昆虫细胞自噬的生物学意义和自噬体膜的来源

细胞自噬(autophagy)是生物体广泛存在的细胞内自主降解过程。该过程通过自我吞噬细胞质成分和细胞器形成具有双层膜结构的自噬体, 与溶酶体融合实现细胞内物质的循环利用。细胞自噬在饥饿、 缺氧、 内质网胁迫、 病原入侵、 蛋白聚集等不良环境条件下实现自我挽救, 而细胞自噬的大量发生也是程序性细胞死亡(PCD)的启动和执行者之一。目前人们对自噬体分子组装和自噬发生的分子通路已有较深入的了解, 但仍然在很多重要问题上难以达成共识。本文结合我们的研究进展, 对昆虫细胞自噬的生物学意义和自噬体膜的来源问题进行综述和探讨。昆虫在营养相对匮乏的情况下发生低水平自噬(常态自噬), 用于维持细胞内的新陈代谢和继续生存的需要。昆虫在摄食阶段受到过度饥饿的刺激, 在变态发育时期受到蜕皮激素(20E)的诱导, 幼虫组织细胞发生高水平自噬和凋亡(apoptosis), 细胞表现为不可逆死亡, 过度饥饿导致幼虫发育迟缓或者死亡, 而20E导致幼虫蜕皮和幼虫组织退化或消亡。不同于酵母和高等动物细胞中的深入研究, 病原入侵是否和如何诱导昆虫细胞发生自噬, 目前尚缺乏足够的文献依据, 值得深入探讨。几乎所有的细胞器(内质网、 高尔基体、 线粒体)膜都可能是自噬体膜的来源, 这一问题在昆虫中也有待进一步诠释。     

果蝇变态过程中的细胞凋亡和细胞自噬

程序化细胞死亡(programmed cell death,PCD)分为I型PCD细胞凋亡(apoptosis)和II型PCD细胞自噬(autophagy)。果蝇等完全变态昆虫有2种类型的器官:即细胞内分裂器官(如脂肪体、表皮、唾液腺、中肠、马氏管等)和有丝分裂器官(复眼、翅膀、足、神经系统等)。在昆虫变态过程中,细胞内分裂器官进行器官重建,幼虫器官大量发生细胞凋亡和细胞自噬到最后完全消亡,同时成虫器官由干细胞从新生成;而有丝分裂器官则由幼虫器官直接发育为成虫器官。在果蝇等昆虫的变态过程中,细胞凋亡和细胞自噬在幼虫器官的死亡和成虫器官的生成中发挥了非常重要的作用。文章简要介绍细胞凋亡和细胞自噬在果蝇变态过程中的生理功能和分子调控机制。     

家蚕幼虫-蛹变态期前胸腺和脂肪体细胞解离和程序性细胞死亡的比较分析

【目的】检测家蚕Bombyx mori变态期前胸腺细胞的解离、自噬与凋亡,并与脂肪体的进行对比,从而解析昆虫幼虫-蛹变态期过程中不同组织重塑的异同。【方法】以家蚕5龄期、游走期、预蛹期和蛹期前胸腺和脂肪体组织为材料,在光学显微镜下观察前胸腺和脂肪体细胞解离情况;分别利用Lyso-Tracker和TUNEL染色,在荧光共聚焦显微镜下观察细胞自噬和细胞凋亡的发生情况;利用qRT-PCR检测家蚕前胸腺中自噬发生标志基因Atg8的表达水平;利用透射电镜观察前胸腺和脂肪体细胞自噬小体和前胸腺线粒体;利用Caspase3酶活性检测试剂盒测定Caspase3酶活性;利用qRT-PCR检测前胸腺中蜕皮酮(ecdysone)合成相关基因Spo,Phm,Dib和Sad的表达水平;利用酶免疫试验(enzyme-immunoassay, EIA)测定前胸腺中蜕皮酮的含量,进而检测合成蜕皮酮的活力。【结果】在家蚕幼虫到蛹的变态发育过程中,在化蛹第1天家蚕前胸腺和脂肪体细胞中同时开始出现细胞解离;脂肪体细胞自噬和凋亡分别在游走期和预蛹第1天开始出现并逐渐增强;而前胸腺一直到化蛹第2天都没有发生明显的细胞自噬和凋亡;此外,前胸腺中线粒体的形态变化和蜕皮酮合成相关基因的转录水平均与对应时期前胸腺合成蜕皮酮的活力一致。【结论】在变态发育时家蚕不同组织消亡发生的时间不同,虽然前胸腺和脂肪体在化蛹第1天同时出现细胞解离,但是前胸腺直到化蛹第2天都不发生细胞自噬和凋亡,可能与其持续合成蜕皮酮的功能有关。本研究为昆虫幼虫-蛹变态发育时期组织消亡的深入研究提供了理论依据与工作基础。     

