Possibility for detecting 14 typical odorants occurring in drinking water by employing human odor-binding protein OBP2a

IF 6 3区环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES Environmental Sciences Europe Pub Date : 2023-06-09 DOI:10.1186/s12302-023-00746-z

Xinying Chang, Fuguo Qiu, Chunmiao Wang, Yaohan Qian, Yongxin Zhang, Qingyuan Guo, Qi Wang, Shihao Wang, Min Yang, Jianwei Yu

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引用次数: 1

Abstract

Odor issues occurring in drinking water have been a big challenge to face for water suppliers globally, which highly commend to develop quick or on-site odor detection tools for the management of odor problems. Olfactory sensors based on odor-binding proteins (OBPs) have been utilized to analyze pollutants in food and air samples, while their application for the detection of typical odor-causing compounds in drinking water is rarely reported, partly due to the lack of knowledge about the binding properties of odorants. In this study, the binding affinity and mechanism of human odor-binding protein OBP2a to 14 typical odorants in water were first assessed using fluorescent competitive binding assays and molecular docking techniques. The 14 odorants include 7 aldehydes, 2 terpenes, 2 thioethers, bis(2-chloro-1-methylethyl) ether (DCIP), 2-ethyl-4-methyl-1,3-dioxolane (2E4MDL), and 2-isobutyl-3-methoxypyrazine (IBMP). The results showed that OBP2a could bind to 9 odorants (K_i = 29.91 μmol/L–48.36 μmol/L), including IBMP, 2-MIB, and six aldehydes (hexanal, heptanal, benzaldehyde, 2-octenal, decanal, and β-cyclocitral), among which stronger binding affinity for aldehydes is observed (K_i = 29.91 μmol/L–43.87 μmol/L). Molecular docking confirmed that Lys112 and Phe97 are major amino acid residues involved in the binding of the most target odorants. To be specific, IBMP and aldehydes can form hydrogen bonds with Lys112; aromatic ring-containing odorants such as IBMP and benzaldehyde can also form pi–pi stacking with Phe97. The binding affinity of OBP2a to fatty aldehydes including hexanal, heptanal, 2-octenal, decanal, and β-cyclocitral increased with the increase of hydrophobicity of aldehydes. The valuable information to the binding of OBP2a to typical odorants in this study would provide a theoretical foundation for the development of OBP-based odor detection biosensors to achieve quick detection in drinking water, further helping the improvement of water treatment processes in the water industry.

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利用人气味结合蛋白OBP2a检测饮用水中14种典型气味的可能性

饮用水中的气味问题一直是全球供水商面临的巨大挑战，他们高度推荐开发快速或现场气味检测工具来管理气味问题。基于气味结合蛋白(OBPs)的嗅觉传感器已被用于分析食品和空气样本中的污染物，而其用于检测饮用水中典型气味引起的化合物的应用很少报道，部分原因是缺乏对气味剂结合特性的了解。本研究首先利用荧光竞争结合实验和分子对接技术，评估了人气味结合蛋白OBP2a与14种水中典型气味的结合亲和力和机制。这14种气味剂包括7种醛、2种萜烯、2种硫醚、双(2-氯-1-甲基乙基)醚(DCIP)、2-乙基-4-甲基-1,3-二恶烷(2E4MDL)和2-异丁基-3-甲氧基吡嗪(IBMP)。结果表明，OBP2a能结合9种气味剂(Ki = 29.91 μmol/L - 48.36 μmol/L)，包括IBMP、2-MIB和6种醛类(己醛、庚醛、苯甲醛、2-辛醛、癸醛和β-环柠檬醛)，其中对醛类的结合亲和力较强(Ki = 29.91 μmol/L - 43.87 μmol/L)。分子对接证实Lys112和Phe97是参与大多数目标气味剂结合的主要氨基酸残基。具体来说，IBMP和醛类化合物可以与Lys112形成氢键;含芳香环的气味剂如IBMP和苯甲醛也能与Phe97形成pi-pi堆积。OBP2a对己醛、庚醛、2-辛醛、癸醛、β-环癸醛等脂肪醛的结合亲和力随着醛类疏水性的增加而增加。本研究为OBP2a与典型气味剂结合提供了有价值的信息，为开发基于obp的气味检测生物传感器，实现饮用水中的快速检测提供了理论基础，进一步帮助改善水工业的水处理工艺。图形抽象

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来源期刊

Environmental Sciences Europe Environmental Science-Pollution

CiteScore

11.20

自引率

1.70%

发文量

110

审稿时长

13 weeks

期刊介绍： ESEU is an international journal, focusing primarily on Europe, with a broad scope covering all aspects of environmental sciences, including the main topic regulation. ESEU will discuss the entanglement between environmental sciences and regulation because, in recent years, there have been misunderstandings and even disagreement between stakeholders in these two areas. ESEU will help to improve the comprehension of issues between environmental sciences and regulation. ESEU will be an outlet from the German-speaking (DACH) countries to Europe and an inlet from Europe to the DACH countries regarding environmental sciences and regulation. Moreover, ESEU will facilitate the exchange of ideas and interaction between Europe and the DACH countries regarding environmental regulatory issues. Although Europe is at the center of ESEU, the journal will not exclude the rest of the world, because regulatory issues pertaining to environmental sciences can be fully seen only from a global perspective.