New basic water-soluble antibiotics BD-12 and BY-81. I. Taxonomy of the producing organisms and antibiotic production

N-Formimidoylation/-iminoacetylation modification in aminoglycosides requires FAD-dependent and ligand-protein NOS bridge dual chemistry

Oxidized cysteine residues are highly reactive and can form functional covalent conjugates, of which the allosteric redox switch formed by the lysine-cysteine NOS bridge is an example. Here, we report a noncanonical FAD-dependent enzyme Orf1 that adds a glycine-derived N-formimidoyl group to glycinothricin to form the antibiotic BD-12. X-ray crystallography was used to investigate this complex enzymatic process, which showed Orf1 has two substrate-binding sites that sit 13.5 Å apart unlike canonical FAD-dependent oxidoreductases. One site could accommodate glycine and the other glycinothricin or glycylthricin. Moreover, an intermediate-enzyme adduct with a NOS-covalent linkage was observed in the later site, where it acts as a two-scissile-bond linkage facilitating nucleophilic addition and cofactor-free decarboxylation. The chain length of nucleophilic acceptors vies with bond cleavage sites at either N-O or O-S accounting for N-formimidoylation or N-iminoacetylation. The resultant product is no longer sensitive to aminoglycoside-modifying enzymes, a strategy that antibiotic-producing species employ to counter drug resistance in competing species.

tRNA-dependent amide bond-forming enzymes in peptide natural product biosynthesis

In the ribosome-independent biosynthesis of peptide natural products, amino acid building blocks are generally activated in the form of phosphoesters, esters, or thioesters prior to amide bond formation. Following the recent discovery of bacterial enzymes that utilize an aminoacyl ester with a transfer ribonucleic acid (tRNA) in primary metabolism, the number of tRNA-dependent enzymes used in biosynthetic studies of peptide natural products has increased steadily. In this review, we summarize the rapidly growing knowledge base regarding two types of tRNA-dependent enzymes, which are structurally and functionally distinct. Initially, we focus on enzymes with the GCN5-related N-acetyltransferase fold and discuss the catalytic function and aminoacyl-tRNA recognition. Next, newly found peptide-amino acyl tRNA ligases and their ATP-dependent reactions are highlighted.

Functional analysis of methyltransferases participating in streptothricin-related antibiotic biosynthesis

Streptothricin (ST) and its related compounds produced by Streptomyces strains are broad-spectrum antibiotics that consist of carbamoylated d-gulosamine, amino-acid side chain, and streptolidine lactam moieties. BD-12, a streptothricin-related antibiotic, has a glycine-derived side chain and two N-methyl groups, whereas ST-F carrying the l-β-lysine side chain has no methyl group. In our previous studies, we identified and characterized the BD-12 and ST biosynthetic gene clusters. Here we report the functional analysis of two methyltransferase genes (orf 6 and orf 13) in the BD-12 biosynthetic gene cluster. Combinatorial biosynthesis using these two methyltransferase genes and the ST biosynthetic gene cluster resulted in the production of three methylated forms of ST-F. Among them, N,N'-dimethyl-ST-F, a novel compound generated in the present study, showed bacteria-specific antibiotic activities, although ST-F exhibits antibiotic activities against both prokaryotes and eukaryotes. Our findings also demonstrated that the orf 6 and orf 13 genes are responsible for the N-methylations of the amide bonds in the streptolidine lactam and in the amino-acid side chain linkage, respectively, and that N-methyl modification of the streptolidine lactam confers resistance in part against an ST hydrolase, SttH.

tRNA-Dependent Aminoacylation of an Amino Sugar Intermediate in the Biosynthesis of a Streptothricin-Related Antibiotic

The antibiotic streptothricin (ST) possesses an amino sugar bound to an l-β-lysine (β-Lys) residue via a peptide bond. The peptide bond formation has been shown to be catalyzed by a nonribosomal peptide synthetase (NRPS) during ST biosynthesis. The focus of this study is the closely related ST analogue BD-12, which carries a glycine-derived side chain rather than a β-Lys residue. Here, in Streptomyces luteocolor NBRC13826, we describe our biosynthetic studies of BD-12, which revealed that the peptide bond between the amino sugar and the glycine residue is catalyzed by a Fem-like enzyme (Orf11) in a tRNA-dependent manner rather than by an NRPS. Although there have been several reports of peptide bond-forming tRNA-dependent enzymes, to our knowledge, Orf11 is the first enzyme that can accept an amino sugar as a substrate. Our findings clearly demonstrate that the structural diversity of the side chains of ST-type compounds in nature is generated in an unusual manner via two distinct peptide bond-forming mechanisms. Moreover, the identification and functional analysis of Orf11 resulted in not only the production of new ST-related compounds, but also the provision of new insights into the structure-activity relationship of the ST-related antibiotics.

IMPORTANCE

The antibiotic streptothricin (ST) possesses an amino sugar bound to an l-β-lysine (β-Lys) side chain via a peptide bond formed by a nonribosomal peptide synthetase (NRPS). BD-12, an analogue of ST, carries a glycine-derived side chain rather than β-Lys, and here, we describe the BD-12-biosynthetic gene cluster from Streptomyces luteocolor NBRC13826, which contains the orf11 gene encoding a novel tRNA-dependent peptide bond-forming enzyme. The unique Fem-like enzyme (Orf11) accepts the amino sugar as a substrate and mediates the peptide formation between the amino sugar intermediate and glycine. Our studies demonstrate that the structural diversity of the side chains of ST-related compounds in nature is generated via two distinct peptide bond-forming mechanisms.