白藜芦醇经PI3K/Akt/mTOR 信号通路诱导人肾癌786-O细胞自噬

白藜芦醇(resveratrol)可抑制人肾癌786-O细胞增殖,并诱导其凋亡,但是白藜芦醇对786-O细胞自噬(autophagy)的影响及机制尚不清楚。为探究其机制,体外培养786-O细胞,采用CCK-8检测786-O细胞活力;TUNEL染色检测786-O细胞凋亡;透射电子显微镜观察786-O细胞自噬体;吖啶橙染色观察786-O细胞自噬小泡;GFP-LC3质粒转染分析观察786-O细胞自噬体;Western印迹检测LC3、beclin-1、PI3K、p-PI3K、Akt、p-Akt、mTOR和p-mTOR的表达。结果显示,白藜芦醇以浓度和时间依赖性的方式抑制786-O细胞活力,并诱导细胞凋亡;与对照组相比,白藜芦醇使786-O细胞自噬增强;Western印迹结果显示,与对照组相比,白藜芦醇组LC3-II/LC3-I和Beclin-1显著增高(P0.01),表明白藜芦醇导致786-O细胞自噬体积累。与对照组相比,白藜芦醇使786-O细胞的p-PI3K/PI3K,p-Akt/Akt和p-mTOR/mTOR显著降低(P0.01),表明白藜芦醇可通过PI3K/Akt/mTOR信号通路增强自噬。综上所述,白藜芦醇通过抑制PI3K/Akt/mTOR信号通路从而诱导786-O细胞自噬。     

蜕皮激素对家蚕脂肪体中BmATG8蛋白亚细胞定位与细胞核皱缩的调控

【目的】昆虫脂肪体是物质合成代谢、先天免疫的重要器官。ATG8蛋白的亚细胞定位是细胞自噬的主要指标之一,细胞核皱缩是细胞凋亡的形态标记之一,目前家蚕 Bombyx mori 中尚未在蜕皮和变态发育进程中对BmATG8蛋白的细胞生物学变化进行观察。本研究旨在同时检测家蚕脂肪体细胞中BmATG8蛋白亚细胞定位和细胞核皱缩的时空变化,研究蜕皮激素(20E)信号对两者的调控作用。【方法】利用免疫荧光和Hoechst染色方法,分别在家蚕幼虫4龄第2天至预蛹第2天、5龄第2天幼虫注射20E (10 μg/头)后以及对游走期幼虫脂肪体中20E受体基因 usp 进行RNAi后,检测家蚕脂肪体中BmATG8蛋白定位和细胞核形态变化。【结果】在家蚕幼虫蜕皮和幼虫-蛹变态发育时期,BmATG8蛋白高水平存在于脂肪体细胞中,同时细胞核发生皱缩。在正常摄食时期,20E处理(10 μg/头)能够诱导细胞中大量出现BmATG8蛋白且存在于细胞质中并诱导细胞核皱缩。对 usp 基因进行RNAi后,脂肪体细胞内的BmATG8蛋白显著减少,同时细胞核皱缩减弱。【结论】家蚕BmATG8蛋白不仅在幼虫-蛹变态时期细胞质中大量存在,而且在幼虫蜕皮时期也大量表达,与细胞核的皱缩同时出现,BmATG8蛋白在细胞质中的定位与细胞核皱缩两者均受到 20E信号通路的调控。本研究为BmATG8蛋白功能及其调控机制的深入研究提供了重要的科学依据。     

