Structural and enzymatic characterization of BacD, an L-amino acid dipeptide ligase from Bacillus subtilis.

BacD is an ATP-dependent dipeptide ligase responsible for the biosynthesis of L-alanyl-L-anticapsin, a precursor of an antibiotic produced by Bacillus spp. In contrast to the well-studied and phylogenetically related D-alanine: D-alanine ligase (Ddl), BacD synthesizes dipeptides using L-amino acids as substrates and has a low substrate specificity in vitro. The enzyme is of great interest because of its potential application in industrial protein engineering for the environmentally friendly biological production of useful peptide compounds, such as physiologically active peptides, artificial sweeteners and antibiotics, but the determinants of its substrate specificity and its catalytic mechanism have not yet been established due to a lack of structural information. In this study, we report the crystal structure of BacD in complex with ADP and an intermediate analog, phosphorylated phosphinate L-alanyl-L-phenylalanine, refined to 2.5-Å resolution. The complex structure reveals that ADP and two magnesium ions bind in a manner similar to that of Ddl. However, the dipeptide orientation is reversed, and, concomitantly, the entrance to the amino acid binding cavity differs in position. Enzymatic characterization of two mutants, Y265F and S185A, demonstrates that these conserved residues are not catalytic residues at least in the reaction where L-phenylalanine is used as a substrate. On the basis of the biochemical and the structural data, we propose a reaction scheme and a catalytic mechanism for BacD.

Identification of novel L-amino acid alpha-ligases through Hidden Markov Model-based profile analysis.

L-Amino acid alpha-ligase (Lal), catalyzing the formation of alpha-dipeptides from unprotected L-amino acids in an ATP-dependent manner, is used in cost-effective fermentative production of dipeptides. We searched for novel Lals by in silico screening using Hidden Markov Model-based profile analysis, and identified five novel Lals that showed low similarity and different substrate specificity from known Lals.

Effect of multidrug-efflux transporter genes on dipeptide resistance and overproduction in Escherichia coli.

L-Alanyl-L-glutamine (Ala-Gln) is a clinically and nutritionally important dipeptide. We have already shown a novel method for the fermentative production of Ala-Gln using an Escherichia coli strain expressing L-amino acid alpha-ligase (Lal), which catalyzes the formation of dipeptides by combining two amino acids. In the course of Ala-Gln-producing strain development, it was revealed that Lal expression caused growth inhibition. We also found that the addition of some dipeptides, including Ala-Gln, inhibited the growth of a multiple peptidase-deficient strain. To further increase the productivity by overcoming the inhibitory effect of dipeptides, we focused on dipeptide transport systems. The four genes (bcr, norE, ydeE and yeeO) were selected from 34 genes encoding a multidrug-efflux transporter of E. coli as those conferring resistance to growth inhibitory dipeptides. Intracellular concentration of Ala-Gln was reduced by overexpressing these genes in a multiple peptidase-deficient strain. Furthermore, overexpression of each gene in the dipeptide-producing strains resulted in the increase of Ala-Gln and L-alanyl-L-branched chain amino acids titers. These results indicate that some multidrug-efflux transporters of E. coli can transport dipeptides and that enhancement of their activities is effective for fermentative production of dipeptides.

A leuC mutation leading to increased L-lysine production and rel-independent global expression changes in Corynebacterium glutamicum.

We previously found by transcriptome analysis that global induction of amino acid biosynthetic genes occurs in a classically derived industrial L-lysine producer, Corynebacterium glutamicum B-6. Based on this stringent-like transcriptional profile in strain B-6, we analyzed the relevant mutations from among those identified in the genome of the strain, with special attention to the genes that are involved in amino acid biosynthesis and metabolism. Among these mutations, a Gly-456-->Asp mutation in the 3-isopropylmalate dehydratase large subunit gene (leuC) was defined as a useful mutation. Introduction of the leuC mutation into a defined L-lysine producer, AHD-2 (hom59 and lysC311), by allelic replacement led to the phenotype of a partial requirement for L-leucine and approximately 14% increased L-lysine production. Transcriptome analysis revealed that many amino acid biosynthetic genes, including lysC-asd operon, were significantly upregulated in the leuC mutant in a rel-independent manner.

Transcriptome analysis reveals global expression changes in an industrial L-lysine producer of Corynebacterium glutamicum.

Toward the elucidation of advanced mechanisms of L-lysine production by Corynebacterium glutamicum, a highly developed industrial strain B-6 was analyzed from the viewpoint of gene expression. Northern blot analysis showed that the lysC gene encoding aspartokinase, the key enzyme of L-lysine biosynthesis, was up-regulated by several folds in strain B-6, while no repression mechanism exists in L-lysine biosynthesis of this bacterium. To analyze the underlying mechanisms of the up-regulation, we compared the transcriptome between strain B-6 and its parental wild-type, finding that not only lysC but also many other amino acid-biosynthetic genes were up-regulated in the producer. These results suggest that a certain global regulatory mechanism is involved in the industrial levels of L-lysine production.