LUSH odorant-binding protein mediates chemosensory responses to alcohols in Drosophila melanogaster.

The molecular mechanisms mediating chemosensory discrimination in insects are unknown. Using the enhancer trapping approach, we identified a new Drosophila mutant, lush, with odorant-specific defects in olfactory behavior. lush mutant flies are abnormally attracted to high concentrations of ethanol, propanol, and butanol but have normal chemosensory responses to other odorants. We show that wild-type flies have an active olfactory avoidance mechanism to prevent attraction to concentrated alcohol, and this response is defective in lush mutants. This suggests that the defective olfactory behavior associated with the lush mutation may result from a specific defect in chemoavoidance. lush mutants have a 3-kb deletion that produces a null allele of a new member of the invertebrate odorant-binding protein family, LUSH. LUSH is normally expressed exclusively in a subset of trichoid chemosensory sensilla located on the ventral-lateral surface of the third antennal segment. LUSH is secreted from nonneuronal support cells into the sensillum lymph that bathes the olfactory neurons within these sensilla. Reintroduction of a cloned wild-type copy of lush into the mutant background completely restores wild-type olfactory behavior, demonstrating that this odorant-binding protein is required in a subset of sensilla for normal chemosensory behavior to a subset of odorants. These findings provide direct evidence that odorant-binding proteins are required for normal chemosensory behavior in Drosophila and may partially determine the chemical specificity of olfactory neurons in vivo.     

A Drosophila protein specific to pheromone-sensing gustatory hairs delays males' copulation attempts

In insects, increasing evidence suggests that small secreted pheromone binding proteins (PBPs) and odorant binding proteins (OBPs) are important for normal olfactory detection of airborne pheromones and odorants far from their source. In contrast, it is unknown whether extracellular ligand binding proteins participate in perception of less volatile chemicals, including many pheromones, that are detected by direct contact with chemosensory organs. CheB42a, a small Drosophila melanogaster protein unrelated to known PBPs or OBPs, is expressed and likely secreted in only a small subset of gustatory sensilla on males' front legs, the site of gustatory perception of contact pheromones. Here we show that CheB42a is expressed specifically in the sheath cells surrounding the taste neurons expressing Gr68a, a putative gustatory pheromone receptor for female cuticular hydrocarbons that stimulate male courtship. Surprisingly, however, CheB42a mutant males attempt to copulate with females earlier and more frequently than control males. Furthermore, CheB42a mutant males also attempt to copulate more frequently with other males that secrete female-specific cuticular hydrocarbon pheromones, but not with females lacking cuticular hydrocarbons. Together, these data indicate that CheB42a is required for a normal gustatory response to female cuticular hydrocarbon pheromones that modulate male courtship.     

Molecular and functional characterization of an odorant binding protein of the Asian elephant,Elephas maximus: implications for the role of lipocalins in mammalian olfaction

The sex pheromone present in the pre-ovulatory urine of female Asian elephants is the simple lipid (Z)-7-dodecen-1-yl acetate (Z7-12:Ac). Using radiolabeled probes, we have identified a pheromone binding protein that is abundant in the mucus of the trunk; this protein is homologous to a class of lipocalins known as odorant binding proteins (OBPs). To test five previously proposed roles for the OBP in chemosensory perception, we determined the equilibrium dissociation constant of the OBP-pheromone complex, as well as the association and dissociation rates. Using a mathematical model in conjunction with experimental data, we suggest that the binding and release of the pheromone by the OBP are too slow for the OBP to function in transporting the pheromone through the mucus that covers the olfactory sensory epithelium. Our data indicate that the elephant OBP only modestly increases the solubility of the pheromone in the mucus. Our results are most consistent with the notion that elephant OBP functions as a scavenger of the pheromone and possibly other ligands, including odorants. In light of these findings, and published results for other mammalian OBP-ligand complexes, a general model for the role of OBPs in mammalian olfaction is proposed. Moreover, the potential implications of these findings for interaction of Z7-12:Ac with insect antennal proteins are discussed.     

