Stacking nonenzymatic circuits for high signal gain

Chen, Xi; Briggs, Neima; McLain, Jeremy R.; Ellington, Andrew D.

doi:10.1073/pnas.1222807110

Cited by 231 publications

(221 citation statements)

References 29 publications

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“…Synthetic DNA contains a variety of errors, in particular deletions that result in oligonucleotides of length n-1, and such side products are typically not completely removed in PAGE or high-performance liquid chromatography (HPLC) purification procedures. Similar improvements to the ones reported here were also observed in a previous study of a catalyzed hairpin amplifier that used DNA derived from biological sources 21 .…”

Section: Discussionsupporting

confidence: 87%

“…Multiple such reactions can be chained together into multi-step reaction cascades with a high degree of control over the order and timing of individual reaction steps 3 . DNA strand displacement cascades have been used to create digital and analog molecular circuits [4][5][6][7] , switchable nanostructures [8][9][10] , autonomous molecular motors [11][12][13][14][15] , and non-covalent catalytic amplifiers 13,[16][17][18][19][20][21] . Moreover, DNA devices using strand displacement reactions can be simulated and designed for diverse applications using computer-assisted design software [22][23][24] .…”

Section: Introductionmentioning

confidence: 99%

“…Large amounts of DNA can be generated by replication in bacteria and the intrinsic proofreading abilities of living systems ensure the purity of the resulting DNA. In fact, several recent papers have recognized the potential utility of biological DNA for nanotechnology applications 21,[26][27][28] . However, the fully double-stranded nature of plasmid DNA has so far prohibited its use as a material for making dynamic DNA devices, which typically consist of multiple oligonucleotides and contain both double-stranded and single-stranded domains.…”

Section: Introductionmentioning

confidence: 99%

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Plasmid-derived DNA Strand Displacement Gates for Implementing Chemical Reaction Networks

Chen

Rao

Seelig

2015

JoVE

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DNA nanotechnology requires large amounts of highly pure DNA as an engineering material. Plasmid DNA could meet this need since it is replicated with high fidelity, is readily amplified through bacterial culture and can be stored indefinitely in the form of bacterial glycerol stocks. However, the double-stranded nature of plasmid DNA has so far hindered its efficient use for construction of DNA nanostructures or devices that typically contain single-stranded or branched domains. In recent work, it was found that nicked double stranded DNA (ndsDNA) strand displacement gates could be sourced from plasmid DNA. The following is a protocol that details how these ndsDNA gates can be efficiently encoded in plasmids and can be derived from the plasmids through a small number of enzymatic processing steps. Also given is a protocol for testing ndsDNA gates using fluorescence kinetics measurements. NdsDNA gates can be used to implement arbitrary chemical reaction networks (CRNs) and thus provide a pathway towards the use of the CRN formalism as a prescriptive molecular programming language. To demonstrate this technology, a multi-step reaction cascade with catalytic kinetics is constructed. Further it is shown that plasmid-derived components perform better than identical components assembled from synthetic DNA.

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Section: Discussionsupporting

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Plasmid-derived DNA Strand Displacement Gates for Implementing Chemical Reaction Networks

Chen

Rao

Seelig

2015

JoVE

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“…A growing set of tools for engineering in vivo RNA-based logic could be used to design these mechanisms [30][31][32][33]. In vitro, transcriptional circuits [13,34,35] or strand displacement circuits [9,36] could potentially also implement the mechanisms we describe.…”

