Ecdysone signaling at metamorphosis triggers apoptosis of Drosophila abdominal muscles

One of the most dramatic examples of programmed cell death occurs during Drosophila metamorphosis, when most of the larval tissues are destroyed in a process termed histolysis. Much of our understanding of this process comes from analyses of salivary gland and midgut cell death. In contrast, relatively little is known about the degradation of the larval musculature. Here, we analyze the programmed destruction of the abdominal dorsal exterior oblique muscle (DEOM) which occurs during the first 24 h of metamorphosis. We find that ecdysone signaling through Ecdysone receptor isoform B1 is required cell autonomously for the muscle death. Furthermore, we show that the orphan nuclear receptor FTZ-F1, opposed by another nuclear receptor, HR39, plays a critical role in the timing of DEOM histolysis. Finally, we show that unlike the histolysis of salivary gland and midgut, abdominal muscle death occurs by apoptosis, and does not require autophagy. Thus, there is no set rule as to the role of autophagy and apoptosis during Drosophila histolysis.     

Steroid Hormone Control of Cell Death and Cell Survival: Molecular Insights Using RNAi

The insect steroid hormone ecdysone triggers programmed cell death of obsolete larval tissues during metamorphosis and provides a model system for understanding steroid hormone control of cell death and cell survival. Previous genome-wide expression studies of Drosophila larval salivary glands resulted in the identification of many genes associated with ecdysone-induced cell death and cell survival, but functional verification was lacking. In this study, we test functionally 460 of these genes using RNA interference in ecdysone-treated Drosophila l(2)mbn cells. Cell viability, cell morphology, cell proliferation, and apoptosis assays confirmed the effects of known genes and additionally resulted in the identification of six new pro-death related genes, including sorting nexin-like gene SH3PX1 and Sox box protein Sox14, and 18 new pro-survival genes. Identified genes were further characterized to determine their ecdysone dependency and potential function in cell death regulation. We found that the pro-survival function of five genes (Ras85D, Cp1, CG13784, CG32016, and CG33087), was dependent on ecdysone signaling. The TUNEL assay revealed an additional two genes (Kap-α3 and Smr) with an ecdysone-dependent cell survival function that was associated with reduced cell death. In vitro, Sox14 RNAi reduced the percentage of TUNEL-positive l(2)mbn cells (p<0.05) following ecdysone treatment, and Sox14 overexpression was sufficient to induce apoptosis. In vivo analyses of Sox14-RNAi animals revealed multiple phenotypes characteristic of aberrant or reduced ecdysone signaling, including defects in larval midgut and salivary gland destruction. These studies identify Sox14 as a positive regulator of ecdysone-mediated cell death and provide new insights into the molecular mechanisms underlying the ecdysone signaling network governing cell death and cell survival.     

BmMD-2A responds to 20-hydroxyecdysone and regulates Bombyx mori silkworm innate immunity in larva-to-pupa metamorphosis

20E-hydroxyecdysone (20E) plays important roles in larval molting and metamorphosis in insects and is also involved in the insect innate immune response. Insect metamorphosis is a highly successful strategy for environmental adaptation and is the most vulnerable stage during which the insect is susceptible to various pathogens. 20E regulates a series of antimicrobial peptides (AMPs) through the immunodeficiency (IMD) pathway activation in Drosophila; nevertheless, whether other immune pathways are involved in 20E-regulated insect immunity is unknown. Our previous studies showed that BmMD-2A is a member of the MD-2-related lipid recognition (ML) family of proteins that are involved in the Bombyx mori innate immunity Toll signaling pathway. In this study, we further demonstrate that BmMD-2A is also positively regulated by 20E, and the BmMD-2A neutralization experiment suggested that 20E activates some downstream immune effect factors, the AMP genes against Escherichia coli and Staphylococcus aureus, through the regulation of BmMD-2A in larval metamorphosis, implying that B. mori may use the Toll-ML signaling pathway to maintain innate immune balance in the larval-pupal metamorphosis stage, which is a different innate immunity pathway regulated by 20E compared to the IMD pathway in Drosophila.     

Identification of factors that function in Drosophila salivary gland cell death during development using proteomics

Proteasome inhibitors induce cell death and are used in cancer therapy, but little is known about the relationship between proteasome impairment and cell death under normal physiological conditions. Here, we investigate the relationship between proteasome function and larval salivary gland cell death during development in Drosophila. Drosophila larval salivary gland cells undergo synchronized programmed cell death requiring both caspases and autophagy (Atg) genes during development. Here, we show that ubiquitin proteasome system (UPS) function is reduced during normal salivary gland cell death, and that ectopic proteasome impairment in salivary gland cells leads to early DNA fragmentation and salivary gland condensation in vivo. Shotgun proteomic analyses of purified dying salivary glands identified the UPS as the top category of proteins enriched, suggesting a possible compensatory induction of these factors to maintain proteolysis during cell death. We compared the proteome following ectopic proteasome impairment to the proteome during developmental cell death in salivary gland cells. Proteins that were enriched in both populations of cells were screened for their function in salivary gland degradation using RNAi knockdown. We identified several factors, including trol, a novel gene CG11880, and the cop9 signalsome component cop9 signalsome 6, as required for Drosophila larval salivary gland degradation.     

