1.Amino acid exporters and metabolic modification of Corynebacterium glutamicum - a review.
Xiaomei ZHANG ; Yujie GAO ; Ling YANG ; Yi YANG ; Ping ZHENG ; Jibin SUN ; Jinsong SHI ; Zhenghong XU
Chinese Journal of Biotechnology 2020;36(11):2250-2259
Amino acids are important compounds with a wide range of applications in the food, medicine and chemical industries. Corynebacterium glutamicum is a powerful workhorse commonly used in industrial amino acid production, with the scale of more than one million tons. In addition to its efficient anabolism, the effective exporters also ensure the high amino acid production by C. glutamicum. In this review, the research progress of amino acid exporter of C. glutamicum is summarized, to provide the foundation for further improving amino acid production by C. glutamicum via metabolic engineering.
Amino Acids
;
Corynebacterium glutamicum/genetics*
;
Metabolic Engineering
2.Recent advances in developing enabling technologies for Corynebacterium glutamicum metabolic engineering.
Yu WANG ; Ping ZHENG ; Jibin SUN
Chinese Journal of Biotechnology 2021;37(5):1603-1618
Corynebacterium glutamicum is an important workhorse of industrial biotechnology, especially for amino acid bioindustry. This bacterium is being used to produce various amino acids at a level of over 6 million tons per year. In recent years, enabling technologies for C. glutamicum metabolic engineering have been developed and improved, which accelerated construction and optimization of microbial cell factoriers, expanding spectra of substrates and products, and facilitated basic researches on C. glutamicum. With these technologies, C. glutamicum has become one of the ideal microbial chasses. This review summarizes recent key technological developments of enabling technologies for C. glutamicum metabolic engineering and focuses on establishment and applications of CRISPR-based genome editing, gene expression regulation, adaptive laboratory evolution, and biosensor technologies.
Amino Acids
;
Biotechnology
;
Corynebacterium glutamicum/genetics*
;
Gene Editing
;
Metabolic Engineering
3.Advances and prospects in metabolic engineering for the production of amino acids.
Qian MA ; Li XIA ; Miao TAN ; Quanwei SUN ; Mengya YANG ; Ying ZHANG ; Ning CHEN
Chinese Journal of Biotechnology 2021;37(5):1677-1696
Fermentative production of amino acids is one of the pillars of the fermentation industry in China. Recently, with the fast development of metabolic engineering and synthetic biology technologies, the metabolic engineering for production of amino acids has been flourishing. Conventional forward metabolic engineering, reversed metabolic engineering based on omics data and in silico simulation, and evolutionary metabolic engineering mimicking the natural evolution, have shown increasingly promising applications. A series of highly efficient and robust amino acids-producing strains have been developed and applied in the industrial production of amino acids. The increasingly fierce market competition has put forward new requirements for strain breeding and selection, such as developing high value-added amino acids, dynamic regulation of cellular metabolism, and adapting to the requirements of new process. This review summarizes the advances and prospects in metabolic engineering for the production of amino acids.
Amino Acids
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China
;
Corynebacterium glutamicum/genetics*
;
Metabolic Engineering
;
Synthetic Biology
4.Rational metabolic engineering of Corynebacterium glutamicum for efficient synthesis of L-glutamate.
Jiafeng LIU ; Zhina QIAO ; Youxi ZHAO ; Meijuan XU ; Xian ZHANG ; Taowei YANG ; Zhiming RAO
Chinese Journal of Biotechnology 2023;39(8):3273-3289
L-glutamic acid is the world's largest bulk amino acid product that is widely used in the food, pharmaceutical and chemical industries. Using Corynebacterium glutamicum G01 as the starting strain, the fermentation by-product alanine content was firstly reduced by knocking out the gene encoding alanine aminotransferase (alaT), a major by-product related to alanine synthesis. Secondly, since the α-ketoglutarate node carbon flow plays an important role in glutamate synthesis, the ribosome-binding site (RBS) sequence optimization was used to reduce the activity of α-ketoglutarate dehydrogenase and enhance the glutamate anabolic flow. The endogenous conversion of α-ketoglutarate to glutamate was also enhanced by screening different glutamate dehydrogenase. Subsequently, the glutamate transporter was rationally desgined to improve the glutamate efflux capacity. Finally, the fermentation conditions of the strain constructed using the above strategy were optimized in 5 L fermenters by a gradient temperature increase combined with a batch replenishment strategy. The glutamic acid production reached (135.33±4.68) g/L, which was 41.2% higher than that of the original strain (96.53±2.32) g/L. The yield was 55.8%, which was 11.6% higher than that of the original strain (44.2%). The combined strategy improved the titer and the yield of glutamic acid, which provides a reference for the metabolic modification of glutamic acid producing strains.
Glutamic Acid
;
Corynebacterium glutamicum/genetics*
;
Ketoglutaric Acids
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Metabolic Engineering
;
Alanine
5.Current status and future perspectives of metabolic network models of industrial microorganisms.