Le rôle des protéines liant les odeurs (OBP) dans la transduction olfactive

This paper reviews biochemical and functional properties of a family of proteins involved in the transduction process of chemical signals. Odorant-binding proteins (OBPs) are small soluble proteins highly concentrated in the chemosensory organs of Insects and Vertebrates. They are preferentially expressed in the nasal mucus of Vertebrates and in the sensillar lymph of Insects. They have been found to bind reversibly small hydrophobic molecules detected via the olfactory system. The vertebrate OBPs bind non-specific odorants with low affinities. They belong to the lipocalin family as well as other proteins involved in chemical communication and associated to different organs and functions. Nevertheless, no specific ligand for OBPs has been yet identified in Vertebrates. However, the large microdiversity of OBPs in the same animal suggests that OBPs could be involved in the discrimination of odors. Chemical communication in Noctuid moths was used as a model to study the molecular mechanisms of odor recognition. The pheromonal system is extremely sensitive and specific since the male is able to detect only few molecules of the pheromone and to recognize specific blends of the same molecules. The chemical signals were identified for a large number of Lepidopteran species and the associated behaviours they elicit were fully characterized. The Lepidopteran OBPs are divided into two sub-classes according to their ligands: pheromone-binding proteins (PBP) are expressed in sensilla trichodea responding to pheromonal compounds while general odorant binding proteins (GOBP) are associated with sensilla basiconica tuned to the detection of general odors, such as plant volatiles. The PBPs selectively bind components of the female sex-pheromone with measurable affinities. The ligand binding site was localized in the 40–60 aminoacids region. Substitutions in the binding site of different proteins are correlated with the fixation of different ligands, leading to the hypothesis that the primary structure encodes the ligand specificity. Other proteins expressed in chemosensory organs of other orders of Insects were cloned or purified. In absence of functional data, they were called OBP-like. Some of them were localized in the gustatory organs and could be common carriers of odors in both olfactory and gustatory systems. Many arguments are in accordance with an active role of the OBPs in the early steps of odor discrimination. The heterogeneity of OBPs inside species and between species, the spatial segregation in their expression and the different binding affinities of PBPs towards pheromonal compounds support the hypothesis that the coding of odors is realized as soon as the level of OBPs. More, the complex OBP/odor could be the stimulus for olfactory receptors cloned in Vertebrates and still putative in Insects. This hypothesis suggests that OBPs take part as an essential element of the chemosensory transduction.     

Odorant-binding-protein subfamilies associate with distinct classes of olfactory receptor neurons in insects

The olfactory receptors of terrestrial animals exist in an aqueous environment, yet detect odorants that are primarily hydrophobic. The aqueous solubility of hydrophobic odorants is thought to be greatly enhanced via odorant binding proteins (OBP) which exist in the extracellular fluid surrounding the odorant receptors. We have isolated and partially sequenced 14 candidate OBPs from six insect (moth) species. All 14 represent a single homologous family based on conserved sequence domains. The 14 proteins can be divided into three subfamilies based on differences in tissue specific expression and similarities in amino acid sequences. All 14 proteins are specifically expressed in antennal olfactory tissue. Subfamily I represents previously described pheromone binding proteins (PBP), which are male-specific, associate with pheromone-sensitive neurons, and are highly variable in their sequences when compared among species. Subfamilies II and III are expressed in both male and female antennae, appear to associate with general-odorant-sensitive neurons, and are highly conserved when compared among species. The properties of the subfamily II and III proteins suggest these are general-odorant binding proteins (GOBP). The properties of the respective insect OBP subfamilies suggest that they have different odorant binding specificities. The association of different insect OBP subfamilies with distinct classes of olfactory neurons having different odorant specificities suggests that OBPs can act as selective signal filters, peripheral to the actual receptor proteins.     

