Metal chaperone, NhpC, involved in the metallocenter biosynthesis of nitrile hydratase.

Pseudomonas chlororaphis B23 yields nitrile hydratase (NHase) used for the production of 5-cyanovaleramide at the industrial level. Although the nhpC gene (known as P47K) located just downstream of the NHase structural genes (nhpAB) has been important for efficient NHase expression, the key role of nhpC remains poorly studied. Here, we purified two NHases expressed in the presence and absence of nhpC, respectively, and characterized them. The purified NHase expressed with nhpC proved to be an iron-containing holo-NHase, while the purified one expressed without nhpC was identified as an apo-NHase, which was iron-deficient. These findings indicated that nhpC would play a crucial role in the post-translational incorporation of iron into the NHase active site as a metal chaperone. In the overall amino acid sequence of NhpC, only the N-terminus exhibited similarities to the CobW protein involved in cobalamin biosynthesis, the UreG and HypB proteins essential for the metallocenter biosynthesis of urease and hydrogenase, respectively. NhpC contains a P-loop motif known as a nucleotide-binding site, and Lys23 and Thr24 are conserved in the P-loop motif in NhpC. Expression analysis of NHase formed in the presence of each mutant NhpC (i.e., K23A and T24A) resulted in immunodetectable production of a mutant NhpC and remarkable expression of NHase lacking the enzyme activity. These findings suggested that an intact P-loop containing Lys23 and Thr24 would be essential for the NhpC function in vivo for the post-translational metallocenter assembly of NHase.

Modifications to central carbon metabolism in an engineered Streptomyces host to enhance secondary metabolite production.

To improve the production of secondary metabolites by alternation of the carbon metabolic flux, two types of deletion mutants of the central metabolic pathway, the Embden-Meyerhof (EM) or pentose phosphate (PP) pathway, in the genetically engineered Streptomyces avermitilis were constructed. Double-deletion mutants of phosphofructokinase (ΔpfkA1ΔpfkA3) in the EM pathway carrying a gene cluster for chloramphenicol biosynthesis markedly increased chloramphenicol production synthesized through the shikimate pathway. Although the ΔpfkA1ΔpfkA3 double-deletion mutant grew more slowly, its specific productivity of chloramphenicol (per dry cell weight) was 2.0-fold higher than that of the engineered S. avermitilis strain. However, the productivity of chloramphenicol was lower by the double-deletion mutant of transaldolase in the PP pathway, which supplies the precursor of the shikimate pathway. A carbon-flux analysis of the EM and PP pathways using [1-13C] glucose revealed that carbon flux in the ΔpfkA1ΔpfkA3 double-deletion mutant increased through the PP pathway, which enhanced the production of chloramphenicol. These results suggest that a metabolic modification approach has the potential to increase the titers and yields of valuable secondary metabolites.

Discovery of piperonal-converting oxidase involved in the metabolism of a botanical aromatic aldehyde.

Piperonal-catabolizing microorganisms were isolated from soil, the one (strain CT39-3) exhibiting the highest activity being identified as Burkholderia sp. The piperonal-converting enzyme involved in the initial step of piperonal metabolism was purified from strain CT39-3. Gene cloning of the enzyme and a homology search revealed that the enzyme belongs to the xanthine oxidase family, which comprises molybdoenzymes containing a molybdopterin cytosine dinucleotide cofactor. We found that the piperonal-converting enzyme acts on piperonal in the presence of O2, leading to formation of piperonylic acid and H2O2. The growth of strain CT39-3 was inhibited by higher concentrations of piperonal in the culture medium. Together with this finding, the broad substrate specificity of this enzyme for various aldehydes suggests that it would play an important role in the defense mechanism against antimicrobial compounds derived from plant species.