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昆虫味觉受体感知糖的分子基础。

The molecular basis of sugar detection by an insect taste receptor.

机构信息

Department of Pharmacology, Yale University School of Medicine, New Haven, CT, USA.

出版信息

Nature. 2024 May;629(8010):228-234. doi: 10.1038/s41586-024-07255-w. Epub 2024 Mar 6.

DOI:10.1038/s41586-024-07255-w
PMID:38447670
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11062906/
Abstract

Animals crave sugars because of their energy potential and the pleasurable sensation of tasting sweetness. Yet all sugars are not metabolically equivalent, requiring mechanisms to detect and differentiate between chemically similar sweet substances. Insects use a family of ionotropic gustatory receptors to discriminate sugars, each of which is selectively activated by specific sweet molecules. Here, to gain insight into the molecular basis of sugar selectivity, we determined structures of Gr9, a gustatory receptor from the silkworm Bombyx mori (BmGr9), in the absence and presence of its sole activating ligand, D-fructose. These structures, along with structure-guided mutagenesis and functional assays, illustrate how D-fructose is enveloped by a ligand-binding pocket that precisely matches the overall shape and pattern of chemical groups in D-fructose. However, our computational docking and experimental binding assays revealed that other sugars also bind BmGr9, yet they are unable to activate the receptor. We determined the structure of BmGr9 in complex with one such non-activating sugar, L-sorbose. Although both sugars bind a similar position, only D-fructose is capable of engaging a bridge of two conserved aromatic residues that connects the pocket to the pore helix, inducing a conformational change that allows the ion-conducting pore to open. Thus, chemical specificity does not depend solely on the selectivity of the ligand-binding pocket, but it is an emergent property arising from a combination of receptor-ligand interactions and allosteric coupling. Our results support a model whereby coarse receptor tuning is derived from the size and chemical characteristics of the pocket, whereas fine-tuning of receptor activation is achieved through the selective engagement of an allosteric pathway that regulates ion conduction.

摘要

动物之所以渴望糖,是因为糖具有能量潜力,并且品尝到甜味会带来愉悦感。然而,并非所有的糖在新陈代谢上都是等同的,它们需要机制来检测和区分化学性质相似的甜味物质。昆虫使用一系列离子型味觉受体来区分糖,每种受体都被特定的甜味分子选择性激活。为了深入了解糖选择性的分子基础,我们测定了家蚕(Bombyx mori)味觉受体 Gr9(BmGr9)在不存在和存在其唯一激活配体 D-果糖时的结构。这些结构,以及结构引导的突变和功能测定,说明了 D-果糖是如何被一个配体结合口袋所包裹的,该口袋精确地匹配了 D-果糖的整体形状和基团模式。然而,我们的计算对接和实验结合测定显示,其他糖也能与 BmGr9 结合,但它们无法激活受体。我们测定了 BmGr9 与一种非激活糖 L-山梨糖结合的复合物结构。尽管这两种糖结合在相似的位置,但只有 D-果糖能够与两个保守芳香族残基形成桥接,将口袋与孔螺旋连接起来,诱导构象变化,使离子传导孔打开。因此,化学特异性不仅取决于配体结合口袋的选择性,还取决于受体-配体相互作用和变构偶联的综合效应。我们的结果支持这样一种模型,即粗调受体是由口袋的大小和化学特征决定的,而受体激活的微调则是通过选择性地参与调节离子传导的变构途径来实现的。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4ff8/11062906/a1647768e810/41586_2024_7255_Fig14_ESM.jpg
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