Abstract
Methionine (Met), a sulfur-containing amino acid, is essential for the underlying biological processes in living organisms. In addition to its importance as a starting building block for peptide chain elongation in protein biosynthesis, Met is a direct precursor of S-adenosyl-l-methionine, an indispensable methyl donor molecule in primary and secondary metabolism. Streptomyces bacteria are well known to produce diverse secondary metabolites, but many strains lack canonical Met pathway genes for l-homocysteine, a direct precursor of Met in bacteria, plants, and archaea. Here, we report the identification of a novel gene (metM) responsible for the Met biosynthesis in Streptomyces strains and demonstrate the catalytic function of the gene product, MetM. We further identified the metO gene, a downstream gene of metM, and showed that it encodes a sulfur-carrier protein (SCP). In in vitro analysis, MetO was found to play an important role in a sulfur donor by forming a thiocarboxylated SCP. Together with MetO (thiocarboxylate), MetM directly converted O-phospho-l-homoserine to l-homocysteine. O-Phospho-l-homoserine is also known as an intermediate for threonine biosynthesis in bacteria and plants, and MetM shares sequence homology with threonine synthase. Our findings thus revealed that MetM seizes O-phospho-l-homoserine from the threonine biosynthetic pathway and uses it as an intermediate of the Met biosynthesis to generate the sulfur-containing amino acid. Importantly, this MetM/MetO pathway is highly conserved in Streptomyces bacteria and distributed in other bacteria and archaea.IMPORTANCEMethionine (Met) is a sulfur-containing proteinogenic amino acid. Moreover, Met is a direct precursor of S-adenosyl-l-methionine, an indispensable molecule for expanding the structural diversity of natural products. Because Met and its derivatives benefit humans, the knowledge of Met biosynthesis is important as a basis for improving their fermentation. Streptomyces bacteria are well known to produce diverse and valuable natural products, but many strains lack canonical Met pathway genes. Here, we identified a novel l-homocysteine synthase (MetM) in Streptomyces and demonstrated that it converts O-phospho-L-homoserine to l-homocysteine using a thiocarboxylated sulfur-carrier protein as a sulfur donor. Since the metM is distributed in other bacteria and archaea, our pioneering study contributes to understanding Met biosynthesis in these organisms.