本期重点推介

正全变态昆虫在变态发育过程中存在大量的组织细胞凋亡和自噬现象,可作为研究程序性细胞死亡的理想模型。家蚕Bombyx mori翅原基的生长分化过程中存在造血器官和翅囊等组织的消失现象,暗示可能存在细胞凋亡或自噬。华南师范大学生命科学学院刘学术和邓惠敏等以家蚕为材料,采用TUNEL法检测初蛹翅原基细胞凋亡情况,利用定量PCR检测幼虫和蛹期不同阶段翅原基中凋亡相关基因(Caspase     

家蚕蛹变态期丝腺组织的退化与细胞凋亡特征

利用形态学观察方法、分子生物学检测方法以及20-羟基蜕皮酮(20-hydroxyecdysone)和放线菌酮(cycloheximide)体外培养方法, 研究了家蚕Bombyx mori 蛹变态期丝腺组织的退化与细胞凋亡特征。显微镜的观察显示家蚕丝腺的逐渐退化发生在吐丝期间。DNA梯度电泳的分析表明程序性细胞死亡(programmed cell death)可能伴随发生在丝腺的退化过程中。在离体培养条件下, 用20-羟基蜕皮酮处理5龄第6天幼虫的丝腺, 导致的细胞凋亡提前于对照, 提示在进入蛹变态期前, 20-羟基蜕皮酮提早激发了介导家蚕丝腺细胞凋亡与水解机制的遗传调控级联系统。上述结果表明, 20-羟基蜕皮酮能够诱导家蚕丝腺组织在蛹变态期发生程序性细胞死亡。     

雷帕霉素对二种鳞翅目昆虫细胞自噬和凋亡的影响

以2种鳞翅目昆虫细胞为材料,采用雷帕霉素进行处理,初步研究自噬作用与昆虫细胞凋亡的关系。结果表明:雷帕霉素能够提高家蚕细胞系BMN-e细胞的自噬水平,并能诱导BMN-e细胞发生凋亡;自噬抑制剂3-甲基腺嘌呤能抑制雷帕霉素诱导的BMN-e细胞凋亡。相反,雷帕霉素虽能诱导斜纹夜蛾细胞系SL-HP细胞的自噬水平提高,但不能诱导斜纹夜蛾Spodoptera litura(Fabricius)细胞发生凋亡;雷帕霉素的预处理能抑制放线菌素D诱导的斜纹夜蛾细胞系SL-HP细胞发生凋亡;自噬抑制剂3-甲基腺嘌呤对放线菌素D诱导的细胞凋亡没有影响。因此家蚕Bombyx mori细胞自噬水平的提高与细胞凋亡具有正相关性,而斜纹夜蛾细胞自噬水平的提高与细胞凋亡不相关,相反还对细胞凋亡的诱导具有一定的抑制作用。     

家蚕凋亡相关基因研究进展

细胞凋亡指细胞受基因调控的自主的细胞死亡过程,是细胞为维持内环境稳态的一种手段。家蚕Bombyx mori是重要的鳞翅目模式昆虫,对其细胞凋亡机制的研究具有代表性。家蚕细胞凋亡不仅参与了整个变态发育过程,而且在家蚕天然免疫反应中扮演着重要角色。在家蚕卵-幼虫-蛹-成虫各阶段通过凋亡基因的调控促进组织退化及冗余细胞的清除,并且在家蚕抗家蚕核型多角体病毒(Bm NPV)过程中,细胞凋亡的发生对Bm NPV增殖的抑制也有着重要作用。本文就近年来家蚕细胞凋亡诱导因素、细胞凋亡相关基因的研究现状及通路和细胞凋亡对家蚕发育影响的研究进展进行综述,为解决目前家蚕细胞凋亡机制研究不足、内质网通路涉猎少、各通路间联系不清晰等问题,以及深入研究家蚕细胞凋亡并解析家蚕变态发育机制和天然免疫反应提供参考。     

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。     

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     

An in vitro analysis of ecdysteroid-elicited cell death in the prothoracic gland of Manduca sexta

