Abstract
BackgroundGlycolic acid (GA) is a two-carbon hydroxyacid with applications in the cosmetic, textile, and medical industry. Microbial GA production from all sugars can be achieved by engineering the natural glyoxylate shunt. The synthetic (d)-xylulose-1 phosphate (X1P) pathway provides a complementary route to produce GA from (d)-xylose. The simultaneous operation of the X1P and glyoxylate pathways increases the theoretical GA yield from xylose by 20 %, which may strongly improve GA production from hemicellulosic hydrolysates.ResultsWe herein describe the construction of an E. coli strain that produces GA via the glyoxylate pathway at a yield of 0.31 , 0.29 , and 0.37 g/g from glucose, xylose, or a mixture of glucose and xylose (mass ratio: 33:66 %), respectively. When the X1P pathway operates in addition to the glyoxylate pathway, the GA yields on the three substrates are, respectively, 0.39 , 0.43 , and 0.47 g/g. Upon constitutive expression of the sugar permease GalP, the GA yield of the strain which simultaneously operates the glyoxylate and X1P pathways further increases to 0.63 g/g when growing on the glucose/xylose mixture. Under these conditions, the GA yield on the xylose fraction of the sugar mixture reaches 0.75 g/g, which is the highest yield reported to date.ConclusionsThese results demonstrate that the synthetic X1P pathway has a very strong potential to improve GA production from xylose-rich hemicellulosic hydrolysates.
Highlights
Glycolic acid (GA) is a two-carbon hydroxyacid with applications in the cosmetic, textile, and medical industry
We found that the strains Pen1043 and Pen1048 which expressed plasmid which express the ketohexokinase C (pX1P) alone produced no GA, confirming that pGS that bears GhrA and AceA genes was required for GA production through the glyoxylate shunt (Table 5)
We have demonstrated that the simultaneous operation of the synthetic xylulose-1 phosphate (X1P) and the engineered glyoxylate pathways greatly increases the GA yield on xylose-rich sugar mixtures
Summary
Glycolic acid (GA) is a two-carbon hydroxyacid with applications in the cosmetic, textile, and medical industry. Microbial GA production from all sugars can be achieved by engineering the natural glyoxylate shunt. The simultaneous operation of the X1P and glyoxylate pathways increases the theoretical GA yield from xylose by 20 %, which may strongly improve GA production from hemicellulosic hydrolysates. Glycolic acid (GA) is a two-carbon hydroxycarboxylic acid of considerable industrial interest. It is used as a tanning, peeling, and cleaning agent in the cosmetic and textile industry [1,2,3]. GA is produced from fossil resources by treating formaldehyde with carbon monoxide [8], or by treating chloroacetic acid with sodium hydroxide [2]. The best results were obtained with an optimized Escherichia coli strain which produced 56 g/l GA at a yield of 0.52 g/g in a fed-batch reactor using glucose as the carbon source ([11], Table 1)
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