结合反相高效液相色谱和酶联免疫吸附法测定昆虫血淋巴中的蜕皮甾醇激素

【目的】昆虫体内的蜕皮酮和20羟基蜕皮酮(20E)是两种主要的蜕皮甾醇激素,其中蜕皮酮是20E的前体,而20E是有活性的蜕皮甾醇激素。本研究旨在建立一种测定昆虫血淋巴中蜕皮激素高效、稳定、准确的方法。【方法】采集家蚕血淋巴,抽提总蜕皮甾醇激素,利用反相高效液相色谱法(反相HPLC)分离并收集蜕皮酮与20E,进而利用酶联免疫吸附法(ELISA)测定家蚕血淋巴的总蜕皮甾醇激素、蜕皮酮和20E各自的滴度。【结果】计算出总蜕皮甾醇激素中蜕皮酮与20E的比例,推算出蜕皮酮合成和分泌、以及蜕皮酮转化为20E的能力。【结论】该方法高效、稳定、准确,可广泛应用于昆虫蜕皮甾醇激素滴度的测定。     

家蚕蜕皮液蛋白质双向电泳及质谱分析

蜕皮液是存在于新旧表皮之间的一层液体,在昆虫蜕皮和变态发育的过程中发挥了重要的作用。为进一步探究家蚕蜕皮液的功能,利用双向电泳技术对家蚕预蛹期及羽化前期的蜕皮液的蛋白质进行了分析,结果表明,预蛹期及羽化前期的蜕皮液中分别可以检测出超过200个蛋白点,它们主要分布在等电点4-9、分子量10-180 kDa之间。利用MALDI TOF/TOF对羽化前期蜕皮液的42个蛋白点进行了鉴定分析,结果表明34个蛋白点成功得到了鉴定,它们主要包括载脂蛋白类、蛋白酶与蛋白酶抑制剂、免疫相关蛋白、几丁质结合蛋白等,部分蛋白在预蛹期的蜕皮液和羽化前的蜕皮液之间存在明显的差异表达。为了进一步验证蛋白质组分析的结果,对其中1个差异表达明显的蛋白质Apolipoprotein D进行了进一步的分析,Q-PCR的结果表明,该蛋白主要在化蛹第1–4天存在高表达,其在羽化前蜕皮液中的高度累积暗示了它可能参与了家蚕羽化变态的过程。以上研究结果进一步丰富了人们对蜕皮液蛋白质的认识,为深入研究蜕皮液蛋白质的功能提供了一些参考。     

黑胸散白蚁末龄若虫蜕皮羽化行为观察

【目的】了解黑胸散白蚁Reticulitermes chinensis Snyder末龄若虫的蜕皮羽化行为。【方法】室内恒温(26±0.5)℃恒湿(75%±5%)饲养黑胸散白蚁末龄若虫,间隔一定时间进行观察记录。【结果】黑胸散白蚁末龄若虫蜕皮羽化时间持续2~8 h。蜕皮一般从末龄若虫胸腹部交界处背部开始破裂,从腹末、翅末、足端、口器末端或触角端脱落,50%以上的正常羽化蜕皮是从腹末端脱落。初始羽化成虫为白色,随后身体和翅的颜色逐渐加深和变黑,羽化8~12 h后,虫体整体颜色变为黑色。室内观察结果还表明,34.7%的末龄若虫无法正常羽化。【结论】黑胸散白蚁末龄若虫蜕皮羽化持续时间较短,蜕皮一般是从胸腹部交界处背部开始破裂,但可从不同部位脱落,且蜕皮羽化行为容易受到外界环境的影响。     

亚洲玉米螟神经肽羽化激素基因cDNA的克隆及组织表达

羽化激素对调节昆虫的蜕皮和发育起关键作用。亚洲玉米螟Ostrinia furnacalis是亚洲农业重要害虫之一,本实验研究了亚洲玉米螟羽化激素基因cDNA的分子结构和表达模式。利用兼并性引物RT-PCR技术,克隆了亚洲玉米螟羽化激素基因cDNA的中间片段,然后再用RACE方法,获得羽化激素基因的 cDNA全长序列。结果表明： 亚洲玉米螟羽化激素基因cDNA全长986 bp（GenBank登录号： DQ668369）,开放阅读框为267 bp,编码88个氨基酸的前体蛋白,其中包括前26个氨基酸组成的信号肽和62个氨基酸的成熟肽。亚洲玉米螟羽化激素基因与烟草天蛾、棉铃虫和家蚕已报道同源基因的同源性较高,分别为79.5%、77.3%和67.0%,与黑腹果蝇同源基因的同源性最低,仅45.5%。亚洲玉米螟羽化激素基因mRNA只在脑中表达,在咽下神经节、胸神经节、腹神经节等神经组织中检测不到,在非神经组织如中肠、脂肪体和表皮中也不表达。     