Section: Discussionmentioning

confidence: 99%

A self-regulating biomolecular comparator for processing oscillatory signals

Agrawal

Franco

Schulman

2015

J. R. Soc. Interface.

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While many cellular processes are driven by biomolecular oscillators, precise control of a downstream on/off process by a biochemical oscillator signal can be difficult: over an oscillator's period, its output signal varies continuously between its amplitude limits and spends a significant fraction of the time at intermediate values between these limits. Further, the oscillator's output is often noisy, with particularly large variations in the amplitude. In electronic systems, an oscillating signal is generally processed by a downstream device such as a comparator that converts a potentially noisy oscillatory input into a square wave output that is predominantly in one of two well-defined on and off states. The comparator's output then controls downstream processes. We describe a method for constructing a synthetic biochemical device that likewise produces a square-wave-type biomolecular output for a variety of oscillatory inputs. The method relies on a separation of time scales between the slow rate of production of an oscillatory signal molecule and the fast rates of intermolecular binding and conformational changes. We show how to control the characteristics of the output by varying the concentrations of the species and the reaction rates. We then use this control to show how our approach could be applied to process different in vitro and in vivo biomolecular oscillators, including the p53-Mdm2 transcriptional oscillator and two types of in vitro transcriptional oscillators. These results demonstrate how modular biomolecular circuits could, in principle, be combined to build complex dynamical systems. The simplicity of our approach also suggests that natural molecular circuits may process some biomolecular oscillator outputs before they are applied downstream.

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“…Engineering synthetic signaling systems have predominantly been realized with gene expression circuits that relay molecular queues either through transcription factors or functional nucleic acids (4)(5)(6)(7)(8). Here, rational engineering strategies are supported by the modular organization and function of transcription factors and regulatory DNA elements (4), as well as the predictability of base pairing interactions (8).…”

mentioning

confidence: 99%

Protease-based synthetic sensing and signal amplification

Stein

Alexandrov

2014

Proc. Natl. Acad. Sci. U.S.A.

104

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The bottom-up design of protein-based signaling networks is a key goal of synthetic biology; yet, it remains elusive due to our inability to tailor-make signal transducers and receptors that can be readily compiled into defined signaling networks. Here, we report a generic approach for the construction of protein-based molecular switches based on artficially autoinhibited proteases. Using structure-guided design and directed protein evolution, we created signal transducers based on artificially autoinhibited proteases that can be activated following site-specific proteolysis and also demonstrate the modular design of an allosterically regulated protease receptor following recombination with an affinity clamp peptide receptor. Notably, the receptor's mode of action can be varied from >5-fold switch-OFF to >30-fold switch-ON solely by changing the length of the connecting linkers, demonstrating a high functional plasticity not previously observed in naturally occurring receptor systems. We also create an integrated signaling circuit based on two orthogonal autoinhibited protease units that can propagate and amplify molecular queues generated by the protease receptor. Finally, we present a generic two-component receptor architecture based on proximity-based activation of two autoinhibited proteases. Overall, the approach allows the design of protease-based signaling networks that, in principle, can be connected to any biological process.synthetic biology | protein engineering | protein switches | proteases A key objective in the emerging field of synthetic biology is to develop approaches for the systematic engineering of artificial signal transduction systems (1, 2), which is expected to advance our understanding of fundamental biological processes and create new biotechnological and medical applications (3). Engineering synthetic signaling systems have predominantly been realized with gene expression circuits that relay molecular queues either through transcription factors or functional nucleic acids (4-8). Here, rational engineering strategies are supported by the modular organization and function of transcription factors and regulatory DNA elements (4), as well as the predictability of base pairing interactions (8). However, transcription-based signaling circuits usually require hours to process and actuate a specific molecular queue (9). Further, the limited chemical diversity of nucleic acids compared with amino acids ultimately restricts their functionality. Thus, protein-based signaling networks that operate faster compared with gene-based signaling circuits are highly desirable.The systematic engineering of protein-based modules that sense, process, and amplify defined molecular queues has provided a formidable challenge to date. At the molecular level, many biological response functions depend on allosterically regulated protein activities that couple an input to an output function solely through conformational changes. Engineering these has proven difficult with only a few successful designs reported to ...

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Stacking nonenzymatic circuits for high signal gain

Cited by 231 publications

References 29 publications

Plasmid-derived DNA Strand Displacement Gates for Implementing Chemical Reaction Networks

Plasmid-derived DNA Strand Displacement Gates for Implementing Chemical Reaction Networks

A self-regulating biomolecular comparator for processing oscillatory signals

Protease-based synthetic sensing and signal amplification

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