昆虫变态发育类型与调控机制

昆虫变态发育使得昆虫成为地球上种类最多、分布最广的动物种群。它特指末龄幼虫化蛹,或者蛹向成虫的转变过程。根据变态剧烈程度,可将昆虫变态发育简单分为增节变态、表变态、原变态、不完全变态及全变态5种类型。此外,昆虫变态发育是一个极其复杂的生物学过程,受到激素、基因、营养等多种因素的精密调控。本文简要介绍了昆虫变态发育的类型和分子调控机理方面的研究进展。     

昆虫变态发育的激素和营养调控研究进展与展望

变态发育是促进昆虫进化和多样性形成的重要因素之一。昆虫变态发育主要受到蜕皮激素和保幼激素的协同调控,通过信号通路诱导下游基因表达,保证蜕皮、组织重塑等生理过程的正确发生。除内在激素外,外在营养物质亦可通过营养信号影响激素信号进而控制变态发育进程。本文主要综述了近十年来我国科研工作者在昆虫变态发育的激素和营养调控机制研究方面所取得的突出成果,并对未来潜在的研究方向进行了展望,以期对我国的害虫防治和益虫利用研究提供理论指导。     

昆虫变态的激素与基因调控

昆虫变态是一个有趣而复杂的生物学现象,有不完全变态和完全变态。昆虫通过变态获得飞翔与生殖能力,扩大了生活范围,增强了适应能力。昆虫变态主要由咽侧体分泌的保幼激素和前胸腺分泌的蜕皮激素协同调控,众多基因参与。本文综合近几年的研究进展,重点介绍昆虫变态过程中保幼激素与蜕皮激素通过级联反应基因和microRNA调控的机制,以及保幼激素和蜕皮激素的合成调节机制。     

整合昆虫发育生物学和果蝇遗传学来研究昆虫发育与变态

成熟动物(昆虫)个体大小主要由生长持续时间和生长速度2个因素所决定。蜕皮激素和保幼激素协同调控昆虫发育变态,并决定昆虫生长持续时间;胰岛素、营养和细胞接触抑制等生长死亡信号及其传导途径控制细胞分裂、长大、分化、死亡,并最终决定昆虫的生长速度。最近研究成果表明,蜕皮激素信号和胰岛素信号相互影响,对昆虫个体大小起决定性的作用;脂肪体和营养代谢把这2条信号传导途径整合起来。科学家将会整合昆虫发育生物学和果蝇遗传学,抓住生长持续时间和生长速率2个关键因素,并以营养代谢和脂肪体为切入点来研究昆虫的发育变态。     

害虫的遗传与行为调控

本文综述了昆虫的行为遗传机制、昆虫的发育与变态、昆虫对主要环境因子变化的响应、害虫与寄主植物的化学通讯和多营养级信息网及其对昆虫行为调控等国内外研究进展,提出了害虫治理要从杀灭防治转变为行为调控的新思路和新理念,认为未来的研究将围绕害虫暴发成灾的遗传与行为机理等科学问题,通过深入研究害虫发育变态、行为遗传,及其对关键生态因子和食物网内信号物质适应机制,揭示影响害虫发生的内外关键因素,寻找基于基因和生态调控行为治理害虫的新技术和新方法,为有效开展害虫治理、减少化学农药做出贡献。     

MicroRNA对不完全变态昆虫变态及生殖调控作用的研究进展

MicroRNAs(miRNAs)是一类在真核生物中由内源基因编码的小分子RNA,参与昆虫变态、生殖发育、细胞分化等多种重要生物学过程,在转录水平上发挥重要作用.在完全变态昆虫中,大量调控其变态及生殖的miRNA被广泛报道且进行了深入的研究,但miRNA调控不完全变态昆虫的变态及生殖发育的研究仍比较少,对其具体的调控机制也需要进一步阐明.为此,本文综述了近年来miRNA在调控不完全变态昆虫(以直翅目飞蝗Locusta migratoria、半翅目褐飞虱Nilaparvata lugens和蚜虫以及部分蜚蠊目昆虫为代表)的变态及生殖方面的研究进展,以期深化理解miRNA对不完全变态昆虫变态和生殖发育方面的机制,为害虫生态治理和综合防控提供科学依据.     