甲壳动物蜕皮抑制激素调控机制的研究进展

甲壳动物的蜕皮过程主要是由Y器(Y-organ)分泌的蜕皮类固醇激素与X器-窦腺复合体(X-organ-sinus gland,XO-SG)分泌的蜕皮抑制激素MIH相互拮抗而进行调控的。而MIH调控机制较为复杂,且存在争议。本文就MIH调控机制的研究进展,包括研究方法,以及目前调控机制中争议最大的3个问题:MIH受体、cAMP与cGMP功能以及Ca2+功能作一综述。     

鞭角华扁叶蜂蜕皮甾类激素滴度的变化

用放射免疫分析法测定了鞭角华扁叶蜂Chinolyda flagellicornis末龄幼虫及滞育预蛹血淋巴中蜕皮甾类激素滴度。结果表明,末龄幼虫血淋巴中蜕皮甾类激素滴度在第2和4天各有一高峰;滞育预蛹血淋巴中保持一定滴度的蜕皮甾类激素,并随发育时期的不同有所波动;预蛹化蛹前一周血淋巴中蜕皮甾类激素滴度存在两个与变态相对应的峰值。表明鞭角华扁叶蜂的滞育与蜕皮甾类激素相关。     

昆虫蜕皮的分子机理及应用

昆虫蜕皮是一个由PTTH启始的、激素介导的基因序列表达和相互作用的级联反应过程。阐明昆虫蜕皮的分子机理,不仅可以解释发育生物学的科学问题,为害虫控制提供新的思路,还可以从中发现新的可资生产应用的分子。作者通过蛋白质组学方法从棉铃虫Helicoverpa armigera Hubner蜕皮幼虫鉴定到30个差异表达的蛋白质。通过抑制性消减杂交技术,从棉铃虫蜕皮幼虫、变态决定幼虫和5龄取食幼虫鉴定到100个表达序列标签(EST)。证明其中的11个EST在蜕皮或变态时差异表达。通过RT-PCR方法克隆棉铃虫激素接受子3基因,研究该基因在发育中的表达模式。用该基因构建具有绿色荧光蛋白标记和多角体蛋白的基因重组病毒(AcMNPV-GFP-HHR3-Polh)。实验结果表明,AcMNPV-GFPHHR3-Polh病毒可以通过注射或口服感染棉铃虫,导致棉铃虫幼虫非正常蜕皮、生长延缓、半数存活时间下降。该研究显示昆虫蜕皮功能基因在害虫控制中有很好的应用前景。蜕皮功能基因的表达与调控、蜕皮激素介导的信号转导通路、变态过程中组织解体和重建的分子机理、激素调控基因顺序表达的分子机理、变态起始因子、JH受体等是本领域今后的主要研究方向。     

家蚕蜕皮与变态的内分泌调控

家蚕的蜕皮与变态是由前胸腺分泌的脱皮素（ｍｏｌｔｉｎｇ ｈｏｒｍｏｎｅ或 ｅｃｄｙｓｔｅｒｏｉｄ简称 ＭＨ）及由咽侧体分泌的保幼激素（ｊｕｖｅｎｉｌｅ ｈｏｒｍｏｎｅ）控制的,而促有前胸腺激素（ｐｒｏｔｈｏｒａｃｉｃｏｔｒｏｐｉｃ ｈｏｒｍｏｎｅ,以下简称ＰＴＴＨ）的功能为刺激前胸腺分泌蜕皮素。笔者近１０年来从家蚕内分泌体系的一系列研究中发现,蜕皮素浓度的变化可以通过控制咽侧体的保幼激素的生物合成来影响幼虫发育,而ＰＴＴＨ的信息传递可通过调控前胸腺的功能,进而影响血淋巴中蜕皮素浓度。     