昆虫气味结合蛋白的研究进展

昆虫主要依赖其复杂且灵敏的化学感受系统来识别并区分外界环境中的各种化学信号。嗅觉是负责嗅觉信号传导的感官方式,能够引起昆虫觅食、产卵、交配和躲避天敌等对生存和繁殖至关重要的行为反应。在嗅觉感知过程中,气味结合蛋白(odorant binding proteins, OBPs)最先与外界脂溶性化学物质相互作用,并将其转运至化学受体神经元上,激活树突膜表面分布的嗅觉受体(olfactory receptors, ORs),是嗅觉系统正常运行的必需蛋白。近年来,随着高通量测序和分子生物学技术的快速发展,越来越多的昆虫OBPs相继得以鉴定并开展功能研究。昆虫OBPs是一类可溶性的小分子蛋白,一般由6个α-螺旋构成一个稳定、紧密的疏水性结合腔,其构象变化因昆虫种类和配体结构不同而有所差异。OBPs的分布不受限于嗅觉器官,还在口器、足、中肠、腺体等非嗅觉组织中表达,具有嗅觉识别、味觉感受、营养物质转运、信息素合成与释放、组织发育与分化等生理功能。OBPs行使以上功能的共同特性为结合和溶解包括信息素组分、普通气味分子和非挥发性物质等的疏水性小分子物质。昆虫OBPs的稳定性和多功能性暗示其可广泛应用于...     

LUSH shapes up for a starring role in olfaction

In the fruit fly Drosophila, odorant-binding proteins are secreted into the fluid that bathes olfactory neurons. Laughlin et al. (2008) now challenge the assumption that the odorant-binding protein LUSH passively transports its pheromone to a specific olfactory receptor. Instead, LUSH undergoes a conformational change upon pheromone binding that is sufficient for neuronal activation.     

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...     

Functional dissection of Odorant binding protein genes in Drosophila melanogaster

Most organisms rely on olfaction for survival and reproduction. The olfactory system of Drosophila melanogaster is one of the best characterized chemosensory systems and serves as a prototype for understanding insect olfaction. Olfaction in Drosophila is mediated by multigene families of odorant receptors and odorant binding proteins (OBPs). Although molecular response profiles of odorant receptors have been well documented, the contributions of OBPs to olfactory behavior remain largely unknown. Here, we used RNAi-mediated suppression of Obp gene expression and measurements of behavioral responses to 16 ecologically relevant odorants to systematically dissect the functions of 17 OBPs. We quantified the effectiveness of RNAi-mediated suppression by quantitative real-time polymerase chain reaction and used a proteomic liquid chromatography and tandem mass spectrometry procedure to show target-specific suppression of OBPs expressed in the antennae. Flies in which expression of a specific OBP is suppressed often show altered behavioral responses to more than one, but not all, odorants, in a sex-dependent manner. Similarly, responses to a specific odorant are frequently affected by suppression of expression of multiple, but not all, OBPs. These results show that OBPs are essential for mediating olfactory behavioral responses and suggest that OBP-dependent odorant recognition is combinatorial.     

Wake up and smell the pheromones

Odorant binding proteins (OBPs) are abundant proteins of unknown function expressed at high levels in insect and vertebrate chemosensory organs. In this issue of Neuron, Xu et al. show that Drosophila OBP76a is necessary for fruit flies to respond to the aggregation pheromone 11-cis vaccenyl acetate. The results suggest a mechanism by which this OBP is intimately involved in pheromone signal transduction.     

