DHR3 is required for the prepupal-pupal transition and differentiation of adult structures during Drosophila metamorphosis.

Pulses of the steroid hormone ecdysone activate genetic regulatory hierarchies that coordinate the developmental changes associated with Drosophila metamorphosis. A high-titer ecdysone pulse at the end of larval development triggers puparium formation and induces expression of the DHR3 orphan nuclear receptor. Here we use both a heat-inducible DHR3 rescue construct and clonal analysis to define DHR3 functions during metamorphosis. Clonal analysis reveals requirements for DHR3 in the development of adult bristles, wings, and cuticle, and no apparent function in eye or leg development. DHR3 mutants rescued to the third larval instar also reveal essential functions during the onset of metamorphosis, leading to lethality during prepupal and early pupal stages. The phenotypes associated with these lethal phases are consistent with the effects of DHR3 mutations on ecdysone-regulated gene expression. Although DHR3 has been shown to be sufficient for early gene repression at puparium formation, it is not necessary for this response, indicating that other negative regulators may contribute to this pathway. In contrast, DHR3 is required for maximal expression of the midprepupal regulatory genes, EcR, E74B, and betaFTZ-1. Reductions in EcR and betaFTZ-F1 expression, in turn, lead to submaximal early gene induction in response to the prepupal ecdysone pulse and corresponding defects in adult head eversion and salivary gland cell death. These studies demonstrate that DHR3 is an essential regulator of the betaFTZ-F1 midprepupal competence factor, providing a functional link between the late larval and prepupal responses to ecdysone. Induction of DHR3 in early prepupae ensures that responses to the prepupal ecdysone pulse will be distinct from responses to the late larval pulse and thus that the animal progresses in an appropriate manner through the early stages of metamorphosis.     

A conditional rescue system reveals essential functions for the ecdysone receptor (EcR) gene during molting and metamorphosis in Drosophila

In Drosophila, pulses of the steroid hormone ecdysone trigger larval molting and metamorphosis and coordinate aspects of embryonic development and adult reproduction. At each of these developmental stages, the ecdysone signal is thought to act through a heteromeric receptor composed of the EcR and USP nuclear receptor proteins. Mutations that inactivate all EcR protein isoforms (EcR-A, EcR-B1, and EcR-B2) are embryonic lethal, hindering analysis of EcR function during later development. Using transgenes in which a heat shock promoter drives expression of an EcR cDNA, we have employed temperature-dependent rescue of EcR null mutants to determine EcR requirements at later stages of development. Our results show that EcR is required for hatching, at each larval molt, and for the initiation of metamorphosis. In EcR mutants arrested prior to metamorphosis, expression of ecdysone-responsive genes is blocked and normal ecdysone responses of both imaginal and larval tissues are blocked at an early stage. These results show that EcR mediates ecdysone signaling at multiple developmental stages and implicate EcR in the reorganization of imaginal and larval tissues at the onset of metamorphosis.     

Gene transfer to skeletal muscle by site-specific delivery of electroporation and ultrasound

Lipid metabolism drastically changes in response to the environmental factors in metazoans. Lipid is accumulated at the food rich condition, while mobilized in adipocyte tissue in starvation. Such lipid mobilization is also evident during the pupation of the insects. Pupation is induced by metamorphosis hormone, ecdysone via ecdysone receptor (EcR) with lipid mobilization, however, the molecular link of the EcR-mediated signal to the lipid mobilization remains elusive. To address this issue, EcR was genetically knocked-down selectively in 3rd instar larva fat body of Drosophila, corresponding to the adipocyte tissues in mammalians, that contains adipocyte-like cells. In this mutant, lipid accumulation was increased in the fat body. Lipid accumulation was also increased when knocked-down of taiman, which served as the EcR co-activator. Two lipid metabolism regulatory factor, E75B and adipose (adp) as well as cell growth factor, dMyc, were found as EcR target genes in the adipocyte-like cells, and consistently knock-down of these EcR target genes brought phenotypes in lipid accumulation supporting EcR function. These findings suggest that EcR-mediated ecdysone signal is significant in lipid metabolism in insects.     

