Rapid nanopore discrimination between single polynucleotide molecules

Meller, A.; Nivón, Lucas G.; Brandin, Eric; Golovchenko, Jene Andrew; Branton, Daniel

doi:10.1073/pnas.97.3.1079

Cited by 863 publications

(893 citation statements)

References 12 publications

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“…This is in agreement with experimental results. 10,12 Unfortunately, the analytical determination of the time distribution requires the complete Smoluchowski problem to be solved. Since this is not possible, one has to resort to reasonable approximations.…”

Section: Resultsmentioning

confidence: 99%

A Statistical Model for Translocation of Structured Polypeptide Chains through Nanopores

et al. 2009

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The translocation process of a globular protein (ubiquitin) across a cylindrical nanopore is studied via molecular dynamics simulations. The ubiquitin is described by a native-centric model on a C R carbon backbone to investigate the influence of protein-like structural properties on the translocation mechanism. A thermodynamical and kinetic characterization of the process is obtained by studying the statistics of blockage times, the mobility, and the translocation probability as a function of the pulling force F acting in the pore. The transport dynamics occurs when the force exceeds a threshold F c depending on a free-energy barrier that ubiquitin has to overcome in order to slide along the channel. Such a barrier results from competition of the unfolding energy and the entropy associated with the confinement effects of the pore. We implement appropriate umbrella sampling simulations to compute the free-energy profile as a function of the position of the ubiquitin center of mass inside of the channel (reaction coordinate). This free energy is then used to construct a phenomenological drift-diffusion model in the reaction coordinate which explains and reproduces the behavior of the observables during the translocation.

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Section: Resultsmentioning

confidence: 99%

A Statistical Model for Translocation of Structured Polypeptide Chains through Nanopores

et al. 2009

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“…The dynamics and conformation of single biological nanopores with dimensions of order 2 nm or less can be studied electronically using patchclamp techniques 6 . Bio-nanopores have recently been shown to act as electronic sensors capable of identifying and characterizing single molecules in aqueous solution [7][8][9][10][11] . The incorporation of such nanoscale functionality in robust, man-made devices has far-reaching implications, but requires the manipulation of solid state materials on length scales smaller than state of the art device fabrication methods provide today.…”

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confidence: 99%

Ion-beam sculpting at nanometre length scales

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McMullan

et al. 2001

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“…[1][2] Subsequently, the pioneering studies of the use of R-hemolysin protein pore within a lipid bilayer for the translocation of single strands of DNA molecules using a voltage bias across the membranes sparked tremendous interest in such single molecule sensors. [3][4][5][6][7][8] The normal ionic current through the protein pore in a lipid bilayer would detectably reduce as a polyanionic chain of ssDNA molecules traversed through the pore, even allowing the distinction between polycytosine and polyadenine molecules, thus demonstrating the potential of single base discrimination in these sensors. 4,5 Despite these advantages, robust integration of these biological sensors within practical devices is quite problematic, and a mechanical pore 9,10 provides numerous advantages over biological pores.…”

mentioning

confidence: 99%

“…[3][4][5][6][7][8] The normal ionic current through the protein pore in a lipid bilayer would detectably reduce as a polyanionic chain of ssDNA molecules traversed through the pore, even allowing the distinction between polycytosine and polyadenine molecules, thus demonstrating the potential of single base discrimination in these sensors. 4,5 Despite these advantages, robust integration of these biological sensors within practical devices is quite problematic, and a mechanical pore 9,10 provides numerous advantages over biological pores. Besides the obvious advantages of being able to drastically change ambient conditions such as pH, electric field, and temperature without distorting the system, such a system can also allow the integration of different types of electronic or optical sensors 11 or functionalization of the inner surface of the pore, as demonstrated for protein channels for the detection of single chemical molecules and analytes.…”

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confidence: 99%

DNA-Mediated Fluctuations in Ionic Current through Silicon Oxide Nanopore Channels

et al. 2004

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Single molecule sensors in which nanoscale pores within biological or artificial membranes act as mechanical gating elements are very promising devices for the rapid characterization and sequencing of nucleic acid molecules. The two terminal electrical measurements of translocation of polymers through single ion channels and that of ssDNA molecules through protein channels have been demonstrated, and have sparked tremendous interest in such single molecule sensors. The prevailing view regarding the nanopore sensors is that there exists no electrical interaction between the nanopore and the translocating molecule, and that all nanopore sensors reported to-date, whether biological or artificial, operate as a coulter-counter, i.e., the ionic current measured across the pore decreases (is mechanically blocked) when the DNA molecule transverses through the pore. We have fabricated nanopore "channel" sensors with a silicon oxide inner surface, and our results challenge the prevailing view of exclusive mechanical interaction during the translocation of dsDNA molecules through these channels. We demonstrate that the ionic current can actually increase due to electrical gating of surface current in the channel due to the charge on the DNA itself.As a first step toward the ultimate goal of single-molecule DNA sequencing using nanopore sensors, one must first identify the key mechanical and electrical variables that control the translocation of the molecules through the nanopores. First, a nanopore used for characterization and sequencing of a single molecule must have a diameter of less than the persistence length (∼50 nm for dsDNA) to avoid any signal averaging from thermally induced conformational changes. Second, the pores must be chemically stable and mechanically robust under a wide variety of conditions of use. Third, and finally, the mechanical and electrical interaction between the nanopores and the single molecules must be well characterized. Toward this end, the electrical detection of translocation of polymers through single ion channels has been demonstrated. 1-2 Subsequently, the pioneering studies of the use of R-hemolysin protein pore within a lipid bilayer for the translocation of single strands of DNA molecules using a voltage bias across the membranes sparked tremendous interest in such single molecule sensors. [3][4][5][6][7][8] The normal ionic current through the protein pore in a lipid bilayer would detectably reduce as a polyanionic chain of ssDNA molecules traversed through the pore, even allowing the distinction between polycytosine and polyadenine molecules, thus demonstrating the potential of single base discrimination in these sensors. 4,5 Despite these advantages, robust integration of these biological sensors within practical devices is quite problematic, and a mechanical pore 9,10 provides numerous advantages over biological pores. Besides the obvious advantages of being able to drastically change ambient conditions such as pH, electric field, and temperature without distorting the s...

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Rapid nanopore discrimination between single polynucleotide molecules

Cited by 863 publications

References 12 publications

A Statistical Model for Translocation of Structured Polypeptide Chains through Nanopores

A Statistical Model for Translocation of Structured Polypeptide Chains through Nanopores

Ion-beam sculpting at nanometre length scales

DNA-Mediated Fluctuations in Ionic Current through Silicon Oxide Nanopore Channels

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