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【目的】明确小菜蛾Plutella xylostella成虫下唇须感器的形态结构及感器神经元的投射。【方法】利用光学显微镜观察和扫描电子显微镜观察下唇须结构和感器类型,利用神经回填技术和激光共聚焦显微镜观察下唇须感器神经元在脑部的投射。【结果】小菜蛾成虫下唇须共3节,其上存在Böhm氏鬃毛、钟形感器、鳞形感器、锥形感器、微毛形感器5种不同类型的感器和一个陷窝器结构。Böhm氏鬃毛短小尖细,钟形感器形如顶部凹陷的圆帽,两种感器均分布于下唇须第1节,且大小上均无雌雄二型差异;鳞形感器形同柳叶,锥形感器粗而直,均散生于下唇须的第2和3节,两种感器在大小上均存在雌雄二型差异,其中雌性的鳞形感器显著大于雄性的,根据其雌雄二型差异现象推测雌蛾的鳞形感器可能与感受寄主植物挥发物有关;下唇须第3节中上部具有一个圆形陷窝器结构,雄虫的陷窝器内径为5.68±0.33μm,雌虫的为6.03±0.23μm,雌雄间无显著性差异;凹坑内长有表面光滑的微毛形感器。小菜蛾下唇须感器神经元主要投射于脑部咽下神经节、每个触角叶的下唇须陷窝器神经纤维球和腹神经索3条通路。【结论】阐明了小菜蛾下唇须感器的类型、分布和形态特征及其感器神经元在脑部的投射形态,为深入了解小菜蛾下唇须感器的生理和功能奠定了基础。 相似文献
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【目的】探索斜纹夜蛾Spodoptera litura触角叶结构及其神经元对植物气味和性信息素的神经识别机制。【方法】利用共聚焦激光技术扫描斜纹夜蛾成虫触角叶结构,同时采用多通道电生理技术(multi-unit recording,MR)记录斜纹夜蛾触角叶对6种寄主植物气味化合物(苯甲醛、苯甲醇、苯乙醛、水杨醛、乙酸叶醇酯和己烯醛)及性信息素顺9反11十四碳二烯乙酸酯和顺9反12十四碳二烯乙酸酯的反应;并在风洞中测定分析斜纹夜蛾对上述化合物的定向行为反应。【结果】共聚焦激光扫描结果显示,雄性和雌性斜纹夜蛾触角叶内分别密集地分布有67和66个神经纤维球;而雌性斜纹夜蛾触角叶内的纤维球总体积和平均体积都高于雄性。负责识别和追踪性信息素的扩大型纤维球复合体(macroglomerular complex,MGC)只在雄性斜纹夜蛾触角叶内发现。MR试验结果显示斜纹夜蛾触角叶内神经元具有3种自发放电模式:稀疏放电(不规则的放电频率)、温和放电(宽而慢的放电频率)和密集放电(暴发性的放电频率)。同时,斜纹夜蛾触角叶神经元对所有刺激的气味表现出3种反应类型:兴奋性、抑制性和无反应。神经元对气味的兴奋性和抑制性反应以及无反应取决于刺激化合物的结构和浓度。雌虫的触角叶神经元对性信息素和单一的植物气味表现出很小的反应,而雄虫对两种性信息素以及苯甲醛、苯甲醇、苯乙醛和水杨醛具有很强的兴奋性反应。斜纹夜蛾风洞试验也显示绝大部分的斜纹夜蛾雄虫都选择停留在性信息素和芳香族化合物上,这与MR的结果一致。【结论】神经元的反应强度和刺激化合物浓度之间的关系根据不同的神经元和刺激化合物而有所不同。在测试的浓度范围内,雄虫触角叶神经元对性信息素的反应强度随着浓度的增加而加强,但是除乙酸叶醇酯外,对其他植物气味的反应强度在测试的浓度范围内没有显著的变化。 相似文献
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棉铃虫Helicoverpa armigera主要借助于性信息素通讯完成雌雄识别,实现交配和种群繁衍。关于棉铃虫感受性信息素机制的研究一直是我国化学生态学领域的热点和重心,研究结果有助于开发和改进棉铃虫防治的性引诱剂。本文将对棉铃虫雄虫感受雌虫释放的性信息素的机制进行综述,以期为深入研究棉铃虫及其他相关昆虫的性信息素感受的分子和神经机理提供参考。棉铃虫雌虫性信息素腺体合成和释放多种长链、饱和或非饱和的脂肪醛和醇等化合物,其中Z11-16:Ald为主要性信息素成分,Z9-16∶Ald和Z9-14∶Ald为次要性信息素成分,不同组分按一定比例混合可明显增强对雄性棉铃虫的引诱效果,而化合物Z11-16∶OH和高剂量的Z9-14∶Ald对性信息素引诱活性具有明显的抑制效果。相应地,雄性棉铃虫触角上A, B和C 3种类型的毛形感器能够感受这些信息化合物。A类型毛形感器内表达受体OR13感受Z11-16∶Ald,B类型毛形感器内表达OR14b感受Z9-14∶Ald,C类型毛形感器内表达OR6和OR16感受Z9-16∶Ald, Z9-14∶Ald, Z11-16:Ac和Z11-16∶OH。受体的表达位置和功能与不同类型毛形感器的电生理反应特性相一致。钙离子成像证明在棉铃虫触角叶内的3个扩大型神经纤维球接受这些气味信息,其中神经纤维球云状体接受Z11-16∶Ald,背中间后侧纤维球接受Z9-16∶Ald,背中间前侧纤维球接受Z9-14∶Ald, Z11-16∶Ac和Z11-16∶OH。这些研究成果在感器、受体和脑中枢水平上揭示了棉铃虫感受性信息素的机制,在这些研究基础上,我们认为需要深入开展以下方面的研究:(1)进一步鉴定相关性信息素受体的功能和定位;(2)深入研究脑内嗅觉高级中枢对性信息素信息的处理和整合神经机制;(3)明确棉铃虫性信息素感受受到寄主植物、光周期、温度、湿度等环境因素的影响及机制。 相似文献
