Now showing 1 - 3 of 3
  • Publication
    Biosynthesis of Deoxyamphotericins and Deoxyamphoteronolides by Engineered Strains of Streptomyces nodosus
    Amphotericin B is an antifungal antibiotic produced by Streptomyces nodosus. During biosynthesis of amphotericin, the macrolactone core undergoes three modifications: oxidation of a methyl branch to a carboxyl group, mycosaminylation, and hydroxylation. Gene disruption was undertaken to block two of these modifications. Initial experiments targeted the amphDIII gene, which encodes a GDP-D-mannose 4,6-dehydratase involved in biosynthesis of mycosamine. Analysis of products by mass spectrometry and NMR indicated that the amphDIII mutant produced 8-deoxyamphoteronolides A and B. This suggests that glycosylation with mycosamine normally precedes C-8 hydroxylation and that formation of the exocyclic carboxyl group can occur prior to both these modifications. Inactivation of the amphL cytochrome P450 gene led to production of novel polyenes with masses appropriate for 8-deoxyamphotericins A and B. These compounds retained antifungal activity and may be useful new antibiotics.
    Scopus© Citations 64  358
  • Publication
    Exploiting the genome sequence of Streptomyces nodosus for enhanced antibiotic production
    The genome of the amphotericin producer Streptomyces nodosus was sequenced. A single scaffold of 7,714,110 bp was obtained. Biosynthetic genes were identified for several natural products including polyketides, peptides, siderophores and terpenes. The majority of these clusters specified known compounds. Most were silent or expressed at low levels and unlikely to compete with amphotericin production. Biosynthesis of a skyllamycin analogue was activated by introducing expression plasmids containing either a gene for a LuxR transcriptional regulator or genes for synthesis of the acyl moiety of the lipopeptide. In an attempt to boost amphotericin production, genes for acyl CoA carboxylases, a phosphopantetheinyl transferase and the AmphRIV transcriptional activator were overexpressed, and the effects on yields were investigated. This study provides the groundwork for metabolic engineering of S. nodosus strains to produce high yields of amphotericin analogues.
    Scopus© Citations 20  733
  • Publication
    Engineered biosynthesis and characterisation of disaccharide-modified 8-deoxyamphoteronolides
    Several polyene macrolides are potent antifungal agents that have severe side effects. Increased glycosylation of these compounds can improve water solubility and reduce toxicity. Three extending glycosyltransferases are known to add hexoses to the mycosaminyl sugar residues of polyenes. The Actinoplanes caeruleus PegA enzyme catalyses attachment of a D-mannosyl residue in a β-1,4 linkage to the mycosamine of the aromatic heptaene 67-121A to form 67-121C. NppY from Pseudonocardia autotrophica adds an N-acetyl-D-glucosamine to the mycosamine of 10-deoxynystatin. NypY from Pseudonocardia sp. P1 adds an extra hexose to a nystatin, but the identity of the sugar is unknown. Here, we express the nypY gene in Streptomyces nodosus amphL and show that NypY modifies 8-deoxyamphotericins more efficiently than C-8 hydroxylated forms. The modified heptaene was purified and shown to be mannosyl-8-deoxyamphotericin B. This had the same antifungal activity as amphotericin B but was slightly less haemolytic. Chemical modification of this new disaccharide polyene could give better antifungal antibiotics.
    Scopus© Citations 7  663