Programmable assembly of pressure sensors using pattern-forming bacteria

Cao, Yangxiaolu; Feng, Yi; Ryser, Marc D.; Zhu, Kui; Herschlag, Gregory; Cao, Changyong; Marusak, Katherine E.; Zauscher, Stefan; Li, You

doi:10.1038/nbt.3978

Cited by 111 publications

(116 citation statements)

References 66 publications

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“…Future work will reveal if the TS properties are conserved when incorporated in more complex (synthetic) gene regulatory networks, for example when combined with the repressilator (Elowitz and Leibler, 2000, Potvin-Trottier et al, 2016, Santos-Moreno and Schaerli, 2019a to yield the AC-DC network (Perez-Carrasco et al, 2018, Verd et al, 2019, Balaskas et al, 2012, Panovska-Griffiths et al, 2013. Moreover, the here established engineering guidelines on how to control patterning with a synthetic TS will be valuable for future synthetic pattern formation, for example in the context of engineered living materials based on bacterial biofilms (Gilbert and Ellis, 2018, Nguyen et al, 2018, Moser et al, 2019, Cao et al, 2017.…”

Section: Discussionmentioning

confidence: 99%

“…The rise of synthetic biology has successfully allowed to build synthetic systems able to explore core patterning principles (reviewed in (Santos-Moreno and Schaerli, 2019b, Luo et al, 2019, Davies, 2017, Ebrahimkhani and Ebisuya, 2019). In addition, synthetic pattern formation is also an attractive technology for the engineering of living materials (Gilbert and Ellis, 2018, Nguyen et al, 2018, Moser et al, 2019, Cao et al, 2017 and tissues (Davies and Cachat, 2016, Healy and Deans, 2019, Webster et al, 2016.…”

Section: Introductionmentioning

confidence: 99%

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Controlling spatiotemporal pattern formation in a concentration gradient with a synthetic toggle switch

Barbier

Pérez-Carrasco

Schaerli

2019

Preprint

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The formation of spatiotemporal patterns of gene expression is frequently guided by gradients of diffusible signaling molecules. The toggle switch subnetwork, composed of two cross-repressing transcription factors, is a common component of gene regulatory networks in charge of patterning, converting the continuous information provided by the gradient into discrete abutting stripes of gene expression. We present a synthetic biology framework to understand and characterize the spatiotemporal patterning properties of the toggle switch. To this end, we built a synthetic toggle switch controllable by diffusible molecules in Escherichia coli. We analyzed the patterning capabilities of the circuit by combining quantitative measurements with a mathematical reconstruction of the underlying dynamical system. The toggle switch can produce robust patterns with sharp boundaries, governed by bistability and hysteresis. We further demonstrate how the hysteresis, position, timing, and precision of the boundary can be controlled, highlighting the dynamical flexibility of the circuit.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Controlling spatiotemporal pattern formation in a concentration gradient with a synthetic toggle switch

Barbier

Pérez-Carrasco

Schaerli

2019

Preprint

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“…Curli fiber synthesis has been previously placed under the control of genetic sensors and circuits. The control of CsgA by chemical inducers and cell–cell communication signals has been used to change the content of alternative subunits within curli fibers and to promote the self‐assembly of conductive fibers to form a pressure sensing device . Various optogenetic tools have also been used to toggle cell adhesion, disrupt biofilms of medical interest, and to pattern biofilms at high resolution on a 2D surface …”

Section: Introductionmentioning

confidence: 99%

Light‐Controlled, High‐Resolution Patterning of Living Engineered Bacteria Onto Textiles, Ceramics, and Plastic

Moser

Tham

González

et al. 2019

Adv Funct Materials

101

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Living cells can impart materials with advanced functions, such as senseand-respond, chemical production, toxin remediation, energy generation and storage, self-destruction, and self-healing. Here, an approach is presented to use light to pattern Escherichia coli onto diverse materials by controlling the expression of curli fibers that anchor the formation of a biofilm. Different colors of light are used to express variants of the structural protein CsgA fused to different peptide tags. By projecting color images onto the material containing bacteria, this system can be used to pattern the growth of composite materials, including layers of protein and gold nanoparticles. This is used to pattern cells onto materials used for 3D printing, plastics (polystyrene), and textiles (cotton). Further, the adhered cells are demonstrated to respond to sensory information, including small molecules (IPTG and DAPG) and light from light-emitting diodes. This work advances the capacity to engineer responsive living materials in which cells provide diverse functionality.

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“…Lingchong You and his co-workers at Duke University have used it to assemble pressure sensors. 21 They programmed their curli-making bacteria by engineering a gene circuit to self-assemble into a three-dimensional shape on a porous membrane that dictated the structure of the curli biofilm and the inorganic components it templated. They used inkjet printing to create an array of bacterial colonies on the membrane, each of which grew into a hemispherical shape covered by a dome of curli fibrils to which gold nanoparticles could be attached.…”

Section: Managing Many Scalesmentioning

confidence: 99%

Synthetic biology—Engineering nature to make materials

Ball¹

2018

MRS Bull.

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Programmable assembly of pressure sensors using pattern-forming bacteria

Cited by 111 publications

References 66 publications

Controlling spatiotemporal pattern formation in a concentration gradient with a synthetic toggle switch

Controlling spatiotemporal pattern formation in a concentration gradient with a synthetic toggle switch

Light‐Controlled, High‐Resolution Patterning of Living Engineered Bacteria Onto Textiles, Ceramics, and Plastic

Synthetic biology—Engineering nature to make materials

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