From DNA Nanotechnology to Material Systems Engineering

Hu, Yong; Niemeyer, Christof M.

doi:10.1002/adma.201806294

Cited by 130 publications

(102 citation statements)

References 265 publications

(256 reference statements)

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“…For example, chemical modification of the effective valence of one component to change into or out of a magic-ratio condition could shift the phase boundary as a possible means of condensate regulation [5]. Magic-ratio effects could also manifest in other experimental systems, such as non-biological polymers, DNA origami [21], or patchy colloid systems [22]. As an inverse problem, the magic-ratio effect could be exploited to determine the relative valence of associating biomolecules by measuring their phase diagram.…”

Section: Discussionmentioning

confidence: 99%

Decoding the physical principles of two-component biomolecular phase separation

Zhang

Weiner

Meir

et al. 2020

Preprint

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Cells possess a multiplicity of non-membrane bound compartments, which form via liquid-liquid phase separation. These condensates assemble and dissolve as needed to enable central cellular functions. One important class of condensates is those composed of two associating polymer species that form one-to-one specific bonds. What are the physical principles that underlie phase separation in such systems? To address this question, we employed coarse-grained molecular dynamics simulations to examine how the phase boundaries depend on polymer valence, stoichiometry, and binding strength. We discovered a striking phenomenon -- for sufficiently strong binding, phase separation is suppressed at rational polymer stoichiometries, which we termed the magic-ratio effect. We further developed an analytical dimer-gel theory that confirmed the magic-ratio effect and disentangled the individual roles of polymer properties in shaping the phase diagram. Our work provides new insights into the factors controlling the phase diagrams of biomolecular condensates, with implications for natural and synthetic systems.

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Section: Discussionmentioning

confidence: 99%

Decoding the physical principles of two-component biomolecular phase separation

Zhang

Weiner

Meir

et al. 2020

Preprint

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“…This programmability of the polymer backbone, which can be tailored by targeted sequence design over several size scales from the lower nanometer to the upper micrometer range, offers unique advantages over synthetic polymers and thus far-reaching perspectives for the use of DNA material systems to control living organisms. 2,30 With regard to the exoelectrogenic bacteria investigated here, possible applications go beyond the currently intensively researched biosensor and fuel cell systems. For example, the cultivation of biofilms in microfluidic systems is making substantial progress 31 and this technological platform is also being used for research into supramolecular and dissipative material systems.…”

Section: Discussionmentioning

confidence: 99%

Cultivation of Exoelectrogenic Bacteria in Conductive DNA Nanocomposite Hydrogels Yields a Programmable Biohybrid Materials System

Rehnlund

Klein

et al. 2019

Preprint

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The use of living microorganisms integrated within electrochemical devices is an expanding field of research, with applications in microbial fuel cells, microbial biosensors or bioreactors. We describe the use of porous nanocomposite materials prepared by DNA polymerization of carbon nanotubes (CNT) and silica nanoparticles (SiNP) for the construction of a programmable biohybrid system containing the exoelectrogenic bacterium Shewanella oneidensis. We initially demonstrate the electrical conductivity of the CNT-containing DNA composite by employment of chronopotentiometry, electrochemical impedance spectroscopy, and cyclic voltammetry. Cultivation of Shewanella oneidensis in these materials shows that the exoelectrogenic bacteria populate the matrix of the composite, while non-exoelectrogenic Escherichia coli remain on its surface. Moreover, the ability to use extracellular electron transfer pathways is positively correlated with number of cells within the conductive synthetic biofilm matrix. The Shewanella containing composite remains stable for several days. Programmability of this biohybrid material system is demonstrated by on-demand release and degradation induced by a short-term enzymatic stimulus. The perspectives of this approach for technical applications are being discussed.

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“…The sequence‐specific binding properties of nucleic acids have been exploited over the past 35 years to establish the field of DNA nanotechnology, which has developed into a highly innovative and lively field of research at the interface of chemistry, materials science, biotechnology, and nanotechnology . At present, it is becoming clearly evident that the various sub‐disciplines of DNA nanotechnology, ranging from pure “structural DNA nanotechnology” over protein DNA assemblies, nanoparticle‐based DNA materials, and DNA polymers to DNA surface technology, are growing ever closer together to create functional devices for applications in the bio‐ and materials sciences . However, there is still a great need for methodological approaches to bridge the size regime of individual DNA nanostructures with that of micrometer‐ and millimeter‐sized units for real‐world applications.…”

Section: Figurementioning

confidence: 99%

Bottom‐Up Assembly of DNA–Silica Nanocomposites into Micrometer‐Sized Hollow Spheres

Grösche

Sheshachala

et al. 2019

Angewandte Chemie

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Although DNA nanotechnology has developed into a highly innovative and lively field of research at the interface between chemistry, materials science, and biotechnology, there is still a great need for methodological approaches for bridging the size regime of DNA nanostructures with that of micrometer‐ and millimeter‐sized units for practical applications. We report on novel hierarchically structured composite materials from silica nanoparticles and DNA polymers that can be obtained by self‐assembly through the clamped hybridization chain reaction. The nanocomposite materials can be assembled into thin layers within microfluidically generated water‐in‐oil droplets to produce mechanically stabilized hollow spheres with uniform size distributions at high throughput rates. The fact that cells can be encapsulated in these microcontainers suggests that our concept not only contributes to the further development of supramolecular bottom‐up manufacturing, but can also be exploited for applications in the life sciences.

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From DNA Nanotechnology to Material Systems Engineering

Cited by 130 publications

References 265 publications

Decoding the physical principles of two-component biomolecular phase separation

Decoding the physical principles of two-component biomolecular phase separation

Cultivation of Exoelectrogenic Bacteria in Conductive DNA Nanocomposite Hydrogels Yields a Programmable Biohybrid Materials System

Bottom‐Up Assembly of DNA–Silica Nanocomposites into Micrometer‐Sized Hollow Spheres

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