A molecular multi-gene classifier for disease diagnostics

Lopez, Randolph; Wang, Ruofan; Seelig, Georg

doi:10.1038/s41557-018-0056-1

Cited by 118 publications

(92 citation statements)

References 42 publications

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“…However, the sequences that we used are short and unstructured, while biological sequences usually have significant intrinsic secondary structures, which could affect desired kinetic behavior (54) or impose sequence constraints and limit the design space. Despite these challenges, there is a body of work demonstrating strand displacement cascades with natural DNA and RNA inputs, including logic computation both in vitro (9) and in vivo (25), a molecular multigene classifier (21), regulation of cellular gene expression (26,27), and in situ fluorescence imaging of mRNA expression (55). Destabilizing organic solvents (56) and the hybridization probe method (21) can be generally adopted to overcome secondary structure in strand displacement.…”

Section: Discussionmentioning

confidence: 99%

“…Strand displacement reactions underlie molecular motors (4,6), robots (7,8), logic circuits capable of signal restoration, amplification, digital (9,10) and neural network-like computation (11), and controllers that implement prescribed time-varying dynamics (12,13) based on a systematic theory (14,15). Strand displacement-based molecular amplifiers (16)(17)(18)(19) are not only an essential component for signal restoration in digital circuits but also, useful for diagnostic applications (20,21). The successful implementation of synthetic cell-free systems also leads to additional applications at the interface with biology: nucleic acid-based nanodevices have been delivered in vivo (22) as imaging probes (23) or to perform logical computation (24,25).…”

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confidence: 99%

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Effective design principles for leakless strand displacement systems

Wang

Thachuk

Ellington

et al. 2018

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

102

149

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Artificially designed molecular systems with programmable behaviors have become a valuable tool in chemistry, biology, material science, and medicine. Although information processing in biological regulatory pathways is remarkably robust to error, it remains a challenge to design molecular systems that are similarly robust. With functionality determined entirely by secondary structure of DNA, strand displacement has emerged as a uniquely versatile building block for cell-free biochemical networks. Here, we experimentally investigate a design principle to reduce undesired triggering in the absence of input (leak), a side reaction that critically reduces sensitivity and disrupts the behavior of strand displacement cascades. Inspired by error correction methods exploiting redundancy in electrical engineering, we ensure a higher-energy penalty to leak via logical redundancy. Our design strategy is, in principle, capable of reducing leak to arbitrarily low levels, and we experimentally test two levels of leak reduction for a core “translator” component that converts a signal of one sequence into that of another. We show that the leak was not measurable in the high-redundancy scheme, even for concentrations that are up to 100 times larger than typical. Beyond a single translator, we constructed a fast and low-leak translator cascade of nine strand displacement steps and a logic OR gate circuit consisting of 10 translators, showing that our design principle can be used to effectively reduce leak in more complex chemical systems.

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Effective design principles for leakless strand displacement systems

Wang

Thachuk

Ellington

et al. 2018

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

102

149

View full text Add to dashboard Cite

show abstract

“…29,[34][35][36][37] Toehold-mediated DNA strand displacement has proved to be a convenient framework for implementing complex reaction sequences using synthetic DNA in well-mixed test tubes. 38,39 Using the principles of strand displacement, researchers have created sophisticated reaction networks that perform computation like neural networks, 40,41 diagnostic classifiers, 42 dynamic 3D nanostructures 43,44 and even approximate the dynamics of formal, mathematically specified chemical reaction networks (CRNs). [45][46][47][48] Building on these results, theoretical work has argued that a wide range of patterns is achievable if DNA-based CRNs are embedded in a spatial reactor.…”

Section: Introductionmentioning

confidence: 99%

Programmable patterns in a DNA-based reaction–diffusion system

Chen

Seelig

2020

Soft Matter

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“…This important feature could, for example, aid the design of multi-layer DNA-based winner-take-all circuits 47 capable of classifying complex information patterns. Such circuits would be highly valuable in disease diagnostics 48 .…”

Section: Discussionmentioning

confidence: 99%

Distributed DNA-based Communication in Populations of Synthetic Protocells

Joesaar

Yang

Bögels

et al. 2019

Preprint

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Developing distributed communication platforms based on orthogonal molecular communication channels is a crucial step towards engineering artificial multicellular systems. Here, we present a general and scalable platform entitled 'Biomolecular Implementation of Protocellular Communication' (BIO-PC) to engineer distributed multichannel molecular communication between populations of non-lipid semipermeable microcapsules. Our method leverages the modularity and scalability of enzyme-free DNA strand-displacement circuits to develop protocellular consortia that can sense, process and respond to DNA-based messages. We engineer a rich variety of biochemical communication devices capable of cascaded amplification, bidirectional communication and distributed computational operations. Encapsulating DNA strand-displacement circuits further allows their use in concentrated serum where non-compartmentalized DNA circuits cannot operate. BIO-PC enables reliable execution of distributed DNA-based molecular programs in biologically relevant environments and opens new directions in DNA computing and minimal cell technology.Living cells communicate by secreting diffusible signaling molecules that activate key molecular processes in neighboring cells 1,2 . These molecular communication channels facilitate information distribution among cells, enabling collective information processing functions that cannot be achieved by cells in isolation 3,4 . Synthetic biologists have advanced the engineering of synthetic cell-cell communication systems based on living cells resulting in multicellular consortia capable of complex sender-receiving functions 5-9 , bidirectional 10,11 and synchronized 12 communication and distributed computations 13,14 . However, engineering synthetic gene networks in living cells remains challenging due to the large number of context dependent effects arising from, among others, competition between shared resources and loading effects 15 . In contrast, developing molecular communication channels among abiotic synthetic protocell compartments has received much less attention than in living systems 16,17 . Due to their minimalistic design, engineering distributed information processing functions in fully synthetic multicellular communities has several advantages including a high degree of control and reduced design-build-test cycles. Abiotic protocellular consortia, based on lipid or non-lipid compartments and wired by orthogonal information channels, would thus present a versatile technology for the bottom-up construction of complex cell-population behaviors 18,19,20 . Although some elegant strategies to achieve one-way intercellular communication in fully synthetic protocellular systems have been reported 21,22,23,24 , a scalable methodology for implementing distributed functions involving bidirectional communication across populations of protocells is currently lacking.Here, we present Biomolecular Implementation of Protocellular Communication (BIO-PC), a highly programmable protocellular messaging system that ena...

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A molecular multi-gene classifier for disease diagnostics

Cited by 118 publications

References 42 publications

Effective design principles for leakless strand displacement systems

Effective design principles for leakless strand displacement systems

Programmable patterns in a DNA-based reaction–diffusion system

Distributed DNA-based Communication in Populations of Synthetic Protocells

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