蜕皮激素和IIS-TORC1信号的分子互作

蜕皮激素信号主导调控昆虫的蜕皮和变态,决定昆虫的发育时间;IIS-TORC1信号整合生长因子、激素、营养和能量信号,决定昆虫的生长速率。蜕皮激素和IIS-TORC1信号之间发生3种分子互作:(1)IIS-TORC1信号促进前胸腺和卵巢合成蜕皮激素前体。(2)在蜕皮和变态期间,蜕皮激素抑制脂肪体细胞内IIS-TORC1信号、Myc的转录、细胞生长及其内分泌功能,导致脑神经分泌细胞分泌胰岛素样肽的功能减弱,从而降低昆虫全身性的IIS-TORC1信号。(3)在幼虫摄食期间,胰岛素信号抑制FOXO的转录活性,降低了蜕皮激素受体EcR的转录共激活因子DOR编码基因的转录水平,从而阻碍了蜕皮激素信号传导。蜕皮激素信号和IIS-TORC1信号协同调控发育时间和生长速率共同决定昆虫的个体大小。     

社会性昆虫级型和行为分化机制研究进展

社会性的出现是生物演化过程中的重要革新, 理解社会性的演化和调控机制具有重要的理论和实际意义。社会性昆虫的个体间有着明显的级型分化和劳动分工, 这有利于它们适应复杂的环境变化。理解社会性昆虫如何产生不同的形态、行为和生活史特性, 一直是进化和发育生物学的重要目标。随着测序技术的不断更新及生物信息学的快速发展, 已经有众多关于社会性昆虫级型和行为分化机制的研究报道。本文通过整理社会性昆虫研究的已有成果, 从环境因素、生理调控和分子机制等方面对社会性昆虫级型和行为分化机制相关研究进展进行了综述, 并对未来的研究方向做出了展望。根据现有证据, 社会性昆虫所生活的生物环境(食物营养、信息素、表皮碳氢化合物)和非生物环境(温度、气候等)均能直接或间接影响社会性昆虫级型和行为的分化; 保幼激素、蜕皮激素、类胰岛素及生物胺等内分泌激素和神经激素对社会性昆虫的级型和行为分化也有重要的调控作用; 此外, 遗传因素、新基因等DNA序列或基因组结构上的变化以及表观遗传修饰、基因的差异表达等基因调控机制均能不同程度地影响社会性昆虫的行为分化。本文建议加强昆虫纲其他社会性类群如半翅目蚜虫和缨翅目蓟马等的社会性行为及其演化机制的研究, 以加深对社会性昆虫起源及其行为演化的理解和认识。     

昆虫蜕皮激素信号转导途径研究进展

蜕皮与变态是全变态昆虫典型的发育特征。调控昆虫蜕皮与变态的激素主要有蜕皮激素和保幼激素。目前已经阐明了蜕皮激素的核受体EcR及部分核信号转导途径,但蜕皮激素是否存在膜受体及膜信号转导途径研究很少。研究证明,蜕皮激素存在细胞质中的信号转导分子和途径,蜕皮激素通过NTF2和Ran调控EcR入核启动基因转录。蜕皮激素使细胞质中的热休克蛋白Hsc70部分入核与USP结合启动基因转录。蜕皮激素通过蛋白激酶PKC使伴侣蛋白calponin磷酸化,参与蜕皮激素信号途径的基因转录。这些研究结果说明蜕皮激素除了有核受体和核受体信号转导途径外,还存在细胞膜受体和细胞膜信号转导途径。     

保幼激素的分子作用机制

蜕皮激素(ecdysteroids, Ecd)和保幼激素(juvenile hormone, JH)是调控昆虫发育和变态的两种最为重要的昆虫激素。尽管Ecd的分子作用机制已经相当明了,但是,因为迄今为止还没有成功地鉴定出JH受体,人们对JH的分子作用机制还了解甚少。本文从三个方面较为详尽地介绍了近年来JH分子作用机制的相关研究进展：1) JH和Ecd在分子水平上相互作用, JH可以通过改变或者抑制Ecd信号来调控昆虫的发育和变态;2) JH核受体的两个候选基因为Met和USP;3) JH还可以通过膜受体和蛋白激酶C传导信号。     

Amphibian metamorphosis: An exquisite model for hormonal regulation of postembryonic development in vertebrates

Metamorphosis in invertebrates and vertebrates is an ideal model for studying mechanisms of postembryonic development regulated by external signals. Amphibian metamorphosis shares many similarities with mammalian development in the perinatal period. The precocious induction in vivo and in culture of amphibian metamorphosis by exogenous thyroid hormones and its retardation or inhibition by prolactin, have allowed the analysis of such characteristic features of postembryonic development as morphogenesis, tissue remodelling, gene reprogramming and programmed cell death. Recent studies on metamorphosis have revealed the important role played by such processes as auto- and cross-regulation of hormone receptor genes and by cell death or apoptosis, as in the maturation of the central nervous system, tissue restructuring and organolysis.     

