Agrotis segetum雄蛾触角叶神经元对性信息素时间编码的机制分析

应用压力注射,在Agrotis segetum雄蛾触角叶（AL）中33个对性信息素有反应的MGC神经元上探计了对性信息素反应模式的形成机制,压力注射100mmol/L GABA进入AL神经网引起神经元一个慢的超极化电位,并有一个长时程的放电抑制相,与用性信息素刺激诱导的神经元分应很相似,但GABA并不影响神经元对性信息素刺激的去极化反应,低Cl^-溶液可减弱AL神经元对性信息素刺激的超极化反应,甚至使超极化相逆转为兴奋反应,抑制相消失。压力注射Bicuculline使神经元放电频率增加。压力注射Bicuculline的同时给予性信息素刺激,可使性信息素刺激所致的神经元放电增加进一步加强;Bicuculline可使性信息素刺激引起的神经元超极化幅度变小,放电抑制时间变短,甚至其抑制相完全被逆转为正常放电,无超极化反应和抑制相存在,结果表明,AL神经元对性信息系反应的超极化相与GABA受体有关。     

斜纹夜蛾触角叶神经元及其对植物气味和性信息素的反应

【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。     

亚洲玉米螟对性信息素的触角电位反应

本文描述了一个改进的记录触角电位(EAG) 技术。用此方法可以稳定地记录触角电位2小时,便于比较性信息素不同组分的活性。亚洲玉米螟(Ostrinia furnacalis)雌蛾性信息素的二个组分:顺-12-十四碳烯醇乙酸酯(Z-12-14C:AC)和反-12-十四碳烯醇乙酸酯(E-12-14C:AC)以及十四碳醇乙酸酯(14C:AC),在雄蛾触角上进行了测试。Z-和E-12-14C:AC分别能引起几个毫伏的触角电位,然而Z-12-14C:AC 活性大于E-12-14C:AC。用一种异构体重复刺激引起的适应性,不影响另一种异构体接着刺激引起反应的幅度,表明雄蛾触角上可能有对Z-和E-12-14C:AC分别反应的两种类型受体。另外发现14C:AC既不引起触角电位反应,也不抑制触角对 Z-和 E-12-14C:AC反应。     

大鼠下丘脑室旁核神经元对电刺激迷走神经的反应

用玻璃微电极记录了93只大鼠的1059个PVH单位的电活动,观察了电刺激颈部迷走神经对PVH单位自发放电的效应和所引起的PVH单位的诱发反应。电刺激迷走神经分别使46个及10个PVH单位呈诱发兴奋和抑制反应。给予迷走神经以不同强度的刺激时,发现PVH神经元对激活A和C两类纤维的强刺激反应,而对仅激活A类纤维的弱刺激则不反应。PVH单位对电刺激坐骨神经或迷走神经的反应有以下几种:对迷走神经和坐骨神经刺激均作出兴奋或抑制反应;仅对迷走刺激作出兴奋或兴奋-抑制反应,而对坐骨神经刺激不反应;对坐骨神经刺激作出兴奋反应,而对迷走神经刺激不反应。讨论了迷走神经到室旁核的中枢传导特点以及内脏传入和躯体传入信息在PVH单位会聚的可能意义。     

外侧臂旁核神经元对穹隆下器逆向刺激和孤束核顺向刺激的反应

细胞外记录大鼠外侧臂旁核(LPBN)神经元单位放电,观察了刺激穹隆下器(SFO)在记录单位诱发的逆向反应和静脉注射新福林兴奋外周压力感受器和刺激孤束核(NTS)减压区诱发的顺向反应。实验发现:刺激 SFO,9.9%(15/151)的 LPBN 神经元有逆向反应。静脉注射新福林,40.7%(22/54)的 LPBN 神经元有抑制反应,27.8%(17/54)有兴奋反应。刺激 NTS,55.6%(94/169)的 LPBN 神经元呈现顺向兴奋反应;22.5%(38/169)呈现顺向抑制反应。观察静脉注射新福林对 SFO 刺激有逆向反应的 LPBN 神经元自发放电的影响,在两个受试单位均见抑制反应。观察刺激 NTS 对逆向反应单位自发放电的影响,在8个受试单位中,6个呈兴奋反应;2个呈抑制反应。以上结果表明:LPBN 接受来自 NTS 的兴奋性或抑制性压力感受性传入,并把这种信息经 LPBN-SFO 直接通路传输到 SFO。     

