenovirus DNA binding protein reveals a hook-on model for cooperative DNA binding.  EMBO J.  1994, 13, 2994, incorporated by reference herein in its entirety). The protein-coated DNA may then be translocated through a nanopore as has been demonstrated with RecA bound to double-stranded DNA (Smeets, R. M. M.; Kowalczyk, S. W.; Hall, A. R.; Dekker, N. H.; Dekker, C. Translocation of RecA-Coated Double-Stranded DNA through Solid-State Nanopores. Nano Lett. 2009, incorporated by reference herein in its entirety). The protein coating functions in the same manner for single-stranded DNA regions and double-stranded DNA regions. 
         [0082]    In another embodiment of the present invention, the flap formed by the base extension reaction illustrated in  FIG. 3  may be converted from a single-stranded flap to a double-stranded flap. In this embodiment, prior to contacting the target analyte with the binding moiety, the single-stranded flap is exposed to a random selection of oligomer probes with the expectation that at least one will hybridize with a portion of the flap and act as a primer. Following such hybridization, a base extension reaction is carried out to cause the flap to become double-stranded. 
         [0083]    More specifically, a double-stranded DNA molecule  10  having first and second DNA strands  12 ,  14  is shown in  FIG. 5   a . The DNA molecule  10  has a recognition sequence that identifies a nicking site  20  for a preselected nicking endonuclease. As shown in  FIG. 5   b , upon exposure to the nicking endonuclease, a nick  20 ′ is formed on the DNA molecule  10 , i.e., on sequence-specific location on the first DNA strand. By using a predetermined nicking endonuclease with a known recognition sequence, if the site of the nick can be identified, the location of specific recognition sequence can be determined, thereby allowing the molecule to be mapped. 
         [0084]    Following nick  20 ′ formation, a first base extension reaction  22 , beginning at the nick site, (indicated by a dot), is carried out.  FIG. 5   c  shows that as the base extension reaction proceeds toward the 3′ end of the top strand, a flap  24  of single-stranded DNA is formed from the original top strand of the DNA molecule. The base extension reaction is allowed to proceed until the flap  24  has reached a desired length. In one embodiment, it is preferred that the flap  24  be at least one hundred (100) bases in length, however as discussed with respect to  FIG. 3 , the invention is not intended to be limited as such. 
         [0085]    In  FIG. 5   d , the flap  24  is exposed to a random selection of oligonucleotide probes. The identity of the probes need not be known; rather, it is the expectation that at least one such probe  32  will hybridize to a portion of the flap  24  to act as a primer forming a site at which a second base extension  34  may be carried out as shown in  FIG. 5   e . The second base extension can be performed by contacting the flap with a polymerase, one or more nucleotides, a ligase, or any combination thereof. The resulting target analyte  50  comprising a double-stranded DNA base  10  with a double-stranded flap  24 ′ is depicted in  FIG. 5   f.    
         [0086]    In  FIG. 6 , a binding moiety  30  has been used to coat both strands  12 ,  14  of the DNA molecule as well as the double-stranded flap  24 ′. As in the previous embodiments, the binding moiety  30  may be a protein or other composition which binds to single- and double-stranded DNA, such as the protein RecA, T4 gene 32 protein, f1 geneV protein, human replication protein A, Pf3 single-stranded binding protein, adenovirus DNA binding protein, and  E. coli  single-stranded binding protein. The binding moiety enhances electrical detection of the target analyte. 
         [0087]    In some instances, the recognition and nicking sites may be spaced relatively closely together. In these instances, use of the methods described above may result in small, less readily detectable flaps. Since the flap is formed by the single strand between nicks, if the nicks are closely spaced, flap length is limited. Furthermore, in these instances, if the base extension which results in the flap is allowed to proceed too far, the single strand will be excised entirely from the analyte, resulting in the loss of the flap and thereby the data it provides. A solution to this problem is depicted in  FIGS. 7   a - 7   g.    
         [0088]      FIG. 7   a  depicts a DNA molecule  10  having first  12  and second  14  strands. Strand  12  has been reacted with a nicking endonuclease which created closely-spaced nicks  20 ′. A short segment of single-stranded DNA  12 ′, which will form one flap, is positioned between the nicks. 
         [0089]    In  FIG. 7   b , a base extension reaction has been carried out to form flaps  24  at each of the nicks. Due to the close spacing between the nicks, the base extension reaction is preferably terminated before segment  12 ′ is excised entirely from the molecule. As a result, a short flap, which is harder to detect, is formed. Furthermore, since the base extension is not isolated to the single short flap of segment  12 ′, but rather, applies to the entire molecule, the early termination of the base extension results in all flaps being small and less readily detectable. The boxed area  19  is used to indicate the portion of the molecule containing one flap that is depicted in  FIGS. 7   c - 7   g.    