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灰茶尺蠖成虫触角及幼虫头部感器超微结构 总被引:7,自引:0,他引:7
【目的】明确灰茶尺蠖Ectropis grisescens成虫触角及幼虫头部感器的种类、形态、数量和分布,以探讨灰茶尺蠖的行为机制。【方法】利用扫描电镜技术观察灰茶尺蠖雌、雄成虫触角和5龄幼虫头部感器的超微结构。【结果】灰茶尺蠖成虫触角上分布有8种感器,分别是栓锥形感器、耳形感器、毛形感器(Ⅰ-Ⅳ)、B?hm氏鬃毛、腔锥形感器(Ⅰ和Ⅱ)、鳞形感器、锥形感器(Ⅰ和Ⅱ)和刺形感器。其中,栓锥形感器仅分布在雌蛾触角上,耳形感器、毛形感器(STⅠ-Ⅲ)仅分布在雄虫触角上。5龄幼虫触角上着生1个栓锥形感器、1个锥形感器和2个刺形感器;上唇着生有6对刺形感器,内唇着生有3对刺形感器和1对指形感器;上颚基部外侧着生有2个刺形感器;下颚及下颚须着生有5个刺形感器、9个锥形感器和2个栓锥形感器;下唇须着生有1个锥形感器和1个刺形感器;吐丝器前端着生有1对刺形感器。【结论】灰茶尺蠖雌、雄成虫触角感器存在性二型性,且雄虫上感器种类和数量较多,据此推测雄虫感受寄主植物或性信息素的能力较强;幼虫头部感器具有嗅觉和味觉功能,在其判断食物的种类和适应性等生态行为中发挥重要作用。 相似文献
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【目的】明确小菜蛾Plutella xylostella成虫喙管感器的形态结构及感器神经元的投射。【方法】利用扫描电子显微镜观察小菜蛾成虫喙管结构和感器,利用神经回填技术和激光共聚焦显微镜观察喙管感器神经元在脑部的投射。【结果】小菜蛾成虫喙管上存在毛形感器(两种亚型)、腔锥形感器、锥形感器、刺形感器和栓锥形感器5种不同类型的感器。毛形感器表面光滑,分布于外颚叶外侧,可分为毛形感器Ⅰ型和Ⅱ型两种亚型,其中Ⅰ型比Ⅱ型长;锥形感器分布于喙管外表面,由一个感觉锥和一个短的圆形基座组成;腔锥形感器仅分布于食管内侧,只有一个粗短感觉锥而无基座;刺形感器由一个细长的感觉毛和一个圆形基座组成,表面无孔,分布于喙管的外表面;栓锥形感器是昆虫喙管上最典型的感受器,集中分布于喙管顶端区域,感器顶部凹腔伸出一个单感觉锥。此外,喙管上的感觉和运动神经元投射到初级味觉中枢咽下神经节。【结论】本研究阐明了小菜蛾成虫喙管感器的类型、分布和形态特征及其感器神经元在脑部的投射形态,为深入了解小菜蛾喙管感器的生理和功能奠定了基础。 相似文献
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【目的】本研究旨在观察扁角豆芫菁Epicauta impressicornis主要触角感器的形态特征,为进一步开展扁角豆芫菁生物学和行为机制研究提供基础参考,也为今后的触角感受器电生理研究提供前提条件。【方法】对扁角豆芫菁E. impressicornis雌雄成虫触角感器进行了扫描电镜观察,并对雌雄成虫触角感器数量、分布及其差异进行了统计和比较分析。【结果】结果表明,其雌雄成虫触角感器存在性二型现象,二者的感器类型、数量及分布既有共性又存在明显差异。雌雄成虫触角共有的感器分为7种,即2种刺形感器(CH1和CH2),2种锥形感器(SB1和SB2),1种Böhm氏鬃毛(BB),1种耳形感器(SA)和1种钟形感器(CA);雄虫触角特有的感器类型包括1种刺形感器(CH3)和1种锥形感器(SB3),而雌性触角特有的感器类型包含2种锥形感器(SB4和SB5)和1种凹槽钉形感器(GP)。【结论】扁角豆芫菁成虫触角感受器类型丰富多样。根据触角感受器的形态、分布以及与之前报道结果的比较分析,推测其功能可能为信息素感器(CH1)、化学感器(CH2和GP)、嗅觉受体(CH3, SB1-SB5, SA和CA)、机械感器(BB)和温度感器(GP和CA)。 相似文献
