Metabolomics

Dataset Information

0

GNPS - Metabolic engineering of Streptomyces peucetius for biosynthesis of N,N-dimethylated anthracyclines


ABSTRACT: Daunorubicin and doxorubicin, two anthracycline polyketides produced by Streptomyces peucetius, are potent anticancer agents that are widely used in chemotherapy, despite severe side effects. Recent advances have highlighted the potential of producing improved derivatives with reduced side effects by incorporating L-rhodosamine, the N,N-dimethyl analogue of the native amino sugar moiety. In this study, we aimed to produce N,N-dimethylated anthracyclines by engineering the doxorubicin biosynthetic pathway in the industrial S. peucetius strain GOO1. To achieve this, we introduced genes from the aclarubicin biosynthetic pathway encoding the sugar N-methyltransferases AclP and AknX2. Furthermore, the native gene for glycosyltransferase DnrS was replaced with genes encoding the aclarubicin glycosyltransferases AknS and AknT. Additionally, the gene for methylesterase RdmC from the rhodomycin biosynthetic pathway was introduced. A new host was engineered successfully, whereby genes from the aclarubicin pathway were introduced and expressed. LC-MS/MS analysis of the engineered strains showed that dimethylated sugars were efficiently produced, and that these were incorporated ino the anthracycline biosynthetic pathway to produce the novel dimethylated anthracycline N,N-dimethyldaunorubicin. Further downstream tailoring steps catalysed by the cytochrome P450 monooxygenase DoxA exhibited limited efficacy with N,N-dimethylated substrates. This resulted in only low production levels of N,N-dimethyldaunorubicin and no N,N-dimethyldoxorubicin, most likely due to the low affinity of DoxA for dimethylated substrates. S. peucetius GOO1 was engineered such as to produce N,N-dimethylated sugars, which were incorporated into the biosynthetic pathway. This allowed the successful production of N,N-dimethyldaunorubicin, an anticancer drug with reduced cytotoxicity. DoxA is the key enzyme that determines the efficiency of the biosynthesis of N,N-dimethylated anthracyclines, and engineering of this enzyme will be a major step forwards towards the efficient production of more N,N-dimethylated anthracyclines, including N,N-dimethyldoxorubicin. This study provides valuable insights into the biosynthesis of clinically relevant daunorubicin derivatives, highlighting the importance of combinatorial biosynthesis.

INSTRUMENT(S): ACQUITY RDa Detector, LCMS-9030

ORGANISM(S): Streptomyces Peucetius (ncbitaxon:1950)

SUBMITTER: Prof. Gilles van Wezel  

PROVIDER: MSV000093884 | GNPS | Thu Jan 18 00:09:00 GMT 2024

REPOSITORIES: GNPS

Dataset's files

Source:
Action DRS
Other
Items per page:
1 - 1 of 1

Similar Datasets

2024-01-18 | MSV000093884 | MassIVE
2021-04-28 | E-MTAB-9029 | biostudies-arrayexpress
2020-01-09 | GSE123543 | GEO
2024-05-17 | MSV000094792 | MassIVE
2024-02-12 | PXD049454 |
2008-08-31 | GSE12137 | GEO
2021-04-24 | GSE155403 | GEO
2013-12-01 | GSE50688 | GEO
2013-12-01 | E-GEOD-50688 | biostudies-arrayexpress
2022-11-21 | PXD035193 | Pride