2018
DOI: 10.1088/1361-648x/aacc01
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DNA capture into the ClyA nanopore: diffusion-limited versus reaction-limited processes

Abstract: The capture and translocation of biomolecules through nanometer-scale pores are processes with a potentially large number of applications, and hence they have been intensively studied in recent years. The aim of this paper is to review existing models of the capture process by a nanopore, together with some recent experimental data of short single- and double-stranded DNA captured by the Cytolysin A (ClyA) nanopore. ClyA is a transmembrane protein of bacterial origin which has been recently engineered through … Show more

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Cited by 21 publications
(33 citation statements)
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References 34 publications
(93 reference statements)
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“…The field outside the pore is often modeled using the point-like approximation 15,27,28 , which greatly simplifies analytical calculations; for a pore of radius r p and length l, the corresponding potential V (r) is the second equation in the Introduction. The part of the total potential gradient ∆V that is relevant for capture depends on the ratio of the access (ac) and channel (ch) resistances.…”
Section: Appendix A: the Electrostatic Fieldmentioning
confidence: 99%
See 2 more Smart Citations
“…The field outside the pore is often modeled using the point-like approximation 15,27,28 , which greatly simplifies analytical calculations; for a pore of radius r p and length l, the corresponding potential V (r) is the second equation in the Introduction. The part of the total potential gradient ∆V that is relevant for capture depends on the ratio of the access (ac) and channel (ch) resistances.…”
Section: Appendix A: the Electrostatic Fieldmentioning
confidence: 99%
“…is the point-charge approximation 15,[27][28][29] for the electric potential at a distance r when a voltage difference ∆V is applied across the system. Here r e = r p /( 2l rp + π) is the characteristic length of the electrostatic potential outside a pore of radius r p and length l 28 . The capture radius is then defined as the distance R * at which W (R * ) = k B T 15,27,29 .…”
Section: Introductionmentioning
confidence: 99%
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“…It was worth noting that the increase of blockade from 3 to 4 M KCl (1.99%) was actually smaller than the value from 2 to 3 M KCl (2.84%), which was partially in agreement with the greater slope of the voltage induced decrease of ∆I/I 0 in 2 M KCl. One possible explanation for such phenomena was the reduced Debye length at an elevated concentration of electrolyte ( Nomidis et al, 2018 ). As the salt concentration increased, the contribution of counterion screening was inhibited, and the current blockade became more determined by the steric exclusion effect ( Wilson et al, 2019 ), or in other words, reflecting mainly the structural properties of PFCAs.…”
Section: Resultsmentioning
confidence: 99%
“…Although numerous efforts have been made to counteract the electrophoretic force during DNA translocation ( 46 ), the electrophoretic force, which efficiently untangles coiled DNA during translocation ( 47 ), was still considered indispensable during DNA sensing. However, the long persistence length of dsDNA ( 48 ) and the wide opening of ClyA nanopore may reduce the entropic barrier for dsDNA translocation ( 49 ). Furthermore, the relatively large vestibule of ClyA may also serve to accommodate dsDNA in a form of partial translocation to report the sensing signal of dsDNA during the DOP recording as well.…”
Section: Resultsmentioning
confidence: 99%