家蝇卵巢摄取卵黄蛋白的机理

在家蝇Musca domestica viaina 的卵黄发生过程中,卵母细胞摄取卵黄原蛋白与滤泡开放是相关的。观察不同发育时期的家蝇滤泡结果表明,在摄取活动最旺盛的时期也就是卵黄发生的顶盛时期,其滤泡开放程度最大,而在卵黄发生前期和后期基本上没有摄取活动,此时的滤泡上皮细胞间不开放。卵巢体外培养的激素处理表明,JH可以促进滤泡开放。家蝇卵巢微粒体制备物的Na⁺-K⁺ATP酶活力在卵巢发育过程中存在着动态变化。羽化后24小时时有一定的酶活性,随着卵黄发生的进行,酶活力逐渐增加,到羽化48小时时酶活力最高,然后又开始下降,到羽化72小时时已经很小。羽化32小时的家蝇点滴或注躬 JH之后,测得的卵巢微粒体制备物的Na⁺-K⁺ATP酶活力比正常羽化36小时的高,羽化44小时的家蝇点滴和注射JH之后,测得酶活力比正常羽化48小时的低。羽化36小时和48小时的家蝇卵巢微粒体制备物与JH共同作用后,其Na⁺-K⁺ATP酶的活力分别增加2.95倍和3.50倍,羽化48小时的家蝇卵巢在含有JH的培养液中培养启,其匀浆液的酶活性为对照组的1.26倍。 由此我们可以推测在家蝇的卵黄发生过程中,JH通过促进滤泡开放和增加卵巢微粒体制备物Na⁺-K⁺ATP酶的活力,从而调控卵母细胞对卵黄蛋白的摄取。     

外源保幼激素对异色瓢虫卵巢发育及生殖相关基因转录水平的影响

【目的】本研究旨在明确外源保幼激素(juvenile hormone, JH)对异色瓢虫Harmonia axyridis成虫卵巢发育以及生殖信号通路中关键基因转录水平的影响。【方法】以萝卜蚜Lipaphis erysimi饲喂的异色瓢虫雌成虫为空白对照组,以点滴同体积丙酮的雌成虫为溶剂对照组,对人工饲料饲喂的羽化后第2天的雌成虫点滴不同剂量(80, 120和160 ng/头)JHⅢ1, 3, 5, 7和9 d后,解剖成虫卵巢,拍照并测量卵巢长度及其第一卵室的长度和宽度。利用qPCR分析在最适JHⅢ剂量(120 ng/头)处理后1, 5和9 d的异色瓢虫雌成虫生殖信号通路中关键基因JH受体methoprene-tolerant (Met)基因、krüppel homolog 1 (Kr-h1)基因、卵黄原蛋白(vitellogenin, Vg)基因(Vg1和Vg2)和卵黄原蛋白受体(vitellogenin receptor, VgR)基因表达水平。【结果】与溶剂对照组相比,点滴80和120 ng/头剂量JHⅢ可促进异色瓢虫成虫卵巢发育,其中120 ng/头剂量JHⅢ处理羽化后第2天雌...     

七星瓢虫雌成虫卵巢发育不同阶段体内保幼激素的含量

本文以大蜡螟Galleria mellonella(L.)为生测昆虫,应用蜡测定法(Wax test)测定了取食天然食物及人工饲料的七星瓢虫雌成虫在不同卵巢发育阶段体内保幼激素(JH)的含量。取食蚜虫者羽化后8日左右(卵巢管内出现第三卵母细胞,卵黄大量沉积即将排卵),雅虫JH含量达到高峰(593.3G.U.),但一经开始排卵(羽化后约10日左右)保幼激素的含量猛然下降。直至持续产卵达10次的雌虫(羽化后约25日)JH含量仍保持在比较平稳的状态。取食人工饲料者卵巢发育缓慢,羽化30日后不产卵个体的JH水平仍很低,仅及取食蚜虫组高峰的1/6。这一结果证实了JH对七星瓢虫雌成虫卵巢发育及排卵的调控,也指出了取食人工饲料的雌虫产卵率及产卵量明显偏低的重要原因。 在应用蜡测法的过程中肯定了JH浓度与大蜡螟蛾中胸背板保持的部分蛹皮面积之部的关系。     