Chenyang ZHANG ; Yaokang WU ; Xianhao XU ; Xueqin LV ; Jianghua LI ; Guocheng DU ; Long LIU
Chinese Journal of Biotechnology 2021;37(3):860-873
Genome-scale metabolic network model (GSMM) is an extremely important guiding tool in the targeted modification of industrial microbial strains, which helps researchers to quickly obtain industrial microbes with specific traits and has attracted increasing attention. Here we reviewe the development history of GSMM and summarized the construction method of GSMM. Furthermore, the development and application of GSMM in industrial microorganisms are elaborated by using four typical industrial microorganisms (Bacillus subtilis, Escherichia coli, Corynebacterium glutamicum, and Saccharomyces cerevisiae) as examples. In addition, prospects in the development trend of GSMM are proposed.
Corynebacterium glutamicum/genetics*
;
Escherichia coli/genetics*
;
Metabolic Engineering
;
Metabolic Networks and Pathways/genetics*
6.Screening efficient constitutive promoters in Corynebacterium glutamicum based on time-series transcriptome analysis.
Yingchun WANG ; Jiao LIU ; Xiaomeng NI ; Yu LEI ; Ping ZHENG ; Aipo DIAO
Chinese Journal of Biotechnology 2018;34(11):1760-1771
Promoter, an essential regulatory element, is widely used for metabolic engineering of industrial strains. Corynebacterium glutamicum is an important industrial workhorse to produce various amino acids. However, strong constitutive promoters that are applicable to C. glutamicum are rarely reported. In this study, we first performed a time-series transcriptome analysis of a glutamate hyper-producing strain C. glutamicum SL4 by using RNA-Seq. Overall, we picked 10 samples at different time during the fermentation process. By analyzing the time-series transcriptome data, we selected 10 candidate genes with the highest transcriptional level. These genes were all transcribed stably during the fermentation process. We subsequently cloned the promoter sequences and evaluated the promoters' strength in strain SL4 using a red fluorescent protein reporter system. To evaluate the universality of the promoters in different C. glutamicum strains, we further tested the performance of some promoters in wild type C. glutamicum strains, including ATCC 13869 and ATCC 13032. The strongest promoter was further characterized using LacZ as a reporter in all the three C. glutamicum strains. Finally, we successfully obtained three constitutive promoters with universality, PcysK, PgapA and PfumC. PcysK is the most efficient promoter among the three C. glutamicum strains. In strains SL4 and ATCC 13869, the strength of PcysK is 2-fold of the strong inducible promoter Ptac using the red fluorescent protein as a reporter and 4-fold of Ptac using LacZ as a reporter. Moreover, the strength of PcysK reaches 30%-40% of Ptac in strain ATCC 13032. The promoter PcysK is identified as a strong promoter for the first time, which can be used as an efficient biobrick for metabolic engineering of synthesis pathways in C. glutamicum.
Corynebacterium glutamicum
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genetics
;
Gene Expression Profiling
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Gene Expression Regulation, Bacterial
;
Metabolic Engineering
;
Promoter Regions, Genetic
;
Transcriptome
7.Optimization of CRISPR/Cas9-based multiplex base editing in Corynebacterium glutamicum.
Hui LU ; Qi ZHANG ; Sili YU ; Yu WANG ; Ming KANG ; Shuangyan HAN ; Ye LIU ; Meng WANG
Chinese Journal of Biotechnology 2022;38(2):780-795
As a new CRISPR/Cas-derived genome engineering technology, base editing combines the target specificity of CRISPR/Cas and the catalytic activity of nucleobase deaminase to install point mutations at target loci without generating DSBs, requiring exogenous template, or depending on homologous recombination. Recently, researchers have developed a variety of base editing tools in the important industrial strain Corynebacterium glutamicum, and achieved simultaneous editing of two and three genes. However, the multiplex base editing based on CRISPR/Cas9 is still limited by the complexity of multiple sgRNAs, interference of repeated sequence and difficulty of target loci replacement. In this study, multiplex base editing in C. glutamicum was optimized by the following strategies. Firstly, the multiple sgRNA expression cassettes based on individual promoters/terminators was optimized. The target loci can be introduced and replaced rapidly by using a template plasmid and Golden Gate method, which also avoids the interference of repeated sequence. Although the multiple sgRNAs structure is still complicated, the editing efficiency of this strategy is the highest. Then, the multiple gRNA expression cassettes based on Type Ⅱ CRISPR crRNA arrays and tRNA processing were developed. The two strategies only require one single promoter and terminator, and greatly simplify the structure of the expression cassette. Although the editing efficiency has decreased, both methods are still applicable. Taken together, this study provides a powerful addition to the genome editing toolbox of C. glutamicum and facilitates genetic modification of this strain.
CRISPR-Cas Systems/genetics*
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Corynebacterium glutamicum/metabolism*
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Gene Editing
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Plasmids
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RNA, Guide/metabolism*
8.Construction and application of a synthetic promoter library for Corynebacterium glutamicum.