昆虫激素和抗激素类在蚕业上的应用研究进展

控制家蚕幼虫蜕变和变态的内分泌系统是脑一咽侧体一前胸腺。咽侧体分泌的保幼激素（JH）和前胸腺分泌的蜕皮激素（MH）调节着家蚕的幼虫蜕皮、变态等生命现象,而脑分泌的促咽侧体激素和促前胸腺激素又控制着这两种腺体的分泌活动。家蚕的MH和JH的化学结构早在60年代中期被先后阐明,70年代后对这两种主要激素在血淋巴中的浓度已能精确定量,从而阐明了发生幼虫蜕皮和变态的激素环境。与此同时,发现了一些天然化合物能影响家蚕正常的内分泌活动,导致早熟变态和其他生理变化（如体色变化、生有障碍等）,称之为抗激素类物质。家蚕内分…     

棉铃虫蜕皮时期同工酶表达模式

同工酶广泛存在于不同种属生物的组织细胞中,在生物发育的不同阶段有着特定的表达模式和重要的生理功能。昆虫蜕皮是在促前胸腺激素（PTTH）、蜕皮激素和保幼激素共同控制下由一系列基因表达和调控的级联反应。阐明蜕皮发育过程中同工酶的表达模式,可以为研究蜕皮的分子机理提供新的分子靶标,为研制生长调节剂类杀虫剂提供检测的分子标记。该研究分析了棉铃虫Helicoverpa armigera蜕皮时期不同组织中过氧化物酶、乙醇脱氢酶和酯酶的表达模式,找到了3种蜕皮差异表达的过氧化物酶, 2种蜕皮或变态差异表达的乙醇脱氢酶,3种蜕皮差异表达的酯酶。生长调节剂类化学杀虫剂非甾醇类蜕皮激素竞争物RH24-85可以诱导3种酯酶表达上调,可能与蜕皮有关。这些结果为进一步研究棉铃虫蜕皮的分子机理和检测促蜕皮生长调节剂类化学杀虫剂提供了新的分子靶标。     

The roles of central and peripheral eclosion hormone release in the control of ecdysis behavior in Manduca sexta

1. Ecdysis, a behavior by which insects shed the old cuticle at the culmination of each molt, is triggered by a unique peptide hormone, eclosion hormone (EH). In pupal Manduca sexta, EH is released into the hemolymph just prior to ecdysis, and circulating hormone is sufficient to elicit this behavior. 2. Removal of the proctodeal nerves in prepupal animals eliminated the appearance of blood-borne EH, but ecdysis behavior occurred on schedule. Therefore, circulating EH is not necessary for the triggering of ecdysis. 3. In contrast, a set of dermal glands failed to show their expected bout of secretion after proctodeal nerve removal. Injection of exogenous EH rescued this secretion. Thus, circulating EH appears necessary for action on peripheral but not central targets. 4. A major reduction in EH immunostaining is seen in the proctodeal nerves just preceding ecdysis; this coincides with a greater than 90% reduction in extractable EH from this structure and the appearance of circulating EH. A similar, concomitant reduction was seen in central EH cell processes, suggesting release of peptide within the CNS. 5. Antidromic stimulation of the proctodeal nerve stumps following proctodeal nerve removal triggered precocious ecdysis. This result further supports the conclusion that centrally released EH is sufficient to trigger the motor program.     

A command chemical triggers an innate behavior by sequential activation of multiple peptidergic ensembles

BACKGROUND: At the end of each molt, insects shed their old cuticle by performing the ecdysis sequence, an innate behavior consisting of three steps: pre-ecdysis, ecdysis, and postecdysis. Blood-borne ecdysis-triggering hormone (ETH) activates the behavioral sequence through direct actions on the central nervous system. RESULTS: To elucidate neural substrates underlying the ecdysis sequence, we identified neurons expressing ETH receptors (ETHRs) in Drosophila. Distinct ensembles of ETHR neurons express numerous neuropeptides including kinin, FMRFamides, eclosion hormone (EH), crustacean cardioactive peptide (CCAP), myoinhibitory peptides (MIP), and bursicon. Real-time imaging of intracellular calcium dynamics revealed sequential activation of these ensembles after ETH action. Specifically, FMRFamide neurons are activated during pre-ecdysis; EH, CCAP, and CCAP/MIP neurons are active prior to and during ecdysis; and activity of CCAP/MIP/bursicon neurons coincides with postecdysis. Targeted ablation of specific ETHR ensembles produces behavioral deficits consistent with their proposed roles in the behavioral sequence. CONCLUSIONS: Our findings offer novel insights into how a command chemical orchestrates an innate behavior by stepwise recruitment of central peptidergic ensembles.     

