昆虫气味认知的嗅觉神经结构及分子机制

大多数昆虫主要通过气味认知感知外界环境的变化,维持生命活动。探究昆虫气味认知的嗅觉系统神经结构及分子机制,对于完善气味认知神经生物学理论及利用其原理进行仿生学研究等有重要的科学意义。近年,关于昆虫气味认知科学研究有了很大的进展。本文从昆虫神经生物学的视角详细综述了近年关于昆虫气味认知的嗅觉神经结构、分子机制及气味信号的神经传导途径等方面的基本理论及最新研究成果。综述结果显示:昆虫对气味的认知是通过嗅觉神经系统的触角感器、触角叶(AL)、蕈形体(MB)等脑内多层信号处理神经结构来实现的。当外界气味分子进入触角感器内后,由感器内特定的气味识别蛋白(OBP)将气味分子运载到达嗅觉感受神经元(ORN)树突膜上的受体位点,气味分子与表达特定气味的受体(OR)结合产生电信号,并以动作电位的形式通过ORN的轴突传到脑内的触角叶。在触角叶经过嗅觉纤维球对气味信息选择性加工处理,再由投射神经元(PNs)将初步的识别和分类的气味信息传到蕈形体和外侧角(LH)等神经中枢,实现对气味的识别和认知。虽然,近年昆虫气味认知神经生物学的研究有了很大的进步,但是,我们认为目前的研究成果还不能完全阐明昆虫气味认知的神经机制,还有很多问题,例如,触角叶上众多的嗅觉纤维球是如何对嗅觉感受神经元传入的气味信息进行编码处理的?等有待进一步深入研究。为了搞清这些疑难问题,我们认为需要提高现有的实验技术水平,加强电生理学和分子神经生物学相结合的实验研究,从分子水平探究气味认知的神经机制可能是未来研究的热点。     

Searching for the Ligands of Odorant Receptors

Through the sense of smell mammals can detect and discriminate between a large variety of odorants present in the surrounding environment. Odorants bind to a large repertoire of odorant receptors located in the cilia of olfactory sensory neurons of the nose. Each olfactory neuron expresses one single type of odorant receptor, and neurons expressing the same type of receptor project their axons to one or a few glomeruli in the olfactory bulb, creating a map of odorant receptor inputs. The information is then passed on to other regions of the brain, leading to odorant perception. To understand how the olfactory system discriminates between odorants, it is necessary to determine the odorant specificities of individual odorant receptors. These studies are complicated by the extremely large size of the odorant receptor family and by the poor functional expression of these receptors in heterologous cells. This article provides an overview of the methods that are currently being used to investigate odorant receptor–ligand interactions.     

Crystal structure of Apis mellifera OBP14, a C-minus odorant-binding protein, and its complexes with odorant molecules

Apis mellifera (Amel) relies on its olfactory system to detect and identify new-sources of floral food. The Odorant-Binding Proteins (OBPs) are the first proteins involved in odorant recognition and interaction, before activation of the olfactory receptors. The Amel genome possess a set of 21 OBPs, much fewer compared to the 60-70 OBPs found in Diptera genomes. We have undertaken a structural proteomics study of Amel OBPs, alone or in complex with odorant or model compounds. We report here the first 3D structure of a member of the C-minus class OBPs, AmelOBP14, characterized by only two disulfide bridges of the three typical of classical OBPs. We show that AmelOBP14 possesses a core of 6 α-helices comparable to that of classical OBPs, and an extra exposed C-terminal helix. Its binding site is located within this core and is completely closed. Fluorescent experiments using 1-NPN displacement demonstrate that AmelOBP14 is able to bind several compounds with sub micromolar dissociation constants, among which citralva and eugenol exhibit the highest affinities. We have determined the structures of AmelOBP14 in complex with 1-NPN, eugenol and citralva, explaining their strong binding. Finally, by introducing a double cysteine mutant at positions 44 and 97, we show that a third disulfide bridge was formed in the same position as in classical OBPs without disturbing the fold of AmelOBP14.     

