Abstract
Chlorothricin, isolated from Streptomyces antibioticus, is a parent member of spirotetronate family of antibiotics that have long been appreciated for their remarkable biological activities. ChlF1 plays bifunctional roles in chlorothricin biosynthesis by binding to its target genes (chlJ, chlF1, chlG, and chlK). The dissociation constants of ChlF1 to these genes are ∼ 102-140 nm. A consensus sequence, 5'-GTAANNATTTAC-3', was found in these binding sites. ChlF1 represses the transcription of chlF1, chlG, and chlK but activates chlJ, which encodes a key enzyme acyl-CoA carboxyl transferase involved in the chlorothricin biosynthesis. We demonstrate that the end product chlorothricin and likewise its biosynthetic intermediates (demethylsalicycloyl chlorothricin and deschloro-chlorothricin) can act as signaling molecules to modulate the binding of ChlF1 to its target genes. Intriguingly, a correlation between the antibacterial activity and binding ability of signaling molecules to the regulator ChlF1 is clearly observed. These features of the signaling molecules are associated with the glycosylation of spirotetronate macrolide aglycone. The findings provide new insights into the TetR family regulators responding to special structure of signaling molecules, and we reveal the regulatory mini-network mediated by ChlF1 in chlorothricin biosynthesis for the first time.
Highlights
Streptomycetes produce abundant secondary metabolites and provide more than half of medically important antimicrobial and antitumor agents [1]
Chlorothricin (CHL), produced by Streptomyces antibioticus, belongs to a large family of spirotetronate/spirotetramate natural products that possess a characteristic pentacyclic aglycone comprising a trans-decalin system and a tetronate or tetramate spiro-conjugate [8, 9]. The members in this family exhibit a wide variety of remarkable biological activities (10 – 12) and have attracted considerable attention in drug discovery and development to inspire the investigation into their modes of action, such as chlorothricin, kijanimicin, pyrrolosporin, tetrocarcin, lobophorin, versipelostatin, nomimicin, and so on [9, 13, 14], but the regulatory mechanism on the biosynthesis has not been elucidated for this family of antibiotics as we know
Biosynthesis of secondary metabolites in Streptomyces is regulated stringently, including one or two component system associating with regulators and their signaling molecules
Summary
Wild-type chlorothricin producer chlB6 disrupted, demethylsalicycloyl-CHL producer chlF1 disruption mutant chlF1 complementary strain chlF1 high level expression strain chlJ disruption mutant chlJ complementary strain chlJ high level expression strain chlG disruption mutant chlG complementary strain chlG high level expression strain chlK disruption mutant chlK complementary strain chlK high level expression strain.
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