Doxorubicin aromatic polyketide

From the cultures of streptomycetes were isolated anthacyclinones like aklavi-none. Various aromatic polyketide antibiotics produced by fungi and bacteria have quinoid structures, for example, doxorubicin, rhodomycin, and actinorhodin. ... 

A. Actinorhodin, Tetracenomycin, Doxorubicin, and Other Bacterial Aromatic Polyketide Synthases... 

Type II polyketide synthases, also referred to as bacterial aromatic polyketide synthases (25) are involved in the biosynthesis of a number of clinically important bacterial aromatic polyketides products exhibiting antitumor or antibiotic activity, such as doxorubicin and oxytetracycline. As mentioned, type II synthases are evolutionarily and structurally related to type II FASs, which occurr as heteromultimeric complexes. In contrast to type I synthases however, where multiple catalytic sites occur within a given subunit, the polypeptides associated with type II synthase complexes are typically monofimctional and dissociable 20,30). 

Methyl transfer reactions play a significant part in the modifications of aromatic polyketides, both of the polyketide core [61,62] as well as of several of the sugar moieties [44,53]. In Streptomyces, more than 20 amino acid sequences have been found that may represent enzymes involved in methyl transfer reactions in the biosynthesis of aromatic polyketides [149]. One of these enzymes, the S-adenosyl-L-methionine-dependent DnrK, is involved in the methylation of the C-4 hydroxyl group in daunorubicin/doxorubicin biosynthesis (Scheme 10, step 12). The subunit of the homo-dimeric enzyme displays a fold typical for small-molecule methyltransferases. The structure of the ternary complex with bound products S-adenosyl-L-homocysteine and 4-methoxy-8-rhodomycin provided insights into the structural basis of substrate recognition and catalysis [149]. The position and orientation of the substrates suggest an Sn2 mechanism for methyl transfer, and mutagenesis experiments show that there is no catalytic base in the vicinity of the substrate. Rate enhancement is thus most likely due to orientational and proximity effects [149]. 

Figure 3 Aromatic PKS gene clusters and actinorhodin biosynthesis. Partial gene clusters for the polyketides actinorhodin (act), tetracenomycin (tcm), and doxorubicin (dps) are shown. Reconstitution of combinations of act genes in a PKS clean host have led to a proposed pathway by which the early stages of actinorhodin biosynthesis occur.

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