Characteristics of odorant elicited calcium fluxes in acutely-isolated chick olfactory neurons

To understand avian olfaction, it is important to characterize the peripheral olfactory system of a representative bird species. This study determined the functional properties of olfactory receptor neurons of the chicken olfactory epithelium. Individual neurons were acutely isolated from embryonic day-18 to newborn chicks by dissection and enzymatic dissociation. We tested single olfactory neurons with behaviorally relevant odorant mixtures and measured their responses using ratiometric calcium imaging; techniques used in this study were identical to those used in other studies of olfaction in other vertebrate species. Chick olfactory neurons displayed properties similar to those found in other vertebrates: they responded to odorant stimuli with either decreases or increases in intracellular calcium, calcium increases were mediated by a calcium influx, and responses were reversibly inhibited by 100 M L–cis–diltiazem, 1 mM Neomycin, and 20 M U73122, which are biochemical inhibitors of second messenger signaling. In addition, some cells showed a complex pattern of responses, with different odorant mixtures eliciting increases or decreases in calcium in the same cell. It appears that there are common features of odorant signaling shared by a variety of vertebrate species, as well as features that may be peculiar to chickens.     

Improving the odorant sensitivity of olfactory receptor-expressing yeast with accessory proteins

Olfaction depends on the selectivity and sensitivity of olfactory receptors. Previous attempts at constructing a mammalian olfactory receptor-based artificial odorant sensing system in the budding yeast Saccharomyces cerevisiae suffered from low sensitivity and activity. This result may be at least in part due to poor functional expression of olfactory receptors and/or limited solubility of some odorants in the medium. In this study, we examined the effects of two types of accessory proteins, receptor transporting protein 1 short and odorant binding proteins, in improving odor-mediated activation of olfactory receptors expressed in yeast. We found that receptor transporting protein 1 short enhanced the membrane expression and ligand-induced responses of some olfactory receptors. Coexpression of odorant binding proteins of the silkworm moth Bombyx mori enhanced the sensitivity of a mouse olfactory receptor. Our results suggest that different classes of accessory proteins can confer sensitive and robust responses of olfactory receptors expressed in yeast. Inclusion of accessory proteins may be essential in the future development of practical olfactory receptor-based odorant sensors.     

昆虫非典型嗅觉受体Orco的功能和分子结构研究进展

嗅觉受体是参与昆虫嗅觉识别过程的一类重要蛋白。在昆虫的众多嗅觉受体中, 有一类受体明显不同于其他受体, 被称为Orco。该受体基因在不同昆虫种间高度保守, 且表达广泛。Orco在昆虫嗅觉识别过程中发挥关键作用。采用基因突变或RNAi等技术使Orco基因沉默后, 昆虫会出现严重的嗅觉缺陷, 但Orco本身不与气味配体结合, 它与传统嗅觉受体形成复合体Or-Orco, 促进传统嗅觉受体在神经元树突膜上的定位并维持其稳定性, 提高传统嗅觉受体对气味反应的效率。昆虫嗅觉受体的结构与脊椎动物的G蛋白偶联受体相似, 均有7个跨膜区, 但二者的膜拓扑结构相反, 昆虫嗅觉受体的N末端位于细胞质膜内, C末端在细胞质膜外, Orco与传统嗅觉受体通过保守的C末端区域相互作用形成一种新型的配体门控离子通道--Or-Orco复合体。阐明Orco在昆虫嗅觉识别中的功能机制, 可为开创基于昆虫嗅觉行为干扰的新的害虫防治措施提供基础。     

