Abstract
BackgroundGlycolate is an important α-hydroxy carboxylic acid widely used in industrial and consumer applications. The production of glycolate from glucose in Escherichia coli is generally carried out by glycolysis and glyoxylate shunt pathways, followed by reduction to glycolate. Glycolate accumulation was significantly affected by nitrogen sources and isocitrate dehydrogenase (ICDH), which influenced carbon flux distribution between the tricarboxylic acid (TCA) cycle and the glyoxylate shunt, however, the mechanism was unclear.ResultsHerein, we used RNA-Seq to explore the effects of nitrogen sources and ICDH knockout on glycolate production. The Mgly534 strain and the Mgly624 strain (with the ICDH deletion in Mgly534), displaying different phenotypes on organic nitrogen sources, were also adopted for the exploration. Though the growth of Mgly534 was improved on organic nitrogen sources, glycolate production decreased and acetate accumulated, while Mgly624 achieved a balance between cell growth and glycolate production, reaching 0.81 g glycolate/OD (2.6-fold higher than Mgly534). To further study Mgly624, the significant changed genes related to N-regulation, oxidative stress response and iron transport were analyzed. Glutamate and serine were found to increase the biomass and productivity respectively. Meanwhile, overexpressing the arginine transport gene argT accelerated the cell growth rate and increased the biomass. Further, the presence of Fe2+ also speeded up the cells growth and compensated for the lack of reducing equivalents.ConclusionOur studies identified that ICDH knockout strain was more suitable for glycolate production. RNA-Seq provided a better understanding of the ICDH knockout on cellular physiology and glycolate production.
Highlights
Glycolate is an important α-hydroxy carboxylic acid widely used in industrial and consumer applications
Effects of organic nitrogen sources and isocitrate dehydrogenase (ICDH) knockout on cell growth and glycolate production When Mgly534 grew on M9 minimal medium, 24 h was needed to reach stationary phase, producing 3.55 g/L glycolate from 10 g/L glucose after 50 h (Fig. 2a)
Mgly534 overexpressing aceAK and ycdW achieved a high titer of glycolate, we hypothesized that disruption of the tricarboxylic acid (TCA) cycle by deleting the ICDH might direct more carbon to the glyoxylate shunt for glycolate production
Summary
Glycolate is an important α-hydroxy carboxylic acid widely used in industrial and consumer applications. Glycolate is the smallest alpha-hydroxy acid containing both alcohol carboxy groups. It is used as a tanning, peeling, and cleaning agent in the cosmetic and textile industries [1]. Deng et al reported that by overexpressing native aceAK and ycdW, and deleting competitive pathways, the engineered Escherichia coli strain produced more than 65 g/L glycolate, the highest glycolate titer. RNA-Seq has revolutionized transcriptome analysis by facilitating the expression profiling of thousands of genes at the same time [6, 7]. This technique is mainly applied to study transcriptome differences caused by various treatments [8]. Through RNA-Seq we could investigate global transcriptional changes and have new insights into glycolate-producing strains [9,10,11]
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