Phenol oxidases from Rhodnius prolixus: Temporal and tissue expression pattern and regulation by ecdysone

Rhodnius prolixus 5th instar nymphs have significant PO enzymatic activity in the anterior midgut, fat body and hemolymph. The tissue with the major amount of PO activity is the anterior midgut while those with higher specific activities are the fat body and hemolymph. In this work the temporal pattern of PO enzymatic activity in different tissues was investigated. In fat body, PO peaks occur at 7, 12 and 16 days after a blood meal. In hemolymph, PO diminishes until day 7, and then recovers by day 14. In the anterior midgut tissue, PO peaks on day 9 and just before ecdysis; a similar pattern was observed in the anterior midgut contents. Some of these activities are dependent on the release of ecdysone, as feeding blood meal containing azadirachtin suppresses them and ecdysone treatment counteracts this effect. These results suggest that during the development of the 5th instar, the insect has natural regulating cycles of basal PO expression and activation, which could be related to the occurrence of natural infections. The differences in temporal patterns of activity and the effects of azadirachtin and ecdysone in each organ suggest that, at least in R. prolixus, different tissues are expressing different PO genes.     

The Drosophila EcR gene encodes an ecdysone receptor, a new member of the steroid receptor superfamily

The steroid hormone ecdysone triggers coordinate changes in Drosophila tissue development that result in metamorphosis. To advance our understanding of the genetic regulatory hierarchies controlling this tissue response, we have isolated and characterized a gene, EcR, for a new steroid receptor homolog and have shown that it encodes an ecdysone receptor. First, EcR protein binds active ecdysteroids and is antigenically indistinguishable from the ecdysone-binding protein previously observed in extracts of Drosophila cell lines and tissues. Second, EcR protein binds DNA with high specificity at ecdysone response elements. Third, ecdysone-responsive cultured cells express EcR, whereas ecdysone-resistant cells derived from them are deficient in EcR. Expression of EcR in such resistant cells by transfection restores their ability to respond to the hormone. As expected, EcR is nuclear and found in all ecdysone target tissues examined. Furthermore, the EcR gene is expressed at each developmental stage marked by a pulse of ecdysone.     

Mechanisms of midgut remodeling: juvenile hormone analog methoprene blocks midgut metamorphosis by modulating ecdysone action

In holometabolous insects such as mosquito, Aedes aegypti, midgut undergoes remodeling during metamorphosis. Insect metamorphosis is regulated by several hormones including juvenile hormone (JH) and 20-hydroxyecdysone (20E). The cellular and molecular events that occur during midgut remodeling were investigated by studying nuclear stained whole mounts and cross-sections of midguts and by monitoring the mRNA levels of genes involved in 20E action in methoprene-treated and untreated Ae. aegypti. We used JH analog, methoprene, to mimic JH action. In Ae. aegypti larvae, the programmed cell death (PCD) of larval midgut cells and the proliferation and differentiation of imaginal cells were initiated at about 36h after ecdysis to the 4th instar larval stage (AEFL) and were completed by 12h after ecdysis to the pupal stage (AEPS). In methoprene-treated larvae, the proliferation and differentiation of imaginal cells was initiated at 36h AEFL, but the PCD was initiated only after ecdysis to the pupal stage. However, the terminal events that occur for completion of PCD during pupal stage were blocked. As a result, the pupae developed from methoprene-treated larvae contained two midgut epithelial layers until they died during the pupal stage. Quantitative PCR analyses showed that methoprene affected midgut remodeling by modulating the expression of ecdysone receptor B, ultraspiracle A, broad complex, E93, ftz-f1, dronc and drice, the genes that are shown to play key roles in 20E action and PCD. Thus, JH analog, methoprene acts on Ae. aegypti by interfering with the expression of genes involved in 20E action resulting in a block in midgut remodeling and death during pupal stage.     

果蝇蜕皮激素诱导程序性细胞死亡的遗传调控因子

近年来关于果蝇程序性细胞死亡（programmed cell death, PCD）的研究结果表明,在果蝇的变态发育过程中,蜕皮激素与受体结合后诱导转录因子的表达。这些转录因子作为程序性细胞死亡调控网络中的初、次级应答信号,激活凋亡诱导因子Reaper、Hid和Grim的表达。Reaper、Hid和Grim进而阻止凋亡蛋白抑制因子的活性,从而启动半胱氨酸蛋白酶caspase途径,引起细胞凋亡（apoptosis）。该文综述了蜕皮激素诱导的果蝇程序性细胞死亡中各遗传调控因子之间的关系。     

Hormones, puffs and flies: the molecular control of metamorphosis by ecdysone.