Functional cloning and reconstitution of vertebrate odorant receptors

The olfactory systems of vertebrates have a remarkable capacity to recognize and discriminate thousands of different odorant molecules. The initial step in the process of odorant perception is the recognition of volatile odorant molecules by a group of roughly one thousand G protein-coupled odorant receptors that are expressed on the surface of olfactory neuronal cilia. The aims of this study were to obtain functional evidence that these putative odorant receptors recognize and respond to specific odorant molecules, and to elucidate the mechanisms of odorant discrimination in vertebrate olfaction at a receptor level. In order to identify odorant receptors that specifically recognize a particular odorant of interest, we developed a functional cloning strategy in an odorant-directed manner by combining Ca2+-recording and single cell RT-PCR techniques. We then adopted an adenovirus-mediated expression system or a chimeric receptor approach to reconstitute the functionally cloned receptors for further biochemical analyses. We herein describe how we obtained experimental evidence for a combinatory mechanism of odorant recognition by examining the diversity of odorant receptors that recognize a particular odorant of interest, and by determining ligand specificity and structure-function relationships for individual odorant receptors.     

Go contributes to olfactory reception in Drosophila melanogaster

Background  

Seven-transmembrane receptors typically mediate olfactory signal transduction by coupling to G-proteins. Although insect odorant receptors have seven transmembrane domains like G-protein coupled receptors, they have an inverted membrane topology and function as ligand-gated cation channels. Consequently, the involvement of cyclic nucleotides and G proteins in insect odor reception is controversial. Since the heterotrimeric G_oα subunit is expressed in Drosophila olfactory receptor neurons, we reasoned that G_o acts together with insect odorant receptor cation channels to mediate odor-induced physiological responses.     

昆虫嗅觉相关蛋白的研究进展

嗅觉是昆虫产生行为的重要物质基础,阐明昆虫嗅觉机理有助于调控昆虫行为和进行害虫治理。近年来,许多与嗅觉相关的生物活性分子和相关基因的发现和克隆,对揭示嗅觉机理具有重要作用。作者针对近年来研究较多的气味结合蛋白、化学感受蛋白、气味受体、气味降解酶以及感觉神经元膜蛋白等,就其生化特性、表达部位、分子结构、生理功能等进行了综述。     

Sex pheromones and olfactory proteins in Antheraea moths: A. pernyi and A. polyphemus (Lepidoptera: Saturniidae)

Olfaction is essential for regulating the physiological and behavioral actions of insects with specific recognition of various odors. Antheraea moths (Lepidoptera: Saturniidae) possess relatively large bodies and antennae so that they are good subjects for exploring molecular aspects of insect olfaction. Current knowledge of the molecular aspects of Antheraea olfaction is focused on the Chinese tussah silkmoth A. pernyi Guérin-Méneville and another species A. polyphemus (Cramer) in their pheromones, odorant-binding proteins (OBPs), odorant receptors (ORs), odorant receptor coreceptors (ORCOs), sensory neuron membrane proteins (SNMPs), and odorant-degrading enzymes (ODEs). The first insect OBP, SNMP, and ODE were identified from A. polyphemus. This review summarizes the principal findings associated with the olfactory physiology and its molecular components in the two Antheraea species. Three types of olfactory neurons may have specific ORs for three respective sex-pheromone components, with the functional sensitivity and specificity mediated by three respective OBPs. SNMPs and ODEs are likely to play important roles in sex-pheromone detection, inactivation, and degradation. Identification and functional analysis of the olfactory molecules remain to be further performed in A. pernyi, A. polyphemus, and other Antheraea species.     

A new concept of olfactory biosensor based on interdigitated microelectrodes and immobilized yeasts expressing the human receptor OR17-40

This work shows the feasibility of an olfactory biosensor based on the immobilization of Saccharomyces cerevisiae yeast cells genetically modified to express the human olfactory receptor OR17-40 onto interdigitated microconductometric electrodes. This olfactory biosensor has been applied to the detection of its specific odorant (helional) with a high sensitivity (threshold 10⁻¹⁴ M). In contrast, no significant response was observed using a non-specific odorant (heptanal), which suggests a good selectivity. Thus, this work may represent a first step towards a new kind of bioelectronic noses based on whole yeast cells and allowing a real time monitoring of olfactory receptor activation. Presented at the joint biannual meeting of the SFB-GEIMM-GRIP, Anglet, France, 14–19 October, 2006.     

