实夜蛾属和铃夜蛾属昆虫性信息素通讯系统的研究进展

实夜蛾属Heliothis和铃夜蛾属Helicoverpa昆虫的性信息素通讯系统主要包括雌蛾的性信息素合成和雄蛾对性信息素接收两个方面,每方面都有分子、细胞、系统水平上进行协同作用的生物过程。性信息素生物合成激活肽（PBAN）与其受体作用,启动信号转导系统,从而激活合成性信息素的酶系统来合成性信息素,利用化学和生物测定的方法鉴定出具有诱蛾活性的性信息素腺体组分及行为功能;性信息素分子与性信息素结合蛋白（PBP）的复合体同受体相互作用,启动信号转导系统,诱导产生神经信号,从而引起一系列性行为反应。这些生物过程受到各种内部和外部因素的影响。     

蛾类性信息素生物合成途径及其调控

蛾类通过产生和识别物种特异性性信息素来引发后续交配行为,因此它在两性交配行为中至关重要.它们具有不同碳链长度、末端官能团、不同双键位置和构型等化学结构特征,本文详细讨论了不同蛾类性信息素的合成途径以及催化每一步反应的相关酶系,列举了15种夜蛾科不同亚科常见物种的性信息素组分及其比例,总结了产生特定比例性信息素的可能原因,查阅了夜蛾科不同物种已经鉴别的性信息素,并按照不同亚科、不同官能团和碳链长度对其进行分类,归纳了同一物种及其亲缘物种性信息素组分和比例的变异,总结了产生变异的分子机理,讨论了性信息素变异和物种进化的关系.最后以生物合成激活神经肽(PBAN)为主, 介绍了其调控途径和机制.本文旨在以不同的蛾类性信息素合成途径为线索,从共有合成途径出发深入了解其规律和共性,从特异合成途径出发探究物种间的进化和变异,展望未来的研究方向及其应用.     

水稻螟虫神经肽PBAN及其受体序列的生物信息学分析

【目的】性信息素合成激活肽(PBAN)是控制昆虫产生性信息素的激素,本文旨在分析水稻螟虫神经肽PBAN及其受体的序列。【方法】通过t Blastn同源检索从水稻螟虫基因组和转录组数据库中鉴定水稻螟虫PBAN神经肽及其受体序列,在此基础上进行序列比对及系统发生分析。【结果】发现二化螟Chilo suppressalis、三化螟Tryporyza incertulas和大螟Sesamia inferens的PBAN成熟肽序列均含有33个氨基酸残基,其C端五肽序列完全相同,3种水稻螟虫PBAN多肽相似度为54.55%~63.64%;发现二化螟PBAN受体3个异构体全长氨基酸序列(PBANR-A、PBANR-B和PBANR-C),均含有7个跨膜区域。【结论】进化树分析发现不同昆虫PBAN神经肽及其受体存在一定的保守性和多样性,并且在进化树上的位置几乎与昆虫系统发育分类一致,推测PBAN神经肽和PBAN受体在昆虫系统进化过程中可能存在协同进化现象。本研究为水稻螟虫PBAN神经肽及其受体的结构和功能分析提供基础。     

铃夜蛾属昆虫性信息素生物合成及内分泌调控

综述了铃夜蛾属Helicoverpa昆虫性信息素生物合成途径及内分泌因子的调控作用 ,包括信息素生物合成激活神经肽 (PBAN)和信息素生物合成抑制肽 (PSP)等的来源、结构和作用机制及一些种中保幼激素 (JH)和章鱼胺 (OA)对性信息素生物合成的作用 ,并展望了未来的研究方向。     

PBAN/pyrokinin神经肽类及其基因的研究进展

昆虫在其生长发育过程中,如胚胎发育、蜕皮变态、滞育、迁飞、代谢、生殖等都离不开神经肽的调控。信息素合成激活肽(pheromone biosynthesis activating neuropeptide,PBAN)和Pyrokinin神经肽是C端具有五肽FXPRL(X=S,V,T,G等)(苯丙-X-脯-精-亮氨酸)序列的一类神经肽,在昆虫的生长发育中起重要的生理功能,如性信息素的合成、控制表皮色素、促进胚胎滞育和刺激内脏肌肉收缩等重要的生理功能。因此近几年对PBAN/pyrokinin神经肽的鉴定、加工、作用和降解方式的研究成为研究的热点,为研制高效、低毒、专一性强、无公害的杀虫剂提供了思路。介绍了PBAN/pyrokinin神经肽类及其基因的研究进展,并对PBAN/pyrokinin神经肽在害虫防治中的应用进行了展望。     

