Genome Replication Engineering Assisted Continuous Evolution (GREACE) to Improve Microbial Tolerance for Biofuels Production

Luan, Guodong; Zhang, Cai; Li, Yin; Ma, Yanhe

doi:10.1201/b18525-18

Cited by 5 publications

(8 citation statements)

References 63 publications

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“…Recently, the development of modern molecular biology has contributed to the generation of several novel in vivo mutagenesis methods (Table 2). On the one hand, global in vivo mutagenesis methods, like genome replication engineering-assisted continuous evolution (GREACE) [91,92] and mutagenesis plasmid (MP6) [93], are proposed to increase global mutation rates in E. coli and S. cerevisiae by overexpression of mutator genes on plasmid vectors (Figure 3A). It was notable that, by expressing six mutator genes simultaneously, the MP6 mutator plasmid increased mutation rate by 322 000-fold in E. coli, surpassing various traditional in vivo mutagenesis methods.…”

Section: Novel Tools For Efficient Ale and Their Applicationsmentioning

confidence: 99%

“…ICE was successfully applied in improving a two-enzyme xylose catabolism-related pathway [103]. And GREACE facilitated the improvement of 1-butanol and acetate tolerance after introducing global perturbations [91]. Notably, when targeted to a global transcription factor [105], targeted methods also have the potential to reprogram genome-wide gene expression and unlock complex phenotypes.…”

Section: Novel Tools For Efficient Ale and Their Applicationsmentioning

confidence: 99%

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Advanced strategies and tools to facilitate and streamline microbial adaptive laboratory evolution

Jameel

Xing

et al. 2022

Trends in Biotechnology

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Section: Novel Tools For Efficient Ale and Their Applicationsmentioning

confidence: 99%

Section: Novel Tools For Efficient Ale and Their Applicationsmentioning

confidence: 99%

Advanced strategies and tools to facilitate and streamline microbial adaptive laboratory evolution

Jameel

Xing

et al. 2022

Trends in Biotechnology

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“…In this regard, the approach of growth enrichment is most effective for improving stress tolerance and nutrient usage as these phenotypes easily couple with cell growth . As examples, growth selection linked with gene diversity strategies enable the selection of variants with improved growth rate in extreme environments, such as low pH and high temperature, as well as high concentrations of toxic compounds such as ionic liquids . Catabolic pathways can likewise be improved via directed evolution and growth selection.…”

Section: Screening and Selection Processesmentioning

confidence: 99%

“…To address this, Luan et al . established a genome replication engineering assisted continuous evolution (GREACE) strategy to improve a strain's tolerance to extreme environments (Fig. (F)).…”

Section: Continuous Evolution Strategiesmentioning

confidence: 99%

“…Specifically, by introducing a proofreading element library for the E. coli DNA polymerase complex it was possible to select for the ideal mutator gene. This method successfully improved thermotolerance (capable of growth in 50°C), kanamycin resistance (capable of growth in 300 µg L −1 kanamycin), n‐butanol (capable of growth in 1.25% n‐butanol) and acetate (8‐fold improvement in 0.1% acetate) tolerances of E. coli …”

Section: Continuous Evolution Strategiesmentioning

confidence: 99%

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Strategies for directed and adapted evolution as part of microbial strain engineering

Zhou

Alper

2018

J of Chemical Tech & Biotech

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The industrial production of chemicals by microorganisms usually requires improvements to the enzymes, pathways, and strain that go beyond the capacity of innate enzymes. To achieve these phenotypes and overcome our limited capacity to de novo design these parts, directed and adaptive evolutionary approaches are used to explore new functions. This review highlights the recent advances in both sequence diversity generation and selection strategies from traditional in vitro mutagenesis to novel in vivo continuous evolution applications. The focus here is on comparison of the different gene diversity methods in an attempt to distinguish the best strategy for protein or strain engineering for a given goal. Furthermore, the important role that screening and selection can play in advancing directed and adapted evolution is discussed. © 2018 Society of Chemical Industry

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Recent advances, challenges and metabolic engineering strategies in the biosynthesis of 3‐hydroxypropionic acid

Liang

Sun

Nie

et al. 2022

Biotech & Bioengineering

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As an attractive and valuable platform chemical, 3‐hydroxypropionic acid (3‐HP) can be used to produce a variety of industrially important commodity chemicals and biodegradable polymers. Moreover, the biosynthesis of 3‐HP has drawn much attention in recent years due to its sustainability and environmental friendliness. Here, we focus on recent advances, challenges, and metabolic engineering strategies in the biosynthesis of 3‐HP. While glucose and glycerol are major carbon sources for its production of 3‐HP via microbial fermentation, other carbon sources have also been explored. To increase yield and titer, synthetic biology and metabolic engineering strategies have been explored, including modifying pathway enzymes, eliminating flux blockages due to byproduct synthesis, eliminating toxic byproducts, and optimizing via genome‐scale models. This review also provides insights on future directions for 3‐HP biosynthesis.

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Genome Replication Engineering Assisted Continuous Evolution (GREACE) to Improve Microbial Tolerance for Biofuels Production

Cited by 5 publications

References 63 publications

Advanced strategies and tools to facilitate and streamline microbial adaptive laboratory evolution

Advanced strategies and tools to facilitate and streamline microbial adaptive laboratory evolution

Strategies for directed and adapted evolution as part of microbial strain engineering

Recent advances, challenges and metabolic engineering strategies in the biosynthesis of 3‐hydroxypropionic acid

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