用于检测谷氨酸棒杆菌中胆氨酸和顺式、顺式粘液酸的生物传感器。

IF 3.2 4区 生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Journal of Industrial Microbiology & Biotechnology Pub Date : 2024-01-09 DOI:10.1093/jimb/kuae024
Jeanette C Velasquez-Guzman, Herbert M Huttanus, Demosthenes P Morales, Tara S Werner, Austin L Carroll, Adam M Guss, Chris M Yeager, Taraka Dale, Ramesh K Jha
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引用次数: 0

摘要

谷氨酸棒杆菌(Corynebacterium glutamicum)ATCC 13032 是一种很有前途的微生物底盘,可用于工业生产有价值的化合物,包括从莽草酸途径中提取的芳香族氨基酸。在这项工作中,我们开发了两种基于转录因子的全细胞荧光生物传感器,用于跟踪谷氨酸链球菌中的顺式粘多糖酸(ccMA)和氯氨酸。氯代氨基甲酸是莽草酸途径中的一个关键中间体,可从中生产出高附加值的化学品,而莽草酸途径的分流可将碳转移到高附加值化学品 ccMA 上。我们将刺胞杆菌 ADP1 中的 ccMA 诱导转录因子 CatM 移植到谷氨酸球菌中,并筛选了一个启动子文库,通过提供苯甲酸(在细胞内转化为 ccMA),分离出对 ccMA 具有高灵敏度和动态范围的变体。该生物传感器还能检测到外源提供的 ccMA,这表明谷氨酸蘑菇中存在一种假定的 ccMA 转运体,但引起反应的外部 ccMA 浓度阈值比通过细胞内 ccMA 生成所需的苯甲酸浓度高 100 倍。随后,我们开发了一种络氨酸生物传感器,其中的络氨酸诱导启动子由本地表达的 QsuR 调节,经过优化后可对外源补充的奎特(一种络氨酸前体)表现出剂量依赖性反应。在谷氨酸棒状杆菌中引入了络氨酸-丙酮酸裂解酶编码基因 ubiC,以降低细胞内的络氨酸池,从而失去了对醌氨酸的剂量依赖性。此外,阻断奎宁酸转化为络丝氨酸的基因敲除菌株也导致对奎宁酸没有剂量依赖性,从而验证了络丝氨酸生物传感器对细胞内的络丝氨酸池具有特异性。将 ccMA 和氯ismate 生物传感器插入谷氨酸棒状杆菌,可同时检测细胞内产生的氯ismate 和 ccMA。生物传感器,如本研究中开发的生物传感器,可应用于谷氨酸梭菌的多重传感,从而通过代谢工程加速这一前景广阔的底盘生物的途径设计和优化。
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Biosensors for the detection of chorismate and cis,cis-muconic acid in Corynebacterium glutamicum.

Corynebacterium glutamicum ATCC 13032 is a promising microbial chassis for industrial production of valuable compounds, including aromatic amino acids derived from the shikimate pathway. In this work, we developed two whole-cell, transcription factor based fluorescent biosensors to track cis,cis-muconic acid (ccMA) and chorismate in C. glutamicum. Chorismate is a key intermediate in the shikimate pathway from which value-added chemicals can be produced, and a shunt from the shikimate pathway can divert carbon to ccMA, a high value chemical. We transferred a ccMA-inducible transcription factor, CatM, from Acinetobacter baylyi ADP1 into C. glutamicum and screened a promoter library to isolate variants with high sensitivity and dynamic range to ccMA by providing benzoate, which is converted to ccMA intracellularly. The biosensor also detected exogenously supplied ccMA, suggesting the presence of a putative ccMA transporter in C. glutamicum, though the external ccMA concentration threshold to elicit a response was 100-fold higher than the concentration of benzoate required to do so through intracellular ccMA production. We then developed a chorismate biosensor, in which a chorismate inducible promoter regulated by natively expressed QsuR was optimized to exhibit a dose-dependent response to exogenously supplemented quinate (a chorismate precursor). A chorismate-pyruvate lyase encoding gene, ubiC, was introduced into C. glutamicum to lower the intracellular chorismate pool, which resulted in loss of dose dependence to quinate. Further, a knockout strain that blocked the conversion of quinate to chorismate also resulted in absence of dose dependence to quinate, validating that the chorismate biosensor is specific to intracellular chorismate pool. The ccMA and chorismate biosensors were dually inserted into C. glutamicum to simultaneously detect intracellularly produced chorismate and ccMA. Biosensors, such as those developed in this study, can be applied in C. glutamicum for multiplex sensing to expedite pathway design and optimization through metabolic engineering in this promising chassis organism.

One-sentence summary: High-throughput screening of promoter libraries in Corynebacterium glutamicum to establish transcription factor based biosensors for key metabolic intermediates in shikimate and β-ketoadipate pathways.

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来源期刊
Journal of Industrial Microbiology & Biotechnology
Journal of Industrial Microbiology & Biotechnology 工程技术-生物工程与应用微生物
CiteScore
7.70
自引率
0.00%
发文量
25
审稿时长
3 months
期刊介绍: The Journal of Industrial Microbiology and Biotechnology is an international journal which publishes papers describing original research, short communications, and critical reviews in the fields of biotechnology, fermentation and cell culture, biocatalysis, environmental microbiology, natural products discovery and biosynthesis, marine natural products, metabolic engineering, genomics, bioinformatics, food microbiology, and other areas of applied microbiology
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