豆野螟成虫触角对植物挥发性和性信息素化合物的触角电位反应

以顺3-己烯乙酸酯为标准化合物,研究了豆野螟雌、雄成虫触角对不同浓度的植物挥发性和性信息素化合物组分的触角电位（EAG）反应.结果表明：豆野螟雌、雄成虫触角对植物挥发性气味具有强烈的EAG反应,但在大部分浓度下,雌、雄虫的反应没有显著差异.在测试的9种植物挥发性化合物中,雌、雄虫对高浓度反-2-己烯醛刺激的相对EAG反应的最大值分别达到250%和260%,且雌、雄虫触角对这种化合物的EAG反应的形状也有很大差异;但对豇豆花气味中的柏木烯和柏木脑没有明显的EAG反应.雌、雄蛾对性信息素都有明显反应,且雌、雄虫的反应存在显著差异,雄虫触角对性信息素化合物主要组分（反10,反12）-十六碳二烯醛的EAG反应的最大值达到250%,远超过雌虫反应的最大值(53%).雌、雄成虫这种神经感觉反应的差异反映了它们在感器结构、功能和行为上的差异.     

大鼠性周期内缰核神经元电活动的变化

目的：探讨缰核与生殖神经内分泌功能的关系。方法：采用电生理学方法记录细胞外放电。结果：①本实验观察到动情前期及动情间期大鼠缰核（ｈａｂｅｎｕｌａｒ ｎｕｃｌｅｕｓ,Ｈｂ） 的神经元对阴道、宫颈刺激（ｖａｇｉｎｏｃｅｒｖｉｃａｌｓｔｉｍｕｌａｔｉｏｎ,ＶＣ刺激） 发生两种反应。一类神经元对ＶＣ 刺激发生放电频率增快或持续时间延长的反应,即ＶＣＥ 神经元,另一类神经元则对ＶＣ刺激发生放电频率降低或暂时终止的反应,即ＶＣＩ神经元。动情前期大鼠的ＶＣＥ及ＶＣＩ神经元多呈周期性放电;②本实验还发现,大鼠Ｈｂ 中对ＶＣ刺激发生反应的性相关神经元中多数为非特异性反应型神经元,即对ＶＣ刺激和夹尾等其它刺激发生兴奋或抑制反应,少数为特异反应型神经元,即只对ＶＣ 刺激发生反应。结论：①提示这两种神经元可能与神经分泌活动有关; ②特异反应型神经元的存在表明,Ｈｂ 可以接受ＶＣ刺激的传入信息,并对其发生反应。ＶＣ刺激可能通过影响Ｈｂ 神经元的活动,从而影响生殖神经内分泌功能     

利用单感器记录与神经元示踪结合对棉铃虫主要性信息素感器内神经元投射的鉴定

【目的】鉴定雄性棉铃虫Helicoverpa armigera成虫触角性信息素感器嗅觉受体神经元的功能、形态及中枢投射路径。【方法】利用单感器记录技术记录棉铃虫嗅觉受体神经元对性信息素的反应,同时采用荧光染料作为示踪剂染色标记嗅觉受体神经元;使用免疫组织化学方法处理相应的脑组织,标记脑内触角叶的神经纤维球结构;用激光扫描共聚焦显微镜获取图像数据,使用图形软件ZEN和Amira 4.1.1进行三维结构重建。【结果】记录到雄性棉铃虫成虫触角上长毛形感器对主要性信息素成分Z11-16∶Ald产生明显的电生理反应,并成功染色标记了该感器内的嗅觉受体神经元。染色标记显示该感器内具有两个嗅觉受体神经元,其轴突通过触角神经分别投射触角叶内的云状体神经纤维球和普通神经纤维球。【结论】单感器记录与神经元示踪两技术结合能够用于鉴定昆虫触角嗅觉受体神经元的功能、形态和投射至神经纤维球的路径。与赖氨酸钴方法比较,使用荧光染料法进行神经元示踪,操作更简便,且易于进行三维空间分析,为调查棉铃虫其他嗅觉神经元的投射路径以明确外周气味受体感受与中枢系统的联系提供了有力技术支持。     

