A gene cluster from Streptomyces galilaeus involved in glycosylation of aclarubicin.

Abstract

We have cloned and characterized a gene cluster for anthracycline biosynthesis from Streptomyces galilaeus. This cluster, 15-kb long, includes eight genes involved in the deoxyhexose biosynthesis pathway, a gene for a glycosyltransferase and one for an activator, as well as two genes involved in aglycone biosynthesis. Gene disruption targeted to the activator gene blocked production of aclacinomycins in S. galilaeus. Plasmid pSgs4, containing genes for a glycosyltransferase (aknS), an aminomethylase (aknX), a glucose-1-phosphate thymidylyltransferase (akn Y) and two genes for unidentified glycosylation functions (aknT and aknV), restored the production of aclacinomycins in the S. galilaeus mutants H063, which accumulates aklavinone, and H054, which produces aklavinone with rhodinose and deoxyfucose residues. Furthermore, pSgs4 directed the production of L-rhamnosyl-epsilon-rhodomycinone and L-daunosaminyl-epsilon-rhodomycinone in S. peucetius strains that produce epsilon-rhodomycinone endogenously. Subcloning of the gene cluster was carried out in order to further define the genes that are responsible for complementation and hybrid anthracycline generation.