Towards an understanding of the structural basis for insect olfaction by odorant receptors

Insects have co-opted a unique family of seven transmembrane proteins for odour sensing. Odorant receptors are believed to have evolved from gustatory receptors somewhere at the base of the Hexapoda and have expanded substantially to become the dominant class of odour recognition elements within the Insecta. These odorant receptors comprise an obligate co-receptor, Orco, and one of a family of highly divergent odorant “tuning” receptors. The two subunits are thought to come together at some as-yet unknown stoichiometry to form a functional complex that is capable of both ionotropic and metabotropic signalling. While there are still no 3D structures for these proteins, site-directed mutagenesis, resonance energy transfer, and structural modelling efforts, all mainly on Drosophila odorant receptors, are beginning to inform hypotheses of their structures and how such complexes function in odour detection. Some of the loops, especially the second extracellular loop that has been suggested to form a lid over the binding pocket, and the extracellular regions of some transmembrane helices, especially the third and to a less extent the sixth and seventh, have been implicated in ligand recognition in tuning receptors. The possible interaction between Orco and tuning receptor subunits through the final intracellular loop and the adjacent transmembrane helices is thought to be important for transducing ligand binding into receptor activation. Potential phosphorylation sites and a calmodulin binding site in the second intracellular loop of Orco are also thought to be involved in regulating channel gating. A number of new methods have recently been developed to express and purify insect odorant receptor subunits in recombinant expression systems. These approaches are enabling high throughput screening of receptors for agonists and antagonists in cell-based formats, as well as producing protein for the application of biophysical methods to resolve the 3D structure of the subunits and their complexes.     

Subunit contributions to insect olfactory receptor function: channel block and odorant recognition

Insect olfactory receptors are heteromeric ligand-gated ion channels composed of at least one common subunit (Orco) and at least one subunit that confers odorant specificity. Little is known about how individual subunits contribute to the structure and function of the olfactory receptor complex. We expressed insect olfactory receptors in Xenopus oocytes to investigate 2 functional features, ion channel block and odorant recognition. The sensitivity of Drosophila olfactory receptors to inhibition by ruthenium red, a cation channel blocker, varied widely when different specificity subunits were present, suggesting that the specificity subunits contribute to the structure of the ion pore. Olfactory receptors formed by Dmel\Or35a and Orco subunits from several different species displayed highly similar odorant response profiles, suggesting that the Orco subunit does not contribute to the structure of the odorant-binding site. We further explored odorant recognition by conducting a detailed examination of the odorant specificity Dmel\Or67a + Dmel\Orco, a receptor that responds to aromatic structures. This screen identified agonists, partial agonists, and an antagonist of Dmel\Or67a + Dmel\Orco. Our findings favor specific subunit arrangements within the olfactory receptor complex and provide a preliminary odorophore for an olfactory receptor, offering a useful foundation for future exploration of insect olfactory receptor structure.     

High-throughput Analysis of Mammalian Olfactory Receptors: Measurement of Receptor Activation via Luciferase Activity

Odorants create unique and overlapping patterns of olfactory receptor activation, allowing a family of approximately 1,000 murine and 400 human receptors to recognize thousands of odorants. Odorant ligands have been published for fewer than 6% of human receptors^1-11. This lack of data is due in part to difficulties functionally expressing these receptors in heterologous systems. Here, we describe a method for expressing the majority of the olfactory receptor family in Hana3A cells, followed by high-throughput assessment of olfactory receptor activation using a luciferase reporter assay. This assay can be used to (1) screen panels of odorants against panels of olfactory receptors; (2) confirm odorant/receptor interaction via dose response curves; and (3) compare receptor activation levels among receptor variants. In our sample data, 328 olfactory receptors were screened against 26 odorants. Odorant/receptor pairs with varying response scores were selected and tested in dose response. These data indicate that a screen is an effective method to enrich for odorant/receptor pairs that will pass a dose response experiment, i.e. receptors that have a bona fide response to an odorant. Therefore, this high-throughput luciferase assay is an effective method to characterize olfactory receptors—an essential step toward a model of odor coding in the mammalian olfactory system.     