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蛾类昆虫性信息素受体首先从烟芽夜蛾Heliothis virescens和家蚕Bombyx mori中鉴定出来, 到目前为止已经克隆得到了19种蛾类昆虫的几十种性信息素受体基因, 并且这些基因在系统发育树中聚成一个亚群。性信息素受体从蛾类蛹期开始表达, 主要表达在雄性触角的毛形感器中, 少部分受体在雌性触角、 雄性触角其他感器以及身体其他部位中也有表达。大部分蛾类性信息素受体的配体并不是单一的, 而是能够对多种性信息素组分有反应, 部分性信息素受体还能够识别性信息素以外的其他物质, 还有一部分性信息素受体的识别配体目前尚不清楚。另外发现在雌性蛾类触角中也存在一些嗅觉受体能够识别雄性分泌的性信息素。在蛾类性信息素受体与性信息素识别的过程中, 性信息素结合蛋白不仅能够特异性地运送配体到嗅觉神经元树状突上, 还能够提高性信息素与性信息素受体之间的结合效率。另外, OrCo类受体与性信息素受体共表达在嗅觉神经元中, 在蛾类性信息素受体与配体的识别过程中扮演了重要角色。但是蛾类信息素对神经元刺激的终止并非由性信息素受体控制, 而是由细胞中的气味降解酶等其他因子调控。蛾类性信息素受体研究中还有很多疑问需要解答, 其过程可能比我们想象的更为复杂。 相似文献
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【目的】明确茶谷蛾成虫触角上感器的种类、数量、分布及形态结构。【方法】利用扫描电镜分别对茶谷蛾雌、雄成虫触角上各类感器的超微结构进行观察。【结果】茶谷蛾触角上共分布8种感器,类型分别为Bhm氏鬃毛(2种亚型)、鳞形感器、刺形感器(2种亚型)、腔锥形感器、栓锥形感器、锥形感器、毛形感器(4种亚型)、舌形感器。【结论】茶谷蛾雌、雄成虫触角感器存在性二型性,雌雄蛾感器种类相同,但在感器亚型和数量上,雄蛾多于雌蛾。研究结果将为茶谷蛾通讯及行为机制的研究提供理论基础。 相似文献
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Seong-Gyu Lee Mikael A. Carlsson Bill S. Hansson Julie L. Todd Thomas C. Baker 《Journal of comparative physiology. A, Neuroethology, sensory, neural, and behavioral physiology》2006,192(4):351-363
We used single sensillum recordings to define male Helicoverpa zea olfactory receptor neuron physiology followed by cobalt staining to trace the axons to destination glomeruli of the antennal
lobe. Receptor neurons in type A sensilla that respond to the major pheromone component, (Z)-11-hexadecenal, projected axons to the cumulus of the macroglomerular complex (MGC). In approximately 40% of these sensilla
a second receptor neuron was stained that projected consistently to a specific glomerulus residing in a previously unrecognized
glomerular complex with six other glomeruli stationed immediately posterior to the MGC. Cobalt staining corroborated by calcium
imaging showed that receptor neurons in type C sensilla sensitive to (Z)-9-hexadecenal projected to the dorsomedial posterior glomerulus of the MGC, whereas the co-compartmentalized antagonist-sensitive
neurons projected to the dorsomedial anterior glomerulus. We also discovered that the olfactory receptor neurons in type B
sensilla exhibit the same axonal projections as those in type C sensilla. Thus, it seems that type B sensilla are anatomically
type C with regard to the projection destinations of the two receptor neurons, but physiologically one of the receptor neurons
