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。     

RNA干扰对家蚕丝腺蜕皮激素相关基因表达的影响

昆虫变态发育过程中,蜕皮激素通过一系列的激素相关转录因子进行信号的转导和放大,从而完成对生长变态发育的调控,其中蜕皮激素受体(EcR)及转录因子BR-C和E74A可能作为早期因子发挥作用.为了研究这3个早期转录因子在鳞翅目昆虫中的功能,本研究采用体外合成dsRNA的方法,将合成的dsRNA分别注射熟蚕期的家蚕Bomby...     

昆虫蜕皮激素受体研究进展

昆虫的蜕皮激素(molting hormone,MH)是甾醇类激素,在昆虫体内的活性形式为20-羟基蜕皮酮(20-hydroxyecdysone,20E)。在昆虫的正常发育过程中,昆虫的蜕皮、变态和繁殖受到蜕皮激素的调控。昆虫蜕皮激素受体(ecdysone receptor,EcR)和超气门蛋白(ultraspiracle,USP)均属于核受体超家族成员,具有核受体的结构特征,包括A/B域(转录激活域transactivation domain)、C域(DNA结合域DNA-binding domain,DBD)、D域(铰链域hinge region)、E域(配体结合域ligand binding domain,LBD)和F域。蜕皮激素受体在昆虫蜕皮、变态和繁殖等重要的生命过程中的级联反应启动位置,对昆虫的生长发育和繁殖的正常完成有着非常重要的作用。蜕皮激素通过与蜕皮激素受体和超气门蛋白组成的复合体相互作用,然后启动一系列级联反应的过程。本文介绍了EcR和USP的结构和功能,以及它们与蜕皮激素相互作用的机理,并对EcR在农业害虫防治等方面的应用进行了介绍,并讨论了研究中遇到的问题以及对未来的研究进行展望。     

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。     

蜕皮激素与其受体EcR-USP的转录调控机制

蜕皮激素20-羟基蜕皮酮(20-hydroxyecdysone, 20E)是一种典型的类固醇激素, 主导调控昆虫的蜕皮、变态、生殖等重要生理过程。20E受体EcR-USP已被鉴定近20年, 20E与其受体复合物的转录调控机制也有了许多重要突破。已有研究表明： （1）20E受体由核受体EcR和USP形成; （2）EcR-USP异源二聚体在分子伴侣蛋白复合物的协助下获得DNA结合活性; （3）20E通过解除共阻遏因子和募集共激活因子来激活EcR USP异源二聚体并启动下游基因的转录; (4）20E-EcR-USP配体-受体复合物引发20E初级应答基因的表达, 由20E初级反应基因编码的转录因子诱导表达的20E次级应答基因级联放大20E信号, 从而调控昆虫蜕皮、变态、生殖等生理过程。     

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。     

MicroRNA在昆虫变态及生殖过程中的调控作用

MicroRNA（miRNA）是一类广泛存在于真核生物中的小分子非编码RNA,通过抑制靶基因的翻译过程或降解靶基因的mRNA,在转录后水平上调控基因表达。在昆虫中已报道了大量的miRNA,其中部分miRNA的功能得到了解析。在昆虫变态过程中,let-7, miR-100, miR-125, miR-34, miR-14, miR-8, miR-281和 miR-252-3p能够作用于保幼激素或蜕皮激素信号通路,影响昆虫蜕皮、化蛹或翅、足及神经系统的发育。在昆虫生殖阶段,bantam, miR-184和miR-275影响生殖干细胞的分化或卵子发生。本文在介绍miRNA生物合成和作用机制的基础上,重点对昆虫变态与生殖过程中miRNA的最新研究进展进行综述。     

昆虫蜕皮激素受体及其类似物的杀虫机制研究进展

昆虫的蜕皮、变态和繁殖受到蜕皮激素的严格调控。蜕皮激素作用靶标由蜕皮激素受体（ecdysteroid receptor, EcR）和超气门蛋白（ultraspiracle protein, USP）组成,蜕皮激素与EcR/USP作用启动蜕皮级联反应过程。昆虫EcR具有种类或类群的特异性,研究其结构、功能和调控机理在开发环境友好型新药剂和基因调控开关等方面具有重要指导作用。该文介绍了昆虫EcR的结构和功能特点,蜕皮激素及其类似物与EcR/USP的分子作用方式,以及基于EcR/USP的新杀虫剂创制和基因调控开关设计等方面的重要进展。     

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。     

How a RING finger protein and a steroid hormone control autophagy

Previous work in our laboratory has indicated that the steroid hormone ecdysone triggers programmed autophagy in the fat body of Drosophila larvae by downregulating the class I phosphoinositide 3-kinase (PI3K) pathway. We recently found evidence that Deep orange (Dor), a Drosophila RING finger protein implicated in late-endosomal trafficking, controls ecdysone signaling as well as autolysosome fusion, thus exerting a dual regulation of autophagy. We found that dor mutants are defective in programmed autophagy. The mutant larvae showed impaired upregulation of ecdysone signaling during development, accompanied by a failure to downregulate the PI3K pathway. Downregulation of the PI3K pathway could be restored by feeding the dor mutants with ecdysone. Even though ecdysone signaling and autophagy were impaired in the dor mutants, we detected an accumulation of autophagosomes in dor mutant fat bodies. This could probably be attributed to the failure of autophagosomes to fuse with lysosomes. In this Addendum we review these findings and provide some speculations about how Dor may control both ecdysone signalling and autolysosomal fusion.     