Pulses of the steroid hormone ecdysone during late larval and prepupal development in Drosophila coordinate the activation of a large number of primary and secondary response genes, signalling the onset of metamorphosis. Molecular characterization of some of these genes has provided valuable clues to regulatory mechanisms by which the ecdysone signal is transduced and amplified.     

斜纹夜蛾中肠糖代谢相关基因的克隆及表达模式分析

斜纹夜蛾Spodoptera litura是一种世界性分布的重要农业害虫, 在生长发育过程中要经历幼虫 蛹的变态发育过程。由于变态发育前后昆虫的食性发生了明显的改变, 作为食物消化吸收的中肠也发生了解体和重建。与此相适应, 昆虫中肠的各种物质和能量代谢也可能会相应地发生改变。为研究斜纹夜蛾中肠变态发育过程中糖代谢途径的变化情况, 我们从斜纹夜蛾中肠EST文库中鉴定出了12个糖代谢相关基因, 克隆了其中3个基因的全长cDNA, 并应用半定量PCR和定量PCR的方法检测了其在幼虫 蛹变态发育期中肠组织的转录表达以及对激素和饥饿等因素的响应情况。结果表明： 这3个基因（α-L-岩藻糖苷酶、 N-乙酰葡萄糖胺-6-磷酸去乙酰酶和烯醇化酶基因）的开放阅读框分别为1 461, 1 200和1 299 bp, 预测的分子量分别为56.3, 43.3和46.7 kDa。这12个糖代谢相关的基因在变态发育期的中肠组织中具有5种不同的mRNA表达模式： （Ⅰ）只在幼虫期高表达（唾液麦芽糖酶前体蛋白、 糖基水解酶31家族成员蛋白、 线粒体乙醛脱氢酶、 β-1,3 葡聚糖酶基因）; （Ⅱ）只在预蛹期高表达（β-葡萄糖醛酸酶、 β-N-酰基氨基葡萄糖苷酶3基因）; （Ⅲ）只在蛹期高表达（葡萄糖胺-6-磷酸异构酶基因）; （Ⅳ）在预蛹期和蛹期高表达（α-葡萄糖苷酶、 α-淀粉酶、 N-乙酰葡糖胺 6 磷酸脱乙酰酶和α-L-岩藻糖苷酶基因）; （Ⅴ）在变态发育期恒定表达（烯醇化酶基因）。这说明, 为适应变态发育斜纹夜蛾中肠糖代谢途径发生了明显的改变。保幼激素对这些基因的表达没有明显的影响, 但蜕皮激素对Ⅰ类基因（如糖基水解酶31家族成员蛋白基因）具有一定的抑制作用, 对Ⅲ类基因（如葡萄糖胺-6-磷酸异构酶基因）有显著的上调作用。此外, 我们还发现饥饿对几乎所有这些基因的表达都有显著的抑制作用。这些结果说明, 昆虫中肠变态发育过程中糖代谢相关基因的动态变化可能受到蜕皮激素以及饥饿相关因素的共同调控。这一研究对从代谢角度揭示昆虫变态发育的分子机理具有重要意义。     

Ecdysone-Induced Receptor Tyrosine Phosphatase PTP52F Regulates Drosophila Midgut Histolysis by Enhancement of Autophagy and Apoptosis

The rapid removal of larval midgut is a critical developmental process directed by molting hormone ecdysone during Drosophila metamorphosis. To date, it remains unclear how the stepwise events can link the onset of ecdysone signaling to the destruction of larval midgut. This study investigated whether ecdysone-induced expression of receptor protein tyrosine phosphatase PTP52F regulates this process. The mutation of the Ptp52F gene caused significant delay in larval midgut degradation. Transitional endoplasmic reticulum ATPase (TER94), a regulator of ubiquitin proteasome system, was identified as a substrate and downstream effector of PTP52F in the ecdysone signaling. The inducible expression of PTP52F at the puparium formation stage resulted in dephosphorylation of TER94 on its Y800 residue, ensuring the rapid degradation of ubiquitylated proteins. One of the proteins targeted by dephosphorylated TER94 was found to be Drosophila inhibitor of apoptosis 1 (DIAP1), which was rapidly proteolyzed in cells with significant expression of PTP52F. Importantly, the reduced level of DIAP1 in response to inducible PTP52F was essential not only for the onset of apoptosis but also for the initiation of autophagy. This study demonstrates a novel function of PTP52F in regulating ecdysone-directed metamorphosis via enhancement of autophagic and apoptotic cell death in doomed Drosophila midguts.