Orthogonal Enzyme-Driven Timers for DNA Strand Displacement Reactions

Bucci, Juliette; Irmisch, Patrick; Grosso, Erica Del; Seidel, Ralf; Ricci, Francesco

doi:10.1021/jacs.2c06599

Cited by 30 publications

(24 citation statements)

References 66 publications

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“…With our prediction model, a rough estimate of displacement kinetics can be made. With a more precise kinetic predictor, it would be possible to control and alter strand displacement kinetics, for example, the release of an output strand could be precisely controlled by the addition of rationally designed interfering strands, similar as previously demonstrated in the context of timer circuits. − …”

Section: Discussionmentioning

confidence: 99%

Toehold-Mediated Strand Displacement in Random Sequence Pools

2022

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Toehold-mediated strand displacement (TMSD) has been used extensively for molecular sensing and computing in DNA-based molecular circuits. As these circuits grow in complexity, sequence similarity between components can lead to cross-talk, causing leak, altered kinetics, or even circuit failure. For small nonbiological circuits, such unwanted interactions can be designed against. In environments containing a huge number of sequences, taking all possible interactions into account becomes infeasible. Therefore, a general understanding of the impact of sequence backgrounds on TMSD reactions is of great interest. Here, we investigate the impact of random DNA sequences on TMSD circuits. We begin by studying individual interfering strands and use the obtained data to build machine learning models that estimate kinetics. We then investigate the influence of pools of random strands and find that the kinetics are determined by only a small subpopulation of strongly interacting strands. Consequently, their behavior can be mimicked by a small collection of such strands. The equilibration of the circuit with the background sequences strongly influences this behavior, leading to up to 1 order of magnitude difference in reaction speed. Finally, we compare two established and one novel technique that speed up TMSD reactions in random sequence pools: a three-letter alphabet, protection of toeholds by intramolecular secondary structure, or by an additional blocking strand. While all of these techniques were useful, only the latter can be used without sequence constraints. We expect that our insights will be useful for the construction of TMSD circuits that are robust to molecular noise.

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Section: Discussionmentioning

confidence: 99%

Toehold-Mediated Strand Displacement in Random Sequence Pools

2022

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“…[43] We envision that this approach can be employed to induce functional changes in more complex DNA structures (including origami) providing diverse clinical and sensing applications. [30,41,44] Coupling this approach with other DNA-based temporally controlled systems [45,46] could also allow for dynamic control of the decoration of structures over time and space.…”

Section: Discussionmentioning

confidence: 99%

Dynamic and Reversible Decoration of DNA‐Based Scaffolds

et al. 2023

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usually proceeds through the formation of non-covalent reversible interactions, they can also be designed to undergo a change in their structural configuration or functionality in response to multiple chemical and environmental stimuli. [15,16] Rational and programmable control of these supramolecular functional bio-scaffolds remain, however, challenging, and it is often difficult to achieve higher-order organization of multiple labeling groups in a versatile and dynamic way.Compared to other biomolecules employed for the self-assembly of structures and scaffolds, the use of synthetic DNA as a building block presents several advantages. First, the predictable and programmable nature of DNA-DNA base pairing allows the rational design of DNAbased structures with well-defined 2D and 3D geometry. [17,18] Second, the sequencespecific addressability of DNA strands together with the possibility to covalently attach different functional moieties on the backbone of a DNA oligonucleotide permits the controlled nanoscale decoration at specific locations on the DNA structure with several molecular labels. The above features have been successfully exploited in the last years to make DNA-based scaffolds decorated with a variety of different chemical and biological species such as antibodies, [19,20] signaling moieties, [21,22] aptamers, [23,24] virus capsids, [25,26] and proteins [27,28] that have found applications in bioimaging, drug delivery, and cancer therapeutics. [21,29,30] Despite the above examples clearly illustrating the versatility of synthetic DNA as building blocks to create molecular bio-scaffolds, the methods employed so far for the decoration of DNA-based assemblies often lack versatility and programmability, they are "static" and do not allow the replacement of the labels "on the fly" without prior structure disassembly. Developing novel approaches to control the decoration and labeling of DNA scaffolds with multiple functional moieties in a dynamic way will allow for achieving functional biomaterials with improved adaptability, precision, and sensing capabilities.Motivated by the above arguments, we demonstrate here a strategy to achieve dynamic and site-specific decoration of DNAbased scaffolds. To do so, we employed a model scaffold system DNA structure formed through the self-assembly of DNA tiles. More specifically, we have employed anti parallel double-crossover DNA tiles (DAE-E) formed through the hybridization of five different DNA strands. [31][32][33] These tiles display 4 singlestranded sticky ends (each of 5 nucleotides) that induce their An approach to achieving dynamic and reversible decoration of DNA-based scaffolds is demonstrated here. To do this, rationally engineered DNA tiles containing enzyme-responsive strands covalently conjugated to different molecular labels are employed. These strands are designed to be recognized and degraded by specific enzymes (i.e., Ribonuclease H, RNase H, or Uracil DNA Glycosylase, UDG) inducing their spontaneous de-hybridization from the assembled tile and rep...

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“…Enzymes in DSD computational systems can be used as regulators to control their reactions. Bucci et al (2022) designed a blocker strand that can bind to the toehold domain, which prevented the DSD reactions. Then they took two steps to recover the activity of DSD.…”

Section: Dsd Combines With Enzymesmentioning

confidence: 99%

“…DSD can be combined with other technologies and utilized in a wide range of applications. So far, DSD has been combined with CRISPR technology (Ishino et al, 1987;Montagud-Martínez et al, 2021), DNA origami (Rothemund, 2006;Zhang et al, 2022), enzymes (Bucci et al, 2022;Schaffter and Strychalski, 2022), proteins , etc. These combinations effectively expand the application scenarios for DSD.…”

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confidence: 99%

DNA strand displacement based computational systems and their applications

Wen

Song

et al. 2023

Front. Genet.

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DNA computing has become the focus of computing research due to its excellent parallel processing capability, data storage capacity, and low energy consumption characteristics. DNA computational units can be precisely programmed through the sequence specificity and base pair principle. Then, computational units can be cascaded and integrated to form large DNA computing systems. Among them, DNA strand displacement (DSD) is the simplest but most efficient method for constructing DNA computing systems. The inputs and outputs of DSD are signal strands that can be transferred to the next unit. DSD has been used to construct logic gates, integrated circuits, artificial neural networks, etc. This review introduced the recent development of DSD-based computational systems and their applications. Some DSD-related tools and issues are also discussed.

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Orthogonal Enzyme-Driven Timers for DNA Strand Displacement Reactions

Cited by 30 publications

References 66 publications

Toehold-Mediated Strand Displacement in Random Sequence Pools

Toehold-Mediated Strand Displacement in Random Sequence Pools

Dynamic and Reversible Decoration of DNA‐Based Scaffolds

DNA strand displacement based computational systems and their applications

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