主要利什曼原虫核苷水解酶的比较分析，旨在选择多靶点策略。

Comparative Analysis of Leishmania major Nucleoside Hydrolases Toward Selecting Multi-target Strategy.

机构信息

Biotechnology Department, Faculty of Advanced Sciences and Technology, Tehran Medical Sciences, Islamic Azad University, Tehran, 1916893813, Iran.

出版信息

Acta Parasitol. 2024 Mar;69(1):332-342. doi: 10.1007/s11686-023-00748-0. Epub 2023 Dec 12.

DOI:10.1007/s11686-023-00748-0

PMID:38085461

Abstract

PURPOSE

Leishmania causes multiple types of leishmaniasis in different parts of the world. It has a lack of metabolic machine to produce purine bases. Therefore, the parasite produces purine bases through the breakdown of nutritional nucleotides and it makes the nucleoside hydrolases (NHs) good drug targets. They have different substrate-preferring (SP) types. Our objectives were modeling and comparative analysis of these protein structures for Leishmania major.

METHOD

In this work, available sequences for all SP types of L. major NH enzymes including inosine-uridine preferring NH (IUNH), inosine-guanosine preferring NH (IGNH), and inosine-adenosine-guanosine preferring NH (IAGNH) were used to make 24 structural models via SWISS-MODEL and LOMETS. After evaluating the structural models, three enzyme structures were finalized and used to analyze substrate-binding pockets.

RESULTS

The three SP types of L. major NH enzymes that can breakdown purine nucleosides were highly different in terms of sequence, structure, and profile of interacting residues within the substrate-binding pockets. In this study, new enzyme structures have been presented for three SP types and they have been compared in different aspects and it indicated that they were very different from each other.

CONCLUSION

Although, previously indicated that from these three SP types in genera other than Leishmania, the role of IGNH and IAGNH was greater than IUNH in supplying purine bases, till this work, just IUNH has been structurally studied and used in drug-design investigations for Leishmania. Therefore, we are offering to use all three SP types of NHs as multi-target strategy in anti-leishmaniosis drug-design studies.

摘要

目的

利什曼原虫在世界不同地区引起多种利什曼病。它缺乏代谢机器来产生嘌呤碱基。因此，寄生虫通过分解营养核苷酸来产生嘌呤碱基，这使得核苷水解酶（NHs）成为良好的药物靶点。它们具有不同的底物偏好（SP）类型。我们的目标是对利什曼原虫的这些蛋白质结构进行建模和比较分析。

方法

在这项工作中，使用了利什曼原虫所有 SP 类型的 NH 酶的可用序列，包括次黄嘌呤-尿嘧啶偏好 NH（IUNH）、次黄嘌呤-鸟嘌呤偏好 NH（IGNH）和次黄嘌呤-腺嘌呤-鸟嘌呤偏好 NH（IAGNH），通过 SWISS-MODEL 和 LOMETS 制作了 24 个结构模型。在评估结构模型后，确定了三种酶结构，并用于分析底物结合口袋。

结果

三种 SP 类型的利什曼原虫 NH 酶在序列、结构和底物结合口袋内相互作用残基的分布方面差异很大，可以分解嘌呤核苷。在这项研究中，提出了三种 SP 类型的新酶结构，并在不同方面进行了比较，表明它们彼此之间非常不同。

结论

尽管之前的研究表明，在除利什曼原虫以外的属中，IGNH 和 IAGNH 的作用大于 IUNH，为生物体提供嘌呤碱基，但直到这项工作，仅 IUNH 的结构已被研究，并用于利什曼病的药物设计研究。因此，我们建议将所有三种 SP 类型的 NHs 作为多靶点策略用于抗利什曼病药物设计研究。

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主要利什曼原虫核苷水解酶的比较分析，旨在选择多靶点策略。

Comparative Analysis of Leishmania major Nucleoside Hydrolases Toward Selecting Multi-target Strategy.

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出版信息

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METHOD

RESULTS

CONCLUSION

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结果

结论

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