针刺过程中猴的操作式条件反射和大脑皮层体感区神经元电活动的观察

为了研究大脑皮层体感Ⅰ区与痛觉以及针刺镇痛作用的关系,以钾离子透入下肢皮肤作为痛刺激,以操作式条件反射作为痛指标,用钨丝微电极记录大脑皮层体感Ⅰ区单个神经元的电活动,在10只清醒、可以活动的猴子上进行了实验观察。在下肢的皮层代表区分离和记录了能对不同传入刺激起反应的神经元215个。28个对皮肤伤害性刺激起反应。其中25个发放增加(兴奋型神经元),3个发放减少(抑制型神经元)。对12个伤害性神经元进行了针刺效应的观察。在针刺过程中有6个神经元(4个兴奋型、2个抑制型)对伤害性刺激的反应受到抑制。其中有些神经元的抑制可伴有痛阈的升高,但两者未呈现严格的平行关系。皮层体感Ⅰ区中亦可记录到会聚性神经元,即同一神经元既可接受皮肤机械刺激,亦可接受皮肤伤害性刺激。其中有些神经元对于不同性质的刺激可以出现不同型式的反应,如对钾离子刺激皮肤出现抑制性反应而对触觉刺激出现兴奋性反应。针刺时,往往只有伤害性刺激引起的反应受到抑制,而机械刺激引起的反应没有明显变化。实验表明,针刺可以使皮层体感Ⅰ区的某些神经元对皮肤伤害性刺激的反应减弱;但是这种效应可能不是发生在皮层本身,而是续发于皮层下结构活动的变化。     

昆虫嗅觉感受细胞电反应计算机数据分析

昆虫嗅觉感受细胞电反应计算机数据分析吴锋,吴才宏（北京志同电子公司北京１０００８０）（北京大学生命科学学院北京１００８７１）昆虫触角电位和单个嗅觉感受细胞电反应记录已成为研究昆虫性信息素及化学通讯机制的重要手段。实验中要记录和分析处理大量数据。在所记...     

Male-specific,sex pheromone-selective projection neurons in the antennal lobes of the mothManduca sexta

A subset of olfactory projection neurons in the brain of male Manduca sexta is described, and their role in sex pheromone information processing is examined. These neurons have extensive arborizations in the macroglomerular complex (MGC), a distinctive and sexually dimorphic area of neuropil in the antennal lobe (AL), to which the axons of two known classes of antennal pheromone receptors project. Each projection neuron sends an axon from the AL into the protocerebrum. Forty-one projection neurons were characterized according to their responses to electrical stimulation of the antennal nerve as well as olfactory stimulation of antennal receptors. All neurons exhibited strong selectivity for female sex pheromones. Other behaviorally relevant odors, such as plant volatiles, had no obvious effect on the activity of these neurons. Two broad physiological categories were found: cells that were excited by stimulation of the ipsilateral antenna with pheromones (29 out of 41), and cells that received a mixed input (inhibition and excitation) from pheromone pathways (12 out of 41). Of the cells in the first category, 13 out of 29 were equally excited in response to stimulation of the antenna with either the principal natural pheromone (bombykal) or a mimic of a second unidentified pheromone ('C-15') and were similarly excited by the natural pheromone blend. The remaining 16 out of 29 cells responded selectively, and in some cases, in a dose-dependent manner, to stimulation of the antenna with bombykal or C-15, but not both. Some of these neurons had dendritic arborizations restricted to only a portion of the MGC neuropil, whereas most had arborizations throughout the MGC. Of the cells in the second category, 9 out of 12 were excited by bombykal, inhibited by C-15, and showed a mixed response to the natural pheromone blend. For the other 3 out of 12 cells, the response polarity was reversed for the two chemically-identified odors. Two additional neurons, which were not tested with olfactory stimuli, were tonically inhibited in response to electrical stimulation of the ipsilateral antennal nerve. These observations suggest that some of the male-specific projection neurons may signal general pheromone-triggered arousal, whereas a smaller number can actively integrate inputs from the two know receptor classes (Bal- and C-15-selective) and may operate as 'mixture detectors' at this level of the olfactory subsystem that processes information about sex pheromones.     

Sex pheromone and plant-associated odour processing in antennal lobe interneurons of male Spodoptera littoralis (Lepidoptera: Noctuidae)

