Development of Artificial Riboswitches for Monitoring of Naringenin <i>In Vivo</i>

Jang, Se Bok; Jang, Sungyeon; Xiu, Yu; Kang, Taek Jin; Lee, Sang‐Hyeup; Koffas, Mattheos; Jung, Gyoo Yeol

doi:10.1021/acssynbio.7b00128

Cited by 79 publications

(62 citation statements)

References 52 publications

(92 reference statements)

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“…In vitro and in vivo selections can then be performed to empirically validate each design in a high-throughput manner in an environment where the dynamic RNA controllers should work. The potential of empirical selection should be further explored because the quantitative properties of RNA controllers can be modulated using well-designed in vivo selection schemes [43 ]. Emerging approaches in the development of dynamic RNA controllers will expand the repertoire of genetic parts for applications in metabolic engineering and synthetic biology.…”

Section: Discussionmentioning

confidence: 99%

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RNA-based dynamic genetic controllers: development strategies and applications

Jang

Yang

et al. 2018

Current Opinion in Biotechnology

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Dynamic regulation of gene expression in response to various molecules is crucial for both basic science and practical applications. RNA is considered an attractive material for creating dynamic genetic controllers because of its specific binding to ligands, structural flexibility, programmability, and small size. Here, we review recent advances in strategies for developing RNA-based dynamic controllers and applications. First, we describe studies that re-engineered natural riboswitches to generate new dynamic controllers. Next, we summarize RNA-based regulatory mechanisms that have been exploited to build novel artificial dynamic controllers. We also discuss computational methods and high-throughput selection approaches for de novo design of dynamic RNA controllers. Finally, we explain applications of dynamic RNA controllers for metabolic engineering and synthetic biology.

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Section: Discussionmentioning

confidence: 99%

“…In vitro selection recently published work utilizing a coupled in vitro-in vivo selection strategy [43 ]. In this study, an aptamer library that binds to a flavonoid, naringenin, was cloned upstream of a dual selectable marker gene.…”

Section: Library Generationmentioning

confidence: 99%

RNA-based dynamic genetic controllers: development strategies and applications

Jang

Yang

et al. 2018

Current Opinion in Biotechnology

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“…Previous studies showed that modifying binding kinetics and affinity by directed mutagenesis of aptamer domains of riboswitches shifted the dose-response curves [18][19][20]. Another approach focused on modifying an expression platform, which was also effective for tuning of riboswitches [21,22].…”

Section: Introductionmentioning

confidence: 99%

Toehold Switch-Based Genetic Modulator for Tuning of Riboswitch Sensor

Hwang¹,

Kim²,

Jang³

et al. 2020

Preprint

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BackgroundSynthetic biological circuits are widely utilized to control microbial cell functions. Natural and synthetic riboswitches are attractive classes of sensor modules for use in synthetic biological applications. However, tuning the dose-response parameters of riboswitch circuits is challenging because considerable understanding of riboswitch mechanism and screening of mutant libraries are generally required. Therefore, novel molecular parts and strategies for controlling the dose-response parameters of riboswitch circuits are needed.ResultsHere, we developed a toehold switch-based genetic modulator that combines a previously reported hybrid input construct, which consists of riboswitch and transcriptional repressor, and de-novo-designed riboregulators named as toehold switches. First, the introduction of a pair of toehold switch and trigger as a downstream signal-processing module resulted in a functional riboswitch circuit. Next, several optimization strategies that focused on the stoichiometric ratio of RNA components greatly improved the fold-change. Finally, further characterizations confirmed low leakiness and high orthogonality for multiple toehold switches, indicating its applicability in riboswitch circuits in a seamless manner.ConclusionsThe toehold switch-based genetic modulator improved the dynamic range and dramatically shifted the operational range compared to the previous sensors only with hybrid input construct. The programmable RNA-RNA interactions amenable to in silico design and optimization can facilitate further development of RNA-based genetic modulators for flexible tuning of riboswitch circuitry and synthetic biosensors.

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“…Common biosensors in dynamic control are transcriptional riboswitches [7] and transcription factors [75]. Progress in RNA engineering has led to a growing number of riboswitches that respond to specific metabolites [66,26]. Studies have shown that RNA sequences shape the sensitivity and threshold of riboswitch dose-response curves [52,5], yet the precise tuning of riboswitch function remains a significant challenge.…”

Section: § 1 Introductionmentioning

confidence: 99%

Dynamic metabolic control: towards precision engineering of metabolism

Liu

Mannan

Han

et al. 2018

Journal of Industrial Microbiology and Biotechnology

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Advances in metabolic engineering have led to the synthesis of a wide variety of valuable chemicals in microorganisms. The key to commercializing these processes is the improvement of titer, productivity, yield, and robustness. Traditional approaches to enhancing production use the "push-pull-block" strategy that modulates enzyme expression under static control. However, strains are often optimized for specific laboratory set-up and are sensitive to environmental fluctuations. Exposure to sub-optimal growth conditions during large-scale fermentation often reduces their production capacity. Moreover, static control of engineered pathways may imbalance cofactors or cause the accumulation of toxic intermediates, which imposes burden on the host and results in decreased production. To overcome these problems, the last decade has witnessed the emergence of a new technology that uses synthetic regulation to control heterologous pathways dynamically, in ways akin to regulatory networks found in nature. Here, we review natural metabolic control strategies and recent developments in how they inspire the engineering of dynamically regulated pathways. We further discuss the challenges of designing and engineering dynamic control and highlight how model-based design can provide a powerful formalism to engineer dynamic control circuits, which together with the tools of synthetic biology, can work to enhance microbial production.

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Development of Artificial Riboswitches for Monitoring of Naringenin In Vivo

Cited by 79 publications

References 52 publications

RNA-based dynamic genetic controllers: development strategies and applications

RNA-based dynamic genetic controllers: development strategies and applications

Toehold Switch-Based Genetic Modulator for Tuning of Riboswitch Sensor

Dynamic metabolic control: towards precision engineering of metabolism

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