Chang-Hun Ji scite author profile

Promoter engineering has emerged as a powerful tool to activate transcriptionally silent natural product biosynthetic gene clusters found in bacterial genomes. Since biosynthetic gene clusters are composed of multiple operons, their promoter engineering requires the use of a set of regulatory sequences with a similar level of activities. Although several successful examples of promoter engineering have been reported, its widespread use has been limited due to the lack of a library of regulatory sequences suitable for use in promoter engineering of large, multiple operon-containing biosynthetic gene clusters. Here, we present the construction of a library of constitutively active, synthetic Streptomyces regulatory sequences. The promoter assay system has been developed using a single-module nonribosomal peptide synthetase that produces the peptide blue pigment indigoidine, allowing for the rapid screening of a large pool of regulatory sequences. The highly randomized regulatory sequences in both promoter and ribosome binding site regions were screened for their ability to produce the blue pigment, and they are classified into the strong, medium, and weak regulatory sequences based on the strength of a blue color. We demonstrated the utility of our synthetic regulatory sequences for promoter engineering of natural product biosynthetic gene clusters using the actinorhodin gene cluster as a model cluster. We believe that the set of Streptomyces regulatory sequences we report here will facilitate the discovery of new natural products from silent, cryptic biosynthetic gene clusters found in sequenced Streptomyces genomes.

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mpCRISTAR: Multiple Plasmid Approach for CRISPR/Cas9 and TAR-Mediated Multiplexed Refactoring of Natural Product Biosynthetic Gene Clusters

Kim

et al. 2019

ACS Synth. Biol.

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Multiplexed refactoring provides a tool for rapid transcriptional optimization of biosynthetic gene clusters (BGCs) through simultaneous replacement of multiple native promoters with synthetic counterparts. Here, we present the mpCRISTAR, a multiple plasmid-based CRISPR/Cas9 and TAR (transformation-associated recombination), that enables a rapid and highly efficient, multiplexed refactoring of natural product BGCs in yeast. A series of CRISPR plasmids with different auxotrophic markers that could be stably maintained in yeast cells were constructed to express multiple gRNAs simultaneously. We demonstrated the multiplexing capacity of mpCRISTAR using the actinorhodin biosynthetic gene cluster as a model cluster. mpCRISTAR1, in which each CRISPR plasmid expresses one gRNA, allows for simultaneous replacement of up to four promoter sites with nearly 100% efficiency. By expressing two gRNAs from one CRISPR plasmid, termed mpCRISTAR2, we simultaneously replaced a total of six and eight promoter sites with 68% and 32% efficiency, respectively. The mpCRISTAR could be performed iteratively using two different auxotrophic markers, allowing for refactoring of any type of BGC regardless of their operon complexities. The mpCRISTAR platform we report here would become a useful tool for the discovery of new natural products from transcriptionally silent biosynthetic gene clusters present in microbial genomes.

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Synthetic Inducible Regulatory Systems Optimized for the Modulation of Secondary Metabolite Production in Streptomyces

Kim

Kang

2019

ACS Synth. Biol.

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Biosynthesis of secondary metabolites is a highly complex process that often requires tight control of their production, as overproduction of metabolites could be toxic and also may cause metabolic burden to their hosts. Tight control of metabolite production could be achieved by expressing key biosynthetic genes under control of an inducible regulatory system. In this study, we employed the modular design approach to build a high performance synthetic inducible regulatory system that displays a large dynamic range and thus is well-suited for the modulation of secondary metabolite production in Streptomyces.To this end, an inducible regulatory system was divided into three separate functional modules: (1) the induction module, (2) the target expression module, and (3) the repressor expression module. Then, these three separate modules were individually optimized in a stepwise manner and assembled to a new system. First, the cumate (CMT) induction module was chosen as the best performing induction module based on the large dynamic range and moderate inducer sensitivity. Then the CMT induction module maintained its performance when combined with diverse constitutive target expression modules, in which overall dynamic ranges varied depending on maximum promoter strengths. Lastly, the repressor expression module was optimized to achieve complete elimination of leaky expression, further increasing the dynamic range of the system. We also demonstrate that any strong constitutive regulatory system could be converted into an inducible regulatory system by simple CRISPR/Cas9-aided markerless insertion of an operator sequence whenever tight control of gene expression is required. We believe that the synthetic inducible regulatory system we report here would become a useful tool in modulating secondary metabolite production in Streptomyces.

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Top-down synthetic biology approach for titer improvement of clinically important antibiotic daptomycin in Streptomyces roseosporus

Kim

et al. 2022

Metabolic Engineering

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Comparative Genomics Reveals a Remarkable Biosynthetic Potential of the Streptomyces Phylogenetic Lineage Associated with Rugose-Ornamented Spores

Chung

Kim

et al. 2021

mSystems

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Chang-Hun Ji

Library of Synthetic Streptomyces Regulatory Sequences for Use in Promoter Engineering of Natural Product Biosynthetic Gene Clusters

mpCRISTAR: Multiple Plasmid Approach for CRISPR/Cas9 and TAR-Mediated Multiplexed Refactoring of Natural Product Biosynthetic Gene Clusters

Synthetic Inducible Regulatory Systems Optimized for the Modulation of Secondary Metabolite Production in Streptomyces

Top-down synthetic biology approach for titer improvement of clinically important antibiotic daptomycin in Streptomyces roseosporus

Comparative Genomics Reveals a Remarkable Biosynthetic Potential of the Streptomyces Phylogenetic Lineage Associated with Rugose-Ornamented Spores

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