棉铃虫和烟青虫性信息素腺体脂肪醇和乙酸酯转化的比较研究

棉铃虫Helicoverpa armigera和烟青虫H. assulta属于可同域发生的近缘种昆虫,通过产生比例相反的两种性信息素化合物——顺9-十六碳烯醛和顺11-十六碳烯醛维持种间生殖隔离。本研究应用外源不饱和脂肪醇及乙酸酯在棉铃虫和烟青虫性信息素腺体进行在体转化,利用气相色谱法分析转化产物,从酶学角度探讨了上述两近缘种昆虫性信息素腺体组分差异的形成原因。实验结果表明,两种昆虫信息素腺体表皮伯醇氧化酶对外源顺9-十六碳烯醇、顺11-十六碳烯醇和反10-十六碳烯醇无催化专一性,说明末端氧化过程对于醛类性信息素组分特定比例的形成不起作用。棉铃虫性信息素腺体组织具有较高的乙酸酯酶活性,可水解外源乙酸酯,但烟青虫性信息素腺体乙酸酯酶活性很低。这些发现对于进一步了解两种昆虫的生殖隔离机制有重要参考价值。     

PBAN对亚洲玉米螟(Ostrinia furnacalis)性外激素生物合成路线的控制(英)

去头处理致使亚洲玉米螟性外激素的含量显著地下降到很低的水平。注射雄性或雌性玉米螟头部提取物或合成PBAN(激活外激素生物合成神经肽)可使外激素的含量得以恢复。因此可知玉米螟外激素的产生系受一种类PBAN因子控制。玉米螟性外激素生物合成路线由棕榈酸的生物合成开始,然后经14位脱饱和化,碳链缩短,还原和乙酰化形成外激素顺和反12—十四碳烯乙酸酯。为了阐明受PBAN控制的生物合成步骤,研究了不同的标记前体掺入外激素及其中间体的情况。根据结果推论,PBAN主要通过调节由乙酸酯到棕榈酸的生物合成步骤来控制外激素生物合成。     

一种用于昆虫性信息素成分单不饱和双键定位的简便方法

昆虫利用特定的性信息素成分实现种内信息交流和种间生殖隔离,性信息素成分异构体的细微差异都能导致其生物活性的很大改变。本研究利用二甲基二硫醚（DMDS）甲硫基化反应和气相色谱-电子轰击质谱（GC-EI-MS）的方法对脂肪族单不饱和醇、醛和乙酸酯类昆虫性信息素成分双键在碳链中的位置异构进行系统研究。质谱分析结果表明,含有醇和乙酸酯官能团的单不饱和烯烃甲硫基化衍生物的质谱特征碎片分子离子峰（M+）及2个主要的诊断离子m/z 61+14m ［H-（CH₂）_m-CH=S⁺ CH₃］和77+14n［CH₃S⁺ =CH（CH₂）_nOH］（或119+14n,［CH₃S⁺ =CH（CH₂）_nOOCCH₃］）丰度都很强,可以据此直接推断双键在碳链中的位置。尽管单不饱和醛类化合物DMDS衍生物的特征碎片峰也很明显,但是由于羰基的质量数和2个亚甲基的质量数相同,不能由低分辨质谱的特征碎片峰直接推断双键在碳链中的位置。DMDS甲硫基化反应结合GC-EI-MS分析方法鉴定昆虫性信息素成分单不饱和双键在碳链中的位置异构,该方法简单快捷,为昆虫性信息素的结构鉴定工作奠定了坚实的基础。     

小木蠹蛾性行为和性信息素产生与释放的时辰节律

观察了小木蠹蛾Holcocerus insularis的性行为反应,并采用腺体提取、空气收集 、触角电位和田间试验等方法对雌蛾产生和释放性信息素的时辰节律进行了研究。结果表明： (1) 该虫羽化24 h后性成熟,婚飞和交配活动主要在1：00～4：00,交配历时15～45 min;(2) 大部分雌蛾一生交配1～3次,雄蛾多数一生只交配1次,雌雄比为1∶0.89; (3) 雌蛾腺体提取物中性信息素含量同蛾龄有关,2日龄雌蛾腺体性信息素含量最高;(4) 雌蛾腺体中性信息素含量在1：00时最高,而性信息素释放高峰在2：30。     

