Insect ecdysteroids biosynthesis and its regulation by neuropeptides

蜕皮激素是对节肢动物体内类固醇激素的统称,昆虫的蜕皮激素主要由内分泌器官前胸腺合成,具有诱发幼虫周期性蜕皮以及最终变态蜕皮的生理功能.近期的研究工作阐明了前胸腺中原先被称为“黑箱”的一系列酶促反应步骤,此外促前胸腺激素受体的成功鉴定使人们对PTTH信号转导通路调控前胸腺蜕皮激素合成有了更深入的理解.     

桑蚕促前胸腺激素的作用与前胸腺分泌活动的某些特点

本工作以前胸腺的体外器官培养技术和蜕皮激素的放射免疫分析法(MH-RIA)相结合,研究了桑蚕(Bombyx mori)促前胸腺激素(PTTH)的作用与前胸腺分泌的某些特点。结果表明,被PTTH激活后的前胸腺,在一定的时相过程内合成并分泌脱皮甾类激素;前胸腺本体不积累蜕皮甾类激素;PTTH对前胸腺的作用是积累性的;五龄不同天数的前胸腺合成分泌脱皮甾类激素的能力不同,并有不同的剂量反应。     

昆虫促前胸腺激素研究进展

昆虫促前胸腺激素研究进展李毅平龚和（中国科学院动物研究所,北京１０００８０）关键词促前胸腺激素受体信号系统促前胸腺激素（ｐｒｏｔｈｏｒａｃｉｃｏｔｒｏｐｉｃｈｏｒ－ｍｏｎｅＰＴＴＨ）因其促进前胸腺（ＰＧ）合成和分泌蜕皮激素而得名,以前也称为脑激素,因...     

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。     

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…     

东方粘虫末龄幼虫血淋巴蜕皮甾类滴度的变化及促前胸腺激素对前胸腺的活化作用

东方粘虫六龄幼虫血淋巴蜕皮甾类滴度,在幼虫的取食生长期一直处在很低的水平(<6pg/μl血淋巴),其后于徘徊期的前一天开始升高,至预蛹期形成唯一的1个高峰(～450pg/μl血淋巴)。前胸腺离体培养的结果表明,前胸腺分泌活力与血淋巴蜕皮甾类滴度的动态呈基本平行的趋势,只是较后者超前了约24小时。促前胸腺激素粗提物能直接活化离体前胸分泌蜕皮甾类。粘虫六龄2日龄(LVI_2)幼虫的前胸腺已能被促前胸腺激素活化,说明此时的前胸腺对促前胸腺激素已具感受性。     

昆虫蜕皮行为的生理生化和分子生物学研究进展

羽化激素与蜕皮触发激素诱发昆虫蜕皮行为及蜕皮末期的其它生理变化。羽化激素在一些特定的脑神经分泌细胞中合成,在蜕皮激素的调控下,释放到中枢神经系统和血淋巴中。蜕皮触发激素是由Inka细胞分泌的,直接作用于中枢神经系统,触发前蜕皮和蜕皮行为。越来越多的证据表明羽化激素可能存在于所有的昆虫中,并作为一种调节蜕皮的一般性激素机制。     

天蚕卵黄发生的激素调控

报告了蜕皮激素和保幼激素对天蚕Antheraea yamamai卵黄发生的调控作用。当单独以20－羟基蜕皮酮或保幼激素类似物methoprene处理,以及同时用这两种激素处理天蚕蛹时,蛹期脂肪体和血淋巴中卵黄原蛋白（Vg)含量明显高于对照,即二对Vg的合成起促进作用。然而,卵巢中卵黄蛋白（Vt)含量则因激素种类而异,以保幼激素处理时明显低于对照,以20－羟基蜕皮酮处理则反之,即前抑制卵巢对Vg的摄取,而后则起促进作用。离体培养脂肪体并以激素处理的结果表明,20－羟基蜕皮酮和methoprene均能促进Vg合成,但前作用更。综合考虑上述结果可以认为蜕皮激素对该蚕的卵黄发生起主要调控作用。     