         [0090]      FIG. 7   c  depicts a single short flap  24  (isolation from box  19 ) following termination of the base extension. 
         [0091]    In  FIG. 7   d , a double-stranded flap  24 ′ is depicted. This double-stranded flap has been formed using the method shown in  FIG. 5   e . Specifically, the single-stranded flap has been exposed to a random selection of oligonucleotide probes, and one such probe hybridized to the flap and acted as a primer, allowing a second base extension to be carried out. The result is formation of a short, double-stranded flap  24 ′. 
         [0092]      FIG. 7   e  depicts the molecule of  FIG. 7   d  following an extension of the flap. Specifically, following the base extension reaction which formed the double-stranded probe, the molecule is reacted with a terminal transferase to allow extension of the double-stranded flap. The extension  40  occurs on the strand having an exposed 3′ end. While any sequence could be extended from the flap  24 ′, it a preferable to form the extension as a polymer of a single base, with polyA and polyT extensions preferred. In the embodiment of  FIG. 7   e , a polyT extension is shown, however, the invention is not intended to be limited as such. Regardless of the specific sequence of the extension, it may be any length desirable for detection, with lengths of several hundred bases preferred. 
         [0093]    As a result of the extensions formed on the flaps, detection of the flaps using the methods described below is enhanced as compared to short flaps lacking such extensions. Further enhancements to flap and molecule detection are envisioned as well. For example, the molecule may be reacted with a binding moiety using the methods outlined in  FIGS. 4   a  and  4   b . Alternatively, tagged probes may be hybridized to the extensions. Thus, as shown in  FIG. 7   f , oligonucleotide probes having specificity to the sequence of the extension may be employed. In  FIG. 7   f , the polyT extension  40  is hybridized with complementary polyA oligonucleotide probes  42 . As shown in  FIG. 7   g , these probes  42  may be provided with tags  44  connected to the probes  42  by a linker  46 . While any of a wide variety of tags may be employed, in one preferred embodiment, the tags  44  comprise gold beads. It is intended that the tags will enhance detection of the flaps formed at each of the original nicking sites. Regardless of the enhancement method used, the principle is the same; i.e., detection of the flaps allows determination of the relative position of the original nicking sites. Since the particular nicking endonuclease used to form the nicks is known, determination of the identity and relative location of the nicking sites is enabled. 
         [0094]    The target analytes described herein may be configured for detection of positional information in a nanopore and/or a fluidic channel, i.e., a micro-channel or nano-channel system. Mapping of target analytes may be carried out using electrical detection methods employing nanopores, nano-channels or micro-channels using the methods described in U.S. patent application Ser. No. 12/789,817, filed May 28, 2010, the teachings of which have previously been incorporated herein by reference. It is contemplated that such methods may be applied to uncoated analytes having single- or double-stranded flaps, or to analytes having single- or double-stranded flaps where one or both of the base molecule and the single- or double-stranded flap is coated with a binding moiety. 
         [0095]    In one embodiment, current across a nanopore is measured during translocation of a DNA strand through the nanopore as shown in  FIG. 8   a . When used in embodiments of the present invention, a nanopore may have a diameter selected from a range of about 1 nm to about 1 μm. More preferably the nanopore has a diameter that is between about 2.3 nm and about 100 nm. Even more preferably the nanopore has a diameter that is between about 2.3 nm and about 50 nm. Changes in an electrical property across a nanopore may be monitored as the target analyte is translocated therethrough, with changes in the electrical property being indicative of double-stranded regions of the target analyte and of the single-stranded or double-stranded flap regions. 
         [0096]    Specifically, for nanopore  100 , a measurable current produced by electrodes  120 ,  122  runs parallel  110  to the movement of the target analyte  50 , i.e., a DNA molecule having a flap  24 . Variations in current are a result of the relative diameter of the target analyte  50  as it passes through the nanopore  100 . This relative increase in volume of the target analyte  50  passing through the nanopore  100  causes a temporary interruption or decrease in the current flow through the nanopore, resulting in a measurable current variation. Portions of the target analyte  50  including a flap  24  are larger in diameter than portions of the target analyte that do not include a flap. As a result, when the flap  24  passes through the nanopore  100 , further interruptions or decreases in the current flow between electrodes  120 ,  122  occurs. These changes in current flow are depicted in the waveform  200  in  FIG. 8   b.    