Antennal lobe interneurons of male Spodoptera littoralis (Boisd.) were investigated by using intracellular recording and staining techniques. Physiological and morphological characteristics of local interneurons and projection neurons responding to sex pheromone and plant-associated volatiles are described. The interneurons identified were divided into three groups, depending on their physiological response characteristics. Both types of interneurons, local interneurons and projection neurons, were described in all three groups. 1. Interneurons responding exclusively to sex pheromone stimuli, displayed different degrees of specificity. These neurons responded to either one, two, three or all four of the single sex pheromone or sex pheromone-like compounds tested. Most of these neurons also responded to a mixture of the two pheromone components present in the female S. littoralis blend. Two local interneurons and one projection neuron were identified as blend specialists, not responding to the single female produced sex pheromone components, but only to their mixture. Five pheromone specific projection neurons arborized in one or more subcompartments of the macroglomercular complex (MGC) and some of them had axonal branches in the calyces of the mushroom body and in different parts of the lateral protocerebrum. 2. Interneurons responding only to plant-associated volatiles varied highly in specificity. Neurons responding to only one of the stimuli, neurons responding to a variety of different odours and one neuron responding to all stimuli tested, were found. Three specialized local interneurons had arborizations only in ordinary glomeruli. One specialized and three less specialized local interneurons had arborizations within the MGC and the ordinary glomeruli. The projection neurons responding only to plant-associated volatiles had mostly uni- or multiglomerular arborizations within the ordinary glomeruli. 3. Interneurons responding to both sex pheromones and plant-associated stimuli varied in specificity. Individual interneurons that responded to few plant-associated odours mostly responded to several pheromone stimuli as well. Projection neurons responding to most of the plant-associated volatiles also responded to all pheromone stimuli. Two local interneurons responding to both stimulus groups, arborized within the MGC and the ordinary glomeruli. Projection neurons mostly arborized in only one ordinary glomerulus or in one compartment of the MGC. The variation in specificity and sensitivity of antennal lobe interneurons and structure-function correlations are discussed.     

Central processing of sex pheromone stimuli is differentially regulated by juvenile hormone in a male moth

In the male moth, Agrotis ipsilon, the neuronal basis for juvenile hormone (JH)-linked modulation of sex pheromone responsiveness was investigated following stimulation of the antenna with i) an extract of female pheromone gland, ii) the synthetic pheromone blends from A. ipsilon and a closely related species, A. segetum, and iii) single components of the A. ipsilon blend. Response characteristics of olfactory interneurons were studied in the antennal lobe (AL) at different ages and with manipulated JH levels using intracellular recording techniques. Blend-specific, generalist and component-specific neurons were identified and described according to their response pattern. The proportion of low threshold AL interneurons increased significantly with age for all stimuli tested. Changes were, however, less pronounced for the minor single components. The proportion of low threshold AL interneurons in allatectomized (JH-deprived) mature males was significantly lower for all stimuli than in intact mature males. A large proportion of low threshold AL interneurons responding to the pheromone blends, but not as pronounced for single pheromone components, could be restored/induced by injecting JH either into JH-deprived mature males or into young immature males. The specificity for the species-specific blend compared to the A. segetum blend increased with age and JH injections.     

A CPG component LE generates depolarization of buccal neurons by producing constant plateau potentials during feeding responses of Aplysia kurodai

In the buccal ganglia of Aplysia kurodai we have identified neurons (here termed LE neurons, or LE) producing plateau potentials lasting several seconds by application of short depolarizing currents. Results obtained from experiments using various bath solutions suggest that generation of these plateau potentials may be an endogenous property of LE. Application of various intensities or lengths of depolarizing currents induced in LE almost constant plateau potentials with fixed duration and depolarizing size. LE spikes produced monosynaptic EPSPs in the ipsilateral multi-action neuron (MA) and the jaw-closing motor neuron (JC) in the buccal ganglia. Conversely, MA spikes produced monosynaptic IPSPs in LE. There was electrical coupling between LE and both MA and JC. During the feeding-like response elicited by electrical stimulation of the nerve, LE showed rhythmic depolarization almost simultaneously with MA and JC, and firing on the plateau potentials occurred during the period of JC firing, the later phase of radula retraction. Hyperpolarization of LE during the feeding-like response suppressed generation of plateau potentials, though rhythmic small depolarization was still induced. During LE hyperpolarization, the duration of the depolarization of MA and JC was shortened. These results suggest that LE may be an element of the feeding CPG circuit and may contribute to part of the depolarization of MA and JC by generating constant plateau potentials during the feeding response, though LE may not have rhythm-generating ability.     

Glomerular targets of Heliothis subflexa male olfactory receptor neurons housed within long trichoid sensilla

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.     

Morphology and physiology of multiglomerular olfactory projection neurons in the spiny lobster

Whole-cell patch-clamp recording was used to characterize olfactory projection neurons in an isolated brain preparation of the spiny lobster, Panulirus argus. Responses to electrical stimulation of the olfactory afferents were recorded from projection neuron somata using biocytin-filled electrodes. All projection neurons were multiglomerular, innervating up to 80% of all olfactory lobe glomeruli, but the innervation was heterogeneous. Most neurons densely innervated only 3–4 glomeruli; the remaining glomeruli in their dendritic arbor were sparsely innervated, thereby creating two distinct patterns of intraglomerular branching. Projection neurons responded to orthodromic stimulation with an initial depolarization and spiking followed by a 1–3 s hyperpolarization. The inhibitory phase of the response was lower in threshold and longer in latency than the excitatory phase, a response pattern also reported in olfactory projection neurons of insects and vertebrates. The somata of the projection neurons supported voltage-activated currents and TTX-sensitive action potentials, suggesting that the soma, although spatially separated from the axon and dendrites, may play a significant functional role in these cells. Dye coupling between some projection neurons correlated with the presence of multiple amplitude action potentials, suggesting that at least some projection neurons may be coupled via gap junctions.     

