Abstract
L-2-Aminobutyric acid (L-2-ABA) is a non-proteinogenic amino acid and an important chiral intermediate widely used in pharmaceuticals and fine chemicals. However, its fermentative production is limited by intermediate toxicity and imbalanced metabolic flux. In this study, Escherichia coli was systematically engineered for efficient de novo synthesis of L-2-ABA using a multi-layer metabolic engineering strategy. A quorum-sensing-based dynamic control circuit was introduced to decouple cell growth from 2-oxobutyric acid formation, thereby alleviating precursor toxicity and improving flux coordination. Combined with optimization of the L-2-ABA conversion pathway, model-guided carbon flux redistribution, cofactor regeneration, and tuning of global transcriptional regulation, a high-performance production strain was obtained without the need for antibiotics or inducers. The final engineered strain ABA40 achieved 45.3 g/L L-2-ABA with a yield of 0.31 g/g glucose in a 72 h fed-batch fermentation. This study demonstrates the effectiveness of dynamic and integrated metabolic engineering strategies for the biosynthesis of non-natural amino acids.