自噬体膜的来源

细胞自噬是指细胞通过自噬-溶酶体(autolysosome)降解变性蛋白聚集物和受损细胞器的过程. 自噬对于细胞内环境的稳态、物质的平衡、胚胎发育以及疾病的发生发挥重要作用. 在电镜下观察,自噬体膜是一个双层脂质膜结构. 细胞中因缺乏除了自噬相关蛋白9 (autophagy-related protein 9,ATG9)以外的自噬体膜相关蛋白,故难以确定自噬体膜的来源. 自噬体膜的来源也因此成为目前自噬研究领域的热点问题. 关于自噬体膜的来源,学术界存在两种观点：一种认为自噬体膜是细胞在自噬体组装位点(pre-autophagosomal structure, PAS)重新合成的;另一种观点则认为自噬体膜来源于细胞已有的某些细胞器(如内质网、高尔基体、内吞体、质膜和线粒体). 该文综述了近年有关自噬体膜来源于细胞已有的某些细胞器的研究进展,旨在为相关领域的研究提供参考.     

植物细胞自噬研究进展

细胞自噬是一类依赖于溶酶体和液泡的蛋白质降解途径。在动物细胞中, 靶物质通过自噬体包裹被运送到溶酶体中,由特定的水解酶降解; 而植物和酵母细胞中该过程在液泡内进行。近年来, 在模式植物拟南芥(Arabidopsis thaliana)中鉴定到多个关键ATG基因, 它们对植物细胞自噬体的形成及自噬调控起到关键作用。该文全面综述了植物细胞自噬的调控及其在植物逆境胁迫中的生理功能。     

活性氧对植物自噬调控的研究进展

自噬是一种在真核生物中高度保守的降解细胞组分的生物过程, 在饥饿、衰老和病菌感染等过程中起关键作用。而活性氧是有氧生物在正常或胁迫条件下产生的一种代谢副产物, 在植物的生长发育、胁迫适应和程序性细胞死亡过程中起重要作用。最新研究结果表明, 当植物受到病菌感染产生超敏反应时活性氧和自噬在程序性细胞死亡、生长发育和胁迫适应过程中起重要调控作用。因此, 该文结合最新的研究进展, 从活性氧的种类及特点、自噬的分子基础以及活性氧在植物自噬中的作用等方面, 探讨了活性氧与植物自噬之间的信号转导关系。     

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。     

基于转录组测序的Cd胁迫下芹菜细胞自噬相关基因的筛选

细胞自噬是植物逆境应答过程中最常见的保护机制之一。动物中,自噬相关基因抵御镉(Cd)毒害的功能研究较清楚,但植物却知之甚少。文中以芹菜品种‘皇后’为试材,采用外源Cd(终浓度为0、2、4、8mg/L)添加营养液水培处理,利用转录组测序(RNA-seq)技术筛选细胞自噬相关差异基因并进行q RT-PCR验证。结果表明Cd胁迫对芹菜植株产生了明显的毒害作用,并与浓度间产生了量效关系。在筛选的8个差异表达的自噬相关基因中,ATG8a、ATG8f、ATG13、AMPK-1、AMPK-2基因随Cd浓度升高表达上调,ATG12、VPS30和VPS34则先上调后下降,说明自噬相关基因可能通过表达上调增加了自噬小体结构以抵御Cd毒性作用;而高浓度Cd(8mg/L)可能超出芹菜的耐受范围,导致多个自噬基因又出现表达下调趋势。以上结果有助于后期自噬相关基因的功能研究,为进一步探讨芹菜对Cd胁迫的耐性机制提供参考依据。     

细胞自噬研究进展

细胞自噬是真核生物在进化过程中高度保守、基于溶酶体的一种胞内降解途径,对维持细胞和生物体的稳态平衡有重要作用。研究表明,自噬参与生物体发育、免疫反应、代谢调节、细胞凋亡和衰老等多种过程。自噬功能异常与神经退行性疾病、肿瘤等的发生发展密切相关。近30年,我们对细胞自噬的认识无论是在分子机制上还是生理功能方面都有了长足的发展。为进一步加深对细胞自噬的认识,该文主要对细胞自噬的概念、自噬核心机器的组成及调控机制、自噬类型、生理功能及与疾病的关系作一简单综述。     