is now unresponsive to everything except (Z)-9-tetradecenal, and the other responds to none of the pheromone-related odorants tested. 相似文献
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Anton S van Loon JJ Meijerink J Smid HM Takken W Rospars JP 《Arthropod Structure & Development》2003,32(4):319-327
In insects, olfactory receptor neurons (ORNs) are located in cuticular sensilla, that are present on the antennae and on the maxillary palps. Their axons project into spherical neuropil, the glomeruli, which are characteristic structures in the primary olfactory center throughout the animal kingdom. ORNs in insects often respond specifically to single odor compounds. The projection patterns of these neurons within the primary olfactory center, the antennal lobe, are, however, largely unknown.We developed a method to stain central projections of intact receptor neurons known to respond to host odor compounds in the malaria mosquito, Anopheles gambiae. Terminal arborizations from ORNs from antennal sensilla had only a few branches apparently restricted to a single glomerulus. Axonal arborizations of the different neurons originating from the same sensillum did not overlap.ORNs originating from maxillary palp sensilla all projected into a dorso-medial area in both the ipsi- and contralateral antennal lobe, which received in no case axon terminals from antennal receptor neurons. Staining of maxillary palp receptor neurons in a second mosquito species (Aedes aegypti) revealed unilateral arborizations in an area at a similar position as in An. gambiae. 相似文献
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N. K. Hillier C. Kleineidam N. J. Vickers 《Journal of comparative physiology. A, Neuroethology, sensory, neural, and behavioral physiology》2006,192(2):199-219
The neurophysiology and antennal lobe projections of olfactory receptor neurons housed within short trichoid sensilla of female
Heliothis virescens F. (Noctuidae: Lepidoptera) were investigated using a combination of cut-sensillum recording and cobalt-lysine staining techniques.
