A single Leishmania adenylate forming enzyme of the ANL superfamily generates both acetyl- and acetoacetyl-CoA.

IF 4 2区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Journal of Biological Chemistry Pub Date : 2024-10-10 DOI:10.1016/j.jbc.2024.107879

Andrew J Jezewski,Taiwo E Esan,Jonah Propp,Andrew J Fuller,Drashti G Daraji,Charles Lail,Bart L Staker,Elijah L Woodward,Linjun Liu,Kevin P Battaile,Scott Lovell,Timothy J Hagen,Damian J Krysan

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引用次数: 0

Abstract

Leishmania, a protozoan parasite, is responsible for significant morbidity and mortality worldwide, manifesting as cutaneous, mucocutaneous, and visceral leishmaniasis. These diseases pose a substantial burden, especially in impoverished regions with limited access to effective medical treatments. Current therapies are toxic, have low efficacy, and face growing resistance. Understanding the metabolic pathways of Leishmania, particularly those differing from its host, can unveil potential therapeutic targets. In this study, we investigated the acetyl-CoA synthetase (ACS) enzyme from Leishmania infantum (LiAcs1), which, unlike many organisms, also exhibits acetoacetyl-CoA synthetase (KBC) activity. This dual functionality is unique among ANL superfamily enzymes and crucial for the parasite's reliance on leucine catabolism, energy production and sterol biosynthesis. Our biochemical characterization of LiAcs1 revealed its ability to utilize both acetate and acetoacetate substrates. Additionally, LiAcs1 displayed a distinct CoA substrate inhibition pattern, partially alleviated by acetoacetate. Structural analysis provided insights into the substrate binding flexibility of LiAcs1, highlighting a more promiscuous substrate pocket compared to other ACS or KBC-specific enzymes. Substrate mimetics elucidated its ability to accommodate both small and large AMP-ester derivatives, contributing to its dual ACS/KBC functionality. These findings not only advance our understanding of Leishmania metabolism but also present LiAcs1 as a promising drug target. The dual functionality of LiAcs1 underscores the potential for developing selective inhibitors that could disrupt critical metabolic pathways across Leishmania spp. as it appears this enzyme is highly conserved across this genus. This paves the way for developing novel effective treatments against this devastating disease.

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ANL 超家族中的单个利什曼原虫腺苷酸形成酶可生成乙酰基和乙酰乙酰-CoA。

利什曼病是一种原生动物寄生虫，在全球范围内造成严重的发病率和死亡率，表现为皮肤、粘膜和内脏利什曼病。这些疾病造成了沉重的负担，尤其是在贫困地区，有效的医疗手段有限。目前的疗法毒性大、疗效低，而且面临越来越多的抗药性。了解利什曼原虫的代谢途径，尤其是与宿主不同的代谢途径，可以发现潜在的治疗目标。在这项研究中，我们研究了来自婴儿利什曼原虫（LiAcs1）的乙酰-CoA 合成酶（ACS），与许多生物不同的是，LiAcs1 还具有乙酰乙酰-CoA 合成酶（KBC）活性。这种双重功能在 ANL 超家族酶中是独一无二的，对于寄生虫依赖亮氨酸分解代谢、能量生产和固醇生物合成至关重要。我们对 LiAcs1 进行的生化鉴定显示，它能够利用醋酸和乙酰乙酸两种底物。此外，LiAcs1 还显示出独特的 CoA 底物抑制模式，乙酰乙酸可部分缓解这种抑制。结构分析深入揭示了 LiAcs1 与底物结合的灵活性，与其他 ACS 或 KBC 特异性酶相比，LiAcs1 的底物口袋更加杂乱无章。底物模拟物阐明了它同时容纳小分子和大分子 AMP 酯衍生物的能力，这有助于实现它的 ACS/KBC 双重功能。这些发现不仅增进了我们对利什曼原虫新陈代谢的了解，而且将 LiAcs1 作为一个有前途的药物靶点。LiAcs1 的双重功能凸显了开发选择性抑制剂的潜力，这些抑制剂可以破坏利什曼原虫属的关键代谢途径，因为这种酶似乎在利什曼原虫属中高度保守。这为开发新的有效疗法来治疗这种毁灭性疾病铺平了道路。

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

Journal of Biological Chemistry Biochemistry, Genetics and Molecular Biology-Biochemistry

自引率

4.20%

发文量

1233

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