Abstract
The recent development of molecular cloning systems in Streptomyces1–4 has made possible the isolation of biosynthetic genes for some of the many antibiotics produced by members of this important genus of bacteria5–10. Such clones can now be used to test the idea that novel antibiotics could arise through the transfer of biosynthetic genes between streptomycetes producing different antibiotics11. The likelihood of a ‘hybrid’ compound being produced must depend on the substrate specificities of the biosynthetic enzymes, about which little is known. In attempts to demonstrate hybrid antibiotic production, we therefore began with strains producing different members of the same chemical class of compounds in order to maximize the chance of success. Here we report the production of novel compounds by gene transfer between strains producing the isochromanequinone antibiotics actinorhodin12, granaticin13 and medermycin14. These experiments were made possible by the recent cloning of the whole set of genes for the biosynthetic pathway of actinorhodin from Streptomyces coelicolor A3(2) (ref. 8). We believe that this represents the first report of the production of hybrid antibiotics by genetic engineering.
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Hopwood, D., Malpartida, F., Kieser, H. et al. Production of ‘hybrid’ antibiotics by genetic engineering. Nature 314, 642–644 (1985). https://doi.org/10.1038/314642a0
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DOI: https://doi.org/10.1038/314642a0
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