七星瓢虫雌成虫咽侧体的活性

以短期体外放射化学测定法测定了七星瓢虫雌成虫的咽侧体(CA)活性。结果表明,七星瓢虫的CA在TC 199培养液中培养时活性最高。在最适培养条件下CA合成保幼激素(JH)的速度在1—4小时呈直线增加。 七星瓢虫雌虫生殖期CA的活性变化与卵黄发生有相关性。羽化初期CA活性很低,羽化后4—8天CA活性增加,卵母细胞内卵黄沉积开始增多;羽化后8—12天CA活性高峰出现,此时卵母细胞内有大量卵黄沉积;羽化后12—15天CA活性下降,卵完全成熟并陆续出现产卵个体。 食料对七星瓢虫成虫的卵黄发生的影响:取食人工饲料雌虫的CA活性增长缓慢,直至羽化后15天CA活性仍很低,因而抑制了卵黄原蛋白的合成,使卵巢发育缓慢。此种雌虫中CA活性高峰的出现比取食蚜虫的延迟约2倍,前者的产卵前期也较后者延长约2倍。     

家蝇卵巢摄取卵黄蛋白的机理

在家蝇Ｍｕｓｃａ　ｄｏｍｅｓｔｉｃａ　ｖｉａｉｎａ的印黄发生过程中,卵母细胞摄取卵黄原蛋白与滤沟开放是相关的。观察不同发育时期的家蝇滤泡结果表明,在摄取活动最旺盛的时期也就是卵黄发生的顶盛时期,其滤泡开放程度最大,而在卵黄发生前期和后期基本上没有摄取活动,此时的滤泡上皮细胞间不开放。卵巢体外培养的激素处理表明,ＪＨ可以促进滤泡开放。家蝇卵巢微粒体制备物的Ｎａ＋－Ｋ＋ＡＴＰ酶活力在卵巢发育过程中存在着动态变化。羽化后２４小时时有一定的酶活性,随着卵黄发生的进行,酶活力逐渐增加,到现化４８小时时酶活力最高,然后又开始下降,到弱化７２小时时已经很小。羽化３２小时的家蝇点滴或注射ＪＨ之后,测得的卵巢微粒体制备物的Ｎａ＋－Ｋ＋ＡＴＰ酶活力比正常羽化３６小时的高,羽化率４４小时的家蝇点滴和注射ＪＨ之后,测得酶活力比正常羽化４８小时的低．羽化３６小时和４８小时的家蝇卵巢微粒体制备物与ＪＨ共同作用后,其Ｎａ＋－Ｋ＋ＡＴＰ酶的活力分别增加２．９５倍和３．５０倍,羽化４８小时的家蝇卵巢在含有ＪＨ的培养液中培养后,其匀浆液的酶活性为对照组的１．２６倍。由此我们可以推测在家蝇的卵黄发生过程中,ＪＨ通过促进滤泡开放和增加卵巢微粒体制     

家蝇的卵黄发生及其激素调节

用5—15%SDS-PAGE分析表明,家蝇Musce domestica viaina卵黄蛋白由三个亚基组成,其亚基分子量分别为58KD、50KD、48KD.火箭免疫电泳的结果表明,脂肪体、血淋巴和卵巢内卵黄原蛋白的变化具有密切的相关性,卵黄原蛋白在体内最早出现在羽化后30小时左右,然后迅速增加,在羽化后48小时,脂肪体和血淋巴中卵黄原蛋白含量达到最大值,卵巢开始沉积卵黄蛋白在羽化后30小时,到产卵前达到最大值,脂肪体在离体培养条件下,通过测定³H-亮氨酸掺入卵黄原蛋白的量,对不同发育时期家蝇脂肪体合成卵黄原蛋白的能力及激素的调节作用进行了研究,结果表明,羽化12小时后,合成能力迅速上升,48小时时形成高峰,60小时后迅速下跌直至产卵,其合成能力一直维持在低水平,产卵后合成能力又迅速回升,激素处理结果表明,保幼激素可以促进卵黄发生前期和后期家蝇脂肪体的卵黄原蛋白合成,20-羟基蜕皮酮可以大幅度促进卵黄发生期家蝇脂肪体的卵黄原蛋白合成.当二种激素共同处理时,对卵黄发生前期和卵黄发生期的家蝇脂肪体有协同促进作用,而对卵黄发生后期的脂肪体没有这种作用.本文还对家蝇卵黄发生过程中脂肪体、血淋巴和卵巢三者之间的关系及家蝇卵黄发生的激素调节进行了讨论.     

