Predicting Transcriptional Output of Synthetic Multi-input Promoters

Zong, David; Cinar, Selahittin; Shis, David L.; Josić, Krešimir; Ott, William; Bennett, Matthew R.

doi:10.1021/acssynbio.8b00165

Cited by 15 publications

(24 citation statements)

References 45 publications

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“…However, recent advances in cell‐free methodologies such as the use of degradation tags or continuous exchange of reaction contents would provide a better mimic of in vivo processes while maintaining the simplicity of the in vitro format (Niederholtmeyer et al , ; Garamella et al , ; Swank et al , ). Such approaches could also expedite the characterization of promoters controlled by multiple regulators (Belliveau et al , ) and facilitate their integration into complex regulatory networks (Chen et al , ; Zong et al , ). Transcriptional profiles of entire genetic circuits could also be characterized in cell‐free reactions using whole‐transcriptome library preparation methods, which have been employed in vivo to aid debugging of individual components and dynamic circuit behaviors (Gorochowski et al , ).…”

Section: Discussionmentioning

confidence: 99%

Multiplex transcriptional characterizations across diverse bacterial species using cell‐free systems

Yim

Johns

Park

et al. 2019

Molecular Systems Biology

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Cell‐free expression systems enable rapid prototyping of genetic programs in vitro . However, current throughput of cell‐free measurements is limited by the use of channel‐limited fluorescent readouts. Here, we describe DNA Regulatory element Analysis by cell‐Free Transcription and Sequencing ( DRAFTS ), a rapid and robust in vitro approach for multiplexed measurement of transcriptional activities from thousands of regulatory sequences in a single reaction. We employ this method in active cell lysates developed from ten diverse bacterial species. Interspecies analysis of transcriptional profiles from > 1,000 diverse regulatory sequences reveals functional differences in promoter activity that can be quantitatively modeled, providing a rich resource for tuning gene expression in diverse bacterial species. Finally, we examine the transcriptional capacities of dual‐species hybrid lysates that can simultaneously harness gene expression properties of multiple organisms. We expect that this cell‐free multiplex transcriptional measurement approach will improve genetic part prototyping in new bacterial chassis for synthetic biology.

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Section: Discussionmentioning

confidence: 99%

Multiplex transcriptional characterizations across diverse bacterial species using cell‐free systems

Yim

Johns

Park

et al. 2019

Molecular Systems Biology

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“…An example of such a prediction is shown in Fig 1C (yellow lines) and compared to experimental data obtained when the circuit is constructed. This was repeated for the complete set of 20 circuits (20 × 4 = 80 predictions), and the data are plotted in Fig 1D and Appendix Fig S4. Promoters in series, even when spatially separated, have the potential for transcriptional interference, where one has a suppressive effect on the other (Sneppen et al, 2005;Hao et al, 2017;Zong et al, 2018). Notably, when a repressor is bound tightly to its operator and has a slow off-rate relative to the RNAP elongation rate, RNAPs originating upstream may not be able to dislodge it, referred to as "roadblocking" (Deuschle et al, 1986;Sellitti et al, 1987;Ahlgren-Berg et al, 2016).…”

Section: Resultsmentioning

confidence: 99%

“…Promoters in series, even when spatially separated, have the potential for transcriptional interference, where one has a suppressive effect on the other (Sneppen et al , ; Hao et al , ; Zong et al , ). Notably, when a repressor is bound tightly to its operator and has a slow off‐rate relative to the RNAP elongation rate, RNAPs originating upstream may not be able to dislodge it, referred to as “roadblocking” (Deuschle et al , ; Sellitti et al , ; Ahlgren‐Berg et al , ).…”

Section: Resultsmentioning

confidence: 99%

Programming Escherichia coli to function as a digital display

Shin

Zhang

Der

et al. 2020

Molecular Systems Biology

107

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Synthetic genetic circuits offer the potential to wield computational control over biology, but their complexity is limited by the accuracy of mathematical models. Here, we present advances that enable the complete encoding of an electronic chip in the DNA carried by Escherichia coli (E. coli). The chip is a binary‐coded digit (BCD) to 7‐segment decoder, associated with clocks and calculators, to turn on segments to visualize 0–9. Design automation is used to build seven strains, each of which contains a circuit with up to 12 repressors and two activators (totaling 63 regulators and 76,000 bp DNA). The inputs to each circuit represent the digit to be displayed (encoded in binary by four molecules), and output is the segment state, reported as fluorescence. Implementation requires an advanced gate model that captures dynamics, promoter interference, and a measure of total power usage (RNAP flux). This project is an exemplar of design automation pushing engineering beyond that achievable “by hand”, essential for realizing the potential of biology.

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“…In these cases, additional regulatory proteins could be co-expressed with a library of regulatory DNA variants in the same in vitro reaction and their ligand-response dynamics could be monitored over time. Such approaches could also expedite the characterization of promoters controlled by multiple regulators 47 and facilitate their integration into complex regulatory networks 51,55 .…”

Section: Discussionmentioning

confidence: 99%

Multiplex transcriptional characterizations across diverse and hybrid bacterial cell-free expression systems

Yim

Johns

Park

et al. 2018

Preprint

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Cell-free expression systems enable rapid prototyping of genetic programs in vitro.However, current throughput of cell-free measurements is often limited by the use of single-channel reporter assays. Here, we describe DNA Regulatory element Analysis by cell-Free Transcription and Sequencing (DRAFTS), a rapid and robust in vitro approach for multiplexed measurement of transcriptional activities from thousands of regulatory sequences in a single reaction. We employed this method in active cell lysates developed from ten diverse bacterial species. Interspecies analysis of transcriptional profiles from >1,000 diverse regulatory sequences revealed functional differences in gene expression that could be predictively modeled. Finally, we constructed and examined the transcriptional capacities of dual-species "hybrid" cell lysates that can simultaneously harness gene expression properties of multiple organisms. We expect that this cell-free multiplex transcriptional measurement approach will improve genetic circuit prototyping in new bacterial chassis for synthetic biology.

show abstract

Predicting Transcriptional Output of Synthetic Multi-input Promoters

Cited by 15 publications

References 45 publications

Multiplex transcriptional characterizations across diverse bacterial species using cell‐free systems

Multiplex transcriptional characterizations across diverse bacterial species using cell‐free systems

Programming Escherichia coli to function as a digital display

Multiplex transcriptional characterizations across diverse and hybrid bacterial cell-free expression systems

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