昆虫变态发育过程中的细胞自噬和凋亡

在昆虫变态期,幼虫组织发生退化或消亡,原因在于蜕皮甾醇激素（ecdysteroid）,即通常所说的蜕皮激素,诱导这些组织的细胞发生了自噬(autophagy)和凋亡(apoptosis)的程序性细胞死亡(programmed cell death,PCD)。一般情况下,自噬途径构成一种饥饿应激适应性以避免细胞的死亡,表现为低水平Cvt泡(Cvt vesicle)和自噬体(autophagosome)对部分胞质溶胶、蛋白聚集体和细胞器的吞噬和降解。昆虫进入变态发育时,由于蜕皮激素的激活,由遗传级联系统调控的PCD机制被启动,低水平的常态自噬转入高水平的自噬并同时诱发凋亡,细胞进入不可逆的死亡,导致幼虫组织在变态期退化或消亡。对果蝇Drosophila变态期PCD机制中最重要的发现是:（1）在自噬发生的PI3KⅠ- Tor 和 PI3KⅢ的分子通路中,由自噬相关蛋白Atg1引发的高水平自噬能够诱导凋亡;（2）蜕皮激素诱导表达的βFTZ-F1,E93,BR-C,E74A等转录因子不但激活凋亡的Caspases通路,还能诱导自噬的发生。     

AP-1, but not NF-kappa B, is required for efficient steroid-triggered cell death in Drosophila

Extensive studies in vertebrate cells have assigned a central role to Rel/NF-kappa B and AP-1 family members in the control of apoptosis. We ask here whether parallel pathways might function in Drosophila by determining if Rel/NF-kappa B or AP-1 family members contribute to the steroid-triggered death of larval salivary glands during Drosophila metamorphosis. We show that two of the three Drosophila Rel/NF-kappa B genes are expressed in doomed salivary glands and that one family member, Dif, is induced in a stage-specific manner immediately before the onset of programmed cell death. Similarly, Djun is expressed for many hours before salivary gland cell death while Dfos is induced in a stage-specific manner, immediately before this tissue is destroyed. We show that null mutations in the three Drosophila Rel/NF-kappa B family members, either alone or in combination, have no apparent effect on this death response. In contrast, Dfos is required for the proper timing of larval salivary gland cell death as well as the proper induction of key death genes. This study demonstrates a role for AP-1 in the stage-specific steroid-triggered programmed cell death of larval tissues during Drosophila metamorphosis.     

The hormonal pathway controlling cell death during metamorphosis in a hemimetabolous insect

Metamorphosis in holometabolous insects is mainly based on the destruction of larval tissues. Intensive research in Drosophila melanogaster, a model of holometabolan metamorphosis, has shown that the steroid hormone 20-hydroxyecdysone (20E) signals cell death of larval tissues during metamorphosis. However, D. melanogaster shows a highly derived type of development and the mechanisms regulating apoptosis may not be representative in the insect class context. Unfortunately, no functional studies have been carried out to address whether the mechanisms controlling cell death are present in more basal hemimetabolous species. To address this, we have analyzed the apoptosis of the prothoracic gland of the cockroach Blattella germanica, which undergoes stage-specific degeneration just after the imaginal molt. Here, we first show that B. germanica has two inhibitor of apoptosis (IAP) proteins and that one of them, BgIAP1, is continuously required to ensure tissue viability, including that of the prothoracic gland, during nymphal development. Moreover, we demonstrate that the degeneration of the prothoracic gland is controlled by a complex 20E-triggered hierarchy of nuclear receptors converging in the strong activation of the death-inducer Fushi tarazu-factor 1 (BgFTZ-F1) during the nymphal-adult transition. Finally, we have also shown that prothoracic gland degeneration is effectively prevented by the presence of juvenile hormone (JH). Given the relevance of cell death in the metamorphic process, the characterization of the molecular mechanisms regulating apoptosis in hemimetabolous insects would allow to help elucidate how metamorphosis has evolved from less to more derived insect species.     

