[Advances in applications of activity-based chemical probes in the characterization of amino acid reactivities].

IF 1.2 4区 化学 Q4 CHEMISTRY, ANALYTICAL 色谱 Pub Date : 2023-01-01 DOI:10.3724/SP.J.1123.2022.05013
Jiaying Li, Guosheng Wang, Mingliang Ye, Hongqiang Qin
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Abstract

The discovery of novel drug targets enhances the development of novel drugs, and the discovery of novel target proteins depends on highly accurate high-throughput methods of analyzing drug-protein interactions. Protein expression levels, spatial localization, and structural differences directly affect pharmacodynamics. To date, >20000 proteins have been discovered in the human proteome by the genome and proteome projects via gene and protein sequencing. Understanding the biological functions of proteins is critical in identifying and regulating biological processes, with most remaining unidentified. Until recently, >85% of proteins were considered undruggable, mainly because of the lack of binding pockets and active sites targeted by small molecules. Therefore, characterization of the reactive sites of amino acids based on proteomic hierarchy is the key to novel drug design. Recently, with the rapid development of mass spectrometry (MS), the study of drug-target protein interactions based on proteomics technology has been considerably promoted. Activity-based protein profiling (ABPP) is an active chemical probe-based method of detecting functional enzymes and drug targets in complex samples. Compared with classical proteomics strategies, ABPP is based mainly on protein activity. It has been successfully utilized to characterize the activities of numerous protease families with crucial biological functions, such as serine hydrolases, protein kinases, glycosidases, and metalloenzymes. It has also been used to identify key enzymes that are closely related to diseases and develop covalent inhibitors for use in disease treatment. The technology used in proteome analysis ranges from gel electrophoresis to high-throughput MS due to the progress of MS technology. ABPP strategies combined with chemical probe labeling and quantitative MS enable the characterization of amino acid activity, which may enhance the discovery of novel drug targets and the development of lead compounds. Amino acid residues play critical roles in protein structures and functions, and covalent drugs targeting these amino acids are effective in treating numerous diseases. There are 20 main types of natural amino acids, with different reactivities, in the proteins in the human body. In addition, the proteins and amino acids are affected by the spatial microenvironment, leading to significant differences in their spatial reactivities. The key in evaluating the reactivities of amino acids via ABPP is to select those with high reactivities. The core of the ABPP strategy is the use of chemical probes to label amino acid sites that exhibit higher activities in certain environments. The activity-based probe (ABP) at the core of ABPP consists of three components: reactive, reporter groups and a linker. The reactive group is the basis of the ABP and anchors the drug target via strong forces, such as covalent bonds. The reaction exhibits a high specificity and conversion rate and should display a good biocompatibility. Activity probes based on different amino acid residues have been developed, and the screening of amino acid activity combined with isotope labeling is a new focus of research. Currently, different types of ABPs have been developed to target amino acids and characterize amino acid reactivity, such as cysteine labeled with an electrophilic iodoacetamide probe and lysine labeled with activated esters. ABPP facilitates the discovery of potentially therapeutic protein targets, the screening of lead compounds, and the identification of drug targets, thus aiding the design of novel drugs. This review focuses on the development of ABPP methods and the progress in the screening of amino acid reactivity using ABPs, which should be promising methods for use in designing targeted drugs with covalent interactions.

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[基于活性的化学探针在表征氨基酸反应活性方面的应用进展]。
新型药物靶点的发现促进了新型药物的开发,而新型靶蛋白的发现则依赖于高精确度的高通量药物-蛋白相互作用分析方法。蛋白质的表达水平、空间定位和结构差异直接影响药效学。迄今为止,通过基因和蛋白质测序的基因组和蛋白质组项目已在人类蛋白质组中发现了超过 20000 种蛋白质。了解蛋白质的生物功能对于确定和调控生物过程至关重要,但大多数蛋白质仍未被发现。直到最近,仍有超过 85% 的蛋白质被认为是不可药用的,主要原因是缺乏小分子靶向的结合口袋和活性位点。因此,基于蛋白质组分级的氨基酸活性位点表征是新药设计的关键。近年来,随着质谱(MS)技术的飞速发展,基于蛋白质组学技术的药物-靶标蛋白相互作用研究得到了极大的推广。基于活性的蛋白质分析(ABPP)是一种基于活性化学探针的方法,用于检测复杂样品中的功能酶和药物靶标。与传统的蛋白质组学策略相比,ABPP 主要基于蛋白质的活性。ABPP 已成功用于表征众多具有重要生物功能的蛋白酶家族的活性,如丝氨酸水解酶、蛋白激酶、糖苷酶和金属酶。它还被用来鉴定与疾病密切相关的关键酶,并开发用于疾病治疗的共价抑制剂。由于 MS 技术的进步,蛋白质组分析所使用的技术从凝胶电泳到高通量 MS 不等。ABPP 策略与化学探针标记和定量质谱相结合,可确定氨基酸活性的特征,从而促进新型药物靶点的发现和先导化合物的开发。氨基酸残基在蛋白质结构和功能中起着关键作用,针对这些氨基酸的共价药物可有效治疗多种疾病。人体内的蛋白质中有 20 种主要的天然氨基酸,它们具有不同的反应活性。此外,蛋白质和氨基酸还受到空间微环境的影响,导致它们的空间反应性存在显著差异。通过 ABPP 评估氨基酸反应性的关键在于选择高反应性的氨基酸。ABPP 策略的核心是使用化学探针标记在特定环境中表现出较高活性的氨基酸位点。ABPP 核心的活性探针(ABP)由三部分组成:反应基团、报告基团和连接基团。反应基团是 ABP 的基础,通过共价键等强力锚定药物靶点。该反应具有很高的特异性和转化率,并具有良好的生物相容性。目前已开发出基于不同氨基酸残基的活性探针,结合同位素标记筛选氨基酸活性是研究的新重点。目前已开发出不同类型的 ABPs,用于靶向氨基酸和表征氨基酸反应性,如用亲电性碘乙酰胺探针标记半胱氨酸和用活化酯标记赖氨酸。ABPP 有助于发现潜在的治疗性蛋白质靶点、筛选先导化合物和鉴定药物靶点,从而帮助设计新型药物。本综述重点介绍 ABPP 方法的发展以及利用 ABPs 筛选氨基酸反应性的进展,这些方法在设计具有共价相互作用的靶向药物方面大有可为。
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来源期刊
色谱
色谱 CHEMISTRY, ANALYTICAL-
CiteScore
1.30
自引率
42.90%
发文量
7198
期刊介绍: "Chinese Journal of Chromatography" mainly reports the basic research results of chromatography, important application results of chromatography and its interdisciplinary subjects and their progress, including the application of new methods, new technologies, and new instruments in various fields, the research and development of chromatography instruments and components, instrument analysis teaching research, etc. It is suitable for researchers engaged in chromatography basic and application technology research in scientific research institutes, master and doctoral students in chromatography and related disciplines, grassroots researchers in the field of analysis and testing, and relevant personnel in chromatography instrument development and operation units. The journal has columns such as special planning, focus, perspective, research express, research paper, monograph and review, micro review, technology and application, and teaching research.
期刊最新文献
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