A Biomimetic Potassium Responsive Nanochannel: G-Quadruplex DNA Conformational Switching in a Synthetic Nanopore

Hou, Xu; Guo, Wei; Xia, Fan; Nie, Fu-Qiang; Dong, Hua; Tian, Ye; Wen, Liping; Wang, Lin; Cao, Liuxuan; Yang, Yang; Xue, Jianming; Song, Yanlin; Wang, Yugang; Li, Dongsheng; Jiang, Lei

doi:10.1021/ja901574c

Cited by 323 publications

(275 citation statements)

References 58 publications

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“…[13][14][15][16][17][18][19] Recent advances concerning the fabrication processes and the tailoring of the surface properties have permitted to control the pore geometry [20][21][22][23] and the response to external stimuli such as voltage, 24,25 temperature, 26,27 pH [28][29][30] or the presence of a given analyte in the pore solution. [31][32][33][34] These features have allowed the fabrication of nanofluidic devices [35][36][37][38] with potential applications in sensing, 34,39,40 energy harvesting 41,42 and information processing.…”

Section: Introductionmentioning

confidence: 99%

Nernst-Planck model of photo-triggered, pH–tunable ionic transport through nanopores functionalized with “caged” lysine chains

Nasir

Ramı́rez

Ali

et al. 2013

The Journal of Chemical Physics

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Nasir, S.; Ramirez Hoyos, P.; Ali, M.; Ahmed, I.; Fruk, L.; Mafé, S.; Ensinger, W. (2013). Nernst-Planck model of photo-triggered, pH-tunable ionic transport through nanopores functionalized with "caged" lysine chains. Journal of Chemical Physics. 138(3):034709-1-034709-11. doi:10.1063/1.4775811. Author to whom correspondence should be addressed. Electronic mail: m.ali@gsi.de AbstractWe describe the fabrication of asymmetric nanopores sensitive to ultraviolet (UV) light and give a detailed account of the divalent ionic transport through these pores using a theoretical model based on the Nernst-Planck equations. The pore surface is decorated with lysine chains having pH-sensitive (amine and carboxylic acid) moieties that are caged with photo-labile 4,5-dimethoxy-2-nitrobenzyl (NVOC) groups. The uncharged hydrophobic NVOC groups are removed using UV irradiation, leading to the generation of hydrophilic "uncaged" amphoteric groups on the pore surface. We demonstrate experimentally that polymer membranes containing single pore and arrays of asymmetric nanopores can be employed for the pH-controlled transport of ionic and molecular analytes. Comparison between theory and experiment allows for understanding the individual properties of the 2 phototriggered nanopores and provides also useful clues for the design and fabrication of multipore membranes to be used in practical applications.

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Section: Introductionmentioning

confidence: 99%

Nernst-Planck model of photo-triggered, pH–tunable ionic transport through nanopores functionalized with “caged” lysine chains

Nasir

Ramı́rez

Ali

et al. 2013

The Journal of Chemical Physics

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“…Instead of oligonucleotides, proton, 393,394 metal ions, 395 and metal complexes 396 were used as the fuel. In order to drive the systems, however, "photo-isomerization" is undoubtedly more preferable, since no raw materials are wasted and no byproducts are formed.…”

Section: Determination Of Dna Nanostructures In Solutionsmentioning

confidence: 99%

Chemistry Can Make Strict and Fuzzy Controls for Bio-Systems: DNA Nanoarchitectonics and Cell-Macromolecular Nanoarchitectonics

Komiyama

Yoshimoto

Sisido

et al. 2017

Bulletin of the Chemical Society of Japan

281

131

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In this review, we introduce two kinds of bio-related nanoarchitectonics, DNA nanoarchitectonics and cellmacromolecular nanoarchitectonics, both of which are basically controlled by chemical strategies. The former DNA-based approach would represent the precise nature of the nanoarchitectonics based on the strict or "digital" molecular recognition between nucleic bases. This part includes functionalization of single DNAs by chemical means, modification of the main-chain or side-chain bases to achieve stronger DNA binding, DNA aptamers and DNAzymes. It also includes programmable assemblies of DNAs (DNA Origami) and their applications for delivery of drugs to target sites in vivo, sensing in vivo, and selective labeling of biomaterials in cells and in animals. In contrast to the digital molecular recognition between nucleic bases, cell membrane assemblies and their interaction with macromolecules are achieved through rather generic and "analog" interactions such as hydrophobic effects and electrostatic forces. This cell-macromolecular nanoarchitectonics is discussed in the latter part of this review. This part includes bottom-up and top-down approaches for constructing highly organized cell-architectures with macromolecules, for regulating cell adhesion pattern and their functions in twodimension, for generating three-dimensional cell architectures on micro-patterned surfaces, and for building synthetic/natural macromolecular modified hybrid biointerfaces.

