Decreasing the Limits of Detection and Analysis Time of Ion Current Rectification Biosensing Measurements via a Mechanically Applied Pressure Differential.

Improving on the analytical capabilities of a measurement is a fundamental challenge with all assays, particularly decreasing the limit of detection while maintaining a practical associated analysis time. Of late, ion current rectification (ICR) biosensing measurements have received a great deal of attention as an analyte-specific, label-free assay. In ICR biosensing, a nanopore coated with an analyte specific binding molecule (e.g., an antibody, an aptamer, etc.) is used to detect a target analyte based on the ability of the target analyte to alter the ICR response of the nanopore upon it binding to the aperture interior. This binding changes the local surface charge and/or size of the nanopore aperture, thus altering its ICR response in a time dependent manner. Here, we report the ability to enhance the transport of a target analyte molecule to and through the aperture of an antibody modified glass nanopore membrane (AMGNM) with the application of a mechanically applied pressure differential. We demonstrate that there is an optimal pressure that balances the flux of the target analyte through the AMGNM aperture with its ability to be bound and detected. Applying the optimal pressure differential allows for picomolar concentrations of the cleaved form of synaptosomal-associated protein 25 (cSNAP-25) to be detected within the same analysis time as micromolar concentrations detected without the use of the pressure differential. The methodology presented here significantly expands the utility of ICR biosensing measurements for detecting low-abundance biomolecules by lowering the limit of detection and reducing the associated analysis time.

Antigen detection via the rate of ion current rectification change of the antibody-modified glass nanopore membrane.

Ion current rectification (ICR), defined as an increase in ion conduction at a given polarity and a decrease in ion conduction for the same voltage at the opposite polarity, i.e., a deviation from a linear ohmic response, occurs in conical shaped pores due to the voltage dependent solution conductivity within the aperture. The degree to which the ionic current rectifies is a function of the size and surface charge of the nanopore, with smaller and more highly charged pores exhibiting greater degrees of rectification. The ICR phenomenon has previously been exploited for biosensing applications, where the level of ICR for a nanopore functionalized with an analyte-specific binding molecule (e.g., an antibody, biotin, etc.) changes upon binding its target analyte (e.g., an antigen, streptavidin, etc.) due to a resulting change in the size and/or charge of the aperture. While this type of detection measurement is typically qualitative, for the first time, we demonstrate that the rate at which the nanopore ICR response changes is dependent on the concentration of the target analyte introduced. Utilizing a glass nanopore membrane (GNM) internally coated with a monoclonal antibody specific to the cleaved form of synaptosomal-associated protein 25 (cSNAP-25), creating the antibody-modified glass nanopore membrane (AMGNM), we demonstrate a correlation between the rate of ICR change and the concentration of introduced cSNAP-25, over a range of 500 nM-100 µM. The methodology presented here significantly expands the applications of nanopore ICR biosensing measurements and demonstrates that these measurements can be quantitative in nature.

Creating a Single Sensing Zone within an Alpha-Hemolysin Pore Via Site Directed Mutagenesis.

Although significant progress has recently been made towards realizing the goal of direct nanopore based DNA sequencing [1], there are still numerous hurdles that need to be overcome. One such hurdle associated with the use of the biological nanopore α-hemolysin (αHL) is the fact that the wild type channel contains three very distinct recognition or sensing regions within the ß-barrel [2, 3], making identification of the bases residing within or moving through the pore very difficult. Through site directed mutagenesis, we have been able to selectively remove one of two sensing regions while simultaneously enhancing the third. Our approach has led to the creation of αHL pores containing single sensing zones and provides the basis for engineering αHL pores suitable for direct DNA sequencing.

Sequence-specific single-molecule analysis of 8-oxo-7,8-dihydroguanine lesions in DNA based on unzipping kinetics of complementary probes in ion channel recordings.

Translocation measurements of intact DNA strands with the ion channel α-hemolysin (α-HL) are limited to single-stranded DNA (ssDNA) experiments as the dimensions of the channel prevent double-stranded DNA (dsDNA) translocation; however, if a short oligodeoxynucleotide is used to interrogate a longer ssDNA strand, it is possible to unzip the duplex region when it is captured in the α-HL vestibule, allowing the longer strand to translocate through the α-HL channel. This unzipping process has a characteristic duration based on the stability of the duplex. Here, ion channel recordings are used to detect the presence and relative location of the oxidized damage site 8-oxo-7,8-dihydroguanine (OG) in a sequence-specific manner. OG engages in base pairing to C or A with unique stabilities relative to native base Watson-Crick pairings, and this phenomenon is used here to engineer probe sequences (10-15mers) that, when base-paired with a 65mer sequence of interest, containing either G or OG at a single site, produce characteristic unzipping times that correspond well with the duplex melting temperature (T(m)). Unzipping times also depend on the direction from which the duplex enters the vestibule if the stabilities of leading base pairs at the ends of the duplex are significantly different. It is shown here that the presence of a single DNA lesion can be distinguished from an undamaged sequence and that the relative location of the damage site can be determined based on the duration of duplex unzipping.

