Biophysical analysis of the membrane-proximal Venus Flytrap domain of ESAG4 receptor-like adenylate cyclase from Trypanosoma brucei

IF 1.4 4区医学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY

Molecular and biochemical parasitology Pub Date : 2024-10-22 DOI:10.1016/j.molbiopara.2024.111653

Desirée O. Alves , Rob Geens , Hiam R. da Silva Arruda , Lisa Jennen , Sam Corthaut , Ellen Wuyts , Guilherme Caldas de Andrade , Francisco Prosdocimi , Yraima Cordeiro , José Ricardo Pires , Larissa Rezende Vieira , Guilherme A.P. de Oliveira , Yann G.-J. Sterckx , Didier Salmon

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引用次数: 0

Abstract

The protozoan parasite Trypanosoma brucei possesses a large family of transmembrane receptor-like adenylate cyclases (RACs), primarily located to the flagellar surface and involved in sensing of the extracellular environment. RACs exhibit a conserved topology characterized by a large N-terminal extracellular moiety harbouring two Venus Flytrap (VFT) bilobate structures separated from an intracellular catalytic domain by a single transmembrane helix. RAC activation, which typically occurs under mild acid stress, requires the dimerization of the intracellular catalytic domain. The occurrence of VFT domains in the RAC’s extracellular moiety suggests their potential responsiveness to extracellular ligands in the absence of stress, although no such ligands have been identified so far. Herein we report the biophysical characterization of the membrane-proximal VFT2 domain of a bloodstream form-specific RAC called ESAG4, whose ectodomain 3D structure is completely unknown. The paper describes an AlphaFold2-based optimisation of the expression construct, enabling facile and high-yield recombinant production and purification of the target protein. Through an interdisciplinary approach combining various biophysical methods, we demonstrate that the optimised VFT2 domain obtained by recombination is properly folded and behaves as a monomer in solution. The latter suggests a ligand-binding capacity independent of dimerization, unlike typical mammalian VFT receptors, as guanylate cyclase. In silico VFT2 genomic analyses shows divergence among cyclase isoforms, hinting at ligand specificity. Taken together this improved procedure enabling facile and high-yield recombinant production and purification of the target protein could benefit researchers studying trypanosomal RAC VFT domains but also any trypanosome domain with poorly defined boundaries. Additionally, our findings support the stable monomeric VFT2 domain as a useful tool for future structural investigations and ligand screening.

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布氏锥虫 ESAG4 受体样腺苷酸环化酶膜近端金星捕蝇草结构域的生物物理分析

原生动物布氏锥虫拥有一个庞大的跨膜受体样腺苷酸环化酶（RAC）家族，主要位于鞭毛表面，参与感知细胞外环境。RACs 具有保守的拓扑结构，其特点是 N 端细胞外的大分子含有两个金星捕蝇草（VFT）双叶结构，与细胞内的催化结构域之间由一个跨膜螺旋隔开。RAC 激活通常发生在轻度酸应激状态下，需要细胞内催化结构域的二聚化。在 RAC 的细胞外分子中出现 VFT 结构域表明，在没有压力的情况下，它们可能会对细胞外配体产生反应，尽管迄今为止尚未发现此类配体。在本文中，我们报告了一种名为 ESAG4 的血流形式特异性 RAC 的膜近端 VFT2 结构域的生物物理特征。论文介绍了一种基于 AlphaFold2 的表达构建物优化方法，从而实现了目标蛋白的便捷、高产重组生产和纯化。通过结合各种生物物理方法的跨学科方法，我们证明了通过重组获得的优化 VFT2 结构域是正确折叠的，并且在溶液中表现为单体。后者表明，与典型的哺乳动物 VFT 受体（如鸟苷酸环化酶）不同，VFT2 具有独立于二聚体的配体结合能力。硅学 VFT2 基因组分析表明，环化酶同工酶之间存在差异，暗示了配体的特异性。总之，这种改进的程序能够方便、高产地重组生产和纯化目标蛋白，对研究锥虫 RAC VFT 结构域以及边界不明确的锥虫结构域的研究人员大有裨益。此外，我们的研究结果还支持将稳定的单体 VFT2 结构域作为未来结构研究和配体筛选的有用工具。

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来源期刊

Molecular and biochemical parasitology 医学-寄生虫学

CiteScore

2.90

自引率

0.00%

发文量

审稿时长

63 days

期刊介绍： The journal provides a medium for rapid publication of investigations of the molecular biology and biochemistry of parasitic protozoa and helminths and their interactions with both the definitive and intermediate host. The main subject areas covered are: • the structure, biosynthesis, degradation, properties and function of DNA, RNA, proteins, lipids, carbohydrates and small molecular-weight substances • intermediary metabolism and bioenergetics • drug target characterization and the mode of action of antiparasitic drugs • molecular and biochemical aspects of membrane structure and function • host-parasite relationships that focus on the parasite, particularly as related to specific parasite molecules. • analysis of genes and genome structure, function and expression • analysis of variation in parasite populations relevant to genetic exchange, pathogenesis, drug and vaccine target characterization, and drug resistance. • parasite protein trafficking, organelle biogenesis, and cellular structure especially with reference to the roles of specific molecules • parasite programmed cell death, development, and cell division at the molecular level.