昆虫保幼激素生物合成的调节与测定

<正> 保幼激素(JH)是由昆虫的咽侧体(CA)产生。它调节着发育和生殖。从昆虫中已分离出3种具有JH活性的化合物,分别称为JH1、JH2、JH3。它们的生理活性大不相同。JH3是大部分成虫的主要激素,可促进卵巢的发育,所以是一种促性腺激素。JH1和JH2主要在鳞翅目幼虫和蜚蠊若虫内,它们在变态开始就参与这一过程的调节作用,称为变态激素。     

抑卵激素对家蝇卵巢周期性发育的调控

抑卵激素是调控家蝇Musca dorncstica vicina卵巢周期性发育的关键因子之一。在家蝇中,当第一个周期的卵母细胞处于卵黄发生期或卵黄发生后期时,其第二个周期的卵母细胞的发育不进入卵黄发生期。本文建立了家蝇抑卵激素的生物测定方法,即用一对卵巢提取物注射1头羽化后12h家蝇,并在羽化后60h观察卵母细胞的发育及卵黄蛋白的沉积情况。抑卵激素的作用首先是延缓了卵母细胞在卵黄发生前期的发育;其次,抑卵激素抑制脂肪体中卵黄蛋白的合成,导致血淋巴中卵黄蛋白含量的下降,从而抑制了卵母细胞的发育。抑卵激素并不抑制卵母细胞对卵黄原蛋白的摄取。卵发育神经激素可以颉抗抑卵激素的抑制作用。抑卵激素无种属特异性。     

昆虫保幼激素的生殖调控机制研究进展

保幼激素（Juvenile hormone,JH）是昆虫特有的一类倍半萜烯类激素。JH在幼/若虫中主要通过拮抗蜕皮激素20E信号影响变态发育,从而维持昆虫幼虫性状。JH在成虫中作为促性腺激素,通过调控雌雄一系列生理和行为促进生殖。JH信号调控雌性生殖主要包括促进卵巢卵子发生、卵黄发生、排卵、滞育、雌性性信息素合成、肠道和卵巢等器官的大小适应性调整等。JH信号促进雄性生殖,主要包括促进附性腺精液蛋白的合成、羽化后调节雄性性行为,进而促进生殖。本文从雌雄性昆虫角度分别阐述JH信号调控生殖的机制,以期为深入探明JH调控昆虫生殖的作用机制提供参考。     

型变过程中亚洲小车蝗体内保幼激素滴度及其代谢相关基因表达量的变化

【目的】本研究旨在明确亚洲小车蝗Oedaleus asiaticus在不同发育阶段和型变过程中的保幼激素(juvenile hormone, JH) JHⅢ滴度及其代谢相关基因表达量的变化情况，为阐明保幼激素调控亚洲小车蝗型变中的生理功能奠定基础。【方法】采用高效液相色谱法测定散居型和群居型亚洲小车蝗不同发育阶段(4和5龄若虫及1, 4, 7, 10, 13和20日龄成虫)和3龄若虫群居化处理1, 3, 5和7 d时亚洲小车蝗血淋巴中的保幼激素JHⅢ的滴度变化；用qRT-PCR检测在群居化处理亚洲小车蝗3龄若虫1, 3, 5和7 d时保幼激素代谢相关的3种基因保幼激素酯酶(juvenile hormone esterase, JHE)基因、保幼激素甲基转移酶(juvenile hormone methyltransferase, JHAMT)基因和保幼激素环氧水解酶(juvenile hormone epoxide hydrolase, JHEH)基因的表达量；利用JHⅢ浸液处理散居型亚洲小车蝗3龄若虫后进行群居化处理，测定亚洲小车蝗型变率。【结果】JHⅢ在亚洲小车蝗血淋巴中的滴度甚微...     

