Modularity of RiPP Enzymes Enables Designed Synthesis of Decorated Peptides.

Chemistry & biology Pub Date : 2015-07-23 Epub Date: 2015-07-09 DOI:10.1016/j.chembiol.2015.06.014

Debosmita Sardar, Zhenjian Lin, Eric W Schmidt

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引用次数: 65

Abstract

Macrocyclases and other posttranslational enzymes afford derived peptides with improved properties for pharmaceutical and biotechnological applications. Here, we asked whether multiple posttranslational modifications could be simultaneously controlled and matched to rationally generate new peptide derivatives. We reconstituted the cyanobactin peptide natural products in vitro with up to five different posttranslational enzymes in a single tube. By manipulating the order of addition and identity of enzymes and exploiting their broad-substrate tolerance, we engineered the production of highly unnatural derivatives, including an N-C peptide macrocycle of 22 amino acids in length. In addition to engineering, this work better defines the macrocyclization mechanism, provides the first biochemical demonstration of Ser/Thr posttranslational prenylation, and is the first example of reconstitution of a native, multistep RiPP pathway with multiple enzymes in one pot. Overall, this work demonstrates how the modularity of posttranslational modification enzymes can be used to design and synthesize desirable peptide motifs.

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RiPP酶的模块化使设计合成修饰肽成为可能。

大环化酶和其他翻译后酶为制药和生物技术应用提供了性能改进的衍生肽。在这里，我们想知道是否可以同时控制和匹配多个翻译后修饰，以合理地产生新的肽衍生物。我们在体外用多达五种不同的翻译后酶在单管中重组了蓝藻肽天然产物。通过控制酶的添加顺序和特性，利用它们的宽底物耐受性，我们设计了高度非天然衍生物的生产，包括一个长度为22个氨基酸的N-C肽大环。除了工程方面，这项工作更好地定义了大环化机制，首次提供了Ser/Thr翻译后戊酰化的生化论证，并且是第一个在一个锅中使用多种酶重构天然多步骤RiPP途径的例子。总的来说，这项工作展示了如何使用翻译后修饰酶的模块化来设计和合成所需的肽基序。

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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Chemistry & biology 生物-生化与分子生物学

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4-8 weeks