The prothoracic glands of the tobacco hornworm, Manduca sexta, secrete the precursor of the insect molting hormone and normally undergo programmed cell death (PCD) during pupal-adult metamorphosis, between days 5 and 6 after pupation. This phenomenon can be elicited prematurely in vitro by the addition of 20-hydroxyecdysone (20E) to the gland cultures. To induce nuclear condensation in vitro in the glands from day-1 pupae, the effective dose range of 20E is 0.7-7 micrograms/ml and the minimum exposure period is 24 h. Prothoracic glands from different stages of pupal-adult development express different responsiveness to exogenous ecdysteroids. By utilizing terminal deoxynucleotidyl-transferase-mediated dUTP nick-end-labeling (TUNEL) and the apoptotic DNA laddering method together with transmission electron microscopy, it has been demonstrated that the ecdysteroid-induced cell death of the prothoracic glands occurs via not only apoptosis but also autophagy, i.e., the induced dying cells show both severe nuclear fragmentation and autophagic vacuole formation, characteristics typical of apoptotic and autophagic cell death. The composite data indicate that ecdysteroids regulate directly both apoptotic and autophagic mechanisms of PCD of the prothoracic glands.     

Lepidopteran larval midgut during prepupal instar: digestion or self-digestion?

Programmed cell death (PCD) is crucial in body restructuring during metamorphosis of holometabolous insects (those that have a pupal stage between the final larval and adult stages). Besides apoptosis, an increasing body of evidence indicates that in several insect species programmed autophagy also plays a key role in these developmental processes. We have recently characterized the midgut replacement process in Heliothis virescens larva, during the prepupal phase, responsible for the formation of a new pupal midgut. We found that the elimination of the old larval midgut epithelium is obtained by a combination of apoptotic and autophagic events. In particular, autophagic PCD completely digests decaying tissues, and provides nutrients that are rapidly absorbed by the newly formed epithelium, which is apparently functional at this early stage. The presence of both apoptosis and autophagy in the replacement of midgut cells in Lepidoptera offers the opportunity to investigate the functional peculiarities of these PCD modalities and if they share any molecular mechanism, which may account for possible cross-talk between them.     

棉铃虫幼虫中肠细胞脂筏的制备及鉴定

脂筏是细胞膜上富含胆固醇、鞘脂类和糖基磷脂酰肌醇锚着蛋白的去垢剂不溶性微结构域,被认为是多种细胞膜孔毒素在细胞表面形成寡聚体的平台。为研究脂筏与Bt毒素在细胞膜上形成寡聚体膜孔的关系,本文对棉铃虫Helicoverpa armigera幼虫中肠脂筏的制备与鉴定方法进行了研究。根据脂筏在低温（4℃）下不溶于去垢剂的特性,采用Triton X-100处理棉铃虫幼虫中肠刷状缘膜囊泡,溶解非脂质筏成分,以OptiPrep为介质进行密度梯度离心,分离去垢剂不溶组分,成功地得到了棉铃虫幼虫中肠上皮细胞的脂筏。再以脂筏的特有化学成分神经节苷脂GM1作为脂筏的标志分子,利用霍乱毒素β亚基能与GM1特异性结合的特性,以辣根过氧化物酶标记的霍乱毒素β亚基用点印迹法化学发光检测神经节苷脂的分布,从而对脂筏进行定性鉴定。结果表明我们建立的脂筏制备方法简便、易行,比传统的蔗糖梯度离心法大大缩短了制备所需时间。     

Upregulation of the expression of prodeath serine/threonine protein kinase for programmed cell death by steroid hormone 20-hydroxyecdysone

Serine/threonine protein kinases phosphorylate protein substrates to initiate further cellular events. Different serine/threonine protein kinases have varied functions despite their highly conserved homology. We propose prodeath-S/TK, a prodeath serine/threonine protein kinase from the lepidopteran insect Helicoverpa armigera, promotes programmed cell death (PCD) during metamorphosis. Prodeath-S/TK is expressed in various tissues with a high expression level during molting and metamorphosis by 20-hydroxyecdysone (20E) induction. Prodeath-S/TK is localized in the larval midgut during metamorphosis. Prodeath-S/TK knockdown by injecting dsRNA into larval hemocoel suppresses the 20E-induced metamorphosis and PCD, as well as downregulates a set of genes involved in the PCD and 20E signaling pathway. 20E upregulates prodeath-S/TK expression through its nuclear receptor EcR-B1 and USP1. Prodeath-S/TK overexpression in the epidermal cell line leads to PCD with DNA fragmentation and the activation of caspases 3 and 7. Prodeath-S/TK plays role in the cytoplasm. The N-terminal and C-terminal sequences of prodeath-S/TK determine its subcellular location. These data indicate that prodeath-S/TK participates in PCD by regulating gene expression in the 20E signaling pathway.     