蜕皮激素对昆虫生长及生殖过程的调控

蜕皮激素、保幼激素及神经激素在调节昆虫生长及生殖方面起到重要的作用。本文从蜕皮激素的合成过程、其活性形式20羟基蜕皮酮的作用模式、蜕皮激素与保幼激素的相互调节机制这三个方面综述了蜕皮激素在昆虫生长及生殖过程中的调控作用。     

蜕皮激素及其对蟹虾养殖的影响

蜕皮激素及其对蟹虾养殖的影响房凯（四川绵阳师专生物系）（一）蜕应激素概况昆虫和甲壳动物蜕皮激素的研究是本世纪４０年代开始的。当时日本学者福田等人曾对家蚕进行结扎、断头及器官移植等试验,发现蚕的前胸腺的分泌活动与蜕皮及变态有着内在的密切联系。１９５４～...     

Prothoracicotropic Hormone Acts as a Neuroendocrine Switch between Pupal Diapause and Adult Development

Diapause is a programmed developmental arrest that has evolved in a wide variety of organisms and allows them survive unfavorable seasons. This developmental state is particularly common in insects. Based on circumstantial evidence, pupal diapause has been hypothesized to result from a cessation of prothoracicotropic hormone (PTTH) secretion from the brain. Here, we provide direct evidence for this classical hypothesis by determining both the PTTH titer in the hemolymph and the PTTH content in the brain of diapause pupae in the cabbage army moth Mamestra brassicae. For this purpose, we cloned the PTTH gene, produced PTTH-specific antibodies, and developed a highly sensitive immunoassay for PTTH. While the hemolymph PTTH titer in non-diapause pupae was maintained at high levels after pupation, the titer in diapause pupae dropped to an undetectable level. In contrast, the PTTH content of the post-pupation brain was higher in diapause animals than in non-diapause animals. These results clearly demonstrate that diapause pupae have sufficient PTTH in their brain, but they do not release it into the hemolymph. Injecting PTTH into diapause pupae immediately after pupation induced adult development, showing that a lack of PTTH is a necessary and sufficient condition for inducing pupal diapause. Most interestingly, in diapause-destined larvae, lower hemolymph titers of PTTH and reduced PTTH gene expression were observed for 4 and 2 days, respectively, prior to pupation. This discovery demonstrates that the diapause program is already manifested in the PTTH neurons as early as the mid final instar stage.     

In vitro and in vivo stimulation of extracellular signal-regulated kinase (ERK) by the prothoracicotropic hormone in prothoracic gland cells and its developmental regulation in the silkworm, Bombyx mori

In this study, we investigated activation of the extracellular signal-regulated kinase (ERK) by the prothoracicotropic hormone (PTTH) in prothoracic gland cells of the silkworm, Bombyx mori. The results showed that the PTTH stimulated ERK phosphorylation as this depends on time and dose and ecdysteroidogenic activity. The ERK phosphorylation inhibitors, PD 98059 and U0126, blocked both basal and PTTH-stimulated ERK phosphorylation and ecdysteroidogenesis. In addition, activation of glandular ERK phosphorylation by the PTTH appeared to be developmentally regulated with the refractoriness of gland cells to the PTTH occurring during the latter stages of both the fourth and last larval instars. Moreover, in vitro activation of ERK phosphorylation of prothoracic glands by the PTTH was also verified by in vivo experiments: injection of the PTTH into day 6 last instar larvae greatly increased the activity of glandular ERK phosphorylation and ecdysteroidogenesis. These results suggest that development-specific changes in ERK phosphorylation may play a role in PTTH stimulation of ecdysteroidogenesis.     