Moshi LIU ; Jiao LIU ; Guannan SUN ; Fuping LU ; Yu WANG ; Ping ZHENG ; Jibin SUN
Chinese Journal of Biotechnology 2022;38(2):831-842
Promoter is an important genetic tool for fine-tuning of gene expression and has been widely used for metabolic engineering. Corynebacterium glutamicum is an important chassis for industrial biotechnology. However, promoter libraries that are applicable to C. glutamicum have been rarely reported, except for a few developed based on synthetic sequences containing random mutations. In this study, we constructed a promoter library based on the native promoter of odhA gene by mutating the -10 region and the bystanders. Using a red fluorescent protein (RFP) as the reporter, 57 promoter mutants were screened by fluorescence imaging technology in a high-throughput manner. These mutants spanned a strength range between 2.4-fold and 19.6-fold improvements of the wild-type promoter. The strongest mutant exhibited a 2.3-fold higher strength than the widely used strong inducible promoter Ptrc. Sequencing of all 57 mutants revealed that 55 mutants share a 1-4 bases shift (4 bases shift for 68% mutants) of the conserved -10 motif "TANNNT" to the 3' end of the promoter, compared to the wild-type promoter. Conserved T or G bases at different positions were observed for strong, moderate, and weak promoter mutants. Finally, five promoter mutants with different strength were employed to fine-tune the expression of γ-glutamyl kinase (ProB) for L-proline biosynthesis. Increased promoter strength led to enhanced L-proline production and the highest L-proline titer of 6.4 g/L was obtained when a promoter mutant with a 9.8-fold higher strength compared to the wild-type promoter was used for ProB expression. The use of stronger promoter variants did not further improve L-proline production. In conclusion, a promoter library was constructed based on a native C. glutamicum promoter PodhA. The new promoter library should be useful for systems metabolic engineering of C. glutamicum. The strategy of mutating native promoter may also guide the construction of promoter libraries for other microorganisms.
Corynebacterium glutamicum/metabolism*
;
Gene Library
;
Metabolic Engineering
;
Promoter Regions, Genetic/genetics*
9.Biomanufacturing driven by engineered microbes.
Chinese Journal of Biotechnology 2022;38(4):1267-1294
This article summarized the reviews and research articles published in Chinese Journal of Biotechnology in the field of biomanufacturing in 2021. The article covered major chassis cells such as Escherichia coli, Bacillus subtilis, Corynebacterium glutamicum, Saccharomyces cerevisiae, filamentous fungi, non-model bacteria and non-conventional yeasts. Moreover, this article summarized the advances in the production of amino acids, organic acids, vitamins, higher alcohols, natural compounds (terpenoids, flavonoids, alkaloids), antibiotics, enzymes and enzyme-catalyzed products, biopolymers, as well as the utilization of biomass and one-carbon materials. The key technologies used in the construction of cell factories, such as regulation, evolution, and high-throughput screening, were also included. This article may help the readers better understand the R & D trend in biomanufacturing driven by engineered microbes.
Biomass
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Biotechnology
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Corynebacterium glutamicum/metabolism*
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Escherichia coli/metabolism*
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Metabolic Engineering
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Saccharomyces cerevisiae/genetics*
10.Effect of key notes of TCA cycle on L-glutamate production.
Zhina QIAO ; Meijuan XU ; Mengfei LONG ; Taowei YANG ; Xian ZHANG ; Nakanishi HIDEKI ; Zhiming RAO
Chinese Journal of Biotechnology 2020;36(10):2113-2125
Glutamic acid is an important amino acid with wide range of applications and huge market demand. Therefore, by performing transcriptome sequencing and re-sequencing analysis on Corynebacterium glutamicum E01 and high glutamate-producing strain C. glutamicum G01, we identified and selected genes with significant differences in transcription and gene levels in the central metabolic pathway that may have greatly influenced glutamate synthesis and further increased glutamic acid yield. The oxaloacetate node and α-ketoglutarate node play an important role in glutamate synthesis. The oxaloacetate node and α-ketoglutarate node were studied to explore effect on glutamate production. Based on the integrated strain constructed from the above experimental results, the growth rate in a 5-L fermenter was slightly lower than that of the original strain, but the glutamic acid yield after 48 h reached (136.1±5.53) g/L, higher than the original strain (93.53±4.52) g/L, an increase by 45.5%; sugar-acid conversion rate reached 58.9%, an increase of 13.7% compared to 45.2% of the original strain. The application of the above experimental strategy improved the glutamic acid yield and the sugar-acid conversion rate, and provided a theoretical basis for the metabolic engineering of Corynebacterium glutamicum.
Citric Acid Cycle
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Corynebacterium glutamicum/metabolism*
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Glutamic Acid/metabolism*
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Metabolic Engineering
;
Metabolic Networks and Pathways/genetics*