Synthetic robust perfect adaptation achieved by negative feedback coupling with linear weak positive feedback

Sun, Zhi; Wei, Weijia; Zhang, Mingyue; Shi, Wenjia; Zong, Yeqing; Chen, Yihua; Yang, Xiaojing; Yu, Bo; Tang, Chao; Lou, Chunbo

doi:10.1093/nar/gkac066

Cited by 12 publications

(5 citation statements)

References 50 publications

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“…First, autorepression is regarded as robust modules and can easily be transferred from one host to another . Second, from the perspective of control theory, the control time constants of our autorepression modules are predicted to be less than 5 min (Figure S21), which is much lower than that of open loop regulation, showing efficient control ability of our autoregulated modules. The control gains of autorepression modules varied with input concentration, and smaller control gains can be designed with lower K r , which leads to stronger autorepression strength.…”

Section: Discussionmentioning

confidence: 95%

“…Several design strategies were developed to mitigate unintended circuit–host interferences, including design of network topologies that are insensitive to environmental changes, , part screening and evaluation with big data, design of indirect negative feedback controllers mediated by burden-induced signals , and specificity enhancement of toxic TFs through protein engineering …”

Section: Introductionmentioning

confidence: 99%

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Mitigating Host Burden of Genetic Circuits by Engineering Autonegatively Regulated Parts and Improving Functional Prediction

et al. 2022

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Mitigating unintended interferences between circuits and host cells is key to realize applications of synthetic regulatory systems both for bacteria and mammalian cells. Here, we demonstrated that growth burden and circuit dysregulation occurred in a concentration-dependent manner for specific transcription factors (CymR*/CymR) in E.coli, and direct negative feedback modules were able to control the concentration of CymR*/CymR, mitigate growth burden, and restore circuit functions. A quantitative design scheme was developed for circuits embedded with autorepression modules. Four key parameters were theoretically identified to determine the performance of autoregulated switches and were experimentally modified by fine-tuning promoter architectures and cooperativity. Using this strategy, we synthesized a number of switches and demonstrated its improvement of product titers and host growth controlling the complex deoxyviolacein biosynthesis pathway. Furthermore, we restored functions of a dysregulated multilayer NOR gate by integrating autorepression modules. Our work provides a blueprint for engineering host-adaptable synthetic systems.

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Section: Discussionmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Mitigating Host Burden of Genetic Circuits by Engineering Autonegatively Regulated Parts and Improving Functional Prediction

et al. 2022

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“…For instance, it can be coupled with a metabolite addiction circuit to improve overall performance [ 49 ]. Coupling it with linear weak positive feedback circuits allows the construction of a synthetic robust perfect adaptation system, which exhibits a pulse-like gene expression profile and enables precise expression of a specific amount of protein at a specific time [ 50 ].…”

Section: Discussionmentioning

confidence: 99%

Achieving robust synthetic tolerance in industrial E. coli through negative auto-regulation of a DsrA-Hfq module

Yang,

Huang

et al. 2024

Synthetic and Systems Biotechnology

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“…Plasmid construction was performed following standard molecular biology techniques through Gibson Assembly (Gibson et al, 2009) or Golden Gate Assembly method (Engler et al, 2008). Two plasmids with low copy number features, pSEVA221 (Silva-Rocha et al, 2013) and pBB (Sun et al, 2022) were used for programmable toxin gene expression. Three toxin-gene-carrying plasmids, pSEVA221-P LtetO -200-CcdB, pSEVA221-P LtetO -50-Doc, pSEVA221-P LtetO -50-EcoRI, were used for construction of further anti-escape elements based on the E. coli SS strain reported previously (Xue et al, 2022).…”

Section: Genetic Manipulationsmentioning

confidence: 99%

Mercury bioremediation by engineered Pseudomonas putidaKT2440 with adaptationally optimized biosecurity circuit

Xue

Qiu

Sun

et al. 2022

Environmental Microbiology

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Summary Hazardous materials, such as heavy metals, are the major sources of health risk. Using genetically modified organisms (GMOs) to dispose heavy metals has the advantages of strong environmental compatibility and high efficiency. However, the biosecurity of GMOs used in the environment is a major concern. In this study, a self‐controlled genetic circuit was designed and carefully fine‐tuned for programmable expression in Pseudomonas putida KT2440, which is a widely used strain for environmental bioremediation. The cell behaviours were controlled by automatically sensing the variation of Hg2+ concentration without any inducer requirement or manual interventions. More than 98% Hg2+ was adsorbed by the engineered strain with a high cell recovery rate of 96% from waterbody. The remaining cells were killed by the suicide module after the mission was accomplished. The escape frequency of the engineered P. putida strain was lower than 10−9, which meets the recommendation of US NIH guideline for GMOs release (<10−8). The same performance was achieved in a model experiment by using natural lake water with addition of Hg2+. The microbial diversity analysis further confirmed that the remediation process made little impact on the indigenous ecosystem. Thus, this study provides a practical method for environmental remediation by using GMOs.

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Synthetic robust perfect adaptation achieved by negative feedback coupling with linear weak positive feedback

Cited by 12 publications

References 50 publications

Mitigating Host Burden of Genetic Circuits by Engineering Autonegatively Regulated Parts and Improving Functional Prediction

Mitigating Host Burden of Genetic Circuits by Engineering Autonegatively Regulated Parts and Improving Functional Prediction

Achieving robust synthetic tolerance in industrial E. coli through negative auto-regulation of a DsrA-Hfq module

Mercury bioremediation by engineered Pseudomonas putidaKT2440 with adaptationally optimized biosecurity circuit

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