Amphioxus postembryonic development reveals the homology of chordate metamorphosis

Most studies in evolution are centered on how homologous genes, structures, and/or processes appeared and diverged. Although historical homology is well defined as a concept, in practice its establishment can be problematic, especially for some morphological traits or developmental processes. Metamorphosis in chordates is such an enigmatic character. Defined as a spectacular postembryonic larva-to-adult transition, it shows a wide morphological diversity between the different chordate lineages, suggesting that it might have appeared several times independently. In vertebrates, metamorphosis is triggered by binding of the thyroid hormones (THs) T(4) and T(3) to thyroid-hormone receptors (TRs). Here we show that a TH derivative, triiodothyroacetic acid (TRIAC), induces metamorphosis in the cephalochordate amphioxus. The amphioxus TR (amphiTR) mediates spontaneous and TRIAC-induced metamorphosis because it strongly binds to TRIAC, and a specific TR antagonist, NH3, inhibits both spontaneous and TRIAC-induced metamorphosis. Moreover, as in amphibians, amphiTR expression levels increase around metamorphosis and are enhanced by THs. Therefore, TH-regulated metamorphosis, mediated by TR, is an ancestral feature of all chordates. This conservation of a regulatory network supports the homology of metamorphosis in the chordate lineage.     

Gene expression during metamorphosis: An ideal model for post-embryonic development

The precocious induction in vivo and in culture of insect and amphibian metamorphosis by exogenous ecdysteroids and thyroid hormones, and its retardation or inhibition by juvenile hormone and prolactin, respectively, has allowed the analysis of such diverse processes of post-embryonic development as morphogenesis, tissue remodelling, functional reorganization, and programmed cell death. Metamorphosis in vertebrates also shares many similarities with mammalian development in the late foetal and perinatal period. This review describes the regulation of expression of some of the ‘adult’ gene products during metamorphosis in invertebrates and vertebrates. Recent studies on metamorphosis have revealed the important role played by auto-induction of hormone receptor genes, based on which a model will be presented to explain the activation of ‘downstream’ genes which give rise to the adult phenotype. It will also be argued that metamorphosis is an ideal model for analyzing some of the major mechanisms governing post-embryonic development.     

Induction of Settlement and Metamorphosis of the Veliger Larvae of the Nudibranch,Onchidoris bilamellata

Summary

Onchidoris bilamellata veligers were reared in the laboratory on a combination of phytoñagellates and diatoms. They attained metamorphic competence after a period of 28 to 32 days at 11°C, or 60 to 80 days at a temperature averaging 7.5° C.

Experimental evidence suggests that settlement is stimulated by a diffusible chemical emanating from living barnacles, whereas metamorphosis is induced by a chemical or mechanochemical cue, which is also associated with barnacles. Settlement and metamorphosis are considered to be separable events in O. bilamellata. The settlement response is reversible and can be repeated; it involves a characteristic behavioral repertoire including descent to the bottom, foot contortions and crawling on the pedal sole. Settlement occurs only in seawater that contains, or had previously contained, living barnacles. Metamorphosis is irreversible and involves the resorption of the velum, loss of the larval shell, and incorporation of the visceral mass into the cephalopedal mass. Metamorphosis is triggered only when physical contact with living or dead barnacles is made (dead barnacles refers to shell and tissue fragments which are only effective in inducing metamorphosis when they are used in combination with seawater that had previously contained living barnacles).

Settlement and metamorphosis in O. bilamellata is compared with that of other nudibranch species, and its unique settlement response is discussed.     

The effects of corticosteroid hormones and thyroid hormones on lymphocyte viability and proliferation during development and metamorphosis of Xenopus laevis

Abstract. Metamorphosis in the South African clawed frog, Xenopus laevis , is characterized by a striking loss of lymphocytes in the thymus, liver, and spleen. Changes in the proliferative responses of splenocytes and thymocytes to T cell mitogens and semi-allogeneic cells are also observed at metamorphosis. Because the levels of circulating thyroid hormones (TH) and corticosteroid hormones (CH) increase dramatically during the climax of metamorphosis, we have investigated the possible role of TH and CH as mediators of the changes in lymphocyte numbers or lymphocyte function. Here we report on the in vitro effects of CH and TH on lymphocyte viability and on phytohemagglutinin-P (PHA)-stimulated lymphocyte proliferation at prometamorphosis and climax of metamorphosis. We have observed consistently significant inhibition of proliferation by corticosterone. In contrast, we have observed inconsistent inhibition of proliferation by both thyroxine (T₄) and triiodothyronine (T₃). In short-term studies, the viability of thymocytes and splenocytes was reduced in the presence of CH but not TH.
These observations are consistent with a hypothesis that loss of larval lymphocytes and changes of lymphocyte function at metamorphosis may be due to elevated concentrations of CH rather than TH.
Because CH have been shown to enhance TH-induced effects during metamorphosis, we looked at the combined effects of these agents on PHA-stimulated lymphocyte proliferation. While each agent was inhibitory in several experiments, there was no significantly greater inhibition when splenic lymphocytes were cultured with both.     

