Your search keyword '"Lv, Xueqin"' showing total 8 results

1. Combinatorial pathway enzyme engineering and host engineering overcomes pyruvate overflow and enhances overproduction of N-acetylglucosamine in Bacillus subtilis

Author

Ma, Wenlong, Liu, Yanfeng, Lv, Xueqin, Li, Jianghua, Du, Guocheng, and Liu, Long

Published

2019

2. Synergistic improvement of N-acetylglucosamine production by engineering transcription factors and balancing redox cofactors.

Author

Deng, Chen, Lv, Xueqin, Li, Jianghua, Zhang, Hongzhi, Liu, Yanfeng, Du, Guocheng, Amaro, Rodrigo Ledesma, and Liu, Long

Subjects

*PRODUCTION engineering, *N-acetylglucosamine, *TRANSCRIPTION factors, *CORYNEBACTERIUM glutamicum, *OXIDATION-reduction reaction, *METABOLIC regulation

Abstract

The regulation of single gene transcription level in the metabolic pathway is often failed to significantly improve the titer of the target product, and even leads to the imbalance of carbon/nitrogen metabolic network and cofactor network. Global transcription machinery engineering (gTME) can activate or inhibit the synergistic expression of multiple genes in specific metabolic pathways, so transcription factors with specific functions can be expressed according to different metabolic regulation requirements, thus effectively increasing the synthesis of target metabolites. In addition, maintaining intracellular redox balance through cofactor engineering can realize the self-balance of cofactors and promote the efficient synthesis of target products. In this study, we rebalanced the central carbon/nitrogen metabolism and redox metabolism of Corynebacterium glutamicum S9114 by gTME and redox cofactors engineering to promote the production of the nutraceutical N-acetylglucosamine (GlcNAc). Firstly, it was found that the overexpression of the transcription factor RamA can promote GlcNAc synthesis, and the titer was further improved to 16 g/L in shake flask by using a mutant RamA (RamAM). Secondly, a CRISPR interference (CRISPRi) system based on dCpf1 was developed and used to inhibit the expression of global negative transcriptional regulators of GlcNAc synthesis, which promoted the GlcNAc titer to 27.5 g/L. Thirdly, the cofactor specificity of the key enzymes in GlcNAc synthesis pathway was changed by rational protein engineering, and the titer of GlcNAc in shake flask was increased to 36.9 g/L. Finally, the production of GlcNAc was scaled up in a 50-L fermentor, and the titer reached 117.1 ± 1.9 g/L, which was 6.62 times that of the control group (17.7 ± 0.4 g/L), and the yield was increased from 0.19 g/g to 0.31 g/g glucose. The results obtained here highlight the importance of engineering the global regulation of central carbon/nitrogen metabolism and redox metabolism to improve the production performance of microbial cell factories. • Global transcription machinery engineering was used to increase GlcNAc production. • Redox metabolism was balanced to achieve high GlcNAc titer. • A CRISPR-dCpf1 based CRISPR interference system was constructed in Corynebacterium glutamicum S9114. • 117.1 ± 1.9 g/L GlcNAc was produced in 50-L fermentor. [ABSTRACT FROM AUTHOR]

Published

2021

3. The elucidation of phosphosugar stress response in Bacillus subtilis guides strain engineering for high N‐acetylglucosamine production.

Author

Niu, Tengfei, Lv, Xueqin, Liu, Yanfeng, Li, Jianghua, Du, Guocheng, Ledesma‐Amaro, Rodrigo, and Liu, Long

