One-Pot Biosynthesis of l-Aspartate from Maleic Anhydride via a Thermostable Dual-Enzyme System under High Temperature

L-Aspartate is an important chemical in the food and pharmaceutical industries. Herein, a dual-enzyme system was constructed to synthesize L-aspartate from maleic anhydride at 50 degrees C, which can reduce the byproduct production. Maleate transformed from maleic anhydride in the solution was converted into L-aspartate via fumarate catalyzed by maleate isomerase (MaiA) and thermostable aspartase (AspB), respectively. Because MaiA is a rate-limiting enzyme, enzyme activities of various MaiAs were compared, and the efficient and thermostable maleate isomerase AaMaiA from Alicyclobacillus acidoterrestris was chosen. The Kcat/Km value of AaMaiA was 264.4 mM-1 min-1. AaMaiA and AspB were coexpressed in E. coli to produce L-aspartate. To improve the L-aspartate production rate, the ribosome binding site (RBS) sequence located upstream of AaMaiA was optimized and the Tat signal peptide was fused with AaMaiA. The conversion rate was 96% within 60 min, and the intermediate was not detected, the possible reason of which is that high temperature inhibits the activity of bacterial endogenous enzymes, but functional enzymes remain active. Cells from fermentation produced 243.6 g/L (1.83 M) of L-aspartate with a 2 M substrate. Our study revealed an effective method to produce L-aspartate without using gene knockout and provided a strategy for L-aspartate production in the industrial field.