2014
DOI: 10.1021/ja500619w
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Programmable pH-Triggered DNA Nanoswitches

Abstract: ABSTRACT:Here we have rationally designed a tunable DNA-based nanoswitch whose closing/opening can be triggered over specific different pH windows. This nanoswitch forms an intramolecular triplex DNA structure through pH-sensitive parallel Hoogsteen interactions. We demonstrate that by simply changing the relative content of TAT/CGC triplets in the switch we can rationally tune its pH-dependence over more than 5 pH units. By using a combination of such nanowitches with different pH sensitivity, we also demonst… Show more

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Cited by 324 publications
(391 citation statements)
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References 68 publications
(102 reference statements)
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“…In response to this limitation, we demonstrate here that simulative approaches can help in the optimization of DNA-based nanodevices controlled by pH changes that have been recently proposed for both diagnostic and drug-delivery applications. 20,23,24 Moreover, the simulation approaches we have employed here might help in the characterization of response time and prediction of the effect of environmental conditions which obviously represent crucial factors in the performance of such DNAbased tools. Finally, we note that, while we have focused here on DNA-based switches controlled by pH, the applicability of simulation approaches in the field of DNA nanotechnology could be expanded to other noncanonical DNA structures (i.e., i-motif, G-quadruplex, etc.…”
Section: ■ Conclusionmentioning
confidence: 99%
“…In response to this limitation, we demonstrate here that simulative approaches can help in the optimization of DNA-based nanodevices controlled by pH changes that have been recently proposed for both diagnostic and drug-delivery applications. 20,23,24 Moreover, the simulation approaches we have employed here might help in the characterization of response time and prediction of the effect of environmental conditions which obviously represent crucial factors in the performance of such DNAbased tools. Finally, we note that, while we have focused here on DNA-based switches controlled by pH, the applicability of simulation approaches in the field of DNA nanotechnology could be expanded to other noncanonical DNA structures (i.e., i-motif, G-quadruplex, etc.…”
Section: ■ Conclusionmentioning
confidence: 99%
“…DNA switches have been designed that open and close depending on pH. 79 These switches operate based on Hoogsteen base pairing (an alternative type to Watson-Crick) and can be tuned to respond to a wide pH range of 6.5 to 10.2, depending on the amount of TAT/CGC triplets present in the sequence. The switches demonstrated an extremely fast response time (o100 ms) and could potentially be incorporated into larger nanomachines to trigger response to external stimuli.…”
Section: Dna Nanomachinesmentioning
confidence: 99%
“…Such stem-loop configurations can also be used to monitor global environmental changes such as changes in temperature by using a fluorophore-quencher pair on the ends of the strands. Biosensors for other stimuli such as pH changes are based on structures that involve triplex [17] (Figure 1(c)), i-motif formation [18] (Figure 1(d)), or poly-dA helix formation (Figure 1(e)) [19], all of which are 2 Journal of Nanomaterials sequence-specific and occur under acidic conditions. Gquadruplex formation is another sequence-specific conformational change that forms under specific ionic conditions such as the presence of K + or Na + [20] (Figure 1(f)).…”
Section: Dna Nanostructures For Biosensingmentioning
confidence: 99%
“…A similar example used a graphene surface instead of gold and worked on the basis of pHdependent triplex formation [31]. In addition, solution-based triplex-forming nanoswitches have also been developed for pH detection [17]. This switch was designed so that the fluorophore-quencher pair remains closer when the switch forms a triplex, acting as an indicator of the pH range.…”
Section: Fluorescence-basedmentioning
confidence: 99%