Programming
            <i>Escherichia coli</i>
            to function as a digital display

Shin, Jinwoo; Zhang, Shuyi; Der, Bryan S.; Nielsen, Alec A. K.; Voigt, Christopher A.

doi:10.15252/msb.20199401

Cited by 64 publications

(109 citation statements)

References 62 publications

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“…Indeed, this design has several problems that are exacerbated when carried on the genome. The first is that the upstream promoter is inhibited by the binding of repressor to the downstream promoter ("roadblocking"), which is more problematic at lower copy number (Nielsen et al, 2016;Shin et al, 2020). In addition, maximum repressor expression is less than the sum of the input promoter activities.…”

Section: Nor Gate Design For the Genomementioning

confidence: 99%

“…Each circuit was designed to produce the same 3-input logic operation, encoded using Verilog, but different UCFs were used to map the circuit to a DNA sequence. The first was designed using the Eco1C2G2T2 UCF for the p15a plasmid in E. coli DH10b and was published previously (Nielsen et al, 2016;Shin et al, 2020). The second was designed using the Eco2C1G3T1 for the E. coli MG1655 genome.…”

Section: Evolutionary Stability and Total Rnap Fluxmentioning

confidence: 99%

“…Genetic circuits were first split and cloned into two plasmids, plYJP066 (KanR) and plYJP070 (CmR), that target Landing Pads #1 and #2, respectively, using Type II assembly as previously described (Nielsen et al, 2016;Shin et al, 2020). The order of transcription units within a circuit was assigned by Cello 2.0 based on EUGENE rules.…”

Section: Genetic Circuit Constructionmentioning

confidence: 99%

“…The plasmid-encoded 0xF1 circuit was designed using the UCF for the p15a plasmid (Eco1C2G2T2) and was constructed in E. coli DH10b (Nielsen et al, 2016;Shin et al, 2020). The E. coli MG1655 strain harboring the genome-encoded 0xF1 circuit was streaked on LB agar (2%) plates with Kan (50 lg/ml) and Cm (35 lg/ml) antibiotics and grown overnight.…”

Section: Long Term Stability Testmentioning

confidence: 99%

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P recision design of stable genetic circuits carried in highly‐insulated E. coli genomic landing pads

Park

Borujeni

Gorochowski

et al. 2020

Molecular Systems Biology

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Genetic circuits have many applications, from guiding living therapeutics to ordering process in a bioreactor, but to be useful they have to be genetically stable and not hinder the host. Encoding circuits in the genome reduces burden, but this decreases performance and can interfere with native transcription. We have designed genomic landing pads in Escherichia coli at high‐expression sites, flanked by ultrastrong double terminators. DNA payloads >8 kb are targeted to the landing pads using phage integrases. One landing pad is dedicated to carrying a sensor array, and two are used to carry genetic circuits. NOT/NOR gates based on repressors are optimized for the genome and characterized in the landing pads. These data are used, in conjunction with design automation software (Cello 2.0), to design circuits that perform quantitatively as predicted. These circuits require fourfold less RNA polymerase than when carried on a plasmid and are stable for weeks in a recA+ strain without selection. This approach enables the design of synthetic regulatory networks to guide cells in environments or for applications where plasmid use is infeasible.

show abstract

Section: Nor Gate Design For the Genomementioning

confidence: 99%

Section: Evolutionary Stability and Total Rnap Fluxmentioning

confidence: 99%

Section: Genetic Circuit Constructionmentioning

confidence: 99%

Section: Long Term Stability Testmentioning

confidence: 99%

See 2 more Smart Citations

P recision design of stable genetic circuits carried in highly‐insulated E. coli genomic landing pads

Park

Borujeni

Gorochowski

et al. 2020

Molecular Systems Biology

Self Cite

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show abstract

“…This in turn can be used as the input for another node of the circuit and so on 2,3 . Further abstraction of biological circuits as wholes of Boolean logic gates enables a superior level of complexity, as shown by a suite of examples involving rewiring of stress responses, detection of environmental contaminants, implementation of cellular calculators and others [4][5][6][7] . Yet, as the demand for increasingly complex circuits grows 5,8,9 , so does the interest in automation of their design and execution.…”

mentioning

confidence: 99%

A standardized broad host range inverter package for genetic circuitry design in Gram-negative bacteria

Tas

Goñi-Moreno

2020

Preprint

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Genetically encoded logic gates, especially inverters NOT gates are the building blocks for designing circuits, engineering biosensors or decision-making devices in synthetic biology. However, the repertoire of inverters readily available for different species is rather limited. In this work, a large whole of NOT gates that was shown to function previously in a specific strain of Escherichia coli, was recreated as broad host range (BHR) collection of constructs assembled in low, medium and high copy number plasmid backbones of the SEVA (Standard European Vector Architecture) collection. The input/output function of each of the gates was characterized and parameterized in the environmental bacterium and metabolic engineering chassis Pseudomonas putida. Comparisons of the resulting fluorescence cytometry data with those published for the same gates in Escherichia coli provided useful hints on the portability of the corresponding gates. The hereby described BHR inverter package (20 different versions of 12 distinct gates) thus becomes a toolbox of choice for designing genetic circuitries in a variety of Gram-negative species other than E. coli.

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Functional predictability of universal gene circuits in diverse microbial hosts

Qin,

Xu,

Zhao

et al. 2024

Quant. Biol.

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Although the principles of synthetic biology were initially established in model bacteria, microbial producers, extremophiles and gut microbes have now emerged as valuable prokaryotic chassis for biological engineering. Extending the host range in which designed circuits can function reliably and predictably presents a major challenge for the concept of synthetic biology to materialize. In this work, we systematically characterized the cross‐species universality of two transcriptional regulatory modules—the T7 RNA polymerase activator module and the repressors module—in three non‐model microbes. We found striking linear relationships in circuit activities among different organisms for both modules. Parametrized model fitting revealed host non‐specific parameters defining the universality of both modules. Lastly, a genetic NOT gate and a band‐pass filter circuit were constructed from these modules and tested in non‐model organisms. Combined models employing host non‐specific parameters were successful in quantitatively predicting circuit behaviors, underscoring the potential of universal biological parts and predictive modeling in synthetic bioengineering.

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Programming Escherichia coli to function as a digital display

Cited by 64 publications

References 62 publications

P recision design of stable genetic circuits carried in highly‐insulated E. coli genomic landing pads

P recision design of stable genetic circuits carried in highly‐insulated E. coli genomic landing pads

A standardized broad host range inverter package for genetic circuitry design in Gram-negative bacteria

Functional predictability of universal gene circuits in diverse microbial hosts

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