Protein scaffold optimizes arrangement of constituent enzymes in indigoidine synthetic pathway to improve the pigment production

IF 3.9 3区 生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Lei Wang, Yue Sun, Di Lv, Bin Liu, Yuekai Guan, Dayu Yu
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引用次数: 2

Abstract

Indigoidine is a dark-blue natural pigment with application prospect and synthesized from glutamine (Gln) by series of indigoidine synthetases (IndCs). Indigoidine production can be improved by enhancing Gln pool via supplementing Gln directly or converting metabolism glutamate (Glu) to Gln by glutamine synthetase (GlnA). But, Gln is expensive, and excess Gln inhibits indigoidine production of the recombinant strain. Supplementing Glu instead of Gln may improve the productive and economic efficiency of indigoidine, but the local activities and positions of the indigoidine pathway enzymes GlnA, Sc-IndC, and the helper protein of Sc-IndC (IndB) should be well arranged. We identified the Streptomyces chromofuscus ATCC 49982 derived IndC (Sc-IndC) as an more efficient IndC compared to other IndCs applied for constructing indigoidine-producting strains, and designed series of protein scaffold complexes with architectures of PDZ, SH3, and GBD domains (PxSyG1) to arrange the pathway enzymes. The strain recruiting GlnA, Sc-IndC, and IndB on the PDZ, SH3, and GBD domains of scaffold P1S2G1, respectively, was the most efficient. In the strain, the GlnA supplied sufficient local Gln for Sc-IndC from Glu, and the generated Gln was immediately consumed by Sc-IndC to relieve cell growth inhibition caused by Gln. The optimum Glu concentration (6 g/L) for the strain was higher than those of the strains recruiting Sc-IndC on the GBD domain, which was away from the PDZ domain recruiting GlnA. The highest titer of indigoidine was 12 g/L, which was two folds of the control without scaffold (5.8 g/L). The titer is 5 g/L higher than the control without Glu supplemented (6.9 g/L), meaning that 97% of the supplemented Glu was transformed into indigoidine. The batch fermentation with the optimum strain in a 5-L reactor achieved an indigoidine titer of 14 g/L in 60 h. To our knowledge, this was the most efficient indigoidine productivity achieved so far. The optimization strategies by protein scaffold should be applicative to other pathways with complex substrate demands.

蛋白质支架优化靛蓝苷合成途径中组成酶的排列,提高色素产量
靛蓝是一种具有应用前景的深蓝色天然色素,由谷氨酰胺(Gln)经一系列靛蓝合成酶(IndCs)合成。靛蓝的产生可以通过直接补充Gln来增强Gln库,或者通过谷氨酰胺合成酶(GlnA)将代谢谷氨酸(Glu)转化为Gln来提高。但是,Gln是昂贵的,并且过量的Gln抑制重组菌株的靛蓝苷的产生。补充Glu而不是Gln可以提高靛蓝苷的生产效率和经济效率,但靛蓝苷途径酶GlnA、Sc-IndC和Sc-IndC的辅助蛋白(IndB)的局部活性和位置应该安排好。与其他用于构建靛蓝苷生产菌株的IndC相比,我们鉴定了嗜色链霉菌ATCC 49982衍生的IndC(Sc-IndC)是一种更有效的IndC,并设计了一系列具有PDZ、SH3和GBD结构域(PxSyG1)结构的蛋白质支架复合物来排列途径酶。在支架P1S2G1的PDZ、SH3和GBD结构域上分别招募GlnA、Sc-IndC和IndB的菌株是最有效的。在该菌株中,GlnA从Glu为Sc-IndC提供了足够的局部Gln,并且产生的Gln立即被Sc-IndC消耗,以减轻Gln引起的细胞生长抑制。该菌株的最适Glu浓度(6g/L)高于在GBD结构域上招募Sc-IndC的菌株,而在PDZ结构域上则远离招募GlnA的菌株。靛蓝苷的最高滴度为12g/L,是没有支架的对照(5.8g/L)的两倍,比没有添加Glu的对照(6.9g/L)高5g/L,这意味着97%的添加Glu转化为靛蓝苷。在5L反应器中用最佳菌株分批发酵在60小时内获得14g/L的靛蓝效价。据我们所知,这是迄今为止靛蓝生产效率最高的一次。蛋白质支架的优化策略应适用于其他具有复杂底物需求的途径。
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来源期刊
Applied Microbiology and Biotechnology
Applied Microbiology and Biotechnology 工程技术-生物工程与应用微生物
CiteScore
10.00
自引率
4.00%
发文量
535
审稿时长
2 months
期刊介绍: Applied Microbiology and Biotechnology focusses on prokaryotic or eukaryotic cells, relevant enzymes and proteins; applied genetics and molecular biotechnology; genomics and proteomics; applied microbial and cell physiology; environmental biotechnology; process and products and more. The journal welcomes full-length papers and mini-reviews of new and emerging products, processes and technologies.
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