Behaviorally relevant odorants, including intra- and inter-sexual pheromonal compounds, plant and floral volatiles were selected
for testing sensillar responses. A total of 184 sensilla were categorized into 25 possible sensillar types based on odor responses
and sensitivity. Sensilla exhibited both narrow (responding to few odors) and broad (responding to many odors) response spectra.
Sixty-six percent of the sensilla identified were stimulated by conspecific odors; in particular, major components of the
male H. virescens hairpencil pheromone (hexadecanyl acetate and octadecanyl acetate) and a minor component of the female sex pheromone, (Z)-9-tetradecenal. Following characterization of the responses, olfactory receptor neurons within individual sensilla were
stained with cobalt lysine (N=39) and traced to individual glomeruli in the antennal lobe. Olfactory receptor neurons with specific responses to (Z)-9-tetradecenal, a female H. virescens sex pheromone component, projected to the female-specific central large female glomerulus (cLFG) and other glomeruli. Terminal
arborizations from sensillar types containing olfactory receptor neurons sensitive to male hairpencil components and plant
volatiles were also localized to distinct glomerular locations. This information provides insight into the representation
of behaviorally relevant odorants in the female moth olfactory system.
Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users. 相似文献
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Differential interactions of sex pheromone and plant odour in the olfactory pathway of a male moth 总被引:1,自引:0,他引:1
Deisig N Kropf J Vitecek S Pevergne D Rouyar A Sandoz JC Lucas P Gadenne C Anton S Barrozo R 《PloS one》2012,7(3):e33159
Most animals rely on olfaction to find sexual partners, food or a habitat. The olfactory system faces the challenge of extracting meaningful information from a noisy odorous environment. In most moth species, males respond to sex pheromone emitted by females in an environment with abundant plant volatiles. Plant odours could either facilitate the localization of females (females calling on host plants), mask the female pheromone or they could be neutral without any effect on the pheromone. Here we studied how mixtures of a behaviourally-attractive floral odour, heptanal, and the sex pheromone are encoded at different levels of the olfactory pathway in males of the noctuid moth Agrotis ipsilon. In addition, we asked how interactions between the two odorants change as a function of the males' mating status. We investigated mixture detection in both the pheromone-specific and in the general odorant pathway. We used a) recordings from individual sensilla to study responses of olfactory receptor neurons, b) in vivo calcium imaging with a bath-applied dye to characterize the global input response in the primary olfactory centre, the antennal lobe and c) intracellular recordings of antennal lobe output neurons, projection neurons, in virgin and newly-mated males. Our results show that heptanal reduces pheromone sensitivity at the peripheral and central olfactory level independently of the mating status. Contrarily, heptanal-responding olfactory receptor neurons are not influenced by pheromone in a mixture, although some post-mating modulation occurs at the input of the sexually isomorphic ordinary glomeruli, where general odours are processed within the antennal lobe. The results are discussed in the context of mate localization. 相似文献
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We used single-sensillum recordings to characterize male Heliothis subflexa antennal olfactory receptor neuron physiology in response to compounds related to their sex pheromone. The recordings were then followed by cobalt staining in order to trace the neurons' axons to their glomerular destinations in the antennal lobe. Receptor neurons responding to the major pheromone component, (Z)-11-hexadecenal, in the first type of sensillum, type-A, projected axons to the cumulus of the macroglomerular complex (MGC). In approximately 40% of the type-A sensilla, a colocalized receptor neuron was stained that projected consistently to the posterior complex 1 (PCx1), a specific glomerulus in an 8-glomerulus complex that we call the Posterior Complex (PCx). We found that receptor neurons residing in type-B sensilla and responding to a secondary pheromone component, (Z)-9-hexadecenal, send their axons to the dorsal medial glomerulus of the MGC. As in the type-A sensilla, we found a cocompartmentalized neuron within type-B sensilla that sends its axon to a different glomerulus of the PCx4. One neuron in type-C sensilla tuned to a third pheromone component, (Z)-11-hexadecenol, and a colocalized neuron responding to (Z)-11-hexadecenyl acetate projected their axons to the anteromedial and ventromedial glomeruli of the MGC, respectively. 相似文献
16.