二个不同发育阶段茶银尺蠖雌蛾性腺超微结构的比较研究

本文利用扫描电镜和透射电镜分别对不同发育阶段的茶银尺蠖Scopula subpunctaria Herrich-Schaeffer雌蛾性信息素腺体进行了观察和研究,对探索信息素的合成途径提供科学依据。结果表明,雌蛾性信息素腺体位于第8、9/10腹节的节间膜上,由其表皮下方的单层上皮细胞组成,并几乎覆盖整个节间膜形成一个近乎完整的环状。成熟雌蛾(3日龄)性腺的超微结构照片显示性腺细胞具有发达的微绒毛、质膜内褶、大量的脂滴、细胞间的运输孔道以及细胞桥粒等结构组织。而在未成熟雌蛾(羽化5h内)性腺细胞内,这些结构均明显缺失或发育不完整。     

The Bombyx mori sex pheromone biosynthetic pathway is not mediated by cAMP

In most moths, sex pheromone production is regulated by pheromone biosynthesis-activating neuropeptide (PBAN). How the extracellular PBAN signal is turned into a biological response has been the focus of numerous studies. In the classical scheme of signal transduction, activated G proteins relay the extracellular signal to downstream effector molecules such as calcium channels and adenylyl cyclase. The role of calcium in PBAN signaling has been clearly demonstrated, but the possible involvement of cAMP is not as straightforward. While cAMP has been shown to be necessary for PBAN signaling in most heliothine species, there has been no definitive demonstration of its role in Bombyx mori. To address this question, we used degenerate RT-PCR to clone two Gs subunits, designated P50Gs1 and P50Gs2, from B. mori pheromone gland (PG) cDNAs. The two Gs proteins were expressed in all tissues examined and were not up-regulated in accordance with adult eclosion. Even though two bands corresponding to the approximate molecular weights of P50Gs1 and P50Gs2 were detected in PG homogenates, the Gs antagonist, NF449, had no effect on sex pheromone production. Furthermore, no changes in the intracellular cAMP levels were detected following PBAN stimulation.     

Mechanisms involved in the control of pheromone production in female moths: recent developments

Species‐specific pheromone blends of nocturnal female moths, derived from fatty acid precursors, are produced and released for mate‐finding, and are initiated by the circadian, trophic hormone, Pheromone Biosynthesis Activating Neuropeptide (PBAN). PBAN, produced in the sub‐oesophageal ganglion, is a 33 amino acid neuropeptide with a minimum active core in its FXPRLamide C‐terminal. PBAN acts directly on pheromone gland cells of mature females by binding to a specific G‐protein‐coupled membrane receptor (GPCR), and thereby initiating a signal transduction cascade involving calcium and cAMP. This discussion will review recent developments concerning the identification of the PBAN GPCR, its regulation by juvenile hormone (JH), and its mode of action at the level of the pheromone biosynthetic pathway. The discussion will also include recent developments concerning events occurring as a result of the transfer of pheromonostatic compounds of male origin after mating.     

RNA interference of PBAN receptor suppresses expression of two fatty acid desaturases in female Plutella xylostella

Pheromone biosynthesis-activating neuropeptide (PBAN) stimulates sex pheromone biosynthesis by activating PBAN receptor (PBANr), which triggers a specific signal transduction in the pheromone gland cells. We have shown that RNA interference (RNAi) of PBANr of Plutella xylostella significantly suppressed pheromone biosynthesis and subsequent mating behavior. In order to assess molecular events occurring downstream of PBAN signaling, we cloned partial sequences of Δ9 and Δ11 fatty acid desaturases of P. xylostella. Phylogenetic analysis indicated that these two desaturase genes were highly clustered with other desaturases associated with sex pheromone biosynthesis in other insects. RT-PCR analysis showed that Δ9 desaturase was dominantly expressed in adult females, whereas Δ11 desaturase was expressed in all P. xylostella developmental stages. When PBANr expression was suppressed by PBANr-RNAi, the treated females also showed significant suppression of expression of both desaturases. These results suggest that expressions of the two desaturases are controlled by PBAN and that the two desaturases may be involved as downstream components in sex pheromone biosynthesis of P. xylostella.     

