Ionic Current-Based Mapping of Short Sequence Motifs in Single DNA Molecules Using Solid-State Nanopores

Chen, Kaikai; Juhasz, Matyas; Gularek, Felix; Weinhold, Elmar G.; Tian, Yu; Keyser, Ulrich F.; Bell, Nicholas A. W.

doi:10.1021/acs.nanolett.7b01009

Cited by 61 publications

(69 citation statements)

References 41 publications

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“…As two‐pore control eliminates folding in the majority of translocation events, the technology potentially enables access to a larger portion of the data. For comparison, in conventional single‐pore electronic barcoding, performed with a 14 nm pore, the majority of events are folded and do not possess usable barcodes so that only 30% of the events can be used. For the data shown in Figure d–f, 331/368 or 90% of events are unfolded.…”

Section: Results: Tug‐of‐war With Bound Protein Tagsmentioning

confidence: 99%

“…When DNA in the kbp size range passes through a large (>5 nm) nanopore, the probability of folding occurring during translocation is high (≈60–70% for pores in the 10–14 nm range …”

Section: Dna Folding Signatures During Two‐pore Tug‐of‐warmentioning

confidence: 99%

“…Solid‐state nanopores lack a translocation control mechanism that can slow‐down the DNA while ensuring a high sensing voltage to generate ample signal to noise ratio (SNR) for robust feature detection. In addition, for large diameter (>5 nm) pores that enable efficient capture of long (>10 kbp) DNA, the occurrence of folds during translocation greatly reduces the number of usable events featuring a linear correspondence between translocation time and sequence position . Recently, a new class of “two‐pore” devices has been developed that enables simultaneous capture of a single DNA molecule by two closely spaced pores .…”

Section: Introductionmentioning

confidence: 99%

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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: Results: Tug‐of‐war With Bound Protein Tagsmentioning

confidence: 99%

“…When DNA in the kbp size range passes through a large (>5 nm) nanopore, the probability of folding occurring during translocation is high (≈60–70% for pores in the 10–14 nm range …”

Section: Dna Folding Signatures During Two‐pore Tug‐of‐warmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

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

Zhang

Nagel

et al. 2019

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“…10). Last but not least, the same group also developed a solid-state nanoporebased method to recognize specific DNA motifs [123]. Using DNA methyltransferase, they covalently attached biotin labels at 5 0 -TCGA-3 0 sequence motifs, enabling the position and number of the motifs to be estimated from the secondary ionic current drop caused by bound streptavidin.…”

Section: Specific Interactions Between Proteins and Self-assembled Dnmentioning

confidence: 99%

The applications of nanopores in studies of proteins

2019

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“…(15) More recently, MSA acted as a critical component in a scheme to detect single nucleotide polymorphism, (16) and to map the positions of short sequences in longer dsDNA. (17) Despite the growing body of applied nanopore research into streptavidin-based complexes, no studies have compared the characteristics of passage and capture of the protein itself or the protein-DNA complex under widely varying conditions (i.e. salt type/concentration, voltage magnitude, pore size, etc.)…”

Section: Introductionmentioning

confidence: 99%

Mapping shifts in nanopore signal to changes in protein and protein-DNA conformation

Carlsen

Tabard‐Cossa

2020

Preprint

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Solid-state nanopores have been used extensively in biomolecular studies involving DNA and proteins. However, the interpretation of signals generated by the translocation of proteins or protein-DNA complexes remains challenging. Here, we investigate the behavior of monovalent streptavidin and the complex it forms with short biotinylated DNA over a range of nanopore sizes, salts and voltages. We describe a simple geometric model that is broadly applicable and employ it to explain observed variations in conductance blockage and dwell time with experimental conditions. The general approach developed here underscores the value of nanopore-based protein analysis and represents progress toward the interpretation of complex translocation signals. STATEMENT OF SIGNIFICANCENanopore sensing allows investigation of biomolecular structure in aqueous solution, including electricfield-induced changes in protein conformation. This nanopore-based study probes the tetramer-dimer transition of streptavidin, observing the effects of increasing voltage with varying salt type and concentration. Binding of biotinylated DNA to streptavidin boosts the complex's structural integrity, while complicating signal analysis. We describe a broadly applicable geometric approach that maps stepwise changes in the nanopore signal to real-time conformational transitions. These results represent important progress toward accurate interpretation of nanopore signals generated by macromolecular complexes.

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Ionic Current-Based Mapping of Short Sequence Motifs in Single DNA Molecules Using Solid-State Nanopores

Cited by 61 publications

References 41 publications

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

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

The applications of nanopores in studies of proteins

Mapping shifts in nanopore signal to changes in protein and protein-DNA conformation

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