Rational engineering of BaLal_16 from a novel Bacillus amyloliquefaciens strain to improve catalytic performance.

L-amino acid ligases (Lals) are promising biocatalysts for the synthesis of dipeptides with special biological properties. However, their poor (or broad) substrate specificity limits their industrial applications. To address this problem, a molecular engineering method for Lals was developed to enhance their catalytic performance. Based on substrate channeling, entrances to the active site for different substrates were identified, and the "gate" located around the active site pocket, which plays an essential role in substrate recognition, was then engineered to facilitate acceptance of L-Gln. Two mutants (L110Y and N108F/L110Y) were discovered to display significantly increased catalytic activity toward L-Ala and L-Gln in the biosynthesis of Ala-Gln. The catalytic efficiency (kcat/ Km) of the L110Y and N108F/L110Y mutants was improved by 2.64-fold and 4.06-fold, respectively, compared with that of the wild type. N108F/L110Y was then further applied for batch production of Ala-Gln, which showed that the released Pi yield was 694.47 µM, which was an increase of approximately 21.4 %, and the yield of Ala-Gln was approximately 2.59 mM-1 L-1 mg-1. Collectively, these findings suggest the potential practical application of this method in the rational design of Lals for increased catalytic performance.

l-amino acid ligase: A promising alternative for the biosynthesis of l-dipeptides.

Given their special action mechanisms and structural simplicity, L-amino acid ligases (Lals) are considered to be desirable tools for the catalytic biosynthesis of dipeptides. Ywf E (BacD) was the first Lal identified and was shown to be involved in the biosynthesis of a potent antibacterial, bacilysin, since then, various novel Lals have been discovered. Each Lal has different substrate spectra and is capable of synthesizing different dipeptides. Owning to their great potentials for producing bioactive dipeptides of industrial importance, in this review, recent developments of Lals are discussed, including their structures, action mechanisms, applications and the advantages and disadvantages of different Lals. In addition, protein engineering of Lals to improve their substrate specificity and catalytic performance is also discussed.