Abstract

Bacillus subtilis is a preferred microbial host for the industrial production of nutraceuticals and a promising candidate for the synthesis of functional sugars, such as N‐acetylglucosamine (GlcNAc). Previously, a GlcNAc‐overproducer B. subtilis SFMI was constructed using glmS ribozyme dual‐regulatory tool. Herein, we further engineered to enhance carbon flux from glucose towards GlcNAc synthesis. As a result, the increased flux towards GlcNAc synthesis triggered phosphosugar stress response, which caused abnormal cell growth. Unfortunately, the mechanism of phosphosugar stress response had not been elucidated in B. subtilis. To reveal the stress mechanism and overcome its negative effect in bioproduction, we performed comparative transcriptome analysis. The results indicate that cells slow glucose utilization by repression of glucose import and accelerate catabolic reactions of phosphosugar. To verify these results, we overexpressed the phosphatase YwpJ, which relieved phosphosugar stress and allowed us to identify the enzyme responsible for GlcNAc synthesis from GlcNAc 6‐phosphate. In addition, the deletion of nagBB and murQ, responsible for GlcNAc precursor degradation, further improved GlcNAc synthesis. The best engineered strain, B. subtilis FMIP34, increased GlcNAc titer from 11.5 to 26.1 g/L in shake flasks and produced 87.5 g/L GlcNAc in 30‐L fed‐batch bioreactor. Our results not only elucidate, for the first time, the phosphosugar stress response mechanism in B. subtilis, but also demonstrate how the combination of rational metabolic engineering with novel insights into physiology and metabolism allows the construction of highly efficient microbial cell factories for the production of high‐value chemicals. [ABSTRACT FROM AUTHOR]

Published

2021

4. Assembly of pathway enzymes by engineering functional membrane microdomain components for improved N-acetylglucosamine synthesis in Bacillus subtilis.

Author

Lv, Xueqin, Zhang, Cheng, Cui, Shixiu, Xu, Xianhao, Wang, Lingling, Li, Jianghua, Du, Guocheng, Chen, Jian, Ledesma-Amaro, Rodrigo, and Liu, Long

Subjects

*BACILLUS subtilis, *LYSIS, *ENZYMES, *N-acetylglucosamine, *CELL membranes

Abstract

Enzyme clustering can improve catalytic efficiency by facilitating the processing of intermediates. Functional membrane microdomains (FMMs) in bacteria can provide a platform for enzyme clustering. However, the amount of FMMs at the cell basal level is still facing great challenges in multi-enzyme immobilization. Here, using the nutraceutical N-acetylglucosamine (GlcNAc) synthesis in Bacillus subtilis as a model, we engineered FMM components to improve the enzyme assembly in FMMs. First, by overexpression of the SPFH (stomatin-prohibitin-flotillin-HflC/K) domain and YisP protein, an enzyme involved in the synthesis of squalene-derived polyisoprenoid, the membrane order of cells was increased, as verified using di-4-ANEPPDHQ staining. Then, two heterologous enzymes, GlcNAc-6-phosphate N-acetyltransferase (GNA1) and haloacid dehalogenase-like phosphatases (YqaB), required for GlcNAc synthesis were assembled into FMMs, and the GlcNAc titer in flask was increased to 8.30 ± 0.57 g/L, which was almost three times that of the control strains. Notably, FMM component modification can maintain the OD 600 in stationary phase and reduce cell lysis in the later stage of fermentation. These results reveal that the improved plasma membrane ordering achieved by the engineering FMM components could not only promote the enzyme assembly into FMMs, but also improve the cell fitness. • The plasma membrane order degree was improved by the engineering of FMM components. • FMM component modification promoted the enzyme assembly to increase the synthesis of GlcNAc. • FMM component modification can obviously improve the cell fitness at the later stage of fermentation. [ABSTRACT FROM AUTHOR]

Published

2020

5. Enzyme assembly guided by SPFH‐induced functional inclusion bodies for enhanced cascade biocatalysis.

Author

Lv, Xueqin, Jin, Ke, Wu, Yaokang, Zhang, Cheng, Cui, Shixiu, Zhu, Xiaonan, Li, Jianghua, Du, Guocheng, and Liu, Long