Pheromonotropic stimulation of moth pheromone gland cultures in vitro

The direct neurohormonal control of pheromone biosynthesis by pheromone biosynthesis activating neuropeptide (PBAN) was demonstrated in Helicoverpa (Heliothis) spp. using pheromone gland cultures in vitro. Pheromone gland activation involved the de novo production of the main pheromone component (Z)-11-hexadecenal as revealed by radio-TLC, radio-HPLC, and radio-GC. Activation was found to be a specific response attributed to pheromone gland cultures alone. Specificity of pheromonotropic activation was demonstrated to be limited to nervous tissue extracts. A sensitive and specific radioimmunoassay was developed using [³H]-PBAN, and the spatial and temporal distribution of PBAN-immunore-activity was studied. PBAN-immunoreactivity in brain complexes was found throughout the photoperiod and in all ages. From the distribution of PBAN-immunoreactivity it appears that PBAN release is affected by photoperiod. Pheromone gland cultures were found to be competent to pheromone production irrespective of age and photoperiod. Therefore, the neuroendocrine control of pheromone production operates at the level of neuropeptide synthesis and/or release and not at the level of the target tissue itself. The involvement of cyclic-AMP as a second messenger system was demonstrated. Brain extracts and PBAN were shown to stimulate dose- and time-dependent changes in intracellular cyclic-AMP levels. The role of cyclic-AMP in this mechanism was further verified by the ability of cyclic-AMP mimetics to mimic the pheromonotropic effect of brain extracts and PBAN. However, dose-response studies using PBAN and a hexapeptide C-terminal fragment of PBAN suggested that PBAN induces a two mechanism response, one occurring at low PBAN concentrations (high affinity receptor) and another at higher PBAN concentrations (low affinity receptor). Further evidence indicating a dual receptor system was obtained with the observation that the active phorbol ester (phorbol-12-myristate 13-acetate), the diacyl-glycerol analog (1,2-dioleolyl-sn-glycerol), and the intracellular calcium ionophore (ionomycin) mimicked the physiological action of PBAN and that lithium chloride had a pheromonostatic effect. The results indicate that pheromone glands also possess receptors that are linked to inositol phosphate hydolysis. © 1994 Wiley-Liss, Inc.     

Ant Trail Pheromone Biosynthesis Is Triggered by a Neuropeptide Hormone

Our understanding of insect chemical communication including pheromone identification, synthesis, and their role in behavior has advanced tremendously over the last half-century. However, endocrine regulation of pheromone biosynthesis has progressed slowly due to the complexity of direct and/or indirect hormonal activation of the biosynthetic cascades resulting in insect pheromones. Over 20 years ago, a neurohormone, pheromone biosynthesis activating neuropeptide (PBAN) was identified that stimulated sex pheromone biosynthesis in a lepidopteran moth. Since then, the physiological role, target site, and signal transduction of PBAN has become well understood for sex pheromone biosynthesis in moths. Despite that PBAN-like peptides (∼200) have been identified from various insect Orders, their role in pheromone regulation had not expanded to the other insect groups except for Lepidoptera. Here, we report that trail pheromone biosynthesis in the Dufour''s gland (DG) of the fire ant, Solenopsis invicta, is regulated by PBAN. RNAi knock down of PBAN gene (in subesophageal ganglia) or PBAN receptor gene (in DG) expression inhibited trail pheromone biosynthesis. Reduced trail pheromone was documented analytically and through a behavioral bioassay. Extension of PBAN''s role in pheromone biosynthesis to a new target insect, mode of action, and behavioral function will renew research efforts on the involvement of PBAN in pheromone biosynthesis in Insecta.     

Regulation of pheromone biosynthesis in the "Z strain" of the European corn borer, Ostrinia nubilalis

The regulation of pheromone biosynthesis by the neuropeptide PBAN in the Z strain of the European corn borer, Ostrinia nubilalis, was investigated using labeled intermediates. Injection of radiolabeled acetate showed PBAN did not influence the de novo synthesis of saturated fatty acids in the gland. When deuterium-labeled myristic acid was topically applied to the gland, females injected with PBAN produced more labeled pheromone than did control females, indicating that PBAN controls one of the later steps of pheromone biosynthesis. Although more myristic acid was Delta11-desaturated in the gland in the presence of PBAN, this was counterbalanced by less Delta11-desaturation of palmitic acid, indicating that desaturase activity did not change overall. This change in flux of myristic acid through to pheromone was shown to be caused by increased reduction of fatty acid pheromone precursors occurring in the presence of PBAN.     