The role of eclosion hormone in the larval ecdyses of Manduca sexta

Each larval moult in Manduca sexta consists of an identical series of developmental and behavioural events leading up to ecdysis. Injections of eclosion hormone into staged larvae in any instar resulted in the premature elicitation of the larval pre-ecdysis behaviour, comprising a rhythmic sequence of muscle contractions, followed by the larval ecdysis behaviour.A marked depletion of eclosion hormone stores form the ventral chain of ganglia coincided with each larval ecdysis and in the moult to the fifth instar, eclosion hormone activity appeared in the blood at the onset of the pre-ecdysis behaviour.Responsiveness to eclosion hormone for pre-ecdysis and ecdysis behaviour developed about 12 and 6 hr before normal ecdysis, respectively. Elicitation of ecdysis behaviour by exogenous hormone inhibited both subsequent behavioural responses to eclosion hormone and endogenous hormonal release.In conclusion, the behavioural programme involved in each larval ecdysis appears to be controlled by the eclosion hormone.     

Structure-activity relationship of ETH during ecdysis in the tobacco hornworm, Manduca sexta

In insects, ecdysis or shedding of the old cuticle, consists of a series of behaviors that are regulated by the coordinated actions of a number of neuropeptides, one of which is ecdysis triggering hormone (ETH). ETH acts directly on central pattern generators of the abdominal ganglia to trigger onset of pre-ecdysis behaviors, as well as indirectly to activate release of eclosion hormone, thereby inducing onset of ecdysis behaviors through a cGMP-mediated mechanism. We assessed the minimal C-terminal amino acids required for biological activity of ETH, by assessing: (i) onset of pre-ecdysis and ecdysis behaviors in vivo, after injection of peptide analogs, (ii) onset of fictive pre-ecdysis and ecdysis motor patterns in vitro, as recorded extracellularly, after incubation of the CNS with the peptide analogs, and (iii) accumulation of cGMP within cells of the abdominal ganglia, as assessed immunohistochemically. Amidation of ETH at the C-terminus was required to elicit a biological response in vivo and in vitro, as well as an accumulation of cGMP within the CNS. The five amino acid amidated C-terminus of ETH (NIPRMamide) was the minimal moiety able to induce a robust pre-ecdysis response in vivo and in vitro, while a seven amino acid core (NKNIPRMa) was required for induction of ecdysis, including accumulation of cGMP immunoreactivity within the CNS. Analogs smaller than 12 amino acids in length were only active at very high concentrations in vivo, suggesting that smaller fragments might be susceptible to hemolymph degradation. Some alanine substitutions or removal of internal amino acids altered the activity of ETH, as well as the time of onset of ecdysis behaviors, suggesting that internal amino acids play a role in maintaining proper folding of the peptide for successful binding or activity at the ETH receptor.     

Signal transduction in eclosion hormone-induced secretion of ecdysis-triggering hormone

Inka cells of insect epitracheal glands (EGs) secrete preecdysis and ecdysis-triggering hormones (PETH and ETH) at the end of each developmental stage. Both peptides act in the central nervous system to evoke the ecdysis behavioral sequence, a stereotype behavior during which old cuticle is shed. Secretion of ETH is stimulated by a brain neuropeptide, eclosion hormone (EH). EH evokes accumulation of cGMP followed by release of ETH from Inka cells, and exogenous cGMP evokes secretion of ETH. The secretory responses to EH and cGMP are inhibited by the broad-spectrum kinase inhibitor staurosporine, and the response to EH is potentiated by the phosphatase inhibitor calyculin A. Staurosporine did not inhibit EH-evoked accumulation of cGMP. Changes in cytoplasmic Ca2+ in Inka cells during EH signaling were monitored via fluorescence ratioing with fura-2-loaded EGs. Cytoplasmic Ca2+ increases within 30-120 s after addition of EH to EGs, and it remains elevated for at least 10 min, corresponding with the time course of secretion. Secretion is increased in dose-dependent manner by the Ca2+-ATPase inhibitor thapsigargin, a treatment that does not elevate glandular cGMP above basal levels. The secretory response to EH is partially inhibited in glands loaded with EGTA, while cGMP levels are unaffected. These findings suggest that EH activates second messenger cascades leading to cGMP accumulation and Ca2+ mobilization and/or influx and that both pathways are required for a full secretory response. cGMP activates a staurosporine-inhibitable protein kinase. We propose that Ca2+ acts via a parallel cascade with a time course that is similar to that for cGMP activation of a cGMP-dependent protein kinase.     

