Halogenation of glycopeptide antibiotics occurs at the amino acid level during non-ribosomal peptide synthesis.

Halogenation plays a significant role in the activity of the glycopeptide antibiotics (GPAs), although up until now the timing and therefore exact substrate involved was unclear. Here, we present results combined from in vivo and in vitro studies that reveal the substrates for the halogenase enzymes from GPA biosynthesis as amino acid residues bound to peptidyl carrier protein (PCP)-domains from the non-ribosomal peptide synthetase machinery: no activity was detected upon either free amino acids or PCP-bound peptides. Furthermore, we show that the selectivity of GPA halogenase enzymes depends upon both the structure of the bound amino acid and the PCP domain, rather than being driven solely via the PCP domain. These studies provide the first detailed understanding of how halogenation is performed during GPA biosynthesis and highlight the importance and versatility of trans-acting enzymes that operate during peptide assembly by non-ribosomal peptide synthetases.

The biosynthesis of teicoplanin-type glycopeptide antibiotics: assignment of p450 mono-oxygenases to side chain cyclizations of glycopeptide a47934.

Streptomyces toyocaensis produces A47934, a teicoplanin-like type-IV glycopeptide with antibiotic activity against methicillin-resistant Staphylococcus aureus. A47934 differs from the type-I vancomycin glycopeptides, which possess a tricyclic peptide backbone, by the presence of an additional ring closure between the aromatic amino acids 1 and 3. To elucidate the order of crosslinking reactions, P450 mono-oxygenase-inactivation mutants (DeltastaF, DeltastaG, DeltastaH, and DeltastaJ) of the A47934 producer were generated, and the accumulated intermediates were analyzed. Thus, the formation of each crosslink could unambiguously be assigned to a specific oxygenase. The structure of the released intermediates from the wild-type nonribosomal peptide synthetase assembly line facilitated the determination of the cyclization order. Unexpectedly, the additional ring closure in A47934, catalyzed by StaG, is the second oxygenase reaction.

Genetic analysis of the balhimycin (vancomycin-type) oxygenase genes.

In the balhimycin biosynthesis three oxygenases OxyA, OxyB and OxyC are responsible for the oxidative phenol coupling reactions, which lead to the ring-closures between the aromatic amino acid side chains in the heptapeptide aglycone. These ring-closures constrain the peptide backbone into the cup-shaped conformation that is required for binding to the Lys-D-Ala-D-Ala-terminus of the cell wall precursor peptide and represent one of the essential features of glycopeptide antibiotics. In the balhimycin biosynthetic gene cluster the oxygenase genes oxyA, oxyB and oxyC have been identified downstream of the peptide synthetase genes. Reverse transcription (RT)-PCR analyses revealed that these oxygenase genes in Amycolatopsis balhimycina are co-transcribed. Non-polar mutants (NPoxyA, DeltaoxyB and DeltaoxyC) were constructed, cultivated in production medium and assayed for the presence of glycopeptides and glycopeptide precursors by HPLC-ESI-MS. The mutant NPoxyA produces mainly monocyclic, the mutant DeltaoxyB linear and the mutant DeltaoxyC bicyclic peptides. These results definitely confirm the sequence of the three oxidative ring-closing steps (OxyB-OxyA-OxyC). The heterologous complementation of the mutant strains with the corresponding oxygenase genes from the vancomycin producer A. orientalis restored the production of balhimycin, which proves the functional equivalence of the oxygenases from the balhimycin and vancomycin producer. For the first time it is now possible to combine the genetic data obtained from the balhimycin producer with the biochemical and structural data obtained from the vancomycin producer.