Fluorescence microscopy of the pressure-dependent structure of lipid bilayers suspended across conical nanopores.

Glass and fused-quartz nanopore membranes containing a single conically shaped pore are promising solid supports for lipid bilayer ion-channel recordings due to the high inherent stability of lipid bilayers suspended across the nanopore orifice, as well as the favorable electrical properties of glass and fused quartz. Fluorescence microscopy is used here to investigate the structure of the suspended lipid bilayer as a function of the pressure applied across a fused-quartz nanopore membrane. When a positive pressure is applied across the bilayer, from the nanopore interior relative to the exterior bulk solution, insertion or reconstitution of operative ion channels (e.g., α-hemolysin (α-HL) and gramicidin) in the bilayer is observed; conversely, reversing the direction of the applied pressure results in loss of all channel activity, although the bilayer remains intact. The dependence of the bilayer structure on pressure was explored by imaging the fluorescence intensity from Nile red dye doped into suspended 1,2-diphytanoyl-sn-glycero-3-phosphocholine bilayers, while simultaneously recording the activity of an α-HL channel. The fluorescence images suggest that a positive pressure results in compression of the bilayer leaflets and an increase in the bilayer curvature, making it suitable for ion-channel formation and activity. At negative pressure, the fluorescence images are consistent with separation of the lipid leaflets, resulting in the observed loss of the ion-channel activity. The fluorescence data indicate that the changes in the pressure-induced bilayer structure are reversible, consistent with the ability to repeatedly switch the ion-channel activity on and off by applying positive and negative pressures, respectively.

Nanopore detection of 8-oxo-7,8-dihydro-2'-deoxyguanosine in immobilized single-stranded DNA via adduct formation to the DNA damage site.

The ability to detect DNA damage within the context of the surrounding sequence is an important goal in medical diagnosis and therapies, but there are no satisfactory methods available to detect a damaged base while providing sequence information. One of the most common base lesions is 8-oxo-7,8-dihydroguanine, which occurs during oxidation of guanine. In the work presented here, we demonstrate the detection of a single oxidative damage site using ion channel nanopore methods employing α-hemolysin. Hydantoin lesions produced from further oxidation of 8-oxo-7,8-dihydroguanine, as well as spirocyclic adducts produced from covalently attaching a primary amine to the spiroiminodihydantoin lesion, were detected by tethering the damaged DNA to streptavidin via a biotin linkage and capturing the DNA inside an α-hemolysin ion channel. Spirocyclic adducts, in both homo- and heteropolymer background single-stranded DNA sequences, produced current blockage levels differing by almost 10% from those of native base current blockage levels. These preliminary studies show the applicability of ion channel recordings not only for DNA sequencing, which has recently received much attention, but also for detecting DNA damage, which will be an important component to any sequencing efforts.

Quartz nanopore membranes for suspended bilayer ion channel recordings.

A method is described for fabricating 25-75 mum thick fused quartz membranes containing a single conical shaped nanopore (orifice radius ranging from 10 to 1000 nm). The quartz nanopore membrane (QNM) provides an excellent solid support structure for lipid bilayers in ion channel recordings due to the large electrical resistivity of fused quartz. Electrical measurements demonstrate that the leakage current through 1,2-diphytanoyl-sn-glycero-3-phosphocholine (DPhPC) bilayers suspended across a 500-1000 nm radius QNM orifice is immeasurably small, corresponding to a bilayer resistance greater than 10(12) ohms. Translocation of single-stranded DNA oligomers (poly dA 50-mer and poly dA 20-mer) through a protein ion channel (alpha-hemolysin) reconstituted in a DPhPC bilayer suspended across the QNM orifice is demonstrated.

Controlling the translocation of single-stranded DNA through alpha-hemolysin ion channels using viscosity.

Translocation of single-stranded DNA through alpha-hemolysin (alpha-HL) channels is investigated in glycerol/water mixtures containing 1 M KCl. Experiments using glass nanopore membranes as the lipid bilayer support demonstrate that the translocation velocities of poly(deoxyadenylic acid), poly(deoxycytidylic acid), and poly(deoxythymidylic acid) 50-mers are decreased by a factor of approximately 20 in a 63/37 (vol %) glycerol/water mixture, relative to aqueous solutions. The ion conductance of alpha-HL and the entry rate of the polynucleotides into the protein channel also decrease with increasing viscosity. Precise control of translocation parameters by adjusting viscosity provides a potential means to improve sequencing methods based on ion channel recordings.