Local interneurons and information processing in the olfactory glomeruli of the moth Manduca sexta

Intracellular recordings were made from the major neurites of local interneurons in the moth antennal lobe. Antennal nerve stimulation evoked 3 patterns of postsynaptic activity: (i) a short-latency compound excitatory postsynaptic potential that, based on electrical stimulation of the antennal nerve and stimulation of the antenna with odors, represents a monosynaptic input from olfactory afferent axons (71 out of 86 neurons), (ii) a delayed activation of firing in response to both electrical- and odor-driven input (11 neurons), and (iii) a delayed membrane hyperpolarization in response to antennal nerve input (4 neurons).Simultaneous intracellular recordings from a local interneuron with short-latency responses and a projection (output) neuron revealed unidirectional synaptic interactions between these two cell types. In 20% of the 30 pairs studied, spontaneous and current-induced spiking activity in a local interneuron correlated with hyperpolarization and suppression of firing in a projection neuron. No evidence for recurrent or feedback inhibition of projection neurons was found. Furthermore, suppression of firing in an inhibitory local interneuron led to an increase in firing in the normally quiescent projection neuron, suggesting that a disinhibitory pathway may mediate excitation in projection neurons. This is the first direct evidence of an inhibitory role for local interneurons in olfactory information processing in insects. Through different types of multisynaptic interactions with projection neurons, local interneurons help to generate and shape the output from olfactory glomeruli in the antennal lobe.Abbreviations AL antennal lobe - EPSP excitatory postsynaptic potential - GABA -aminobutyric acid - IPSP inhibitory postsynaptic potential - LN local interneuron - MGC macroglomerular complex - OB olfactory bulb - PN projection neuron - TES N-tris[hydroxymethyl]methyl-2-aminoethane-sulfonic acid     

Network interactions among sensory neurons in the leech

Interactions among mechanosensory neurons, sensitive to touch, pressure and nociceptive stimuli in the leech nervous system were studied in isolated ganglia and in body-wall preparations. Pairs of touch-pressure, touch-nociceptive and pressure-nociceptive neurons were tested by suprathreshold stimulation of one neuron while recording the response of the other, in both directions. Pressure and nociceptive stimulation evoked depolarizing and hyperpolarizing responses in touch cells, mediated by interneurons. The relative expression of these responses depended on the stimulus duration. One or two pressure cell spikes produced, predominantly, a depolarization of the touch cells, and increasing number of spikes evoked a hyperpolarization. Nociceptive cells produced primarily the hyperpolarization of touch cells at any stimulus duration. When touch cells were induced to fire by injection of positive current into the soma, stimulation of pressure cells inhibited touch cell activity. However, when touch cells were induced to fire by peripheral stimulation, pressure cell activation failed to inhibit touch cell firing. The results suggest that excitation of pressure and nociceptive cells would not limit the responses of touch cells to peripheral stimuli, but would inhibit the firing of touch cells evoked by their central connectivity network.     

Projections to higher olfactory centers from subdivisions of the antennal lobe macroglomerular complex of the male silkmoth

The macroglomerular complex (MGC) is the first-order center for synaptic processing of olfactory information about the female sex pheromone in the male moth brain. We have investigated the MGC subdivisions of the male silkmoth Bombyx mori by use of three-dimensional reconstruction of the MGC from sequential series of confocal slice images. The B. mori MGC consists of three subdivisions similar to those of Manduca sexta: the cumulus, toroid and horseshoe. Intracellular recording and staining revealed that responses of MGC projection neurons to pheromonal stimulation correlate with their dendritic arborizations in the subdivisions of the MGC (the cumulus, toroid and horseshoe) and each subdivision specific projection neuron transmits information to different regions in the calyces of the mushroom body and the inferior lateral protocerebrum. We revealed that major pheromone component information is transferred to the medial part of the inferior lateral protocerebrum through three different antennocerebral pathways. Although it is generally accepted that the calyces of the mushroom body and the inferior lateral protocerebrum are the target sites for pheromone information from the MGC in moths, our results suggest that the medial part of the inferior lateral protocerebrum may be a more important processing site for major pheromonal information in B. mori.