Rational construction of genome-reduced and high-efficient industrial Streptomyces chassis based on multiple comparative genomic approaches

Bu, Qing-Ting; Yu, Ping; Wang, Jue; Li, Zi-Yue; Chen, Xin-Ai; Mao, Xu‐Ming; Li, Yongquan

doi:10.1186/s12934-019-1055-7

Cited by 66 publications

(56 citation statements)

References 51 publications

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“…The shared perspectives of synthetic and systems biology together brought into realization the concept of minimal genomes along with their proposed advantages across diverse fields of applications, including expression of heterologous proteins. A growing number of reports already highlight the advantages of genome-reduced microbial strains outperforming their wild-type counterparts in terms of productivity of target proteins [113] and desired biomolecules [114], which result from the elimination of unfavorable features for protein expression and rewired metabolic networks redirected to produce heterologous proteins. In this section, we attempt to provide a brief overview of the concept, design, and mechanism underlying synthesis of the minimal genome.…”

Section: Concept and Overview Of Synthetic Minimal Genomementioning

confidence: 99%

“…Due to relative ease of underlying procedures and cheaper costs, a larger number of top-down genome reduction projects have been published to date as compared with that of bottom-up synthesis (Table 2). Strains subjected to top-down genome-reductions to date include E. coli [123][124][125][126][127], Streptomyces strains [114,[128][129][130][131][132][133], B. subtilis [92,[134][135][136][137][138], L. lactis [139], Pseudomonas putida [140,141], Corynebacterium glutamicum [142], and a yeast strain [143]. This strategy enabled the removal of unnecessary proportions of genome at large scale without causing palpable defects in the target organisms (except in a few instances [135,144]) and sometimes yielded improved cellular performances in terms of growth rates, cell density, transformation efficiency, and protein productivity compared with their wild-type counterparts.…”

Section: Concept and Overview Of Synthetic Minimal Genomementioning

confidence: 99%

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Engineering Biology to Construct Microbial Chassis for the Production of Difficult-to-Express Proteins

Kim

Choe

Lee

et al. 2020

IJMS

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A large proportion of the recombinant proteins manufactured today rely on microbe-based expression systems owing to their relatively simple and cost-effective production schemes. However, several issues in microbial protein expression, including formation of insoluble aggregates, low protein yield, and cell death are still highly recursive and tricky to optimize. These obstacles are usually rooted in the metabolic capacity of the expression host, limitation of cellular translational machineries, or genetic instability. To this end, several microbial strains having precisely designed genomes have been suggested as a way around the recurrent problems in recombinant protein expression. Already, a growing number of prokaryotic chassis strains have been genome-streamlined to attain superior cellular fitness, recombinant protein yield, and stability of the exogenous expression pathways. In this review, we outline challenges associated with heterologous protein expression, some examples of microbial chassis engineered for the production of recombinant proteins, and emerging tools to optimize the expression of heterologous proteins. In particular, we discuss the synthetic biology approaches to design and build and test genome-reduced microbial chassis that carry desirable characteristics for heterologous protein expression.

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Section: Concept and Overview Of Synthetic Minimal Genomementioning

confidence: 99%

Section: Concept and Overview Of Synthetic Minimal Genomementioning

confidence: 99%

Engineering Biology to Construct Microbial Chassis for the Production of Difficult-to-Express Proteins

Kim

Choe

Lee

et al. 2020

IJMS

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“…In vitro Sticky end ligation: pSBAC [113] Blunt end ligation: ICE [95] Gibson assembly: CATCH and MSGE [89,96] In vivo Recombination in native host: IR [114] Recombination in E. coli: LLHR [117] Recombination in yeast: TAR, DNA assembler, DiPac, and mCRISTAR [97,115,116,118] Transferring BGC vector to the expression host Conjugation pUWLcre [136] Protoplast transformation pSKC2 and pOJ446 [137] Target secondary metabolite production by expression of the BGC vector Integrative pSET152, pCAP01, and pESAC [118,138] Replicative pSKC2 and pUWL201 [139] expression vectors in previous studies were integrative vectors, which are more stable after serial generations [109]. Genetic stability is very important for the further fermentation process of secondary metabolites [121]. However, the copy number of the integrative SM-BGC vector is only one compared to multi-copy replicative vectors.…”

Section: Heterologous Expression Of Secondary Metabolite Biosyntheticmentioning

confidence: 99%

“…They include genomic islands (GI), IS elements, and endogenous CRISPR array regions that decrease genomic stability. For example, NGRs in S. avermitilis (1.48 Mb) and S. chattanoogenisis (0.7 Mb) were selected, based on comparative genomics of Streptomyces genomes, and deleted by λ-Red system or Cre/loxP recombination system [121,125]. As expected, deletion of NGRs increased the fitness level of the engineered strain relative to the wild-type strain with beneficial effects on morphology, ATP level, NADPH level, transformation efficiency, and genetic stability in S. chattanoogenisis [121].…”

Section: Streptomyces Chassis Strains For Heterologous Gene Expressionmentioning

confidence: 99%

“…Development of synthetic biology tools can also be exploited to construct the Streptomyces chassis for heterologous expression of novel SM-BGCs. So far, S. albus J1074 with deletion of 15 BGCs and S. chattanoogensis L10 with deletion of 0.7 Mb of a nonessential arm seem to be the best Streptomyces chassis for heterologous expression [121,122]. A further challenge might be the construction of the "superhost Streptomyces chassis" by removing all endogenous SM-BGCs, nonessential genes, and genomic regions and adding all precursor synthetic genes.…”

Section: Future Perspectivementioning

confidence: 99%

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Synthetic Biology Tools for Novel Secondary Metabolite Discovery in Streptomyces

Lee¹,

Hwang²,

Lee³

et al. 2019

Journal of Microbiology and Biotechnology

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Metabolic Engineering of Bacillus – New Tools, Strains, and Concepts

Appelbaum

Schweder

2021

Metabolic Engineering

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Rational construction of genome-reduced and high-efficient industrial Streptomyces chassis based on multiple comparative genomic approaches

Cited by 66 publications

References 51 publications

Engineering Biology to Construct Microbial Chassis for the Production of Difficult-to-Express Proteins

Engineering Biology to Construct Microbial Chassis for the Production of Difficult-to-Express Proteins

Synthetic Biology Tools for Novel Secondary Metabolite Discovery in Streptomyces

Metabolic Engineering of Bacillus – New Tools, Strains, and Concepts

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