Fungal Metabolism of trans-2-Octenoic Acid

Juvenile hormone esterases (JHEs) function in juvenile hormone (JH) degradation. In the silkworm, Bombyx mori, we have characterized authentic JHE (Bmjhe) and five other carboxyl/cholinesterase (CCE) genes (Bmcce-1 to -5) with GQSAG, a motif sequence of JHE. But none of the genes appeared to function in vivo as a JHE, except for Bmjhe. Recently it was reported that the GQSAG motif might be dispensable, and that the Thr-316 residue has functional significance for JHE activity. On the basis of these findings, we identified two novel JHE candidates, Bmcce-6 and Bmcce-7, that lack GQSAG but possess Thr-316. In the CCE phylogenetic tree, BmCCE-6 was close to the lepidopteran JHE cluster, while BmCCE-7 constituted the same cluster as pheromone-degrading esterases. The developmental expression profiles were different among Bmjhe, Bmcce-6, and Bmcce-7. None of the proteins hydrolyzed JH in vitro. Our results suggest that only one CCE (BmJHE) functions as JHE in the silkworm.     

In silico and bio assay of juvenile hormone analogs as an insect growth regulator against Galleria mellonella (wax moth) – Part I

Juvenile hormone (JH) analogs are nowadays in use to control harmful pests. In order to develop new bioactive molecules as potential pesticides, we have incorporated different active structural features like sulfonamide, aromatic rings, amide group, and amino acid moiety to the base structure. We have screened a series of designed novel JH analogs against JH receptor protein (jhbpGm-2RCK) of Galleria mellonella in comparison to commercial insect growth regulators (IGRs) – Pyriproxyfen (T₁) and Fenoxycarb (T₂). All analogs exhibit the binding energy profile comparable to commercial IGRs. Based upon these results, a series of sulfonamide-based JHAs (T₃–T₈) as IGRs have been synthesized and characterized. Further, the efficacy of synthesized analogs (T₃–T₈) and commercial IGRs (Pyriproxyfen and Fenoxycarb) has been assessed against fourth instars larvae of G. mellonella under the laboratory conditions. LC₅₀ values of all the analogs (T₁–T₈) against the fourth instars larvae were 9.99, 10.12, 24.76, 30.73, 38.45, 34.15, 34.14, 19.48 ppm and the LC₉₀ 153.27, 131.69, 112.15, 191.46, 427.02, 167.13, 217.10, 172.00 ppm, respectively. Among these analogs, N-(1-isopropyl-2-oxo-3-aza-3-N-ethyl-pentanyl)-p-toluene sulfonamide (T₈) and N-(1-isopropyl-2-oxo-3-aza-3-N-ethyl-pentanyl) benzene sulfonamide (T₇) exhibited the good pest larval mortality at different exposure periods (in hours) and different concentrations (in ppm) in comparison to in use IGRs- T₁ and T₂. Bio assay results are supported by docking at higher concentration. The present investigation clearly exhibits that analog T₈ could serve as a potential IGR in comparison to in use IGRs (T₁ and T₂). The results are promising and provide new array of synthetic chemicals that may be utilized as IGRs.     

The source and action of head factors regulating juvenile hormone esterase in larvae of the cabbage looper, Trichoplusia ni

Brain (median or lateral regions) or suboesophageal ganglion (SOG) homogenates of Day 1 fifth instar larvae of Trichoplusia ni induced the appearance of haemolymph juvenile hormone esterase (JHE) when injected into Day 1, Day 2 or early Day 4 fifth instar ligated hosts. Brain and SOG homogenates of late fourth instars also induced JHE when injected into Day 1 hosts, whole late fifth instar and pupal tissue did not. The pattern of JHE induction by early fourth through Day 3 fifth instar brain and SOG homogenates correlated with natural haemolymph JHE activity occurring at these times. Implantation of late fourth and Day 1 fifth instar brains and/or SOG into similar age hosts similarly induced JHE activity while prothoracic and abdominal ganglia did not. The relative levels of induction following implantation were SOG<brain<brain+SOG. JHE activity which appears in the haemolymph following injection of brain homogenates appears to be largely due to a single enzyme which has an isoelectric point indistinguishable from that of the natural haemolymph enzyme. Evidence is presented which suggests that inhibitory as well as stimulatory brain factors are involved in JHE regulation.     