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“…To understand the transportation mechanism and behavior of ions, biomolecules in the pore/channel and polymer and inorganic nanopores/nanochannels have been created. To confer on these nanopores/nanochannels stimuliresponsive properties to mimic their natural models, polymers [35,36], peptides [37] and DNA [38][39][40] have been modified onto the inner surface of nanopores/nanochannels. Among these studies, DNA has been demonstrated as an outstanding molecule to create an intelligent nanopore/nanochannel because of the clear transformation of secondary structure.…”

Section: Dna Responsive Nanopore/nanochannelmentioning

confidence: 99%

“…The nanopore/nanochannel has a pH-responsive conductivity change and the authors proposed that the mechanism was related to the charge densities of different DNA conformations. One year later, Hou et al [40] further studied the response mechanisms of DNAmodified nanopore/nanochannel with a potassium ion responding to a DNA sequence that is guanine (G) rich, and can fold into a four-stranded G-quadruplex in the presence of potassium ions. In the presence of lithium, they demonstrated that the G-rich sequences adopted a loosely packed single-stranded structure inside the channel (Figure 4).…”

Section: Dna Responsive Nanopore/nanochannelmentioning

confidence: 99%

“…Taken together, this results in interesting behaviors for this nanopore/nanochannel (Figure 4(b,c)): current first starts to drop with an increase in the concentration of potassium ions from 0 to 500 μM, which could be attributed to the increasing proportion of newly formed G-quadruplex; and with concentrations above 500 μM, currents return to a monotonous linear relation with potassium ion concentration. Hou et al [40] proposed that this was because all DNA strands were folded into the G-quadruplex under this condition. This result and proposed mechanism shows good agreement with a previous nanocontainer study.…”

Section: Dna Responsive Nanopore/nanochannelmentioning

confidence: 99%

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DNA-based switchable devices and materials

2011

Self Cite

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Studies on DNA molecules have long been focused on its biological functions, since the discovery of the molecular structure of DNA by Watson and Crick [1] in 1953. DNA is known to be composed of adenine (A), guanine (G), cytosine (C) and thymine (T), and the Watson-Crick interaction of A-T and C-G base-pairing leads to the formation of the double-helix structure when sequences are complementary; this base-pairing process is also referred to as hybridization. Single-stranded DNA (ssDNA) is considered flexible, whereas double-stranded DNA (dsDNA) has a persistence length of about 50 nm. In the early 1980s [2], scientists started reconsidering the chemical composition of DNA, examining details such as chain structure, adjustable persistence length at the nanoscale, base-pair formation and programmable sequence. DNA quickly gained fresh recognition beyond strict biological roles and was rapidly introduced into the field of nanoscience as a new type of building block [3][4][5][6][7][8]. For example, DNA was used to fabricate nanostructures [9-14] from two-dimensional DNA nanostructures to three-dimensional curved nanostructures, as complex as spheres, ellipsoids, and flasks utilizing DNA origami techniques. DNA was also designed for the construction of molecular devices or machines that can generate nanoscale movement [15][16][17]. Besides static nanostructures, DNA could be applied to self-assembled structures [18,19] or integrated within other functional systems [20], utilizing properties of DNA such as specific recognition, chain-exchange reactions, specific enzyme reactions and secondary structure transformation to enable precise control of motion at the molecular level [19,21] or change properties at the macro scale [22]. Such responsive and switchable properties allow molecular machine-like devices to be built. [5,6] in the past several years. The present review focuses on DNA-based devices and smart materials that can respond to external stimuli, resulting in conformational changes to DNA structures at the nanoscale and detectable changes in properties such as volume, wettability at the macroscopic scale or transduction of force to move objects. This responsiveness is recoverable on removal of the external stimulus. DNA-based devices are introduced relating to smart surfaces and nanopores/nanochannels, while DNA-based smart materials are related to newly developed pure and hybrid DNA hydrogels. Figure 1 shows a typical example of a DNA device or motor. In 2003, Liu and Balasubramanian [19] proposed a pH-driven molecular motor system that is strong and swift. It comprises a 21mer ssDNA sequence X containing four stretches of three cytosines and a 17mer single-stranded DNA sequence Y, which is partially complementary to X. At pH 5, via the formation of C·CH+ base-pairs, sequence X folds into a compact 4-stranded i-motif structure with the 3' and 5' ends close to each other, representing the closed state of the motor. Changing the pH to 8 results in X unfolding and forming an extended DNA duplex structure XY, c...

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A Biomimetic Potassium Responsive Nanochannel: G-Quadruplex DNA Conformational Switching in a Synthetic Nanopore

Cited by 323 publications

References 58 publications

Nernst-Planck model of photo-triggered, pH–tunable ionic transport through nanopores functionalized with “caged” lysine chains

Nernst-Planck model of photo-triggered, pH–tunable ionic transport through nanopores functionalized with “caged” lysine chains

Chemistry Can Make Strict and Fuzzy Controls for Bio-Systems: DNA Nanoarchitectonics and Cell-Macromolecular Nanoarchitectonics

DNA-based switchable devices and materials

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