Increasing the robustness of <i>Escherichia coli</i> for aromatic chemicals production through transcription factor engineering

Xiao-Ling Zhou; Meng-Sang Zhang; Xing-Run Zheng; Zhi-Qian Zhang; Jian-Zhong Liu

doi:10.1007/s44307-024-00023-x

Advanced Biotechnology ›› 2024, Vol. 2 ›› Issue (2) : 0. DOI: 10.1007/s44307-024-00023-x

Article

Increasing the robustness of Escherichia coli for aromatic chemicals production through transcription factor engineering

Author information +

History +

Abstract

Engineering microbial cell factories has been widely used to produce a variety of chemicals, including natural products, biofuels, and bulk chemicals. However, poor robustness limits microbial production on an industrial scale. Microbial robustness is essential to ensure reliable and sustainable production of targeted chemicals. In this study, we developed an approach to screen transcription factors to improve robustness using CRSPRa technology. We applied this approach to identify some transcription factors to increase the robustness of Escherichia coli to aromatic chemicals. Activation of hdfR , yldP , purR , sosS , ygeH , cueR , cra, and treR increased the robustness of E. coli to phenyllactic acid. Upregulation of some transcription factors also improved the robustness to caffeic acid (cra) or tyrosol (cra , cueR , treR , soxS , hdfR and purR). Our study demonstrated that transcription factor engineering using CRISPRa is a powerful method to increase microbial robustness. This research provides new approaches to efficiently find genes responsible for increasing microbial robustness.

Keywords

Robustness / Aromatic chemicals / Transcription factor / Escherichia coli

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾

Xiao-Ling Zhou, Meng-Sang Zhang, Xing-Run Zheng, Zhi-Qian Zhang, Jian-Zhong Liu. Increasing the robustness of Escherichia coli for aromatic chemicals production through transcription factor engineering. Advanced Biotechnology, 2024, 2(2): 0 https://doi.org/10.1007/s44307-024-00023-x

References

Publishing order | Descend order by publishing year | Descend order by cited within

[]	Alper H, Stephanopoulos G. Global transcription machinery engineering: A new approach for improving cellular phenotype. Metab Eng, 2007, 9(3): 258-267, CrossRef Pubmed Google scholar

[]	Chen T, Wang J, Yang R, Li J, Lin M, Lin Z. Laboratory-evolved mutants of an exogenous global regulator, IrrE from Deinococcus radiodurans, enhance stress tolerances of Escherichia coli. PLoS ONE, 2011, 6(1), pmcid: 3022760 CrossRef Pubmed Google scholar

[]

Cheng

, Sun

, Chang

, Cui

, Xue

, Shen

, Wang

, Luo

. Compatible solutes adaptive alterations in Arthrobacter simplex during exposure to ethanol, and the effect of trehalose on the stress resistance and biotransformation performance. Bioprocess Biosyst Eng, 2020, 43: 895-908,

CrossRef Pubmed Google scholar

[]	Chong HQ, Geng HF, Zhang HF, Song H, Huang L, Jiang RR. Enhancing E. coli isobutanol tolerance through engineering its global transcription factor cAMP receptor protein (CRP). Biotechnol Bioeng., 2014, 111(4): 700-8, CrossRef Pubmed Google scholar

[]	Deng C, Lv X, Li J, Zhang H, Liu Y, Du G, Amaro RL, Liu L. Synergistic improvement of N-acetylglucosamine production by engineering transcription factors and balancing redox cofactors. Metab Eng, 2021, 67: 330-346, CrossRef Pubmed Google scholar

[]	Dong C, Fontana J, Patel A, Carothers JM, Zalatan JG. Synthetic CRISPR-Cas gene activators for transcriptional reprogramming in bacteria. Nat Commun, 2018, 9: 2489, pmcid: 6021436 CrossRef Pubmed Google scholar

[]	Fontana J, Dong C, Kiattisewee C, Chavali VP, Tickman BI, Carothers JM, et al.. Effective CRISPRa-mediated control of gene expression in bacteria must overcome strict target site requirements. Nat Commun, 2020, 11(1): 1618, pmcid: 7113249 CrossRef Pubmed Google scholar

[]	Gong ZW, Nielsen J, Zhou YJJ. Engineering robustness of microbial cell factories. Biotechnol J, 2017, 12(10): 1700014, CrossRef Google scholar

[]	Guo SF, Yi XY, Zhang WM, Wu MK, Xin FX, Dong WL, et al.. Inducing hyperosmotic stress resistance in succinate-producing Escherichia coli by using the response regulator DR1558 from Deinococcus radiodurans. Process Biochem, 2017, 61: 30-37, CrossRef Google scholar

[]	Jiang Y, Chen B, Duan C, Sun B, Yang J, Yang S. Multigene editing in the Escherichia coli genome via the CRISPR-Cas9 system. Appl Environ Microbiol, 2015, 81(7): 2506-2514, pmcid: 4357945 CrossRef Pubmed Google scholar

[]	Li XR, Tian GQ, Shen HJ, Liu JZ. Metabolic engineering of Escherichia coli to produce zeaxanthin. J Ind Microbiol Biotechnol, 2015, 42(4): 627-636, CrossRef Pubmed Google scholar

[]	Livak KJ, Schmittgen TD. Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method. Methods, 2001, 25(4): 402-408, CrossRef Pubmed Google scholar

[]	Liu JZ, Zhou XL. Construction of recombinant Escherichia coli for the production of phenyllactic acid and its use. China patient CN202210547622.0. 2022.

