通过蛋白质组尺度的网络分析,以残基分辨率确定布氏锥虫编辑体蛋白质相互作用界面的优先次序。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-01-26 DOI:10.1186/s12860-024-00499-4
Naghmeh Poorinmohammad, Reza Salavati
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引用次数: 0

摘要

背景:布氏锥虫是人类和家畜锥虫病的病原体,由于耐药性的存在,这种疾病正面临着日益严峻的挑战。虽然确定新的药物靶点至关重要,但由于缺乏许多病原体蛋白质的功能信息,这一过程被推迟了。因此,本文提出了一个计算框架,用于确定编辑体中药物靶点的优先顺序,编辑体是负责布氏线粒体 RNA 处理的重要分子机制。重要的是,该框架无需事先进行基因或蛋白质表征,从而有可能加速药物发现工作:通过整合蛋白质-蛋白质相互作用(PPI)网络分析、PPI结构建模和残基相互作用网络(RIN)分析,我们定量排序并确定了顶级中枢编辑酶组蛋白质、它们的关键相互作用界面和热点残基。通过将我们的发现纳入基因组分析和现有的布鲁氏菌各生命阶段定量蛋白质组学数据的差异表达分析,我们对这些发现进行了交叉验证,并进一步确定了优先顺序。在此过程中,我们强调了 KREL2-KREPA1、RESC2-RESC1、RESC12A-RESC13 和 RESC10-RESC6 等 PPIs,将其作为进一步研究的首要候选对象。这包括研究它们的界面和热点残基,从而指导候选药物的选择和功能研究:结论:RNA 编辑为基于靶点的药物发现提供了希望,尤其是在病原体生命周期中发挥核心作用的蛋白质和界面。本研究介绍了一种综合药物靶点鉴定工作流程,它结合了 PPI 网络、PPI 三维结构及其界面的残基级信息,可适用于多种病原体。就布鲁斯氏菌而言,本研究通过这一流程从 RNA 编辑机制中提出了具有残基分辨率的潜在药物靶点。然而,要充分发挥其在推进急需的抗寄生虫药物开发方面的潜力,还需要进行实验验证。
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Prioritization of Trypanosoma brucei editosome protein interactions interfaces at residue resolution through proteome-scale network analysis.

Background: Trypanosoma brucei is the causative agent for trypanosomiasis in humans and livestock, which presents a growing challenge due to drug resistance. While identifying novel drug targets is vital, the process is delayed due to a lack of functional information on many of the pathogen's proteins. Accordingly, this paper presents a computational framework for prioritizing drug targets within the editosome, a vital molecular machinery responsible for mitochondrial RNA processing in T. brucei. Importantly, this framework may eliminate the need for prior gene or protein characterization, potentially accelerating drug discovery efforts.

Results: By integrating protein-protein interaction (PPI) network analysis, PPI structural modeling, and residue interaction network (RIN) analysis, we quantitatively ranked and identified top hub editosome proteins, their key interaction interfaces, and hotspot residues. Our findings were cross-validated and further prioritized by incorporating them into gene set analysis and differential expression analysis of existing quantitative proteomics data across various life stages of T. brucei. In doing so, we highlighted PPIs such as KREL2-KREPA1, RESC2-RESC1, RESC12A-RESC13, and RESC10-RESC6 as top candidates for further investigation. This includes examining their interfaces and hotspot residues, which could guide drug candidate selection and functional studies.

Conclusion: RNA editing offers promise for target-based drug discovery, particularly with proteins and interfaces that play central roles in the pathogen's life cycle. This study introduces an integrative drug target identification workflow combining information from the PPI network, PPI 3D structure, and reside-level information of their interface which can be applicable to diverse pathogens. In the case of T. brucei, via this pipeline, the present study suggested potential drug targets with residue-resolution from RNA editing machinery. However, experimental validation is needed to fully realize its potential in advancing urgently needed antiparasitic drug development.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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