Real-time observation of autophagic programmed cell death of<Emphasis Type="Italic"> Drosophila</Emphasis> salivary glands in vitro

Autophagy, a form of programmed cell death (PCD) that is morphologically distinguished from apoptosis, is thought to be as prevalent as apoptosis, at least during development. In insect metamorphosis, the steroid hormone 20-hydroxyecdysone (ecdysone) activates autophagic PCD to eliminate larval structures that are no longer needed. However, in comparison with apoptosis, there are not many studies on the regulation mechanisms of autophagy. To provide a useful model for studying autophagic PCD, I established an in vitro culture system that enables real-time observation of the autophagic cell destruction of Drosophila salivary glands. The new system revealed that de novo gene expression was still required for the destruction of salivary glands dissected from phanerocephalic pupae. This indicates the usefulness of the system for exploring genes that participate in the last processes of autophagic PCD.Edited by N. Satoh     

Expression,subcellular localization and protein‑protein interaction of four isoforms of EcR/USP in the common cutworm

Ecdysone receptor (EcR) and ultraspiracle (USP) form heterodimers to mediate ecdysteroid signaling during molting and metamorphosis. Various EcR/USP heterodimers have been reported. However, it is unclear what kind of EcR/USP combination is adopted by lepidopteran insects during the larval?pupal metamorphosis and whether the EcR/USP heterodimer varies among different tissues. To address these questions, two isoforms of each EcR and USP were cloned from the common cutworm, their messenger RNA expression patterns were examined by real‐time quantitative polymerase chain reaction in different tissues during the larval–pupal metamorphosis and in the midgut in response to hormonal induction. Furthermore, their subcellular localization and protein?protein interaction were explored by transient expression and far‐western blotting, respectively. All the four genes were significantly up‐regulated in prepuae and/or pupae. The expression profiles of EcRB1 and USP1 were nearly identical to each other in the epidermis, fat body and midgut, and a similar situation also applied to EcRA and USP2. The three genes responded to 20‐hydroxyecdysone (20E) induction except for USP2, and USP1 could be up‐regulated by both 20E and juvenile hormone. The four proteins mainly localized in the nucleus and the nuclear localization was promoted by 20E. The protein?protein interaction between each EcR and USP was found in vitro. These results suggest that two types of EcR/USP heterodimer (EcRA/USP2 and EcRB1/USP1) may exist simultaneously in the common cutworm, and the latter should play more important roles during the larval?pupal metamorphosis. In addition, the types of EcR/USP heterodimer do not vary in the tissues which undergo histolysis and regeneration during metamorphosis.     

Mechanisms of programmed cell death in the midgut and salivary glands from Bradysia hygida (Diptera: Sciaridae) during pupal–adult metamorphosis

Programmed cell death is involved with the degeneration/remodeling of larval tissues and organs during holometabolous development. The midgut is a model to study the types of programmed cell death associated with metamorphosis because its structure while degenerating is a substrate for the formation of the adult organ. Another model is the salivary glands from dipteran because their elimination involves different cell death modes. This study aimed to investigate the models of programmed cell death operating during midgut replacement and salivary gland histolysis in Bradysia hygida. We carried out experiments of real‐time observations, morphological analysis, glycogen detection, filamentous‐actin localization, and nuclear acridine orange staining. Our findings allow us to establish that an intact actin cytoskeleton is required for midgut replacement in B. hygida and nuclear condensation and acridine orange staining precede the death of the larval cells. Salivary glands in histolysis present cytoplasmic blebbing, nuclear retraction, and acridine orange staining. This process can be partially reproduced in vitro. We propose that the larval midgut death involves autophagic and apoptotic features and apoptosis is a mechanism involved with salivary gland histolysis.     

Deoxyribonucleases of the organs of Drosophila hydei at the onset of metamorphosis

The tissue distribution of deoxyribonucleases has been studied in the organs of Drosophila hydei at the onset of metamorphosis. The enzymes were separated by disc electrophoresis and detected directly in the gel. An extensive shift in the wide spectrum of activities that has been observed at metamorphosis indicates that deoxyribonucleases play an important role at this time in development. On the basis of the tissue distribution of these enzymes, it has been possible to assign probable functions to several of the activities. An intense activity appears in the prepupal salivary gland which is not detected in this organ in the larval stage. This observation is of particular interest in view of the changes that have been observed in the chromosomal puffing patterns of the salivary glands just prior to metamorphosis. A class of activities, which is probably of lysosomal origin, is more prevalent in the prepupal tissues. The data suggest that an increased synthesis of lysosomes is a general reaction of most larval tissues at the onset of metamorphosis irrespective of whether a tissue undergoes total histolysis. The larval intestine contains a factor which strongly inhibits Drosophila nucleases that are active at low pH. The major nuclease activities of each tissue have been tentatively characterized. A knowledge of the enzyme properties is expected to facilitate the isolation of DNA from the individual tissues.This work was performed in the Max-Planck-Institut für Biologie, Abteilung Beermann, Tübingen, Germany. The senior author was supported by the Helen Hay Whitney Foundation.