         [0097]    Analysis of the waveform  200  permits differentiation between double-stranded and flap regions of the target analyte based, at least in part, on the detected changes in the electrical property, to thereby determine nick locations and map at least a portion of the double-stranded DNA template. In  FIG. 8   b , the waveform  200  depicts the changes in a detected electrical property as the target analyte passes through the nanopore, and may be interpreted as follows. Current measurement  210  represents measured current prior to passage of the DNA molecule  10  having a flap formed thereon, i.e., the target analyte, through the nanopore  100  from the cis side to the trans side. As the target analyte enters the nanopore  100 , from the cis side of the nanopore, the current is partially interrupted forming a first trough  220  in the recorded current. Once the flap  24  of the target analyte enters the nanopore  100 , a further decrease in current occurs, causing a deeper, second trough  230  in the current measurement. Upon passage of the flap  24  entirely through the nanopore  100 , a distal portion of the target analyte may remain in the nanopore. This causes the measured current  240  to rise to approximately the level of the first trough  220 . Finally, once the entire target analyte has passed completely through the nanopore  100  to the trans side, the measured current  250  returns to a level approximating that of the initial level  210 . The current variation measurements are recorded as a function of time. As a result, the periodic variations in current indicate where, as a function of relative or absolute position, the flaps  24  are formed on the target analyte  10 . Since the flaps are formed at recognition sites for the specific nicking endonucleases used in flap formation, the relative or absolute position of the specific sequences associated with the recognition site for the particular nicking endonuclease employed may be determined. This allows mapping of those specific sequences on the target analyte. Multiple maps produced using multiple nicking endonucleases may be generated. 
         [0098]    The use of a binding moiety, such as the protein RecA, may further enhance detection of target analytes and flap regions on target analytes because the added bulk of the binding moiety coating causes greater current deflections. 
         [0099]    In another embodiment, an electrical property such as electrical potential or current is measured during translocation of a DNA strand through a nano-channel or micro-channel as shown in  FIGS. 9 through 11 . One embodiment of a fluidic channel apparatus is shown schematically in  FIG. 9 . In  FIG. 9 , the apparatus  300  comprises a fluidic micro-channel or nano-channel  302 . The fluidic channel may be a micro-channel having a width selected from a range of about 1 μm to about 25 μm or a nano-channel having a width selected from a range of about 10 nm to about 1 μm. In the case of a micro-channel, the depth may be selected from a range of about 200 nm to about 5 μm, whereas in the case of a nano-channel, the depth may be selected from a range of about 10 nm to about 1 μm. In either case, the channel may have a length selected from a range of about 1 μm to about 10 cm. 
         [0100]    A first pair of electromotive electrodes  304 ,  304 ′ is connected to a voltage source  306  and positioned in a spaced apart relationship in the channel. When a potential is applied to the electromotive electrodes, these electrodes provide an electrical current along the channel and may be used to provide or enhance a driving force  308  to a target analyte  50  in the channel. Other driving forces such as pressure or chemical gradients are contemplated as well. A second pair of electrodes  312 ,  312 ′, i.e., detector electrodes, is positioned preferably substantially perpendicular to the channel in a spaced apart relationship to define a detection volume  314 . The second pair of detector electrodes  312 ,  312 ′ is connected to a detector  316 , such as a voltmeter, which monitors an electrical property in the detection volume  314 . In an embodiment where the detector  316  is a voltmeter, an electrical potential between the pair of detector electrodes  312 ,  312 ′, is measured across the detection volume  314 . 
         [0101]    The operation of the device is depicted schematically in  FIGS. 10   a - 10   d  in which changes in an electrical property across a fluidic channel are monitored, as the target analyte is translocated therethrough, with the changes in the electrical property being indicative of double-stranded regions of the target analyte and of the flap regions. In  FIGS. 10   a - 10   d , the first pair of electromotive electrodes  304 ,  304 ′ and the current source  306  have been omitted for clarity. In  FIG. 10   a , the fluidic channel  302  contains a target analyte  50  traveling therethrough. An electrical property, in this case electrical potential, is measured and recorded across the detection volume  314  by the detector electrodes  312 ,  312 ′ and the detector  316 . The target analyte  50  is a DNA fragment upon which has been formed a flap  24  using the methods described previously. The DNA fragment and/or the flap may be coated with a binding moiety, such as the protein RecA, to enhance detection. 
         [0102]    Prior to the entry of the target analyte  50  into the detection volume  314 , a substantially constant voltage  322  is measured across the detection volume. This voltage is shown in the waveform  320  of  FIG. 10   a . As the target analyte  50  enters the detection volume  314 , it causes an interruption or decrease in the electrical property measured in the detection volume. This interruption or decrease causes a first trough  324  to be exhibited in the waveform  320 . 
