Teresa M. Dreckmann, Lisa Fritz, Christian F. Kaiser, Sarah M. Bouhired, Daniel A. Wirtz, Marvin Rausch, Anna Müller, Tanja Schneider, Gabriele M. König and Max Crüsemann
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引用次数: 0
摘要
珊瑚嗪是由珊瑚球菌 B035 产生的环状脂二肽天然产物。为了破译珊瑚嗪生物合成的基础,我们鉴定并详细分析了珊瑚嗪非核糖体肽合成酶(NRPS)生物合成基因簇 crz。在此,我们通过生物信息学分析和体外研究对合成冠醚嗪核心的双模 NRPS 的支持,提出了冠醚嗪生物合成的模型。氯丙嗪的生物合成显示出几个明显的特征,如脱水缩合结构域的存在,以及两个开放阅读框上独特的分裂腺苷酸化结构域。利用替代的脂肪酰基起始单元,在体外鉴定了冠醚嗪生物合成的第一步,支持了我们的生物合成模型。对脱水缩合结构域进行了详细的生物信息学分析,并与其他修饰 C 结构域进行了比较,发现了该结构域亚家族未报道的特定序列动机。我们利用全球生物信息学分析表明,crz 基因簇家族在细菌中广泛存在,并编码显著的化学多样性。Corallorazine A 对某些革兰氏阳性和革兰氏阴性细菌具有中等程度的抗菌活性。由全细胞分析和体外测试系统组成的作用模式研究表明,氯丙嗪 A 通过靶向 DNA 依赖性 RNA 聚合酶抑制细菌转录。
Biosynthesis of the corallorazines, a widespread class of antibiotic cyclic lipodipeptides†
Corallorazines are cyclic lipodipeptide natural products produced by the myxobacterium Corallococcus coralloides B035. To decipher the basis of corallorazine biosynthesis, the corallorazine nonribosomal peptide synthetase (NRPS) biosynthetic gene cluster crz was identified and analyzed in detail. Here, we present a model of corallorazine biosynthesis, supported by bioinformatic analyses and in vitro investigations on the bimodular NRPS synthesizing the corallorazine core. Corallorazine biosynthesis shows several distinct features, such as the presence of a dehydrating condensation domain, and a unique split adenylation domain on two open reading frames. Using an alternative fatty acyl starter unit, the first steps of corallorazine biosynthesis were characterized in vitro, supporting our biosynthetic model. The dehydrating condensation domain was bioinformatically analyzed in detail and compared to other modifying C domains, revealing unreported specific sequence motives for this domain subfamily. Using global bioinformatics analyses, we show that the crz gene cluster family is widespread among bacteria and encodes notable chemical diversity. Corallorazine A displays moderate antimicrobial activity against selected Gram-positive and Gram-negative bacteria. Mode of action studies comprising whole cell analysis and in vitro test systems revealed that corallorazine A inhibits bacterial transcription by targeting the DNA-dependent RNA polymerase.