Beyond chemoreception: diverse tasks of soluble olfactory proteins in insects

Odorant‐binding proteins (OBPs) and chemosensory proteins (CSPs) are regarded as carriers of pheromones and odorants in insect chemoreception. These proteins are typically located in antennae, mouth organs and other chemosensory structures; however, members of both classes of proteins have been detected recently in other parts of the body and various functions have been proposed. The best studied of these non‐sensory tasks is performed in pheromone glands, where OBPs and CSPs solubilise hydrophobic semiochemicals and assist their controlled release into the environment. In some cases the same proteins are expressed in antennae and pheromone glands, thus performing a dual role in receiving and broadcasting the same chemical message. Several reports have described OBPs and CSPs in reproductive organs. Some of these proteins are male specific and are transferred to females during mating. They likely carry semiochemicals with different proposed roles, from inhibiting other males from approaching mated females, to marking fertilized eggs, but further experimental evidence is still needed. Before being discovered in insects, the presence of binding proteins in pheromone glands and reproductive organs was widely reported in mammals, where vertebrate OBPs, structurally different from OBPs of insects and belonging to the lipocalin superfamily, are abundant in rodent urine, pig saliva and vaginal discharge of the hamster, as well as in the seminal fluid of rabbits. In at least four cases CSPs have been reported to promote development and regeneration: in embryo maturation in the honeybee, limb regeneration in the cockroach, ecdysis in larvae of fire ants and in promoting phase shift in locusts. Both OBPs and CSPs are also important in nutrition as solubilisers of lipids and other essential components of the diet. Particularly interesting is the affinity for carotenoids of CSPs abundantly secreted in the proboscis of moths and butterflies and the occurrence of the same (or very similar CSPs) in the eyes of the same insects. A role as a carrier of visual pigments for these proteins in insects parallels that of retinol‐binding protein in vertebrates, a lipocalin structurally related to OBPs of vertebrates. Other functions of OBPs and CSPs include anti‐inflammatory action in haematophagous insects, resistance to insecticides and eggshell formation. Such multiplicity of roles and the high success of both classes of proteins in being adapted to different situations is likely related to their stable scaffolding determining excellent stability to temperature, proteolysis and denaturing agents. The wide versatility of both OBPs and CSPs in nature has suggested several different uses for these proteins in biotechnological applications, from biosensors for odours to scavengers for pollutants and controlled releasers of chemicals in the environment.     

Fluorescence competition assay for the assessment of green leaf volatiles and trans-β-farnesene bound to three odorant-binding proteins in the wheat aphid Sitobion avenae (Fabricius)

Odorant-binding proteins (OBPs) are important parts of insect olfactory systems, and sensitive olfaction is vital for phytophagous insects in host foraging. Electrophysiological studies are helpful in understanding olfactory sensing in Sitobion avenae (Hemiptera: Aphididae), but the functions of odorant-binding proteins in this insect are poorly understood. In this study, we used fluorescence competition assays to measure the binding specificities of SaveOBPs. The results showed that both SaveOBP2 and SaveOBP3 were superior to SaveOBP7 in binding green leaf volatiles. It was unexpected that SaveOBP7 bound trans-β-farnesene strongly, which was known as alarm pheromone of this species. Host volatiles were recognized much more easily by SaveOBP2, and the observed binding activity of SaveOBP2 equaled for tested green leaf volatiles. Our results imply that SaveOBP7 might play a more important role in aphid alarm pheromone discrimination.     

Expression patterns of two putative odorant-binding proteins in the olfactory organs of Drosophila melanogaster have different implications for their functions

The aqueous medium bathing the dendrites of olfactory neurons contains high concentrations of odorant-binding proteins (OBPs) whose role is still unclear. OBPs may facilitate interactions between odorants and their membrane-bound receptors, perhaps by increasing the water solubility of hydrophobic molecules. Alternatively, OBPs may be involved in the inactivation of odorants and other volatile molecules, preventing desensitization and/or protecting olfactory neurons from toxic chemicals. We report here novel features of the localization of two putative OBPs, PBPRP2 and PBPRP5, that have important and different implications for their role in olfaction. Unlike several other putative OBPs of Drosophila melanogaster that are only found in adult olfactory organs, PBPRP5 is also expressed in the larval olfactory organs, suggesting that it plays a common role in olfaction at both stages. In the adult, PBPRP5 expression is restricted to the sensillum lymph that bathes the olfactory dendrites of a subset of olfactory hairs, the basiconic sensilla. Since individual basiconic sensilla differ in olfactory specificity, PBPRP5 may be able to bind to and mediate olfactory responses to a wide range of odorants. In contrast, PBPRP2 is present in the space immediately below the antennal cuticle and in the outer cavity of approximately 30% of the double-walled coeloconic sensilla on the antennal surface. In neither case is PBPRP2 in contact with the dendritic membranes of olfactory neurons, making a carrier function unlikely for this protein. Instead, PBPRP2 may act as a sink, binding to odorants and other volatile chemicals and limiting their interactions with olfactory neurons.     