Rhythmic release of prothoracicotropic hormone from the brain of an adult insect during egg development

Prothoracicotropic hormone (PTTH) is a brain neurohormone that has been studied for over 80 years. The only known target of PTTH is the prothoracic glands (PGs) of larvae, which synthesize the insect molting hormones (ecdysteroids) and a massive literature exists on this axis. The PGs degenerate around the time of adult emergence, yet presence of PTTH has been reported in the brains of several adult insects. Using an in vitro bioassay system, we confirm that PTTH is present in the adult female brain of Rhodnius prolixus. The material is electrophoretically, immunologically and biologically indistinguishable from larval PTTH. The amount of PTTH in the brain shows a daily rhythm during egg development. We show that brains in vitro release PTTH with a daily rhythm over this period of time. PTTH is released at each scotophase. This is the first report that PTTH is released from the adult brain and functions as a hormone, inviting explanation of its function. Larval PTTH is also known to be released with a daily rhythm, and the clock in the brain controls both larval and adult rhythms. The potential significance of rhythmic PTTH release in female adults is discussed in relation to the regulation of ecdysteroids, egg development and the concept of internal temporal order.     

PURIFICATION AND PROPERTIES OF THE PROTHORACICOTROPIC HORMONE OF THE SILKWORM, BOMBYX MORI

A simple and highly reproducible procedure for partial purification of prothoracicotropic hormone (PTTH) was established starting with 96,000 male adult Bombyx heads. Approximately 28,500-fold purification of PTTH was accomplished with a yield of about 50% and 6 ng of the most purified preparation ("highly purified PTTH") caused adult development in a brainless Samia pupa. The peptidal nature of PTTH was reconfirmed through the effects of various enzymatic and chemical treatments on the biological activity of "highly purified PTTH". Gel-filtration indicated the molecular weight of PTTH to be 4,400.     

The Prothoracicotropes: Source of the Prothoracicotropic Hormone

SYNOPSIS. An in vitro assay for the insect prothoracicolropichormone (PTTH) has been developed which measures the rate ofecdysone synthesized by Manduca sexta prothoracic glands (PG)stimulated in vitro by PTTH. This assay has been used to quantifyPTTH in single neurosecretory cells (NSC) resulting in the identificationof one NSC in each hemisphere of the brain as the prothoracicotrope,source of PTTH. The axonal and dendritic distribution of theprothoracicotrope has been determined by cobalt filling withsilver intensification. From a comparison of the titers of PTTHin brains, corpora cardiaca and corpora allata during larval-pupaldevelopment, the corpus allatum has been identifiedas the neurohemalorgan for PTTH. Electron microscopic analyses suggest that theacellular sheath surrounding the corpus allatum contains theaxon terminals of the prothoracicotropes. There is at least one form of PTTH, {small tilde}22,000 molwt (big PTTH), and possibly a smaller form of about 7,000 molwt (small PTTH). Bioassay and PTTH hemolymph titer data duringthe head critical period (HCP) for larval-larval developmentreveal that big PTTH is released as a single peak lasting {smalltilde}6 hr. By contrast, during the first HCP of the last larvalinstar PTTH is released over a period of {small tilde}18 hrin three bursts, but its molecular weight has not been establishedwith certainty. The kinetics of PG activation by these two formssuggest that big PTTH may function to activate the PG dramaticallyand thereby elicit molting, while small PTTH may activate thePG minimally at the time of cellular reprogramming.     

The steroidogenic action of haemolymph stimulatory factor in Manduca sexta: Comparisons with prothoracicotropic hormone

A recently described protein, found in the haemolymph of Manduca sexta larvae, stimulates ecdysone synthesis by both larval and pupal prothoracic glands in vitro. The mode of action of this haemolymph stimulatory factor has been investigated, particularly as it compares to the action of the cerebral neuropeptide, prothoracicotropic hormone (PTTH). Unlike PTTH, the haemolymph factor does not stimulate ecdysone synthesis via an increase in the level of cAMP in the prothoracic glands. The haemolymph factor requires extracellular calcium for maximal stimulation of the prothoracic glands, but in contrast to PTTH, significant activity is retained in calcium-free medium. Exposure of the prothoracic glands to the haemolymph factor results in enhanced steroidogenesis within 1 min. This rapid stimulation contrasts with the 10–20 min lag period observed following PTTH exposure. However, the prolonged activation elicited by brief exposure to PTTH is not observed following exposure of the glands to the haemolymph stimulatory factor. Rather, the factor appears to be required as a sustained stimulus in order to exert its steroidogenic effects. The data indicate that the mode of action of the haemolymph factor is distinctly different from that reported previously for PTTH, and are consistent with the hypothesized role of the factor as a carrier of a sterol precursor utilized in ecdysone synthesis.     

