Structural diversity in echinocandin biosynthesis: the impact of oxidation steps and approaches toward an evolutionary explanation

Wolfgang Hüttel
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引用次数: 19

Abstract

Abstract Echinocandins are an important group of cyclic non-ribosomal peptides with strong antifungal activity produced by filamentous fungi from Aspergillaceae and Leotiomycetes. Their structure is characterized by numerous hydroxylated non-proteinogenic amino acids. Biosynthetic clusters discovered in the last years contain up to six oxygenases, all of which are involved in amino acid modifications. Especially, variations in the oxidation pattern induced by these enzymes account for a remarkable structural diversity among the echinocandins. This review provides an overview of the current knowledge of echinocandin biosynthesis with a special focus on diversity-inducing oxidation steps. The emergence of metabolic diversity is further discussed on the basis of a comprehensive overview of the structurally characterized echinocandins, their producer strains and biosynthetic clusters. For the pneumocandins, echinocandins produced by Glarea lozoyensis, the formation of metabolic diversity in a single organism is analyzed. It is compared to two common models for the evolution of secondary metabolism: the ‘target-based’ approach and the ‘diversity-based’ model. Whereas the early phase of pneumocandin biosynthesis supports the target-based model, the diversity-inducing late steps and most oxidation reactions best fit the diversity-based approach. Moreover, two types of diversity-inducing steps can be distinguished. Although incomplete hydroxylation is a common phenomenon in echinocandin production and secondary metabolite biosynthesis in general, the incorporation of diverse hydroxyprolines at position 6 is apparently a unique feature of pneumocandin biosynthesis, which stands in stark contrast to the strict selectivity found in echinocandin biosynthesis by Aspergillaceae. The example of echinocandin biosynthesis shows that the existing models for the evolution of secondary metabolism can be well applied to parts of the pathway; however, thus far, there is no comprehensive theory that could explain the entire biosynthesis.
棘白菌素生物合成的结构多样性:氧化步骤的影响和进化解释的途径
棘白菌素是一类重要的环状非核糖体肽,具有较强的抗真菌活性。它们的结构以大量羟基化的非蛋白质原氨基酸为特征。近年来发现的生物合成簇含有多达六种加氧酶,它们都与氨基酸修饰有关。特别是,由这些酶诱导的氧化模式的变化解释了棘白菌之间显着的结构多样性。本文综述了棘白菌素生物合成的最新知识,重点介绍了诱导多样性氧化的步骤。在对棘白菌素的结构特征、产生菌和生物合成菌群进行综述的基础上,进一步讨论了代谢多样性的出现。对于由Glarea lozoyensis产生的尘肺菌、棘球白菌,分析了单个生物代谢多样性的形成。它与二级代谢进化的两种常见模型进行了比较:“基于目标”的方法和“基于多样性”的模型。尽管肺结核菌生物合成的早期阶段支持基于靶标的模型,但诱导多样性的后期步骤和大多数氧化反应最适合基于多样性的方法。此外,可以区分两种类型的多样性诱导步骤。虽然不完全羟基化是棘球菌素生产和次生代谢物生物合成中普遍存在的现象,但在6号位置上多种羟基脯氨酸的结合显然是肺菌素生物合成的独特特征,这与曲霉科棘球菌素生物合成中严格的选择性形成鲜明对比。棘白菌素生物合成的例子表明,现有的次级代谢进化模型可以很好地应用于部分途径;然而,到目前为止,还没有一个全面的理论可以解释整个生物合成过程。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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