Programming Cell-Free Biosensors with DNA Strand Displacement Circuits

Jung, Jaeyoung K.; Kk, Alam; Lucks, Julius B.

doi:10.1101/2021.03.16.435693

Cited by 5 publications

(4 citation statements)

References 57 publications

(74 reference statements)

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“…On the basis of previous works on minimalist RNA-based circuits 28 and theoretical modeling of an RNA-based toggle switch, 32 we demonstrated the behavior of this specific network in vitro and highlighted the potential for implementing this network in living cells and other in vitro applications. 20 , 21 Degrading conditions are closer to how the circuit would behave in a cellular environment and can help to understand its performance in that context. The next step would be testing the RNA-based toggle switch in more cell-like conditions such as cell lysates.…”

Section: Resultsmentioning

confidence: 99%

“…In vitro transcription systems have become an attractive alternative not only to construct and characterize biological circuits without involving the complexities of living systems, but also for other applications such as diagnosis. 20,21 With full control over the concentrations and stoichiometries of each component, these platforms are ideal for the rapid prototyping of genetic circuit designs as well as for developing mathematical models to characterize these systems and help fine-tune their design. 22,23 The most commonly used enzymes for in vitro transcription systems are bacteriophage RNA polymerases due to their high processivity for catalyzing the formation of RNA from DNA templates.…”

Section: ■ Introductionmentioning

confidence: 99%

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Building an RNA-Based Toggle Switch Using Inhibitory RNA Aptamers

et al. 2022

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Synthetic RNA systems offer unique advantages such as faster response, increased specificity, and programmability compared to conventional protein-based networks. Here, we demonstrate an in vitro RNA-based toggle switch using RNA aptamers capable of inhibiting the transcriptional activity of T7 or SP6 RNA polymerases. The activities of both polymerases are monitored simultaneously by using Broccoli and malachite green light-up aptamer systems. In our toggle switch, a T7 promoter drives the expression of SP6 inhibitory aptamers, and an SP6 promoter expresses T7 inhibitory aptamers. We show that the two distinct states originating from the mutual inhibition of aptamers can be toggled by adding DNA sequences to sequester the RNA inhibitory aptamers. Finally, we assessed our RNA-based toggle switch in degrading conditions by introducing controlled degradation of RNAs using a mix of RNases. Our results demonstrate that the RNA-based toggle switch could be used as a control element for nucleic acid networks in synthetic biology applications.

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Section: Resultsmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

Building an RNA-Based Toggle Switch Using Inhibitory RNA Aptamers

et al. 2022

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“…Circuits could then respond multiple times to changing input signals, overcoming a current limitation in DNA computing (11,19). Additionally, regulating input production with allosteric transcription factors allows ctRSD circuits that process non-nucleic acid inputs to be readily developed for smart diagnostics (30,31). Finally, the ability to transcriptionally encode strand displacement components in DNA plasmids allows nucleic acid computing to be employed in a number of new environments where DNA computing is limited due to degradation ( 16), e.g.…”

Section: Discussionmentioning

confidence: 99%

“…Further, ctRSD circuits are designed so that state-of-the-art DNA-based circuits capable of neural network computations and pattern recognition (4, 6) could be directly adopted. ctRSD should enable the power of TMSD circuits to be realized in biological systems for smart diagnostics or sensors (6,30,31). Ultimately, ctRSD circuits could be genetically encoded and continuously operated inside living cells.…”

Section: Introductionmentioning

confidence: 99%

Co-transcriptional RNA strand displacement circuits

Schaffter

Strychalski

2021

Preprint

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Engineered molecular circuits that process information in biological systems could address emerging human health and biomanufacturing needs. However, such circuits can be difficult to rationally design and scale. DNA-based strand displacement reactions have demonstrated the largest and most computationally powerful molecular circuits to date but are limited in biological systems due to the difficulty in genetically encoding components. Here, we develop scalable co-transcriptional RNA strand displacement (ctRSD) circuits that are rationally programmed via base pairing interactions. ctRSD addresses the limitations of DNA-based strand displacement circuits by isothermally producing circuit components via transcription. We demonstrate the programmability of ctRSD in vitro by implementing logic and amplification elements, and multi-layer signaling cascades. Further, we show ctRSD kinetics are accurately predicted by a simple model of coupled transcription and strand displacement, enabling model-driven design. We envision ctRSD will enable rational design of powerful molecular circuits that operate in biological systems, including living cells.

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Programming cell-free biosensors with DNA strand displacement circuits

Jung

Archuleta

Alam³

et al. 2022

Nat Chem Biol

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Cell-free biosensors are powerful platforms for monitoring human and environmental health. Here, we expand their capabilities by interfacing them with toehold-mediated strand displacement circuits, a dynamic DNA nanotechnology that enables molecular computation through programmable interactions between nucleic acid strands. We develop design rules for interfacing a small molecule sensing platform called ROSALIND with toehold-mediated strand displacement to construct hybrid RNA–DNA circuits that allow fine-tuning of reaction kinetics. We use these design rules to build 12 different circuits that implement a range of logic functions (NOT, OR, AND, IMPLY, NOR, NIMPLY, NAND). Finally, we demonstrate a circuit that acts like an analog-to-digital converter to create a series of binary outputs that encode the concentration range of the molecule being detected. We believe this work establishes a pathway to create ‘smart’ diagnostics that use molecular computations to enhance the speed and utility of biosensors.

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Programming Cell-Free Biosensors with DNA Strand Displacement Circuits

Cited by 5 publications

References 57 publications

Building an RNA-Based Toggle Switch Using Inhibitory RNA Aptamers

Building an RNA-Based Toggle Switch Using Inhibitory RNA Aptamers

Co-transcriptional RNA strand displacement circuits

Programming cell-free biosensors with DNA strand displacement circuits

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