Electronic single-molecule identification of carbohydrate isomers by recognition tunnelling

Im, Jong One; Biswas, Sovan; Líu, Hao; Zhao, Yanan; Sen, Suman; Biswas, Sudipta; Ashcroft, Brian; Borges, Chad R.; Wang, Xu; Lindsay, Stuart; Zhang, Peiming

doi:10.1038/ncomms13868

Cited by 45 publications

(72 citation statements)

References 31 publications

(43 reference statements)

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“…Voltage field‐force balancing would be facilitated by the atomic level precision of the biopore structures. Solid‐state based alternatives include patterning recognition tunneling electrodes on a surface between the controlling pores or as part of a multilayered membrane, which have sensing potential beyond nucleic acids . Beyond sequencing, the device could enable genome mapping, or detecting the presence/absence of base modifications along with the sequence context (via PNA‐PEG labeling) that is needed for clinical relevance.…”

Section: Discussionmentioning

confidence: 99%

Controlling DNA Tug‐of‐War in a Dual Nanopore Device

Zhang

Nagel

et al. 2019

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Methods for reducing and directly controlling the speed of DNA through a nanopore are needed to enhance sensing performance for direct strand sequencing and detection/mapping of sequence‐specific features. A method is created for reducing and controlling the speed of DNA that uses two independently controllable nanopores operated with an active control logic. The pores are positioned sufficiently close to permit cocapture of a single DNA by both pores. Once cocapture occurs, control logic turns on constant competing voltages at the pores leading to a “tug‐of‐war” whereby opposing forces are applied to regions of the molecules threading through the pores. These forces exert both conformational and speed control over the cocaptured molecule, removing folds and reducing the translocation rate. When the voltages are tuned so that the electrophoretic force applied to both pores comes into balance, the life time of the tug‐of‐war state is limited purely by diffusive sliding of the DNA between the pores. A tug‐of‐war state is produced on 76.8% of molecules that are captured with a maximum two‐order of magnitude increase in average pore translocation time relative to the average time for single‐pore translocation. Moreover, the translocation slow‐down is quantified as a function of voltage tuning and it is shown that the slow‐down is well described by a first passage analysis for a 1D subdiffusive process. The ionic current of each nanopore provides an independent sensor that synchronously measures a different region of the same molecule, enabling sequential detection of physical labels, such as monostreptavidin tags. With advances in devices and control logic, future dual‐pore applications include genome mapping and enzyme‐free sequencing.

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Section: Discussionmentioning

confidence: 99%

Controlling DNA Tug‐of‐War in a Dual Nanopore Device

Zhang

Nagel

et al. 2019

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“…[25] Before use, the probes were tested in 1 mM phosphate buffer (pH=7.4) at 0.5 V bias to ensure that the leakage current was <1 pA. For functionalization, the probe was gently cleaned using ethanol and water, respectively, and then dried in a flow of nitrogen. The probe was immersed in a 0.5 mg/mL peptide solution for ~20 h. After that, the probe was taken out, rinsed with water, dried with nitrogen gas, and used immediately.…”

Section: Methodsmentioning

confidence: 99%

“…A Pd wire probe, etched to a sharp point and insulated to within a few tens of nm of its apex, was used in an Agilent PicoSPM together with a Pd-coated substrate as described elsewhere. [25] Pd, rather than Au was used because tunneling devices made with Pd are more stable. [26] Probes and substrates were functionalized with cyclic RGD peptide (inset Figure 1B) as described in Methods.…”

Section: Stm Break Junction Measurementsmentioning

confidence: 99%

Observation of giant conductance fluctuations in a protein

et al. 2017

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Proteins are insulating molecular solids, yet even those containing easily reduced or oxidized centers can have single-molecule electronic conductances that are too large to account for with conventional transport theories. Here, we report the observation of remarkably high electronic conductance states in an electrochemically-inactive protein, the ~200 kD αVβ3 extracelluar domain of human integrin. Large current pulses (up to nA) were observed for long durations (many ms, corresponding to many pC of charge transfer) at large gap (>5nm) distances in an STM when the protein was bound specifically by a small peptide ligand attached to the electrodes. The effect is greatly reduced when a homologous, weakly-binding protein (α4β1) is used as a control. In order to overcome the limitations of the STM, the time- and voltage-dependence of the conductance were further explored using a fixed-gap (5 nm) tunneling junction device that was small enough to trap a single protein molecule at any one time. Transitions to a high conductance (~ nS) state were observed, the protein being “on” for times from ms to tenths of a second. The high-conductance states only occur above ~ 100mV applied bias, and thus are not an equilibrium property of the protein. Nanoamp two-level signals indicate the specific capture of a single molecule in an electrode gap functionalized with the ligand. This offers a new approach to label-free electronic detection of single protein molecules. Electronic structure calculations yield a distribution of energy level spacings that is consistent with a recently proposed quantum-critical state for proteins, in which small fluctuations can drive transitions between localized and band-like electronic states.

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“…The potential for integration of additional instrumentation components, such as control and readout electrodes, around the thin-film SiN x nanopore core, is especially compelling 28 , 45 , 46 . Recent (nanopore-free) work on recognition electron tunneling measurements on polysaccharides, for example, has reaffirmed the importance of a nanopore development path that values augmented nanopore sensing capabilities 47 . A key question concerning the use of SiN x nanopores for polysaccharide sensing is whether this fabrication material is compatible with sensing glycans, which can exhibit a wide range of chemical and physical properties.…”

Section: Introductionmentioning

confidence: 99%

“…Variability in polysaccharide electrokinetic mobility arising from differences in molecular structures may exacerbate the effect of these interactions. These issues become particularly important when analyte translocation through a constricted pore is required, such as in transverse electron tunneling measurements 28 , 47 .…”

Section: Introductionmentioning

confidence: 99%

Surveying silicon nitride nanopores for glycomics and heparin quality assurance

et al. 2018

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Polysaccharides have key biological functions and can be harnessed for therapeutic roles, such as the anticoagulant heparin. Their complexity—e.g., >100 monosaccharides with variety in linkage and branching structure—significantly complicates analysis compared to other biopolymers such as DNA and proteins. More, and improved, analysis tools have been called for, and here we demonstrate that solid-state silicon nitride nanopore sensors and tuned sensing conditions can be used to reliably detect native polysaccharides and enzymatic digestion products, differentiate between different polysaccharides in straightforward assays, provide new experimental insights into nanopore electrokinetics, and uncover polysaccharide properties. We show that nanopore sensing allows us to easily differentiate between a clinical heparin sample and one spiked with the contaminant that caused deaths in 2008 when its presence went undetected by conventional assays. The work reported here lays a foundation to further explore polysaccharide characterization and develop assays using thin-film solid-state nanopore sensors.

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Electronic single-molecule identification of carbohydrate isomers by recognition tunnelling

Cited by 45 publications

References 31 publications

Controlling DNA Tug‐of‐War in a Dual Nanopore Device

Controlling DNA Tug‐of‐War in a Dual Nanopore Device

Observation of giant conductance fluctuations in a protein

Surveying silicon nitride nanopores for glycomics and heparin quality assurance

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