Neurohormonal control of ecdysone production: Comparison of insects and crustaceans

Summary

Ecdysteroid synthesis is regulated in insects by prothoracicotropic hormone (PTTH) and in crustaceans by molt-inhibiting hormone (MIH). These neurohormones exert opposite effects on their respective target tissues, PTTH stimulating the prothoracic glands and MIH inhibiting the Y-organs. The present work reviews recent progress in the neurohormonal regulation of prothoracic gland and Y-organ function. The steroid products of these glands are briefly discussed, as is current information on the structures of PTTH and MIH. Focus is placed on the mechanism of action of these hormones at the cellular level, as well as developmental changes in cellular sensitivity to PTTH. Though exerting different effects on ecdysteroid secretion, both PTTH and MIH increase cyclic nucleotide second messengers, are influenced by alterations in cellular calcium, and are likely to activate protein kinases. The contrasting steroidogenic effects of PTTH and MIH probably arise from differences in the cellular kinase substrates. In insects, such substrates enhance ecdysteroid secretion, possibly by increasing the translation of glandular proteins. In crustaceans, MIH-stimulated changes lead to the inhibition of both protein synthesis and steroidogenesis.     

Prothoracicotropic hormone regulates developmental timing and body size in Drosophila

In insects, control of body size is intimately linked to nutritional quality as well as environmental and genetic cues that regulate the timing of developmental transitions. Prothoracicotropic hormone (PTTH) has been proposed to play an essential role in regulating the production and/or release of ecdysone, a steroid hormone that stimulates molting and metamorphosis. In this report, we examine the consequences on Drosophila development of ablating the PTTH-producing neurons. Surprisingly, PTTH production is not essential for molting or metamorphosis. Instead, loss of PTTH results in delayed larval development and eclosion of larger flies with more cells. Prolonged feeding, without changing the rate of growth, causes the overgrowth and is a consequence of low ecdysteroid titers. These results indicate that final body size in insects is determined by a balance between growth-rate regulators such as insulin and developmental timing cues such as PTTH that set the duration of the feeding interval.     

Some aspects of activity regulation of Galleria mellonella PTTH cells

Using the Galleria prothoracicotropic bioassay, five small neurosecretory cells occurring in each dorsolateral part of protocerebrum of Galleria mellonella brain were identified as prothoracicotropic hormone (PTTH) cells. It was found that the critical period for the release of PTTH from a brain implanted in neck-ligated larva lasts up to the third day after implantation. The content of paraldehyde-fuchsin positive neurosecretory material (NSM) in PTTH cells was determined during the penultimate and last larval instar, during pupal instar, and in starved or poststarvation fed or space-deprived last instar larvae. Two peaks of NSM in PTTH cells were found in the penultimate instar (in freshly molted, and 76-h-old larvae), four peaks in the last instar larvae (in freshly molted, and in 67-, 132-, and 174-h-old larvae), and one peak in the pupal instar (in 56-76-h-old pupae). It was also observed that upon starvation NSM accumulated in PTTH cells, while after 3 h of poststarvation feeding it was released. In permanent space-deprived last instar larvae no NSM occurred in PTTH cells. In all investigated larval instars a rapid release of NSM from PTTH cells was found a few hours after molt associated with the beginning of the feeding period. The significance of the NSM content in PTTH cells is discussed in relation to ecdysteroid titer.