Relationship between growth arrest and autophagy in midgut programmed cell death in Drosophila

Autophagy has been implicated in both cell survival and programmed cell death (PCD), and this may explain the apparently complex role of this catabolic process in tumourigenesis. Our previous studies have shown that caspases have little influence on Drosophila larval midgut PCD, whereas inhibition of autophagy severely delays midgut removal. To assess upstream signals that regulate autophagy and larval midgut degradation, we have examined the requirement of growth signalling pathways. Inhibition of the class I phosphoinositide-3-kinase (PI3K) pathway prevents midgut growth, whereas ectopic PI3K and Ras signalling results in larger cells with decreased autophagy and delayed midgut degradation. Furthermore, premature induction of autophagy is sufficient to induce early midgut degradation. These data indicate that autophagy and the growth regulatory pathways have an important relationship during midgut PCD. Despite the roles of autophagy in both survival and death, our findings suggest that autophagy induction occurs in response to similar signals in both scenarios.     

Lepidopteran Larval Midgut During Prepupal Instar: Digestion or Self-Digestion?

Programmed cell death (PCD) is crucial in body restructuring during metamorphosis of holometabolous insects (those that have a pupal stage between the final larval and adult stages). Besides apoptosis, an increasing body of evidence indicates that in several insect species programmed autophagy also plays a key role in these developmental processes. We have recently characterized the midgut replacement process in Heliothis virescens larva, during the prepupal phase, responsible for the formation of a new pupal midgut. We found that the elimination of the old larval midgut epithelium is obtained by a combination of apoptotic and autophagic events. In particular, autophagic PCD completely digests decaying tissues, and provides nutrients that are rapidly absorbed by the newly formed epithelium, which is apparently functional at this early stage. The presence of both apoptosis and autophagy in the replacement of midgut cells in Lepidoptera offers the opportunity to investigate the functional peculiarities of these PCD modalities and if they share any molecular mechanism, which may account for possible cross-talk between them.

Addendum to:

Programmed Cell Death and Stem Cell Differentiation are Responsible for Midgut Replacement in Heliothis virescens During Prepupal Instar

G. Tettamanti, A. Grimaldi, M. Casartelli, E. Ambrosetti, B. Ponti, T. Congiu, R. Ferrarese, M.L. Rivas-Pena, F. Pennacchio and M.D. Eguileor

Cell Tissue Res 2007; In press     

Shaping organisms with apoptosis

Programmed cell death is an important process during development that serves to remove superfluous cells and tissues, such as larval organs during metamorphosis, supernumerary cells during nervous system development, muscle patterning and cardiac morphogenesis. Different kinds of cell death have been observed and were originally classified based on distinct morphological features: (1) type I programmed cell death (PCD) or apoptosis is recognized by cell rounding, DNA fragmentation, externalization of phosphatidyl serine, caspase activation and the absence of inflammatory reaction, (2) type II PCD or autophagy is characterized by the presence of large vacuoles and the fact that cells can recover until very late in the process and (3) necrosis is associated with an uncontrolled release of the intracellular content after cell swelling and rupture of the membrane, which commonly induces an inflammatory response. In this review, we will focus exclusively on developmental cell death by apoptosis and its role in tissue remodeling.     