Evidence for two-step regulation of pheromone biosynthesis by the pheromone biosynthesis-activating neuropeptide in the moth Heliothis virescens

The control of pheromone biosynthesis by the neuropeptide PBAN was investigated in the moth Heliothis virescens. When decapitated females were injected with [2-(14)C] acetate, females co-injected with PBAN produced significantly greater quantities of radiolabeled fatty acids in their pheromone gland than females co-injected with saline. This indicates that PBAN controls an enzyme involved in the synthesis of fatty acids, probably acetyl CoA carboxylase. Decapitated females injected with PBAN showed a rapid increase in native pheromone, and a slower increase in the pheromone precursor, (Z)-11-hexadecenoate. Total native palmitate and stearate (both pheromone intermediates) showed a significant decrease after PBAN injection, before their titers were later restored to initial levels. In contrast, the acyl-CoA thioesters of these two saturated fatty acids increased during the period when their total titers decreased. When a mixture of labeled palmitic and heptadecanoic (an acid that cannot be converted to pheromone) acids was applied to the gland, PBAN-injected females produced greater quantities of labeled pheromone and precursor than did saline-injected ones. The two acids showed similar time-course patterns, with no difference in total titers of each of the respective acids between saline- and PBAN-injected females. When labeled heptadecanoic acid was applied to the gland alone, there was no difference in titers of either total heptadecanoate or of heptadecanoyl-CoA between PBAN- and saline-injected females, suggesting that PBAN does not directly control the storage or liberation of fatty acids in the gland, at least for this fatty acid. Overall, these data indicate that PBAN also controls a later step involved in pheromone biosynthesis, perhaps the reduction of acyl-CoA moieties. The control by PBAN of two enzymes, near the beginning and end of the pheromone biosynthetic process, would seem to allow for more efficient utilization of fatty acids and pheromone than control of only one enzyme.     

Neuroendocrine control of pheromone production in moths

In many moth species regulation of pheromone production has been attributed to the timely release of a pheromone biosynthesis activating neuropeptide (PBAN). The gene encoding PBAN has been sequenced in two moth species. Immunochemical studies as well asin situ hybridization and Northern analysis of PBAN encoding mRNA have localized the neuroendocrine cells responsible for the production of PBAN and have traced the neuronal network of PBAN immunoreactivity. Release into the bloodstream has been demonstrated, the target tissue delineated, and the signal transduction pathway and its modulation analyzed. This paper reviews the current status of research concerning the neuroendocrine control of pheromone production in Lepidopterans and presents some recent developments concerning the receptors involved in the pheromonotropic activity. In this study, we report on the use of a biologically active photoaffinity-biotin-labeled derivative of PBAN N-[N-(4-azido-tetrafluorobenzoyl-biocytinyloxyl-succinimide) and show the presence of a protein (estimated molecular weight of 50 kDa) which specifically binds to PBAN in membrane preparations of pheromone glands. Contribution from the Agricultural Research Organization, The Volcani Center, Bet Dagan, Israel. No.2279-E, 1997 series     

Involvement of calcineurin in the signal transduction of PBAN in the silkworm, Bombyx mori (Lepidoptera)

In several moth species sex pheromone production in the pheromone gland is regulated by a neurohormone, pheromone biosynthesis activating neuropeptide (PBAN). In Bombyx mori it is suggested that PBAN, after binding to the cell-surface receptor, primarily activates a plasma membrane receptor-activated Ca2+ channel to increase cytosolic levels of Ca2+, and Ca2+/calmodulin complex directly or indirectly activates a phosphoprotein phosphatase, which in turn elicits activation of acyl CoA reductase (the key enzyme under PBAN control) through dephosphorylation, resulting in pheromone (bombykol) production. The effect of cyclosporin A (CsA) and FK 506, specific inhibitors of calcineurin (phosphoprotein phosphatase 2B) was studied on the sex pheromone production, in B. mori. The in vitro experiments showed that both chemicals exerted a dose-dependent inhibitory action when they were co-incubated with TKYFSPRL amide (Hez-PBAN fragment peptide). Practically, no difference was detected between the two chemicals in the tested doses (0.025-1250 microM). When effects of CsA or FK 506 were studied on cell-free production of bombykol by using microsomal fraction no inhibition was detected. Since microsomal fraction contains the acyl CoA synthetase, the rate-limiting acyl CoA reductase and the precursor, bombykol is produced if supplied with CoA, ATP and NADPH. Thus, the inhibitory action of CsA and FK506 under in vitro conditions should occur before the step of acyl group reduction and the effect is likely to be attributable to the inhibition of calcineurin in the signal transduction cascade mechanism of PBAN, in B. mori. The existence of calcineurin in the pheromone gland by using Western blot analysis is also demonstrated.