Local requirement of the Drosophila insulin binding protein imp-L2 in coordinating developmental progression with nutritional conditions

In Drosophila, growth takes place during the larval stages until the formation of the pupa. Starvation delays pupariation to allow prolonged feeding, ensuring that the animal reaches an appropriate size to form a fertile adult. Pupariation is induced by a peak of the steroid hormone ecdysone produced by the prothoracic gland (PG) after larvae have reached a certain body mass. Local downregulation of the insulin/insulin-like growth factor signaling (IIS) activity in the PG interferes with ecdysone production, indicating that IIS activity in the PG couples the nutritional state to development. However, the underlying mechanism is not well understood. In this study we show that the secreted Imaginal morphogenesis protein-Late 2 (Imp-L2), a growth inhibitor in Drosophila, is involved in this process. Imp-L2 inhibits the activity of the Drosophila insulin-like peptides by direct binding and is expressed by specific cells in the brain, the ring gland, the gut and the fat body. We demonstrate that Imp-L2 is required to regulate and adapt developmental timing to nutritional conditions by regulating IIS activity in the PG. Increasing Imp-L2 expression at its endogenous sites using an Imp-L2-Gal4 driver delays pupariation, while Imp-L2 mutants exhibit a slight acceleration of development. These effects are strongly enhanced by starvation and are accompanied by massive alterations of ecdysone production resulting most likely from increased Imp-L2 production by neurons directly contacting the PG and not from elevated Imp-L2 levels in the hemolymph. Taken together our results suggest that Imp-L2-expressing neurons sense the nutritional state of Drosophila larvae and coordinate dietary information and ecdysone production to adjust developmental timing under starvation conditions.     

Ecdysteroid biosynthesis in workers of the European honeybee Apis mellifera L

We previously reported preferential expression of genes for ecdysteroid signaling in the mushroom bodies of honeybee workers, suggesting a role of ecdysteroid signaling in regulating honeybee behaviors. The organs that produce ecdysteroids in worker honeybees, however, remain unknown. We show here that the expression of neverland and Non-molting glossy/shroud, which are involved in early steps of ecdysteroid synthesis, was enhanced in the ovary, while the expression of CYP306A1 and CYP302A1, which are involved in later steps of ecdysone synthesis, was enhanced in the brain, and the expression of CYP314A1, which is involved in converting ecdysone into active 20-hydroxyecdysone (20E), was enhanced in the brain, fat body, and ovary. In in vitro organ culture, a significant amount of ecdysteroids was detected in the culture medium of the brain, fat body, and hypopharyngeal glands. The ecdysteroids detected in the culture medium of the fat body were identified as ecdysone and 20E. These findings suggest that, in worker honeybees, cholesterol is converted into intermediate ecdysteroids in the ovary, whereas ecdysone is synthesized and secreted mainly by the brain and converted into 20E in the brain and fat body.     

How a RING Finger Protein and a Steroid Hormone Control Autophagy?

Previous work in our laboratory has indicated that the steroid hormone ecdysone triggers programmed autophagy in the fat body of Drosophila larvae by downregulating the class I phosphoinositide 3-kinase (PI3K) pathway. We recently found evidence that Deep orange (Dor), a Drosophila RING finger protein implicated in late-endosomal trafficking, controls ecdysone signaling as well as autolysosome fusion, thus exerting a dual regulation of autophagy. We found that dor mutants are defective in programmed autophagy. The mutant larvae showed impaired upregulation of ecdysone signaling during development, accompanied by a failure to downregulate the PI3K pathway. Downregulation of the PI3K pathway could be restored by feeding the dor mutants with ecdysone. Even though ecdysone signaling and autophagy were impaired in the dor mutants, we detected an accumulation of autophagosomes in dor mutant fat bodies. This could probably be attributed to the failure of autophagosomes to fuse with lysosomes. In this Addendum we review these findings and provide some speculations about how Dor may control both ecdysone signalling and autolysosomal fusion.

Addendum to:

A Dual Function for Deep Orange in Programmed Autophagy in the Drosophila melanogaster Fat Body

K. Lindmo, A. Simonsen, A. Brech, K. Finley, T.E. Rusten and H. Stenmark

Exp Cell Res 2006; Epub ahead of print     

Flies on steroids: the interplay between ecdysone and insulin signaling

In the fruit fly Drosophila melanogaster, the insulin and ecdysone signaling pathways have long been known to regulate growth and developmental timing, respectively. Recent findings reveal that crosstalk between these pathways allows coordination of growth and developmental timing and thus determines final body size.     

The TOR pathway couples nutrition and developmental timing in Drosophila

In many metazoans, final adult size depends on the growth rate and the duration of the growth period, two parameters influenced by nutritional cues. We demonstrate that, in Drosophila, nutrition modifies the timing of development by acting on the prothoracic gland (PG), which secretes the molting hormone ecdysone. When activity of the Target of Rapamycin (TOR), a core component of the nutrient-responsive pathway, is reduced in the PG, the ecdysone peak that marks the end of larval development is abrogated. This extends the duration of growth and increases animal size. Conversely, the developmental delay caused by nutritional restriction is reversed by activating TOR solely in PG cells. Finally, nutrition acts on the PG during a restricted time window near the end of larval development that coincides with the commitment to pupariation. In conclusion, the PG uses TOR signaling to couple nutritional input with ecdysone production and developmental timing.