A tight cold-inducible switch built by coupling thermosensitive transcriptional and proteolytic regulatory parts

Zheng, Yang; Fan, Meng; Zhu, Zihui; Wei, Weijia; Sun, Zhi; Chen, Jinchun; Yu, Bo; Lou, Chunbo; Chen, Guoqiang

doi:10.1093/nar/gkz785

Cited by 31 publications

(30 citation statements)

References 83 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…6c). The mutant library sizes were 2.02×10 7 and 1.5×10 6 for module B and C, respectively. After fermentation, the high naringenin-producing strains were sorted ( Supplementary Fig.…”

Section: Directed Evolution To Fine-tune Drn and Achieve High Level Pmentioning

confidence: 99%

“…Generally, biosensors that could respond to universal, environmental induction factors such as temperature (6), dissolved oxygen (5), and light (7) enable construction of environment-responding dynamic regulation networks (DRNs). For example, Zhao et al established a blue light inducible transcription factor (VP16-EL222) controlled OptoEXP system for isobutanol production and demonstrated a 4-fold improvement in the titer compared with the strain lacking dynamic regulatory circuits (8).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Development of a growth coupled dynamic regulation network balancing malonyl-CoA node to enhance (2S)-naringenin synthesis inE. coli

Zhou

Yuan

et al. 2020

Preprint

View full text Add to dashboard Cite

AbstractGenerally, high- and low-performance nongenetic variants and young and aged cells co-existed in culture at all growth phases. In this regard, individually and dynamically regulating the metabolic flux of single cells based on their cellular state is highly useful for improving the performance of populations. However, balancing the trade-offs between biomass formation and compound over-production requires sophisticated dynamic regulation networks (DRNs) which can be challenging. Here, we developed a growth coupled NCOMB (Naringenin-Coumaric acid-Malonyl-CoA-Balanced) DRN with systematic optimization of (2S)-naringenin and p-coumaric acid-responsive regulation pathways for real-time control of intracellular supply of malonyl-CoA. In doing so, the acyl carrier protein was used as a new critical node for fine-tuning malonyl-CoA consumption instead of fatty acid synthase. Following directed evolution of the NCOMB DRN, we obtained a strain with cumulative 8.4-fold improvement in (2S)-naringenin production with balanced cell growth, demonstrating the high efficiency of this system for improving pathway production.

show abstract

“…6c). The mutant library sizes were 2.02×10 7 and 1.5×10 6 for module B and C, respectively. After fermentation, the high naringenin-producing strains were sorted ( Supplementary Fig.…”

Section: Directed Evolution To Fine-tune Drn and Achieve High Level Pmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Development of a growth coupled dynamic regulation network balancing malonyl-CoA node to enhance (2S)-naringenin synthesis inE. coli

Zhou

Yuan

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…Although reasonable fold changes were observed in current systems, it can be further improved to suit specific applications potentially via the addition of positive feedbacks (Nistala et al, 2010) and/or introducing temperature-sensitive proteolytic modules (Yang Zheng et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

“…There are several notable examples of transcriptional based heat-inducible systems as described (Fu et al, 2020;Hussaina et al, 2014;Pearce et al, 2017;Piraner et al, 2017). However, there are limited heat-repressible systems which rely on transcriptional regulation (Liang et al, 2007;Yang Zheng et al, 2019). A recent work has performed temperature-based screening on the modified bacteriophage λ Cl434 repressor that contained the tobacco etch virus (TEV) cleavage site (Yang Zheng et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Highly Reversible Tunable Thermal-repressible Split-T7 RNA polymerases (Thermal-T7RNAPs) for dynamic gene regulation

Chee

Yeoh

Dao

et al. 2021

Preprint

View full text Add to dashboard Cite

Temperature is a physical cue that is easy to apply, allowing cellular behaviors to be controlled in a contactless and dynamic manner via heat-inducible/repressible systems. However, existing heat-repressible systems are limited and rely on thermal sensitive mRNA or transcription factors which function at low temperatures, lack tunability, suffer delays or overly-complex. To provide an alternative mode of thermal regulation, we developed a library of compact, reversible and tunable thermal-repressible split-T7 RNA polymerase systems (Thermal-T7RNAPs) which fuses temperature-sensitive domains of Tlpa protein with split-T7RNAP to enable direct thermal control of the T7RNAP activity between 30-42 °C. We generated a large mutant library with varying thermal performances via automated screening framework to extend temperature tunability. Lastly, using the mutants, novel thermal logic circuitry was implemented to regulate cell growth and achieve active thermal control of the cell proportions within co-cultures. Overall, this technology expands avenues for thermal control in biotechnology applications.

show abstract

“…2C ). Cold-inducible switches have also been developed via directed evolution ( Zheng et al, 2019 ). Temperature induction also has limitations: (1) heat can alter protein folded structures and folding dynamics; (2) large or rapid change in temperature can trigger heat- or cold-shock responses and alter the global regulatory and metabolic networks; and (3) implementing temperature change in large fermenters uniformly can be slow due to heat transfer limitations.…”

Section: Sensors and Actuationmentioning

confidence: 99%

Dynamic control in metabolic engineering: Theories, tools, and applications

Hartline

Schmitz

Han

et al. 2021

Metabolic Engineering

115

View full text Add to dashboard Cite

Metabolic engineering has allowed the production of a diverse number of valuable chemicals using microbial organisms. Many biological challenges for improving bio-production exist which limit performance and slow the commercialization of metabolically engineered systems. Dynamic metabolic engineering is a rapidly developing field that seeks to address these challenges through the design of genetically encoded metabolic control systems which allow cells to autonomously adjust their flux in response to their external and internal metabolic state. This review first discusses theoretical works which provide mechanistic insights and design choices for dynamic control systems including two-stage, continuous, and population behavior control strategies. Next, we summarize molecular mechanisms for various sensors and actuators which enable dynamic metabolic control in microbial systems. Finally, important applications of dynamic control to the production of several metabolite products are highlighted, including fatty acids, aromatics, and terpene compounds. Altogether, this review provides a comprehensive overview of the progress, advances, and prospects in the design of dynamic control systems for improved titer, rate, and yield metrics in metabolic engineering.

show abstract

A tight cold-inducible switch built by coupling thermosensitive transcriptional and proteolytic regulatory parts

Cited by 31 publications

References 83 publications

Development of a growth coupled dynamic regulation network balancing malonyl-CoA node to enhance (2S)-naringenin synthesis inE. coli

Development of a growth coupled dynamic regulation network balancing malonyl-CoA node to enhance (2S)-naringenin synthesis inE. coli

Highly Reversible Tunable Thermal-repressible Split-T7 RNA polymerases (Thermal-T7RNAPs) for dynamic gene regulation

Dynamic control in metabolic engineering: Theories, tools, and applications

Contact Info

Product

Resources

About