昆虫气味受体研究进展

嗅觉在昆虫的多种行为中发挥关键作用。气味分子与嗅觉神经元树突上气味受体的结合,参与了昆虫嗅觉识别的初始过程。昆虫的嗅觉神经元表达两类气味受体： 一是传统气味受体,该类受体同源性较低,在少部分嗅觉神经元中表达; 二是Or83b家族受体,该类受体不感受气味,在不同昆虫间较为保守且在大多数嗅觉神经元中表达。目前,对于单个传统气味受体的气味分子配体特异性所知甚少; 对于Or83b家族受体,一般认为其可能具有将传统气味受体运送至嗅觉神经元树突膜上的功能。此外,有一些实验证据不支持昆虫气味受体为G蛋白偶联受体的观点。     

昆虫嗅觉相关蛋白的结构和功能

昆虫在长期进化的过程中形成了复杂的嗅觉系统,气味剂结合蛋白(odorant binding proteins,OBPs)、嗅觉受体(olfactory receptors,ORs)是其最主要的组分.其主要作用是结合外围挥发性的气味分子并将信号传递给细胞内的第二信使.OBPs和ORs的结构、功能、表达、进化是昆虫行为与进化关系的重要研究领域和研究热点.本文主要总结了近年来昆虫OBPs和ORs的结构特点、生理功能、表达特点、遗传进化等方面研究的最新进展,对OBPs和ORs的研究趋势进行了展望,为昆虫嗅觉系统进化研究及寻找害虫防治新途径提供参考信息.     

昆虫嗅觉结合蛋白研究进展

嗅觉结合蛋白是嗅觉系统的第一个参与者,主要表达在嗅觉外周系统淋巴液中,负责识别、结合和转运气味和信息素分子到达嗅觉受体。近些年,随着各种生物新技术的应用,大量昆虫嗅觉结合蛋白被鉴定出来,其各种不同功能得到揭示。本文对近年来嗅觉结合蛋白的分子特征、蛋白结构、功能和应用等方面的研究进展进行总结和综述。总的来说,嗅觉结合蛋白包括气味结合蛋白(odorant-binding proteins, OBPs)、化学感受蛋白(chemosensory proteins, CSPs)和尼曼 匹克C2型蛋白(Niemann-Pick type C2 proteins, NPC2)三大家族,在α-螺旋和β-折叠的基础上形成了相对简单而稳定的球形结构,使它们能适应各种环境和任务,所以嗅觉结合蛋白蛋白具有复杂多样的功能,且这些功能对昆虫生理和行为尤为重要。基于嗅觉结合蛋白功能,研究者已经把它们应用于生物防治、品种选育和制作生物嗅觉传感器等,具有巨大的潜在价值。本综述为昆虫嗅觉结合蛋白后续研究提供了参考信息及一些新的思路。     

Combinatorial receptor codes for odors

The discriminatory capacity of the mammalian olfactory system is such that thousands of volatile chemicals are perceived as having distinct odors. Here we used a combination of calcium imaging and single-cell RT-PCR to identify odorant receptors (ORs) for odorants with related structures but varied odors. We found that one OR recognizes multiple odorants and that one odorant is recognized by multiple ORs, but that different odorants are recognized by different combinations of ORs. Thus, the olfactory system uses a combinatorial receptor coding scheme to encode odor identities. Our studies also indicate that slight alterations in an odorant, or a change in its concentration, can change its "code," potentially explaining how such changes can alter perceived odor quality.