Invariant association of ecdysis with increases in cyclic 3′,5′-guanosine monophosphate immunoreactivity in a small network of peptidergic neurons in the hornworm, Manduca sexta

At the end of each molt insects shed their old cuticle by performing the stereotyped behavior of ecdysis. In the moth, Manduca sexta, this behavior is triggered by the neuropeptide eclosion hormone (EH). Insights into the mechanism of action of EH have come from the identification of a small network of peptidergic neurons that shows increased cyclic 3′,5′-guanosine monophosphate (cGMP) immunoreactivity at ecdysis in insects from many different orders. Here we present further evidence that strengthens the association between ecdysis and the occurrence of this cGMP response in Manduca. We found that the cGMP increases occurred at every ecdysis, although some of the neurons that showed a response at larval ecdysis did not participate at pupal and adult ecdysis. Both ecdysis and the cGMP increases only required an intact connection with the brain for the first 30 min after EH injection. Interestingly, ecdysis in debrained animals only occurred if the cGMP response had been initiated, suggesting that the onset of this response marks the time at which the central nervous system is first able to drive ecdysis. Finally, we found that the appearance of sensitivity to EH for triggering the cGMP response coincided with the time at which EH first triggers ecdysis. Accepted: 6 May 1997     

Deletion of the ecdysis-triggering hormone gene leads to lethal ecdysis deficiency.

At the end of each developmental stage, insects perform a stereotypic behavioral sequence leading to ecdysis of the old cuticle. While ecdysis-triggering hormone (ETH) is sufficient to trigger this sequence, it has remained unclear whether it is required. We show that deletion of eth, the gene encoding ETH in Drosophila, leads to lethal behavioral and physiological deficits. Null mutants (eth(-)) fail to inflate the new respiratory system on schedule, do not perform the ecdysis behavioral sequence, and exhibit the phenotype buttoned-up, which is characterized by incomplete ecdysis and 98% mortality at the transition from first to second larval instar. Precisely timed injection of synthetic DmETH1 restores all deficits and allows normal ecdysis to occur. These findings establish obligatory roles for eth and its gene products in initiation and regulation of the ecdysis sequence. The ETH signaling system provides an opportunity for genetic analysis of a chemically coded physiological and behavioral sequence.     

Dynamics and metamorphosis of an identifiable peptidergic neuron in an insect

Eclosion hormone (EH) is a 7000 Da peptide that triggers ecdysis behavior in insects. In the moth, Manduca sexta, EH is found in two pairs of ventromedial (VM) cells in the brain which send their axons down the ventral nerve cord to a neurohemal site in the proctodeal nerve in the larva and pupa. During adult development, these cells send axon collaterals to the corpora cardiaca where they form a new release site used for adult eclosion. Studies of bioassayable peptide during the 5th larval instar and the larval-pupal transformation revealed that after depletion at ecdysis, the VM cells showed a transient increase in EH found in their cell bodies and axons. By contrast, their terminals in the proctodeal nerve showed a gradual accumulation of peptide followed by a release of over 90% of the stored material at pupal ecdysis. In situ hybridization analysis on whole mounts of the brains showed that the VM cells always contained EH mRNA with increased accumulation during the larval and pupal molting periods with a slight decline just before ecdysis. High levels of EH mRNA were found in brains of diapausing pupae. During the first two-thirds of adult development, mRNA accumulated to high levels, then slowly declined until ecdysis. EH mRNA levels up to 3 days after adult eclosion. At no time was EH mRNA found in the lateral neurosecretory cell cluster previously reported to produce EH for adult eclosion. 1994 John Wiley & Sons, Inc.     

Steroid induction of a peptide hormone gene leads to orchestration of a defined behavioral sequence.

At the end of each molt, insects shed the old cuticle by performing preecdysis and ecdysis behaviors. Regulation of these centrally patterned movements involves peptide signaling between endocrine Inka cells and the CNS. In Inka cells, we have identified the cDNA and gene encoding preecdysis-triggering hormone (PETH) and ecdysis-triggering hormone (ETH), which activate these behaviors. Prior to behavioral onset, rising ecdysteroid levels induce expression of the ecdysone receptor (EcR) and ETH gene in Inka cells and evoke CNS sensitivity to PETH and ETH. Subsequent ecdysteroid decline is required for peptide release, which initiates three motor patterns in specific order: PETH triggers preecdysis I, while ETH activates preecdysis II and ecdysis. The Inka cell provides a model for linking steroid regulation of peptide hormone expression and release with activation of a defined behavioral sequence.