Synthetic gene circuits as tools for drug discovery

Beitz, Adam M.; Oakes, Conrad G.; Galloway, Kate E.

doi:10.1016/j.tibtech.2021.06.007

Cited by 14 publications

(7 citation statements)

References 132 publications

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“…Cells coordinate complex behaviors through precise spatiotemporal control of gene expression. To rapidly advance gene- and cell-based therapies, synthetic biology aims to harness the power of native biology by constructing synthetic gene regulatory networks capable of dynamically prescribing cellular processes, states, and identities ( Chen et al, 2012 ; Beitz et al, 2022 ; Purnick and Weiss, 2009 ; Elowitz and Lim, 2010 ). Synthetic networks process diverse inputs into complex logical and temporal responses ( Weinberg et al, 2017 ; Xie et al, 2011 ; Tabor et al, 2009 ).…”

Section: Introductionmentioning

confidence: 99%

Supercoiling-mediated feedback rapidly couples and tunes transcription

Johnstone¹,

Galloway²

2022

Cell Reports

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Section: Introductionmentioning

confidence: 99%

Supercoiling-mediated feedback rapidly couples and tunes transcription

Johnstone¹,

Galloway²

2022

Cell Reports

Self Cite

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“…One possible challenge for the host-independent system is that it may take too much translational resources and induce unexpected cellular burden or toxicity for mammalian cells. Other challenges would be the resource-limiting factors coming from translational process and other regulatory processes [31][32][33] . For example, ribosomes and other translational factors were found to be the limiting resources for expressing multiple genes 31 .…”

Section: Discussionmentioning

confidence: 99%

“…For example, ribosomes and other translational factors were found to be the limiting resources for expressing multiple genes 31 . Dicer proteins as a common cofactor of miRNA regulations would be a limiting factor for the regulatory functions of multiple miRNAs, which could result in retroactivity for genetic circuits composed of multiple miRNAs 32 .…”

Section: Discussionmentioning

confidence: 99%

Precise programming of multigene expression stoichiometry in mammalian cells by a modular and programmable transcriptional system

et al. 2023

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Context-dependency of mammalian transcriptional elements has hindered the quantitative investigation of multigene expression stoichiometry and its biological functions. Here, we describe a host- and local DNA context-independent transcription system to gradually fine-tune single and multiple gene expression with predictable stoichiometries. The mammalian transcription system is composed of a library of modular and programmable promoters from bacteriophage and its cognate RNA polymerase (RNAP) fused to a capping enzyme. The relative expression of single genes is quantitatively determined by the relative binding affinity of the RNAP to the promoters, while multigene expression stoichiometry is predicted by a simple biochemical model with resource competition. We use these programmable and modular promoters to predictably tune the expression of three components of an influenza A virus-like particle (VLP). Optimized stoichiometry leads to a 2-fold yield of intact VLP complexes. The host-independent orthogonal transcription system provides a platform for dose-dependent control of multiple protein expression which may be applied for advanced vaccine engineering, cell-fate programming and other therapeutic applications.

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“…Cells coordinate complex behaviors through precise spatiotemporal control of gene expression. To rapidly advance gene and cell-based therapies, synthetic biology aims to harness the power of native biology by constructing synthetic gene regulatory networks capable of dynamically prescribing cellular processes, states, and identities [1][2][3][4]. Synthetic networks process diverse inputs into complex logical and temporal responses [5][6][7].…”

Section: Introductionmentioning

confidence: 99%

Supercoiling-mediated feedback rapidly couples and tunes transcription

Johnstone¹,

Galloway²

2022

Preprint

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Transcription induces a wave of DNA supercoiling, altering the binding affinity of RNA polymerases and reshaping the biochemical landscape of gene regulation. As supercoiling rapidly diffuses, transcription dynamically reshapes the regulation of proximal genes, forming a complex feedback loop. The resulting intergene coupling may provide a mechanism to control transcriptional variance in engineered gene networks and explain the behavior of co-localized native circuits. However, a theoretical framework is needed for integrating both biophysical and biochemical transcriptional regulation to investigate the role of supercoiling-mediated feedback within multi-gene systems. Here, we model transcriptional regulation under the influence of supercoiling-mediated polymerase dynamics, allowing us to identify patterns of expression that result from physical intergene coupling and explore integration of this biophysical model with a set of canonical biochemical gene regulatory systems. We find that gene syntax--the relative ordering and orientation of genes--defines the expression profiles, variance, burst dynamics, and intergene correlation of two-gene systems. By applying our model to both a synthetic toggle switch and the endogenous zebrafish segmentation network, we find that supercoiling can enhance or weaken conventional biochemical regulatory strategies such as mRNA- and protein-mediated feedback loops. Together, our results suggest that supercoiling couples behavior between neighboring genes, representing a novel regulatory mechanism. Integrating biophysical regulation into the analysis and design of gene regulation provides a framework for enhanced understanding of native networks and engineering of synthetic gene circuits.

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Synthetic gene circuits as tools for drug discovery

Cited by 14 publications

References 132 publications

Supercoiling-mediated feedback rapidly couples and tunes transcription

Supercoiling-mediated feedback rapidly couples and tunes transcription

Precise programming of multigene expression stoichiometry in mammalian cells by a modular and programmable transcriptional system

Supercoiling-mediated feedback rapidly couples and tunes transcription

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