[]	Lu Q, Liu JZ. Enhanced astaxanthin production in Escherichia coli via morphology and oxidative stress engineering. J Agric Food Chem, 2019, 67(42): 11703-11709, CrossRef Pubmed Google scholar

[]	Lu Q, Zhou XL, Liu JZ. Adaptive laboratory evolution and shuffling of Escherichia coli to enhance its tolerance and production of astaxanthin. Biotechnol Biof Biop, 2022, 15(1): 17

[]	Mohedano MT, Konzock O, Chen Y. Strategies to increase tolerance and robustness of industrial microorganisms. Syn Syst Biotechnol, 2022, 7(1): 533-540, CrossRef Google scholar

[]	Niu FX, Huang YB, Ji LN, Liu JZ. Genomic and transcriptional changes in response to pinene tolerance and overproduction in evolved Escherichia coli. Syn Syst Biotechno, 2019, 4(3): 113-119, CrossRef Google scholar

[]	Niu FX, Du YP, Huang YB, Zhou HT, Liu JZ. Recent advances in the production of phenylpropanoic acids and their derivatives by genetically engineered microorganisms. Syn Biol J, 2020, 1(3): 337-357

[]	Patnaik R, Liao JC. Engineering of Escherichia coli central metabolism for aromatic metabolite production with near theoretical yield. Appl Environ Microbiol, 1994, 60(11): 3903-3908, pmcid: 201913 CrossRef Pubmed Google scholar

[]	Pereira R, Mohamed ET, Radi MS, Herrgård MJ, Feist AM, Nielsen J, Chen Y. Elucidating aromatic acid tolerance at low pH in Saccharomyces cerevisiae using adaptive laboratory evolution. Proc Natl Acad Sci, 2020, 117: 27954-27961, pmcid: 7668050 CrossRef Pubmed Google scholar

[]

Qin

, Dong

, Yu

, Ning

, Xu

, Zhang

S-J

, Xu

, Li

B-Z

, Li

, Yuan

Y-J

, Li

. Stress-driven dynamic regulation of multiple tolerance genes improves robustness and productive capacity of Saccharomyces cerevisiae in industrial lignocellulose fermentation. Metab Eng, 2020, 61: 160-170,

CrossRef Pubmed Google scholar

[]	Sariaslani FS. Development of a combined biological and chemical process for production of industrial aromatics from renewable resources. Annu Rev Microbiol, 2007, 61: 51-69, CrossRef Pubmed Google scholar

[]

Shen

, Fong

, Yan

, Liu

. Combining directed evolution of pathway enzymes and dynamic pathway regulation using a quorum-sensing circuit to improve the production of 4-hydroxyphenylacetic acid in Escherichia coli. Biotechnol Biofuels, 2019, 12: 94, pmcid: 6477704

CrossRef Pubmed Google scholar

[]	Shen YP, Niu FX, Yan ZB, Fong LS, Huang YB, Liu JZ. Recent advances in metabolically engineered microorganisms for the production of aromatic chemicals derived from aromatic amino acids. Front Bioeng Biotechnol, 2020, 8: 407, pmcid: 7214760 CrossRef Pubmed Google scholar

[]	Shen YP, Liao YL, Lu Q, He X, Yan ZB, Liu JZ. ATP and NADPH engineering of Escherichia coli to improve the production of 4-hydroxyphenylacetic acid using CRISPRi. Biotechnol Biofuels, 2021, 14(1): 100, pmcid: 8056492 CrossRef Pubmed Google scholar

[]	Shen YP, Pan Y, Niu FX, Liao YL, Huang M, Liu JZ. Biosensor-assisted evolution for high-level production of 4-hydroxyphenylacetic acid in Escherichia coli. Metab Eng, 2022, 70: 1-11, CrossRef Pubmed Google scholar

[]	Swinnen S, Henriques SF, Shrestha R, Ho PW, Sa-Correia I, Nevoigt E. Improvement of yeast tolerance to acetic acid through Haa1 transcription factor engineering: towards the underlying mechanisms. Microb Cell Fact, 2017, 16: 7, pmcid: 5220606 CrossRef Pubmed Google scholar

[]	Tao YX, Wang HX, Wang JN, Jiang WK, Jiang YJ, Xin FX, et al.. Strategies to improve the stress resistance of Escherichia coli in industrial biotechnology. Biofuel Bioprod Bior, 2022, 16(4): 1130-1141, CrossRef Google scholar

[]	Wang L, Li N, Yu S, Zhou J. Enhancing caffeic acid production in Escherichia coli by engineering the biosynthesis pathway and transporter. Bioresour Technol, 2023, 368, CrossRef Pubmed Google scholar

[]	Xu K, Gao L, Hassan JU, Zhao Z, Li C, Huo Y-X, Liu G. Improving the thermo-tolerance of yeast base on the antioxidant defense system. Chem Eng Sci, 2018, 175: 335-342, CrossRef Google scholar

[]	Xu P, Lin NQ, Zhang ZQ, Liu JZ. Strategies to increase the robustness of microbial cell factories. Adv Biotechnol, 2024, 2: 9, CrossRef Google scholar

[]	Yan ZB, Liang JL, Niu FX, Shen YP, Liu JZ. Enhanced production of pterostilbene in Escherichia coli through directed evolution and host strain engineering. Front Microbiol, 2021, 12, pmcid: 8530161 CrossRef Pubmed Google scholar

[]	Zhang HF, Chong HQ, Ching CB, Jiang RR. Random mutagenesis of global transcription factor cAMP receptor protein for improved osmotolerance. Biotechnol Bioeng, 2012, 109(5): 1165-1172, CrossRef Pubmed Google scholar

[]	Zhu C, Chen J, Wang Y, Wang L, Guo X, Chen N, Zheng P, Sun J, Ma Y. Enhancing 5-aminolevulinic acid tolerance and production by engineering the antioxidant defense system of Escherichia coli. Biotechnol Bioeng, 2019, 116: 2018-2028, CrossRef Pubmed Google scholar