         [0103]      FIG. 10   b  shows the device and waveform  320  once the portion of the target analyte  50  including the flap  24  has entered the detection volume  314 . Entry of the flap  24  into the detection volume  314  causes a further interruption or decrease in the electrical property measured in the detection volume. This further interruption or decrease causes a second trough  326  to be exhibited in the waveform  320 . 
         [0104]    In  FIG. 10   c , the portion of the target analyte  50  containing the flap  24  has exited the detection volume  314 ; however, a distal portion of the target analyte  50  may still be present in the detection volume. As a result, the waveform  320  has returned to a level  328  approximating that detected when the initial portion of the analyte first entered the detection volume. 
         [0105]    Finally, as shown in  FIG. 10   d , the target analyte  50  has fully exited the detection volume  314 . As a result, the waveform  320  has returned to a level  330  approximating that detected prior to initial entry of the analyte into the detection volume. Analysis of the waveform  320  permits differentiation between double-stranded DNA and flap regions of the target analyte based, at least in part, on the detected changes in the electrical property, to thereby determine nick locations and map at least a portion of the double-stranded DNA template. 
         [0106]    Another embodiment of a fluidic channel apparatus is shown in  FIG. 11 . In  FIG. 11 , the apparatus  400  comprises a fluidic micro-channel or nano-channel  402 . As before, the fluidic channel may be a micro-channel having a width selected from a range of about 1 μm to about 25 μm or a nano-channel having a width selected from a range of about 10 nm to about 1 μm. In the case of a micro-channel, the depth may be selected from a range of about 200 nm to about 5 μm, whereas in the case of a nano-channel, the depth may be selected from a range of about 10 nm to about 1 μm. In either case, the channel may have a length selected from a range of about 1 μm to about 10 cm. 
         [0107]    A first pair of electromotive electrodes  304 ,  304 ′ is connected to a voltage source  306  and positioned in a spaced apart relationship in the channel. When a potential is applied to the electromotive electrodes, these electrodes provide an electrical current along the channel and may be used to provide or enhance a driving force  408  to an analyte  410  in the channel. Other driving forces such as pressure or chemical gradients are contemplated as well. Multiple detector electrodes  412 ,  414 ,  416 ,  418 , are positioned preferably perpendicular to the channel in a spaced apart relationship to define a plurality of detection volumes between adjacent detector electrodes. Thus, as seen in  FIG. 11 , detector electrodes  412  and  414  define detection volume  420 , detector electrodes  414  and  416  define detection volume  422 , and detector electrodes  416  and  418  define detection volume  424 . The detector electrodes are each connected to detectors  426 ,  428 ,  430  such as voltmeters, which monitor an electrical property in each detection volume. In the embodiment where the detectors are voltmeters, a drop in electrical potential is measured across each detection volume. Operation of the apparatus is similar to that of the system of  FIG. 10 , with the exception that additional waveforms are generated due to the presence of additional detection volumes. The additional waveforms may be combined to further improve the quality of the data being generated by the device. 
         [0108]    It should be understood that number of detector electrodes and detection volumes is not intended to limited to those depicted in  FIG. 11 . Rather, any number of detection volumes may be included along the length of the fluidic channel. Further, the detector electrodes and detection volumes need not be evenly spaced, evenly sized or directly adjacent to one another. Various detection volume sizes, spacing and configurations are contemplated. 
         [0109]    Both the nanopore apparatus and the fluidic channel apparatus allow detection of an analyte as well as detection of a flap formed on that analyte. Furthermore, relative or absolute positional information of the flap may be obtained. Since, when using a known nicking endonuclease a specific recognition sequence is known, determination of the location of the flap allows determination of the location of the known recognition sequence. This in turn, allows the biomolecule to be mapped. The repeated use of different nicking endonucleases allows greater complexity, i.e., multiple recognition sequences, to be combined and mapped. 
       EQUIVALENTS 
       [0110]    Several of the illustrated examples show DNA templates having a single nick formed thereon, with a single flap being formed thereafter. Embodiments of the present invention are not intended to be limited as such; rather, it is contemplated that a nicking endonuclease may form a plurality of nicks at sequence specific locations on a first DNA strand. 
         [0111]    Those skilled in the art will readily appreciate that all parameters listed herein are meant to be exemplary and actual parameters depend upon the specific application for which the methods and materials of embodiments of the present invention are used. It is, therefore, to be understood that the foregoing embodiments are presented by way of example only and that, within the scope of the appended claims and equivalents thereto, the invention may be practiced otherwise than as specifically described. Thus, numerous variations and modifications will be apparent to those skilled in the art. All such variations and modifications are intended to be within the scope of the present invention as defined in the appended claims.