Novel, tightly structurally related N-myristoyltransferase inhibitors display equally potent yet distinct inhibitory mechanisms

IF 4.4 2区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Structure Pub Date : 2024-08-28 DOI:10.1016/j.str.2024.08.001

Frédéric Rivière, Cyril Dian, Rémi F. Dutheil, Paul Monassa, Carmela Giglione, Thierry Meinnel

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Abstract

N-myristoyltransferases (NMTs) catalyze essential acylations of N-terminal alpha or epsilon amino groups of glycines or lysines. Here, we reveal that peptides tightly fitting the optimal glycine recognition pattern of human NMTs are potent prodrugs relying on a single-turnover mechanism. Sequence scanning of the inhibitory potency of the series closely reflects NMT glycine substrate specificity rules, with the lead inhibitor blocking myristoylation by NMTs of various species. We further redesigned the series based on the recently recognized lysine-myristoylation mechanism by taking advantage of (1) the optimal peptide chassis and (2) lysine side chain mimicry with unnatural enantiomers. Unlike the lead series, the inhibitory properties of the new compounds rely on the protonated state of the side chain amine, which stabilizes a salt bridge with the catalytic base at the active site. Our study provides the basis for designing first-in-class NMT inhibitors tailored for infectious diseases and alternative active site targeting.

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结构紧密相关的新型 N-肉豆蔻酰基转移酶抑制剂显示出同等效力但不同的抑制机制

N-肉豆蔻酰转移酶（NMTs）可催化甘氨酸或赖氨酸的 N-末端α或ε氨基的必要酰化。在这里，我们揭示了与人类 NMTs 的最佳甘氨酸识别模式紧密配合的多肽是依靠单次转化机制的强效原药。对该系列抑制效力的序列扫描密切反映了 NMT 甘氨酸底物特异性规则，主要抑制剂阻断了不同物种 NMT 的肉豆蔻酰化作用。我们根据最近认识到的赖氨酸-肉豆蔻酰化机制进一步重新设计了该系列，利用了（1）最佳肽底盘和（2）非天然对映体的赖氨酸侧链模拟。与先导系列不同的是，新化合物的抑制特性依赖于侧链胺的质子化状态，这种状态可以稳定活性位点催化碱的盐桥。我们的研究为设计针对传染性疾病和替代活性位点靶向的一流 NMT 抑制剂奠定了基础。

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来源期刊

Structure 生物-生化与分子生物学

CiteScore

8.90

自引率

1.80%

发文量

155

审稿时长

3-8 weeks

期刊介绍： Structure aims to publish papers of exceptional interest in the field of structural biology. The journal strives to be essential reading for structural biologists, as well as biologists and biochemists that are interested in macromolecular structure and function. Structure strongly encourages the submission of manuscripts that present structural and molecular insights into biological function and mechanism. Other reports that address fundamental questions in structural biology, such as structure-based examinations of protein evolution, folding, and/or design, will also be considered. We will consider the application of any method, experimental or computational, at high or low resolution, to conduct structural investigations, as long as the method is appropriate for the biological, functional, and mechanistic question(s) being addressed. Likewise, reports describing single-molecule analysis of biological mechanisms are welcome. In general, the editors encourage submission of experimental structural studies that are enriched by an analysis of structure-activity relationships and will not consider studies that solely report structural information unless the structure or analysis is of exceptional and broad interest. Studies reporting only homology models, de novo models, or molecular dynamics simulations are also discouraged unless the models are informed by or validated by novel experimental data; rationalization of a large body of existing experimental evidence and making testable predictions based on a model or simulation is often not considered sufficient.

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