Thomas Heinbockel Vonnie D. C. Shields Carolina E. Reisenman 《Journal of comparative physiology. A, Neuroethology, sensory, neural, and behavioral physiology》2013,199(11):929-946
An open question in olfactory coding is the extent of interglomerular connectivity: do olfactory glomeruli and their neurons regulate the odorant responses of neurons innervating other glomeruli? In the olfactory system of the moth Manduca sexta, the response properties of different types of antennal olfactory receptor cells are known. Likewise, a subset of antennal lobe glomeruli has been functionally characterized and the olfactory tuning of their innervating neurons identified. This provides a unique opportunity to determine functional interactions between glomeruli of known input, specifically, (1) glomeruli processing plant odors and (2) glomeruli activated by antennal stimulation with pheromone components of conspecific females. Several studies describe reciprocal inhibitory effects between different types of pheromone-responsive projection neurons suggesting lateral inhibitory interactions between pheromone component-selective glomerular neural circuits. Furthermore, antennal lobe projection neurons that respond to host plant volatiles and innervate single, ordinary glomeruli are inhibited during antennal stimulation with the female’s sex pheromone. The studies demonstrate the existence of lateral inhibitory effects in response to behaviorally significant odorant stimuli and irrespective of glomerular location in the antennal lobe. Inhibitory interactions are present within and between olfactory subsystems (pheromonal and non-pheromonal subsystems), potentially to enhance contrast and strengthen odorant discrimination. 相似文献
17.
【目的】本研究旨在观察菊小长管蚜Macrosiphoniella sanborni各虫龄和翅型的鉴别特征,以及其触角感器的超微结构,从而为鉴别菊小长管蚜虫龄和研究菊小长管蚜感器功能以及气味识别机制提供参考。【方法】借助超景深显微镜以及扫描电子显微镜分别对各型菊小长管蚜整体形态和触角感器超微结构进行观察,并对触角感受器的数量、分布和大小进行统计和比较分析。【结果】结果表明,翅芽、腹末投影角、以及尾片等定性指标可被用于菊小长管蚜虫龄高效鉴别。尾片形状可用于区分成蚜和若蚜;翅芽有无可用于区分3和4龄若蚜的有翅蚜与无翅蚜;翅芽形状可用于区分3龄与4龄的有翅若蚜;腹末投影角可用于区分3龄和4龄的无翅若蚜;2龄若蚜与3龄若蚜可通过触角节数进行区分。菊小长管蚜触角为丝状,1和2龄若蚜触角分5节,其余龄期为6节。其触角上共有5种形态特异的感器:板形感器、腔锥形感器、毛形感器Ⅰ、毛形感器Ⅱ、钟形感器。成蚜与若蚜在触角节数、感器类型和感器数量上存在差异;有翅蚜与无翅蚜在感器类型、数量以及分布位置上也存在差异。【结论】通过翅芽、腹末投影角以及尾片发达程度等形态指标可以准确地鉴别各型菊小长管蚜;不同翅型不同虫龄的菊小长管蚜触角感器的类型、数量以及分布位置存在差异,这些差异可能直接影响着其在定位寄主植株时的行为表现。 相似文献
18.
