Nakano T, Miyake K, Ikeda M, Mizukami T, Katsumata R
Tokyo Research Laboratories, Kyowa Hakko Kogyo Co., Ltd., Machida, Tokyo 194-8533, Japan.
Appl Environ Microbiol. 2000 Apr;66(4):1400-4. doi: 10.1128/AEM.66.4.1400-1404.2000.
The secondary metabolite 6-demethylchlortetracycline (6-DCT), which is produced by Streptomyces aureofaciens, is used as a precursor of semisynthetic tetracyclines. Strains that produce 6-DCT also produce a melanin-like pigment (MP). The correlation between MP production and 6-DCT production was investigated by using S. aureofaciens NRRL 3203. Production of both MP and 6-DCT was repressed by phosphate or ammonium ions, suggesting that syntheses of these compounds are controlled by the same regulators. Ten chlortetracycline-producing recombinants were derived from 6-DCT-producing mutant NRRL 3203 by gene replacement. All of the recombinants produced chlortetracycline but not MP, indicating that MP production is the results of a defect in the 6-methylation step and suggesting that the polyketide nonaketideamide is a common intermediate leading to MP as well as 6-DCT. To further examine the possibility that MP might be synthesized via the 6-DCT-biosynthetic pathway, mutants defective in 6-DCT biosynthesis were derived from a 6-DCT producer. Some of these mutants were able to produce MP, while others, including mutants with mutations in the gene encoding anhydrotetracycline oxygenase, an enzyme catalyzing the penultimate step in the pathway, produced neither 6-DCT nor MP. Production of 6-DCT and production of MP were restored simultaneously by integrative transformation with the corresponding 6-DCT-biosynthetic genes, indicating that some of 6-DCT-biosynthetic enzymes are indispensable for MP production. These findings suggest that a defect in the 6-methylation step results in redirection of carbon flux from a certain intermediate in the 6-DCT-biosynthetic pathway to a shunt pathway and results in MP production.
由金色链霉菌产生的次生代谢产物6-去甲基金霉素(6-DCT)被用作半合成四环素的前体。产生6-DCT的菌株也会产生一种黑色素样色素(MP)。利用金色链霉菌NRRL 3203研究了MP产生与6-DCT产生之间的相关性。MP和6-DCT的产生均受到磷酸盐或铵离子的抑制,这表明这些化合物的合成受相同调节因子的控制。通过基因替换从产生6-DCT的突变体NRRL 3203中获得了10个产生金霉素的重组体。所有重组体都产生金霉素但不产生MP,这表明MP的产生是6-甲基化步骤缺陷的结果,并表明聚酮九酮酰胺是导致MP以及6-DCT的共同中间体。为了进一步研究MP可能通过6-DCT生物合成途径合成的可能性,从6-DCT生产者中获得了6-DCT生物合成缺陷的突变体。其中一些突变体能够产生MP,而其他突变体,包括编码脱水四环素氧化酶(该途径倒数第二步的催化酶)的基因突变体,既不产生6-DCT也不产生MP。通过用相应的6-DCT生物合成基因进行整合转化,6-DCT的产生和MP的产生同时恢复,这表明一些6-DCT生物合成酶对于MP的产生是必不可少的。这些发现表明,6-甲基化步骤的缺陷导致碳通量从6-DCT生物合成途径中的某个中间体重新导向到一个分流途径,并导致MP的产生。