A novel geminal diol as a highly specific and stable in vivo inhibitor of insect juvenile hormone esterase

Thio-containing and acetylenic trifluoromethyl ketones were potent inhibitors of insect juvenile hormone (JH) esterase with greater inhibitory activity than aliphatic and α,β-unsaturated homologs. Octylthio-1,1,1-trifluoropropan-2-one was the most potent inhibitor with the greatest equilibrium hydration constant in pure water. However, a keto/hydrate equilibrium was not necessary for JH esterase inhibition. The carbonyl tautomer of 1-octyl [1-(3,3,3-trifluoropropan-2,2- dihydroxy)] sulfone (OTPdOH-sulfone) was not detectable, and yet OTPdOH-sulfone was a potent in vitro inhibitor of JH esterase with an I₅₀ of 1.2 nM. The mechanism of JH esterase inhibition by these compounds is discussed. OTPdOH-sulfone inhibited JH esterase with minimal activity toward insect 1-naphthyl acetate esterase and electric eel acetylcholinesterase. The inhibitor was also active in vivo, selective for JH esterase, and persistent for over 32 h. OTPdOH-sulfone when topically applied to larval and adult cabbage loopers, Trichoplusia ni, elicited juvenoid activity apparently because of the specific in vivo inhibition of JH metabolism. Arch. Insect Biochem. Physiol. 36:165–179, 1997. © 1997 Wiley-Liss, Inc.     

Juvenile hormone esterases in diapause and nondiapause larvae of the European corn borer, Ostrinia nubilalis

Haemolymph levels of juvenile hormone esterase, 1-naphthyl acetate esterase, and juvenile hormone were measured in synchronously staged diapause and nondiapause larvae of the European corn borer, Ostrinia nubilalis. Juvenile hormone esterase levels were monitored using juvenile hormone I as a substrate while juvenile hormone titres were measured with the Galleria bioassay. Haemolymph of nondiapause larvae showed two peaks of juvenile hormone hydrolytic activity: one near the end of the feeding phase and a smaller one just prior to pupal ecdysis. These peaks of enzyme activity correlated well with the low levels of haemolymph juvenile hormone. Juvenile hormone titres were high early in the stadium then showed a second peak during the prepupal stage coinciding with low esterase activity. Diapause haemolymph had peak juvenile hormone esterase activity nearly 4 times the nondiapause level, reaching a peak near the end of the feeding phase. Diapause-destined larvae retained high juvenile hormone titres even during the rise of the high esterase levels. 1-naphthyl acetate esterase levels did not correlate with the juvenile hormone esterase levels in either the diapause or nondiapause haemolymph. High levels of 1-naphthyl acetate esterase activity were associated with moulting periods.     

保幼激素的代谢

保幼激素的代谢由保幼激素酯酶、保幼激素环氧水解酶和保幼激素二醇激酶等共同催化完成。在这些代谢酶的作用下,保幼激素代谢成保幼激素酸、保幼激素二醇、保幼激素酸二醇和保幼激素二醇磷酸。作者总结了保幼激素代谢的研究方法;按实验室和昆虫种类为线索,归纳和概括了每一种保幼激素代谢酶的研究进程;对保幼激素酯酶和保幼激素环氧水解酶作了序列分析;最后对保幼激素的代谢研究进行了展望。     

Juvenile hormone acid methyltransferase activity in imaginal discs of Manduca sexta prepupae

The occurrence of a peak of juvenile hormone (JH) during the prepupal period has been noted in several lepidopterans. In Manduca sexta and Hyalophora cecropia this peak is known to prevent the precocious onset of adult differentiation in imaginal tissues. However, it has previously been observed in our laboratory that corpora allata (CA) of this age are incapable of making JH owing to a lack of the terminal synthetic enzyme, juvenile hormone acid methyltransferase (JHAMT). Since the CA are required for normal pupation, it is likely that JH acid is the product released by the prepupal CA. Therefore, we analyzed whether JH acid treatment would prevent precocious adultoid differentiation in allatectomized M. sexta larvae. JH acid injections were found to be as effective as JH in normalizing pupation, and acted in a time- and dose-dependent manner. This finding led to a question of whether injected or endogenous JH acid could be methylated to JH. Homogenates of several tissues from prepupae were assayed for the presence of JHAMT. Of the tissues assayed, only imaginal discs possessed significant levels of the enzyme. These results support our previously proposed mechanism for production of the prepupal JH peak in M. sexta.     