橘小实蝇化学通讯机制与引诱剂开发策略

实蝇是全球重大的果蔬虫害,对世界年均造成的经济损失高达20亿美元。橘小实蝇Bactrocera dorsalis是该类害虫的代表之一,每年对我国柑橘产业造成严重损失。以雄性引诱剂和蛋白饵剂为核心的诱杀技术已用于害虫监测和绿色防控,但是田间防控效果有待进一步提高。随着高通量测序技术成本的降低以及现代分子生物学技术的发展,科学家们提出先解析害虫化学感受的分子机制,鉴定关键的化学感受分子靶标,并以鉴定的新靶标设计和筛选更为稳定和高效引诱剂和食诱剂。为促进以关键化学感受分子为靶标的橘小实蝇行为调控技术的发展,本文综述了调控橘小实蝇行为的重要化学物质及其化学感受识别机制的研究现状。调控橘小实蝇行为的重要挥发物主要包括性信息素、植物挥发物和食物源蛋白气味。前两者中鉴定获得的特异性化合物质与橘小实蝇成虫的行为关系较为明确,例如性信息素中得到吡嗪类物质能够引诱雌虫,植物挥发物中的甲基丁香酚引诱雄虫,γ-辛内酯能够诱发雌虫产卵等;而后者食物源蛋白气味则由于成分复杂,在田间虽有一定效果,但缺乏特定化合物在雌雄虫具体行为中的功能验证。嗅觉感受机制中,外周神经感器与中枢触角叶仅有形态描述,不同类型嗅觉神经元的...     

Odorant-binding proteins and chemosensory proteins in pheromone detection and release in the silkmoth Bombyx mori

The genome of the silkmoth Bombyx mori contains 44 genes encoding odorant-binding proteins (OBPs) and 20 encoding chemosensory proteins (CSPs). In this work, we used a proteomic approach to investigate the expression of proteins of both classes in the antennae of adults and in the female pheromone glands. The most abundant proteins found in the antennae were the 4 OBPs (PBP, GOBP1, GOBP2, and ABP) and the 2 CSPs (CSP1 and CSP2) previously identified and characterized. In addition, we could detect only 3 additional OBPs and 2 CSPs, with clearly different patterns of expression between the sexes. Particularly interesting, on the other hand, is the relatively large number of binding proteins (1 OBP and 7 CSPs) expressed in the female pheromone glands, some of them not present in the antennae. In the glands, these proteins could be likely involved in the solubilization of pheromonal components and their delivery in the environment.     

Ligand binding and homology modelling of insect odorant‐binding proteins

This review describes the main characteristics of odorant‐binding proteins (OBPs) for homology modelling and presents a summary of structure prediction studies on insect OBPs, along with the steps involved and some limitations and improvements. The technique involves a computing approach to model protein structures and is based on a comparison between a target (unknown structure) and one or more templates (experimentally determined structures). As targets for structure prediction, OBPs are considered to play a functional role for recognition, desorption, scavenging, protection and transportation of hydrophobic molecules (odourants) across an aqueous environment (lymph) to olfactory receptor neurones (ORNs) located in sensilla, the main olfactory units of insect antennae. Lepidopteran pheromone‐binding proteins, a subgroup of OBPs, are characterized by remarkable structural features, in which high sequence identities (approximately 30%) among these OBPs and a large number of available templates can facilitate the prediction of precise homology models. Approximately 30 studies have been performed on insect OBPs using homology modelling as a tool to predict their structures. Although some of the studies have assessed ligand‐binding affinity using structural information and biochemical measurements, few have performed docking and molecular dynamic (MD) simulations as a virtual method to predict best ligands. Docking and MD simulations are discussed in the context of discovery of novel semiochemicals (super‐ligands) using homology modelling to conceive further strategies in insect management.