Abstract

Enzyme clustering into compact agglomerates could accelerate the processing of intermediates to enhance metabolic pathway flux. However, enzyme clustering is still a challenging task due to the lack of universal assembly strategy applicable to all enzymes. Therefore, we proposed an alternative enzyme assembly strategy based on functional inclusion bodies. First, functional inclusion bodies in cells were formed by the fusion expression of stomatin/prohibitin/flotillin/HflK/C (SPFH) domain and enhanced green fluorescent protein, as observed visually and by transmission electron microscopy. The formation of SPFH‐induced functional inclusion bodies enhanced intermolecular polymerization as revealed by further analysis combined with Förster resonance energy transfer and bimolecular fluorescent complimentary. Finally, the functional inclusion bodies significantly improved the enzymatic catalysis in living cells, as proven by the examples with whole‐cell biocatalysis of phenyllactic acid by Escherichia coli, and the production of N‐acetylglucosamine by Bacillus subtilis. Our findings suggest that SPFH‐induced functional inclusion bodies can enhance the cascade reaction of enzymes, to serve as a potential universal strategy for the construction of efficient microbial cell factories. [ABSTRACT FROM AUTHOR]

Published

2020

6. Synergetic engineering of central carbon and nitrogen metabolism for the production of N‐acetylglucosamine in Bacillus subtilis.

Author

Niu, Tengfei, Lv, Xueqin, Liu, Zhenmin, Li, Jianghua, Du, Guocheng, and Liu, Long

Subjects

*CARBON metabolism, *BACILLUS subtilis, *GLUTAMATE dehydrogenase, *RIBOSOMES, *N-acetylglucosamine, *BINDING sites

Abstract

N‐acetylglucosamine (GlcNAc) is a nitrogen‐containing compound, which is widely used as a nutraceutical and pharmaceutical. In our previous work, we constructed a recombinant Bacillus subtilis strain for the biosynthesis of GlcNAc by engineering the central carbon metabolism. However, nitrogen is also required for the synthesis of GlcNAc. Hence, it is necessary to simultaneously coordinate the carbon and nitrogen metabolism to improve production of GlcNAc. In this work, we attempted to enhance GlcNAc production in B. subtilis by increasing supply of precursors N‐acetylglucosamine 6‐phosphate (GlcNAc6P) and glutamate. The expression of a key enzyme, GlcNAc6P N‐acetyltransferase (GNA1), was enhanced by engineering the promoter and ribosome binding site to enhance the production of GlcNAc6P. Next, we examined the effect of different nitrogen sources on GlcNAc synthesis. We observed that urea can promote nitrogen assimilation for GlcNAc synthesis. The glutamate synthesis was improved by deleting the two endogenous glutamate dehydrogenase genes (rocG and gudB) and by integrating one exogenous glutamate dehydrogenase gene (gdh). This strategy enhanced the intracellular glutamate and glutamine by 69.8% and 46.9%, respectively. The synergetic engineering of central carbon and nitrogen metabolisms increased the GlcNAc titer from 14.0 to 22.2 g/L in the shaker flask. Hence, our study demonstrated the importance of carbon and nitrogen metabolism coordination in the production of nitrogen‐containing compounds. [ABSTRACT FROM AUTHOR]

Published

2020

7. Synthetic redesign of central carbon and redox metabolism for high yield production of N-acetylglucosamine in Bacillus subtilis.

Author

Gu, Yang, Lv, Xueqin, Liu, Yanfeng, Li, Jianghua, Du, Guocheng, Chen, Jian, Rodrigo, Ledesma-Amaro, and Liu, Long

Subjects

*BACILLUS subtilis, *BACTERIAL metabolism, *AMINES, *OXIDATION-reduction reaction, *CARBON metabolism