Induction and regulation of juvenile hormone esterases during the last larval instar of the cabbage looper, Trichoplusia ni

Juvenile hormone esterase titres were monitored in gate I and gate II last instar larvae of Trichoplusia ni using JH III as substrate. Two peaks of activity were observed for both gate I and gate II larvae, although the first and second juvenile hormone esterase peaks for the gate II larvae are extended and delayed one day, respectively. Head or thoracic ligations before the prepupal stage lower or block the appearance of both esterase peaks. Juvenile hormone I and II, as well as homo and dihomo juvenoids can induce the second juvenile hormone esterase peak in both normal and ligated larvae, and increase the esterase titre during the first peak in nonligated larvae. Induction of the juvenile hormone esterases is possible in non-ligated larvae as soon as the moult to the last instar has occurred and in ligated larvae as soon as the first esterase peak has started to decline. Distinct mechanisms of regulation are present for the first and second juvenile hormone esterase peaks. Juvenile hormone does not appear to be involved in regulating its own metabolism by directly inducing the first esterase peak; however, evidence is consistent with a brief burst of juvenile hormone which occurs prior to pupation inducing the production of the second peak of juvenile hormone esterase activity.     

JUVENILE HORMONE BINDING PROTEIN IN THE OVARIES OF HOUSEFLY MUSCA DOMESTICA VACINA

Abstract  By using charcocal binding assay, the juvenile hormone binding protein (JHBP) was determined in the ovaries of houseflies. This ovarian JHBP possesses high affinity with juvenile hormone III (JH III) and has a K_d of 2.1 III 10^--⁸ M. The binding of ³H-juvenile hormone III (³H-JH III) to this protein was inhibited by unlablled JH III, but not by juvenile hormone analog ZR 512 or ZR 515. The level of this ovarian JHBP reached the highest in houseflies 48 h after emergence, and was 6. 5-fold and 15. 5-fold higher than that in housefIies 60 h and 72 h after emergence, respectively. No binding activity was detected in the ovaries of houseflies 24 h or 36 h after emergence. The absence of JHBP in the ovaries of houseflies 36 h after emergence could be reversed by applying JH III to newly emerged houseflies. The data suggest that the fluctuation of the JHBP concentration might associate with the action of juvenile hormone (JH) on housefly vitellogenesis.     

Effects of juvenile hormone I and the anti-juvenile hormone fluoromevalono-lactone on development and juvenile hormone esterase activity in post-feeding last-stadium larvae of Trichoplusia ni (Hübner)

Treatment of post-feeding (early day 3; wandering phase) last-stadium larvae of the cabbage looper, Trichoplusia ni, with the anti-juvenile hormone, fluoromevalonolactone, prevented the normal ecdysis to the pupa. It caused the formation of larval-pupal intermediates, a dose-dependent delay in the time of tanning, and a decrease in juvenile hormone esterase activity at the time of the prepupal juvenile hormone esterase peak. Fluoromevalonolactone was inactive as juvenile hormone esterase inhibitor in vitro. Conversely, juvenile hormone I accelerated the time of tanning, induced the early appearance of juvenile hormone esterase activity, and prevented adult eclosion. Although most of the larvae that were treated with fluoromevalonolactone immediately after the prepupal burst of juvenile hormone (late on day 3; post-spinning phase) still became larval-pupal intermediates, the time of tanning and juvenile hormone esterase activity were close to normal. Topical treatment of day-3 larvae with radiolabelled juvenile hormone I resulted in the rapid appearance and decline of radiolabelled juvenile hormone I in the haemolymph which was associated with the increased production of juvenile hormone I acid and the induced appearance of juvenile hormone esterase activity. Thus, in post-feeding last-stadium larvae of T. ni, juvenile hormone seems to be necessary for the proper formation of the pupa. Juvenile hormone is also involved in determining the time of pupation, and it appears to induce its own degradation.