Distinct requirements of Autophagy-related genes in programmed cell death

Although most programmed cell death (PCD) during animal development occurs by caspase-dependent apoptosis, autophagy-dependent cell death is also important in specific contexts. In previous studies, we established that PCD of the obsolete Drosophila larval midgut tissue is dependent on autophagy and can occur in the absence of the main components of the apoptotic pathway. As autophagy is primarily a survival mechanism in response to stress such as starvation, it is currently unclear if the regulation and mechanism of autophagy as a pro-death pathway is distinct to that as pro-survival. To establish the requirement of the components of the autophagy pathway during cell death, we examined the effect of systematically knocking down components of the autophagy machinery on autophagy induction and timing of midgut PCD. We found that there is a distinct requirement of the individual components of the autophagy pathway in a pro-death context. Furthermore, we show that TORC1 is upstream of autophagy induction in the midgut indicating that while the machinery may be distinct the activation may occur similarly in PCD and during starvation-induced autophagy signalling. Our data reveal that while autophagy initiation occurs similarly in different cellular contexts, there is a tissue/function-specific requirement for the components of the autophagic machinery.There is a fundamental requirement for multicellular organisms to remove excess, detrimental, obsolete and damaged cells by programmed cell death (PCD).^{1, 2} In the majority of cases caspase-dependent apoptosis is the principle pathway of PCD; however, there are other modes of cell death with important context-specific roles, such as autophagy.^{3, 4} Defects in autophagy have significant adverse consequences to normal cellular functions and contribute to the pathogenesis of numerous human diseases. This is particularly evident in cancer where depending on the context autophagy can have tumour-suppressing or -promoting roles. Given the number of clinical trials targeting autophagy in cancer therapy, it will be critically important to understand the context-specific regulation and functions of autophagy.⁵Autophagy is a highly conserved multi-step catabolic process characterised by the encapsulation of part of the cytoplasm inside a double-membrane vesicle called the autophagosome. Autophagosomes then fuse with lysosomes and the components are subsequently degraded by acidic lysosomal hydrolases.⁶ The process of autophagy can be functionally divided into four groups: (1) serine/threonine kinase Atg1 (ULK1 in mammals) complex and its regulators responsible for the induction of autophagy; (2) the class III phosphatidylinositol 3-kinase (PI3K) complex, which involves Atg6 and functions in the nucleation of the autophagosome; (3) the Atg8 and Atg12 conjugation systems, which involves several Autophagy-related (Atg) proteins essential for the expansion of autophagosome; and (4) Atg9 and its associated proteins including Atg2 and Atg18, which aids the recycling of lipid and proteins.⁷ In addition, several of the Atg proteins can function in multiple steps. For example, Atg1 interacts with proteins with different functions (e.g. Atg8, Atg18 and others), suggesting that it is not only required for initiation but also participates in the formation of autophagosomes.⁸ It is yet to be fully established if the context-specific functions of autophagy have distinct requirements for select components of the autophagy pathway.High levels of autophagy are induced in response to stress, such as nutrient deprivation, intracellular stress, high temperature, high culture density, hormones and growth factor deprivation.^{9, 10} The target of rapamycin (TOR) pathway is a central mediator in regulating the response to nutrients and growth signalling. TOR functions in two distinct complexes, with regulatory associated protein of TOR (Raptor) in TOR complex 1 (TORC1) or with rapamycin insensitive companion of TOR (Rictor) in TOR complex 2 (TORC2).^{11, 12, 13, 14, 15} Of these, TORC1 regulates autophagy; in nutrient-rich conditions, TORC1 activity inhibits the Atg1 complex preventing autophagy and cellular stress such as starvation leads to inactivation of TORC1 promoting a dramatic increase in autophagy. TORC2 can also negatively regulate autophagy via the FoxO3 complex in specific context.¹⁶Most direct in vivo evidence for a role of autophagy in cell death has emerged from studies in Drosophila.⁵ Developmentally regulated removal of the Drosophila larval midgut can occur in the absence of canonical apoptosis pathway, whereas inhibiting autophagy delays the process.^{17, 18} Also, inhibition of autophagy leads to delayed degradation of larval salivary glands in Drosophila.¹⁹ Genetic studies have shown that many of the Atg genes known to be involved in starvation-induced autophagy in the Drosophila fat body are also involved in autophagy-dependent degradation of salivary glands and midgut.^{5, 20, 21} However, systematic studies to test whether starvation-induced autophagy and autophagy required for PCD require identical components have not been carried out, and there are some observations suggesting that there may be distinctions. For example, in Atg7-null mutants autophagy is perturbed but the larval–adult midgut transition proceeds normally.²² In addition, a novel Atg7- and Atg3-independent autophagy pathway is required for cell size reduction during midgut removal.²³ Here we show that downregulation of TORC1 activity is required for induction of autophagy during midgut removal. Surprisingly, however, the requirement of part of the autophagy machinery during midgut degradation was found to be distinct to that which is required during autophagy induced by starvation. We report that Atg genes required for autophagy initiation, Atg8a and recycling are all essential for autophagy-dependent midgut removal, whereas other components of the elongation and nucleation steps are not essential.