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Literature DB >> 26488651

Temperature Effect on Ionic Current and ssDNA Transport through Nanopores.

Linda Payet¹, Marlène Martinho¹, Céline Merstorf¹, Manuela Pastoriza-Gallego², Juan Pelta¹, Virgile Viasnoff³, Loïc Auvray⁴, Murugappan Muthukumar⁵, Jérôme Mathé⁶.

Abstract

We have investigated the role of electrostatic interactions in the transport of nucleic acids and ions through nanopores. The passage of DNA through nanopores has so far been conjectured to involve a free-energy barrier for entry, followed by a downhill translocation where the driving voltage accelerates the polymer. We have tested the validity of this conjecture by using two toxins, α-hemolysin and aerolysin, which differ in their shape, size, and charge. The characteristic timescales in each toxin as a function of temperature show that the entry barrier is ∼15 kBT and the translocation barrier is ∼35 kBT, although the electrical force in the latter step is much stronger. Resolution of this fact, using a theoretical model, reveals that the attraction between DNA and the charges inside the barrel of the pore is the most dominant factor in determining the translocation speed and not merely the driving electrochemical potential gradient.

Entities: Chemical

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Year: 2015 PMID： 26488651 PMCID： PMC4624348 DOI： 10.1016/j.bpj.2015.08.043

Source DB: PubMed Journal: Biophys J ISSN： 0006-3495 Impact factor: 4.033

36 in total

1. Driven DNA transport into an asymmetric nanometer-scale pore.

Authors: S E Henrickson; M Misakian; B Robertson; J J Kasianowicz
Journal: Phys Rev Lett Date: 2000-10-02 Impact factor: 9.161

2. Rapid nanopore discrimination between single polynucleotide molecules.

Authors: A Meller; L Nivon; E Brandin; J Golovchenko; D Branton
Journal: Proc Natl Acad Sci U S A Date: 2000-02-01 Impact factor: 11.205

3. Transport of long neutral polymers in the semidilute regime through a protein nanopore.

Authors: Abdel Ghani Oukhaled; Anne-Laure Biance; Juan Pelta; Loic Auvray; Laurent Bacri
Journal: Phys Rev Lett Date: 2012-02-22 Impact factor: 9.161

4. Imaging alpha-hemolysin with molecular dynamics: ionic conductance, osmotic permeability, and the electrostatic potential map.

Authors: Aleksij Aksimentiev; Klaus Schulten
Journal: Biophys J Date: 2005-03-11 Impact factor: 4.033

5. Orientation discrimination of single-stranded DNA inside the alpha-hemolysin membrane channel.

Authors: Jérôme Mathé; Aleksei Aksimentiev; David R Nelson; Klaus Schulten; Amit Meller
Journal: Proc Natl Acad Sci U S A Date: 2005-08-19 Impact factor: 11.205

6. Unfolding of proteins and long transient conformations detected by single nanopore recording.

Authors: G Oukhaled; J Mathé; A-L Biance; L Bacri; J-M Betton; D Lairez; J Pelta; L Auvray
Journal: Phys Rev Lett Date: 2007-04-09 Impact factor: 9.161

7. Enhanced translocation of single DNA molecules through alpha-hemolysin nanopores by manipulation of internal charge.

Authors: Giovanni Maglia; Marcela Rincon Restrepo; Ellina Mikhailova; Hagan Bayley
Journal: Proc Natl Acad Sci U S A Date: 2008-12-05 Impact factor: 11.205

8. Translocation dynamics with attractive nanopore-polymer interactions.

Authors: Kaifu Luo; Tapio Ala-Nissila; See-Chen Ying; Aniket Bhattacharya
Journal: Phys Rev E Stat Nonlin Soft Matter Phys Date: 2008-12-19

9. Effect of charge, topology and orientation of the electric field on the interaction of peptides with the α-hemolysin pore.

Authors: Christopher Christensen; Christian Baran; Besnik Krasniqi; Radu I Stefureac; Sergiy Nokhrin; Jeremy S Lee
Journal: J Pept Sci Date: 2011-07-18 Impact factor: 1.905

10. pH tuning of DNA translocation time through organically functionalized nanopores.

Authors: Brett N Anderson; Murugappan Muthukumar; Amit Meller
Journal: ACS Nano Date: 2012-12-31 Impact factor: 15.881

14 in total

1. Remote Activation of a Nanopore for High-Performance Genetic Detection Using a pH Taxis-Mimicking Mechanism.

Authors: Yong Wang; Kai Tian; Xiao Du; Rui-Cheng Shi; Li-Qun Gu
Journal: Anal Chem Date: 2017-12-04 Impact factor: 6.986

2. Translocation of polyampholytes and intrinsically disordered proteins^⋆.

Authors: A Johner; J F Joanny
Journal: Eur Phys J E Soft Matter Date: 2018-06-21 Impact factor: 1.890

3. Discrimination of oligonucleotides of different lengths with a wild-type aerolysin nanopore.

Authors: Chan Cao; Yi-Lun Ying; Zheng-Li Hu; Dong-Fang Liao; He Tian; Yi-Tao Long
Journal: Nat Nanotechnol Date: 2016-04-25 Impact factor: 39.213

4. Dynamics of a polyelectrolyte through aerolysin channel as a function of applied voltage and concentration^⋆.

Authors: Manuela Pastoriza-Gallego; Bénédicte Thiébot; Laurent Bacri; Loïc Auvray; Juan Pelta
Journal: Eur Phys J E Soft Matter Date: 2018-05-11 Impact factor: 1.890

5. Construction of an aerolysin nanopore in a lipid bilayer for single-oligonucleotide analysis.

Authors: Chan Cao; Dong-Fang Liao; Jie Yu; He Tian; Yi-Tao Long
Journal: Nat Protoc Date: 2017-08-24 Impact factor: 13.491

6. Comparative biosensing of glycosaminoglycan hyaluronic acid oligo- and polysaccharides using aerolysin and [Formula: see text]-hemolysin nanopores^⋆.

Authors: Aziz Fennouri; Joana Ramiandrisoa; Laurent Bacri; Jérôme Mathé; Régis Daniel
Journal: Eur Phys J E Soft Matter Date: 2018-10-23 Impact factor: 1.890