Electronic pH switching of DNA triplex reactions

Minero, Gabriel Antonio S.; Wagler, Patrick F.; Oughli, Alaa A.; McCaskill, John S.

doi:10.1039/c5ra02628h

Cited by 13 publications

(16 citation statements)

References 65 publications

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“…This effect is reversible, and can be used to modify the pH around an electrode by several units if desired. Other electrochemical reactions can be used in a similar way and it has already been shown that it is possible to control the conformation of pH-sensitive DNA structures electrochemically 14,15 . Depending on the pH of the solution, the nanoswitch is either open or closed.…”

Section: A Catalytic Cycle With An Electrochemically Controlled Ph-sementioning

confidence: 99%

“…It has already been demonstrated that DNA molecular machines can be controlled using electrical signals, using electrochemical control of pH and pH-sensitive structures such as imotifs or triplexes 14,15 or electronically triggered release of a signalling species from a surface 16 . In an alternative architecture, an enzymatic logic gate under certain conditions produces NADH, which activates an electrochemical process that leads to release of DNA from an alginate matrix 17 .…”

Section: Introductionmentioning

confidence: 99%

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Towards a bioelectronic computer: A theoretical study of a multi-layer biomolecular computing system that can process electronic inputs

Dunn

Trefzer

Johnson

et al. 2018

Preprint

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DNA molecular machines have great potential for use in computing systems. Since Adleman originally introduced the concept of DNA computing through his use of DNA strands to solve a Hamiltonian path problem, a range of DNA-based computing elements have been developed, including logic gates, neural networks, finite state machines (FSMs) and nondeterministic universal Turing machines. It has also been established that DNA molecular machines can be controlled using electrical signals and that the state of DNA nanodevices can be measured using an electrochemical readout. However, to the best of our knowledge there has as yet been no demonstration of a fully integrated biomolecular computing system that has multiple levels of information processing capacity, can accept electronic inputs and is capable of independent operation. In this paper we address the question of how such a system could work. We present simulation results showing that such an integrated hybrid system could convert electrical impulses into biomolecular signals, perform logical operations and take a decision, storing its history. We also illustrate theoretically how such a system could potentially be used to perform a task such as controlling an autonomous robot navigating through a maze.All rights reserved. No reuse allowed without permission.(which was not peer-reviewed) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity.

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Section: A Catalytic Cycle With An Electrochemically Controlled Ph-sementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Towards a bioelectronic computer: A theoretical study of a multi-layer biomolecular computing system that can process electronic inputs

Dunn

Trefzer

Johnson

et al. 2018

Preprint

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“…7-12), primarily because of cytosine protonation reducing electrostatic repulsion, makes DNA triplex structures useful intermediates in designing amplification systems involving switchable pH, following the early work of Nicoloau [41]. Related work involving a much faster triplex ligation scheme involving disulphide bond formation [42] has been reported [43]. DNA triplexes itself are more widely used as reversible hybridization systems and for the sequence dependent recognition of dsDNA in antiviral and biotechnological applications, and so the extension of mobility control by lipid-DNA to impact dsDNA via triplexes is of more general interest.…”

Section: Programmable Sequence-dependent Gel Mobility Using Triplex Smentioning

confidence: 99%

Sequence‐specific nucleic acid mobility using a reversible block copolymer gel matrix and DNA amphiphiles (lipid‐DNA) in capillary and microfluidic electrophoretic separations

et al. 2015

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Reversible noncovalent but sequence-dependent attachment of DNA to gels is shown to allow programmable mobility processing of DNA populations. The covalent attachment of DNA oligomers to polyacrylamide gels using acrydite-modified oligonucleotides has enabled sequence-specific mobility assays for DNA in gel electrophoresis: sequences binding to the immobilized DNA are delayed in their migration. Such a system has been used for example to construct complex DNA filters facilitating DNA computations. However, these gels are formed irreversibly and the choice of immobilized sequences is made once off during fabrication. In this work, we demonstrate the reversible self-assembly of gels combined with amphiphilic DNA molecules, which exhibit hydrophobic hydrocarbon chains attached to the nucleobase. This amphiphilic DNA, which we term lipid-DNA, is synthesized in advance and is blended into a block copolymer gel to induce sequence-dependent DNA retention during electrophoresis. Furthermore, we demonstrate and characterize the programmable mobility shift of matching DNA in such reversible gels both in thin films and microchannels using microelectrode arrays. Such sequence selective separation may be employed to select nucleic acid sequences of similar length from a mixture via local electronics, a basic functionality that can be employed in novel electronic chemical cell designs and other DNA information-processing systems.

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“…Polypurine-polypyrimidine sequences can fold into triple helical DNA structures forming T-A-T and C-G-C + nucleobase triplets upon protonation of cytosine bases at pH ≤ 6. 1 The predictable and pH-controlled base pairing makes triplex-forming sequences very useful for programming chemical reactions, 2,3 nanomachines, 4,5 nanostructures, [6][7][8] and hydro-gels. 9,10 Switching of pHresponsive DNA composites can be employed for controlled release of targets in delivery systems 11,12 and in on/off regulation of the nanoscale devices upon cyclic alternation of pH values.…”

mentioning

confidence: 99%

“…17 For the latter, the assay time can be reduced to 10-15 min using capillary gel electrophoresis. 3,9 Palindromic homopurine-homopyrimidine tracts have been shown to cause a pHdependent structural transition of a plasmid DNA in vivo and have been observed during the initial replication of tumor viruses. 20 Therefore, dosedependent detection of polypurine tracts (PPT) in human and viral genomes can contribute to molecular diagnostics of genetic biomarkers such as the conserved PPT region of HIV-1.…”

mentioning

confidence: 99%

Optomagnetic detection of DNA triplex nanoswitches

Minero

Fock

McCaskill

et al. 2017

Analyst

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Electronic pH switching of DNA triplex reactions

Abstract: Remote electronic control of fast DNA processing reactions such as S–S-ligation is achievedviapH switching of triplex structures.

Cited by 13 publications

References 65 publications

Towards a bioelectronic computer: A theoretical study of a multi-layer biomolecular computing system that can process electronic inputs

Towards a bioelectronic computer: A theoretical study of a multi-layer biomolecular computing system that can process electronic inputs

Sequence‐specific nucleic acid mobility using a reversible block copolymer gel matrix and DNA amphiphiles (lipid‐DNA) in capillary and microfluidic electrophoretic separations

Optomagnetic detection of DNA triplex nanoswitches

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