Evaluation of molecular mechanisms of (Z)-3-(pentadec-10′-enyl)-catechol (litreol) and synthetic derivatives as inhibitors of human leukotriene biosynthesis

IF 11.9 1区生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

Redox Biology Pub Date : 2025-09-30 DOI:10.1016/j.redox.2025.103880

Alessia Maria Cossu , Simona Pace , Ferdinando Bruno , Lucia Abbatiello , Carmen Cerchia , Emanuele Falbo , Alejandra Catalina Muñoz Ramírez , Christian Kretzer , Laura Miek , Fabiana Troisi , Jana Gerstmeier , Pasquale Ambrosino , Silvia Zappavigna , Antonio La vecchia , Oliver Werz , Michele Caraglia , Rosanna Filosa

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引用次数: 0

Abstract

5-Lipoxygenase (5-LO) catalyzes the early steps of leukotriene (LT) biosynthesis, making it an attractive target for anti-inflammatory drug development. This study provides a more detailed evaluation of the molecular mechanisms and pharmacological effects of litreol (CI), a natural compound from the Anacardiaceae family, along with its synthetic derivatives (CS, AS, and AI). The synthesis and biological evaluation of litreol analogs have already been previously published. Therefore, the aim of this article is to further explore their mechanisms of action, providing a more thorough investigation into their effects on 5-LO. Using both isolated human recombinant 5-LO in cell-free systems and cell-based assays, we evaluated the impact of the synthesized compounds on 5-LO product formation. Among them, CI and CS emerged as potent inhibitors, exhibiting IC₅₀ values of 0.26 μM and 0.80 μM in neutrophils, and 0.06 μM and 0.15 μM in cell-free assays, respectively. Notably, CI exhibited 2.5- to 3-fold greater potency compared to its hydrogenated analogue, CS. Both compounds also showed inhibitory activity against 12-lipoxygenase (12-LO) with IC₅₀ of 3.15 and 5.10 μM, respectively. Moreover, CI prevented the 5-LO/FLAP protein interaction and blocked both ERK-1/2 and p38 MAP kinase-dependent pathways required for 5-LO activation. Conversely, AS and AI derivatives did not show significant 5-LO inhibitory effects. Computational studies revealed that the differing binding modes and stability of CI and CS at the allosteric site of 5-LO explain their varying inhibitory effects. CI forms a stronger interaction network, supporting its higher potency, while CS shows greater flexibility and weaker interactions, correlating with lower activity. Additionally, the free catechol group is essential for activity, as its acetylation leads to loss of function. Overall, our findings highlight CI as a promising 5-LO inhibitor, in intact human leukocytes accounting for a novel potent anti-inflammatory compound.

查看原文本刊更多论文

(Z)-3-（五-10'-烯基）-儿茶酚（litreol）及其衍生物作为人白三烯生物合成抑制剂的分子机制评价。

5-脂氧合酶（5-LO）催化白三烯（LT）生物合成的早期步骤，使其成为抗炎药物开发的一个有吸引力的靶点。本研究对槟榔科天然化合物litreol （CI）及其合成衍生物（CS、AS和AI）的分子机制和药理作用进行了更详细的评价。liteol类似物的合成和生物学评价先前已经发表。因此，本文的目的是进一步探讨它们的作用机制，为它们对5-LO的影响提供更深入的研究。利用分离的人重组5-LO在无细胞系统和基于细胞的实验，我们评估了合成的化合物对5-LO产物形成的影响。其中，CI和CS是有效的抑制剂，在中性粒细胞中IC50值分别为0.26 μM和0.80 μM，在无细胞试验中IC50值分别为0.06 μM和0.15 μM。值得注意的是，CI的效力比其氢化类似物CS高2.5至3倍。两种化合物对12-脂氧合酶（12-LO）均有抑制作用，IC50分别为3.15 μM和5.10 μM。此外，CI阻止了5-LO/FLAP蛋白的相互作用，并阻断了5-LO活化所需的ERK-1/2和p38 MAP激酶依赖通路。相反，AS和AI衍生物没有表现出明显的5-LO抑制作用。计算研究表明，CI和CS在5-LO变构位点的不同结合模式和稳定性解释了它们不同的抑制作用。CI形成了更强的相互作用网络，支持其更高的效力，而CS表现出更大的灵活性和更弱的相互作用，与较低的活性相关。此外，游离儿茶酚群对活性是必不可少的，因为它的乙酰化导致功能丧失。总的来说，我们的研究结果强调了CI作为一种有前途的5-LO抑制剂，在完整的人类白细胞中是一种新的有效的抗炎化合物。

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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来源期刊

Redox Biology BIOCHEMISTRY & MOLECULAR BIOLOGY-

CiteScore

19.90

自引率

3.50%

发文量

318

审稿时长

25 days

期刊介绍： Redox Biology is the official journal of the Society for Redox Biology and Medicine and the Society for Free Radical Research-Europe. It is also affiliated with the International Society for Free Radical Research (SFRRI). This journal serves as a platform for publishing pioneering research, innovative methods, and comprehensive review articles in the field of redox biology, encompassing both health and disease. Redox Biology welcomes various forms of contributions, including research articles (short or full communications), methods, mini-reviews, and commentaries. Through its diverse range of published content, Redox Biology aims to foster advancements and insights in the understanding of redox biology and its implications.