thiostrepton and thiocillin

Thiopeptides are a family of highly modified peptide metabolites, characterized by a macrocycle bearing a central piperidine/dehydropiperidine/pyridine ring, multiple thiazole rings, and several dehydrated amino acid residues. Thiopeptides have useful antibacterial, antimalarial, and anticancer properties but have not been adapted for human clinical applications, owing in part to their poor water solubility. In 2009, it was revealed that the thiopeptide scaffold is derived from a ribosomally synthesized precursor peptide subjected to extensive posttranslational modifications. Shortly thereafter, three groups developed two types of in vivo strategies to generate thiopeptide variants: precursor peptide mutagenesis and gene inactivation. The thiopeptide analogs and biosynthetic intermediates obtained from these studies provide much-needed insight into the biosynthetic process for these complicated metabolites. Furthermore, the in vivo production of variants can be employed to interrogate thiopeptide structure-activity relationships and may be useful to address the bioavailability issues plaguing these otherwise promising lead molecules. This chapter discusses the in vivo systems developed to generate thiopeptide variants.

Topics: Anti-Bacterial Agents; Genes, Bacterial; Genetic Engineering; Multigene Family; Peptide Biosynthesis; Peptides; Plasmids; Protein Precursors; Ribosomes; Streptomyces; Structure-Activity Relationship; Thiazoles; Thiostrepton

Thiopeptides, with potent activity against various drug-resistant pathogens, contain a characteristic macrocyclic core consisting of multiple thiazoles, dehydroamino acids, and a 6-membered nitrogen heterocycle. Their biosynthetic pathways remain elusive, in spite of great efforts by in vivo feeding experiments. Here, cloning, sequencing, and characterization of the thiostrepton and siomycin A gene clusters unveiled a biosynthetic paradigm for the thiopeptide specific core formation, featuring ribosomally synthesized precursor peptides and conserved posttranslational modifications. The paradigm generality for thiopeptide biosynthesis was supported by genome mining and ultimate confirmation of the thiocillin I production in Bacillus cereus ATCC 14579, a strain that was previously unknown as a thiopeptide producer. These findings set the stage to accelerate the discovery of thiopeptides by prediction at the genetic level and to generate structural diversity by applying combinatorial biosynthesis methods.

Topics: Bacillus; Bacterial Proteins; Cloning, Molecular; Genes, Bacterial; Multigene Family; Peptides; Protein Processing, Post-Translational; Ribosomes; Streptomyces; Thiostrepton