Abstract

Abstract One of the primary goals of microbial metabolic engineering is to achieve high titer, yield and productivity (TYP) of engineered strains. This TYP index requires optimized carbon flux toward desired molecule with minimal by-product formation. De novo redesign of central carbon and redox metabolism holds great promise to alleviate pathway bottleneck and improve carbon and energy utilization efficiency. The engineered strain, with the overexpression or deletion of multiple genes, typically can't meet the TYP index, due to overflow of central carbon and redox metabolism that compromise the final yield, despite a high titer or productivity might be achieved. To solve this challenge, we reprogramed the central carbon and redox metabolism of Bacillus subtilis and achieved high TYP production of N -acetylglucosamine. Specifically, a "push–pull–promote" approach efficiently reduced the overflown acetyl-CoA flux and eliminated byproduct formation. Four synthetic NAD(P)-independent metabolic routes were introduced to rewire the redox metabolism to minimize energy loss. Implementation of these genetic strategies led us to obtain a B. subtilis strain with superior TYP index. GlcNAc titer in shake flask was increased from 6.6 g L−1 to 24.5 g L−1, the yield was improved from 0.115 to 0.468 g GlcNAc g−1 glucose, and the productivity was increased from 0.274 to 0.437 g L−1 h−1. These titer and yield are the highest levels ever reported and, the yield reached 98% of the theoretical pathway yield (0.478 g g−1 glucose). The synthetic redesign of carbon metabolism and redox metabolism represent a novel and general metabolic engineering strategy to improve the performance of microbial cell factories. Highlights • First description of yield depends on theoretical pathway yield and rigidity. • Simultaneous coordination of carbon and redox metabolism achieved high TYP. • Introduction of synthetic reactions coordinated the imbalanced redox metabolism. [ABSTRACT FROM AUTHOR]

Published

2019

8. CRISPRi allows optimal temporal control of N-acetylglucosamine bioproduction by a dynamic coordination of glucose and xylose metabolism in Bacillus subtilis.

Author

Wu, Yaokang, Chen, Taichi, Liu, Yanfeng, Lv, Xueqin, Li, Jianghua, Du, Guocheng, Ledesma-Amaro, Rodrigo, and Liu, Long

Subjects

*CRISPRS, *N-acetylglucosamine synthesis, *GLUCOSE derivatives, *XYLOSE, *BACILLUS subtilis genetics, *CATABOLITE repression

Abstract

Abstract Glucose and xylose are the two most abundant sugars in renewable lignocellulose sources; however, typically they cannot be simultaneously utilized due to carbon catabolite repression. N-acetylglucosamine (GlcNAc) is a typical nutraceutical and has many applications in the field of healthcare. Here, we have developed a gene repressor system based on xylose-induced CRISPR interference (CRISPRi) in Bacillus subtilis, aimed at downregulating the expression of three genes (zwf , pfkA , glmM) that control the major competing reactions of GlcNAc synthesis (pentose phosphate pathway (HMP), glycolysis, and peptidoglycan synthesis pathway (PSP)), with the potential to relieve glucose repression and allow the co-utilization of both glucose and xylose. Simultaneous repression of these three genes by CRISPRi improved GlcNAc titer by 13.2% to 17.4 ± 0.47 g/L, with the GlcNAc yield on glucose and xylose showing an 84.1% improvement, reaching 0.42 ± 0.036 g/g. In order to further engineer the synergetic utilization of glucose and xylose, a combinatorial approach was developed based on 27 arrays containing sgRNAs with different repression capacities targeting the three genes. We further optimized the temporal control of the system and found that when 15 g/L xylose was added 6 h after inoculation, the most efficient strain, BNX122, synthesized 20.5 ± 0.85 g/L GlcNAc with a yield of 0.46 ± 0.010 g/g glucose and xylose in shake flask culture. Finally, the GlcNAc titer and productivity in a 3-L fed-batch bioreactor reached 103.1 ± 2.11 g/L and 1.17 ± 0.024 g/L/h, which were 5.0-fold and 2.7-fold of that in shake flask culture, respectively. Taken together, these findings suggest that a CRISPRi-enabled regulation method provides a simple, efficient, and universal way to promote the synergetic utilization of multiple carbon sources by microbial cell factories. Highlights • A xylose induced CRISPRi system was constructed in B. subtilis. • The efficient synergetic utilization of glucose and xylose was achieved. • The first report of utilization of xylose and glucose mixtures for GlcNAc production. • 103.1 ± 2.11 g/L GlcNAc was produced in 3-L fed-batch bioreactor. [ABSTRACT FROM AUTHOR]

Published

2018