The history of a developmental stage: metamorphosis in chordates

Metamorphosis displays a striking diversity in chordates, a deuterostome phylum that comprises vertebrates, urochordates (tunicates), and cephalochordates (amphioxus). In anuran amphibians, the tadpole loses its tail, develops limbs, and undergoes profound changes at the behavioral, physiological, biochemical, and ecological levels. In ascidian tunicates, the tail is lost and the head tissues are drastically remodeled into the adult animal, whereas in amphioxus, the highly asymmetric larva transforms into a relatively symmetric adult. This wide diversity has led to the proposal that metamorphosis evolved several times independently in the different chordate lineages during evolution. However, the molecular mechanisms involved in metamorphosis are largely unknown outside amphibians and teleost fishes, in which metamorphosis is regulated by the thyroid hormones (TH) T3 and T4 binding to their receptors (thyroid hormone receptors). In this review, we compare metamorphosis in chordates and then propose a unifying definition of the larva-to-adult transition, based on the conservation of the role of THs and some of their derivatives as the main regulators of metamorphosis. According to this definition, all chordates (if not, all deuterostomes) have a homologous metamorphosis stage during their postembryonic development. The intensity and the nature of the morphological remodeling varies extensively among taxa, from drastic remodeling like in some ascidians or amphibians to more subtle events, as in mammals.     

Comparing thyroid and insect hormone signaling

Transitions between different states of development, physiology,and life history are typically mediated by hormones. In insects,metamorphosis and reproductive maturation are regulated by aninteraction between the sesquiterpenoid juvenile hormone (JH)and the steroid 20-hydroxy-ecdysone (20E). In vertebrates andsome marine invertebrates, the lipophilic thyroid hormones (THs)affect metamorphosis and other life history transitions. Interestingly,when applied to insects, THs can physiologically mimic manyfacets of JH action, suggesting that the molecular actions ofTHs and JH/20E might be similar. Here we discuss functionalparallels between TH and JH/20E signaling in insects, with aparticular focus on the fruit fly, Drosophila melanogaster,a genetically and physiologically tractable model system. Comparingthe effects of THs with the well defined physiological rolesof insect hormones such as JH and 20E in Drosophila might provideimportant insights into hormone function and the evolution ofendocrine signaling.     

Autoinduction of nuclear hormone receptors during metamorphosis and its significance

Metamorphosis is a most dramatic example of hormonally regulated genetic reprogramming during postembryonic development. The initiation and sustenance of the process are under the control of ecdysteroids in invertebrates and thyroid hormone, 3,3', 5-triiodothyronine, in oviparous vertebrates. Their actions are inhibited or potentiated by other endogenous or exogenous hormones - juvenile hormone in invertebrates and prolactin and glucocorticoids in vertebrates. The nuclear receptors for ecdysteroids and thyroid hormone are the most closely related members of the steroid/retinoid/thyroid hormone receptor supergene family. In many pre-metamorphic amphibia and insects, the onset of natural metamorphosis and the administration of the exogenous hormones to the early larvae are characterized by a substantial and rapid autoinduction of the respective nuclear receptors. This review will largely deal with the phenomenon of receptor autoinduction during amphibian metamorphosis, although many of its features resemble those in insect metamorphosis.In the frog Xenopus, thyroid hormone receptor autoinduction has been shown to be brought about by the direct interaction between the receptor protein and the thyroid-responsive elements in the promoter of its own gene. Three lines of evidence point towards the involvement of receptor autoinduction in the process of initiation of amphibian metamorphosis: (1) a close association between the extent of inhibition or potentiation by prolactin and glucocorticoid, respectively, and metamorphic response in whole tadpoles and in organ and cell cultures; (2) thyroid hormone fails to upregulate the expression of its own receptor in obligatorily neotenic amphibia but does so in facultatively neotenic amphibia; and (3) dominant-negative receptors known to block hormonal response prevent the autoinduction of wild-type Xenopus receptors in vivo and in cell lines.Autoinduction is not restricted to insect and amphibian metamorphic hormones but is also a characteristic of other nuclear receptors (e.g., retinoid, sex steroids, vitamin D(3) receptors) where the ligand is involved in a postembryonic developmental function. A wider significance of such receptor autoregulation is that the process may also be important for mammalian postembryonic development.