Reinhard F. Stocker 《Cell and tissue research》1996,275(1):3-26
This review surveys the organization of the olfactory and gustatory systems in the imago and in the larva of Drosophila melanogaster, both at the sensory and the central level. Olfactory epithelia of the adult are located primarily on the third antennal segment (funiculus) and on the maxillary palps. About 200 basiconic (BS), 150 trichoid (TS) and 60 coeloconic sensilla (CS) cover the surface of the funiculus, and an additional 60 BS are located on the maxillary palps. Males possess about 30% more TS but 20% fewer BS than females. All these sensilla are multineuronal; they may be purely olfactory or multimodal with an olfactory component. Antennal and maxillary afferents converge onto approximately 35 glomeruli within the antennal lobe. These projections obey precise rules: individual fibers are glomerulus-specific, and different types of sensilla are associated with particular subsets of glomeruli. Possible functions of antennal glomeruli are discussed. In contrast to olfactory sensilla, gustatory sensilla of the imago are located at many sites, including the labellum, the pharynx, the legs, the wing margin and the female genitalia. Each of these sensory sites has its own central target. Taste sensilla are usually composed of one mechano-and three chemosensory neurons. Individual chemosensory neurons within a sensillum respond to distinct subsets of molecules and project into different central target regions. The chemosensory system of the larva is much simpler and consists essentially of three major sensillar complexes on the cephalic lobe, the dorsal, terminal and ventral organs, and a series of pharyngeal sensilla. 相似文献
19.
Reinhard F. Stocker 《Cell and tissue research》1994,275(1):3-26
This review surveys the organization of the olfactory and gustatory systems in the imago and in the larva of Drosophila melanogaster, both at the sensory and the central level. Olfactory epithelia of the adult are located primarily on the third antennal segment (funiculus) and on the maxillary palps. About 200 basiconic (BS), 150 trichoid (TS) and 60 coeloconic sensilla (CS) cover the surface of the funiculus, and an additional 60 BS are located on the maxillary palps. Males possess about 30% more TS but 20% fewer BS than females. All these sensilla are multineuronal; they may be purely olfactory or multimodal with an olfactory component. Antennal and maxillary afferents converge onto approximately 35 glomeruli within the antennal lobe. These projections obey precise rules: individual fibers are glomerulus-specific, and different types of sensilla are associated with particular subsets of glomeruli. Possible functions of antennal glomeruli are discussed. In contrast to olfactory sensilla, gustatory sensilla of the imago are located at many sites, including the labellum, the pharynx, the legs, the wing margin and the female genitalia. Each of these sensory sites has its own central target. Taste sensilla are usually composed of one mechano-and three chemosensory neurons. Individual chemosensory neurons within a sensillum respond to distinct subsets of molecules and project into different central target regions. The chemosensory system of the larva is much simpler and consists essentially of three major sensillar complexes on the cephalic lobe, the dorsal, terminal and ventral organs, and a series of pharyngeal sensilla. 相似文献
20.
Yamagata N Nishino H Mizunami M 《Proceedings. Biological sciences / The Royal Society》2006,273(1598):2219-2225
Tremendous evolutional success and the ecological dominance of social insects, including ants, termites and social bees, are due to their efficient social organizations and their underlying communication systems. Functional division into reproductive and sterile castes, cooperation in defending the nest, rearing the young and gathering food are all regulated by communication by means of various kinds of pheromones. No brain structures specifically involved in the processing of non-sexual pheromone have been physiologically identified in any social insects. By use of intracellular recording and staining techniques, we studied responses of projection neurons of the antennal lobe (primary olfactory centre) of ants to alarm pheromone, which plays predominant roles in colony defence. Among 23 alarm pheromone-sensitive projection neurons recorded and stained in this study, eight were uniglomerular projection neurons with dendrites in one glomerulus, a structural unit of the antennal lobe, and the remaining 15 were multiglomerular projection neurons with dendrites in multiple glomeruli. Notably, all alarm pheromone-sensitive uniglomerular projection neurons had dendrites in one of five 'alarm pheromone-sensitive (AS)' glomeruli that form a cluster in the dorsalmost part of the antennal lobe. All alarm pheromone-sensitive multiglomerular projection neurons had dendrites in some of the AS glomeruli as well as in glomeruli in the anterodorsal area of the antennal lobe. The results suggest that components of alarm pheromone are processed in a specific cluster of glomeruli in the antennal lobe of ants. 相似文献