A fermentation method that bypasses the low-yielding semisynthesis of epirubicin (4'-epidoxorubicin) and 4'-epidaunorubicin, important cancer chemotherapy drugs, has been developed for Streptomyces peucetius. This bacterium normally produces the anthracycline antibiotics, doxorubicin and daunorubicin; the 4'-epimeric anthracyclines are formed by introducing the heterologous Streptomyces avermitilis avrE or Saccharopolyspora eryBIV genes into an S. peucetius dnmV mutant blocked in the biosynthesis of daunosamine, the deoxysugar component of these antibiotics. Product yields were enhanced considerably by replacing the chromosomal copy of dnmV with avrE and by introducing further mutations that can increase daunorubicin and doxorubicin yields in the wild-type strain. This method demonstrates that valuable hybrid antibiotics can be made by combinatorial biosynthesis with bacterial deoxysugar biosynthesis genes.
We previously proposed that the adjacent dnrIJ genes represent a two-component regulatory system controlling daunorubicin biosynthesis in Streptomyces peucetius on the basis of the homology of the DnrI and DnrJ proteins to other response regulator proteins and the effect of a dnrI::aphII mutation. In the present paper we report the results of work with the dnrI::aphII mutant in complementation, bioconversion, and transcriptional analysis experiments to understand the function of dnrI. For five putative operons in the sequenced portion of the S. peucetius daunorubicin biosynthesis gene cluster examined, all of the potential transcripts are present in the ⌬dnrJ mutant and wild-type strains but absent in the dnrI::aphII strain. Since these transcripts code for both early-and late-acting enzymes in daunorubicin biosynthesis, dnrI seems to control all of the daunorubicin biosynthesis genes directly or indirectly. Transcriptional mapping of the 5 and 3 ends of the dnrIJ transcript and the termination site of the convergently transcribed dnrZUV transcript reveals, interestingly, that the two transcripts share extensive complementarity in the regions coding for daunorubicin biosynthesis enzymes. In addition, dnrI may regulate the expression of the drrAB and drrC daunorubicin resistance genes. The ⌬dnrJ mutant accumulates -rhodomycinone, the aglycone precursor of daunorubicin. Since this mutant contains transcripts coding for several early-and late-acting enzymes and since dnr mutants blocked in deoxysugar biosynthesis accumulate -rhodomycinone, we conclude that dnrJ is a daunosamine biosynthesis gene. Moreover, newly available gene sequence data show that the DnrJ protein resembles a group of putative aminotransferase enzymes, suggesting that the role of dnrJ is to add an amino group to an intermediate of daunosamine biosynthesis.
Most of the S. spinosa genes involved in spinosyn biosynthesis are found in one 74 kb cluster, though it does not contain all of the genes required for the essential deoxysugars. Characterization of the clustered genes suggests that the spinosyns are synthesized largely by mechanisms similar to those used to assemble complex macrolides in other actinomycetes. However, there are several unusual genes in the spinosyn cluster that could encode enzymes that generate the most striking structural feature of these compounds, a tetracyclic polyketide aglycone nucleus.
Rhamnose is an essential component of the insect control agent spinosad. However, the genes coding for the four enzymes involved in rhamnose biosynthesis in Saccharopolyspora spinosa are located in three different regions of the genome, all unlinked to the cluster of other genes that are required for spinosyn biosynthesis. Disruption of any of the rhamnose genes resulted in mutants with highly fragmented mycelia that could survive only in media supplemented with an osmotic stabilizer. It appears that this single set of genes provides rhamnose for cell wall synthesis as well as for secondary metabolite production. Duplicating the first two genes of the pathway caused a significant improvement in the yield of spinosyn fermentation products.Spinosyns, the active ingredients in Dow AgroSciences' new Naturalyte line of insect control products, are produced by fermentation of the actinomycete Saccharopolyspora spinosa. Spinosyns are macrolides ( Fig. 1) consisting of a 21-carbon tetracyclic lactone to which are attached two deoxysugars: tri-O-methylated rhamnose and forosamine (6). The most active components of the spinosyn family of compounds are spinosyns A and D, which differ from each other by a single methyl substituent at position 6 of the polyketide. Other factors in this family have different levels of methylation and are significantly less active. Both the rhamnose and forosamine moieties are essential for the insecticidal activity of spinosyns (2). Spinosad is highly effective against target insects and has an excellent environmental and mammalian toxicological profile (2,13,14).Spinosyn biosynthesis occurs via the nonglycosylated intermediate, the aglycone (AGL). Rhamnose is the first sugar attached and is tri-O-methylated to yield the intermediate pseudoaglycone.Only after the rhamnose is attached can the forosamine sugar be incorporated (M. C. Broughton, M. L. B. Huber, L. C. Creemer, H. A. Kirst, and J. R. Turner, Abstr. 91st Annu. Meet. Am. Soc. Microbiol. 1991, abstr. K-58, p. 224, 1991. Both trimethyl rhamnose and forosamine are believed to be synthesized from glucose-1-phosphate via the common intermediate 4-keto-6-deoxy-D-glucose (Fig. 2). The biosynthetic pathway for rhamnose (Fig. 2) has been elucidated in enteric bacteria, where the deoxysugar is an element of surface antigens (8, 18). The first step, activation of glucose by addition of a nucleotidyl diphosphate (NDP), is catalyzed by an NDP-glucose synthase (the gtt gene product). The second step, dehydration to NDP-4-keto-6-deoxyglucose, is catalyzed by glucose dehydratase (the gdh gene product). 4-Keto-6-deoxy-D-glucose is the common intermediate to many deoxysugar biosynthetic pathways, and the enzymes encoded by the gtt and gdh genes may supply the precursors for all of them. Rhamnose synthesis requires two additional enzymes, a 3Ј5Ј epimerase (encoded by epi) and a 4Ј ketoreductase (encoded by kre), that are unique to the pathway. They convert the NDP-4-keto-6-deoxyglucose to NDP-L-rhamnose, the activated sugar that is the substrate of th...
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