State Key Laboratory of Natural and Biomimetic Drugs, School of Pharmaceutical Sciences, Peking University, Beijing, China.
School of Basic Medical Sciences, Peking University, Beijing, China.
J Biol Chem. 2021 Jul;297(1):100822. doi: 10.1016/j.jbc.2021.100822. Epub 2021 May 23.
The fungal cyclohexadepsipeptides destruxins (DTXs), isaridins (ISDs), and isariins (ISRs) are nonribosomal peptides whose structures include a 19-membered ring composed of five amino acid residues and one α- or β-hydroxy acid residue. These cyclohexadepsipeptides contain unusual nonproteinogenic amino acid-building blocks and possess a range of antiviral, antibacterial, and other activities. The biosynthetic gene clusters for ISDs and ISRs have not been identified, and the biosynthesis of the nonproteinogenic (3S)-methyl-l-proline residue, which is found in DTXs, ISDs, and many other natural products, lacks full characterization. In an ongoing effort to identify compounds that can inhibit the Zika virus (ZIKV), we examined the extract of marine-derived fungus Beauveria felina SX-6-22 and discovered 30 DTXs, ISDs, and ISRs (1-30) including seven new compounds (1-7). The anti-ZIKV assays showed that 9-12 and 16-18 possess inhibitory activities against ZIKV RNA replication and NS5 (nonstructural protein 5) production in ZIKV-infected A549 cells. We sequenced the genome of B. felina SX-6-22 and identified three biosynthetic gene clusters detx, isd and isr, which are responsible for the biosynthesis of DTXs, ISDs, and ISRs, respectively. Comparative analyses of the three gene clusters clarified the biosynthetic relationships among these cyclohexadepsipeptides. Finally, we characterized the entire biosynthesis of nonproteinogenic building block (3S)-methyl-l-proline. The Δ-pyrroline-5-carboxylate reductases (P5CRs), also used in the biosynthesis of l-proline, were demonstrated to catalyze the final reduction step in (3S)-methyl-l-proline formation, suggesting potential cross talk between primary and secondary metabolisms. These results provide opportunities for biosynthetic pathway engineering to generate new anti-ZIKV cyclohexadepsipeptides.
真菌环己二肽类毒素(DTXs)、伊沙菌素(ISDs)和伊沙烷(ISRs)是非核糖体肽,其结构包括由五个氨基酸残基和一个α-或β-羟基酸残基组成的 19 元环。这些环己二肽含有不常见的非蛋白质氨基酸构建块,并具有抗病毒、抗菌等多种活性。ISDs 和 ISRs 的生物合成基因簇尚未被鉴定,而 DTXs、ISDs 和许多其他天然产物中发现的非蛋白质(3S)-甲基-L-脯氨酸残基的生物合成缺乏充分的特征描述。在寻找能抑制寨卡病毒(ZIKV)的化合物的持续努力中,我们研究了海洋来源真菌拟青霉 SX-6-22 的提取物,并发现了 30 种 DTXs、ISDs 和 ISRs(1-30),其中包括 7 种新化合物(1-7)。抗 ZIKV 测定表明,9-12 和 16-18 对 ZIKV 感染的 A549 细胞中 ZIKV RNA 复制和 NS5(非结构蛋白 5)产生具有抑制活性。我们对拟青霉 SX-6-22 的基因组进行了测序,并鉴定了三个生物合成基因簇 detx、isd 和 isr,它们分别负责 DTXs、ISDs 和 ISRs 的生物合成。对这三个基因簇的比较分析阐明了这些环己二肽之间的生物合成关系。最后,我们对非蛋白质氨基酸构建块(3S)-甲基-L-脯氨酸的整个生物合成进行了表征。Δ-吡咯啉-5-羧酸还原酶(P5CRs)也用于 L-脯氨酸的生物合成,被证明能催化(3S)-甲基-L-脯氨酸形成的最后还原步骤,这表明初级和次级代谢之间存在潜在的交叉对话。这些结果为生成新的抗 ZIKV 环己二肽的生物合成途径工程提供了机会。