编者按: 自噬与疾病

自噬是细胞的一个重要生物学功能。细胞通过对自噬底物的识别、自噬囊泡的形成,再经过与溶酶体的融合,清除老化细胞器以及降解长周期蛋白和异常积聚蛋白。因此,自噬在蛋白质的代谢、细胞器更新以及组织发育中有着重要作用,其功能调控直接参与了机体对细胞稳态的维持和对疾病的抵抗。目前已有大量研究表明,自噬与疾病的发生密切相关,如心血管病、肿瘤、炎症和免疫以及神经退行性疾病等。近年来,自噬研究得到了国内外科学家的广泛重视,研究论文的数量直线上升。科技部和国家自然科学基金委均已资助相关课题,这进一步促进了我国在自噬研究领域的发展。我国科学家在自噬的机制和疾病关系研究中也取得了重大进展,许多研究成果已经走在世界前沿。本刊对自噬这一研究领域一直十分关注,为促进对该领域现状及发展的了解,本期汇集了6 篇述评和1 篇研究论文,作为自噬研究专题发表,以飨读者。 本专题主要对自噬与一些相关疾病关系的现状和发展进行了评述,并对自噬研究方法学和基本机制也进行了综述,同时报道了在果蝇脊髓小脑变性3型动物模型中开展的关于自噬与Sir2发挥神经保护作用相关性的研究,反映了目前自噬研究的一个侧面。马泰等主要综述了目前自噬研究的技术和方法进展,评价了自噬的评估指标和这些自噬方法学的应用,提供了一个自噬方法学上的基础交流。吴葩等介绍了PI3K复合物中各组分蛋白与细胞自噬的关系,详细阐述了该通路在细胞自噬调节中的最新研究进展,为这一信号通路研究提供了信息。何云凌等很好地总结了低氧环境诱导线粒体自噬发生的相关分子机制,对参与调节线粒体自噬的重要蛋白进行了系统的描述,为目前人们普遍关注的线粒体自噬与疾病的关系提供了前沿资料。谢凤等对心脏疾病状态下细胞自噬的发生、发展及其对心脏疾病的影响进行了详细的论述,有助于研究者从自噬的角度来探讨心脏疾病的发生发展及其机制。林小龙等围绕当前热点问题对自噬与血管内皮细胞的关系作了描述,介绍了血管内皮细胞在各种药物刺激以及相关蛋白质过表达情况下对于自噬的反应以及所引起的下游应答,探讨了自噬与血管疾病发病的相互关系。向波等介绍了细胞自噬与肿瘤的发生发展的关系,描述了炎症-自噬-肿瘤的相关性以及自噬可能的抑瘤机制。曾爱源等利用果蝇的遗传性脊髓小脑变性3 型模型,研究了Sir2在自噬存在情况下对转基因果蝇的神经保护作用,并发现在自噬抑制后Sir2的保护作用明显减弱,揭示了Sir2通过自噬保护神经元、减缓神经变性蛋白损伤的作用机制。 本刊欢迎和期待更多、更好的有关自噬研究的来稿,以更广泛和深入地促进我国自噬研究领域的发展和学术交流。     

自噬与肿瘤耐药的研究进展

自噬(autophagy)是真核细胞特有的普遍生命现象,通过降解受损细胞器和大分子并实现细胞内成分的循环利用。在维持细胞自我稳态、促进细胞生存方面起重要作用,广泛参与多种生理和病理过程。自噬活性与肿瘤及其耐药密切相关,所以就自噬及其在肿瘤耐药中作用的研究进展进行简要综述。     

溶酶体途径在细胞自噬过程中的功能意义

溶酶体具有高度保守的异质性,是细胞自噬的关键细胞器。细胞质中的蛋白质和细胞器最终在溶酶体降解,故溶酶体在维持细胞结构和功能的平衡方面起着重要生理作用。通过自噬溶酶体途径,细胞可清除某些病原体并参与抗原呈递。细胞自噬与异噬经溶酶体密切联系。自噬过程中溶酶体功能障碍与某些疾病和衰老等相关。对细胞自噬的溶酶体途径及其功能意义作了概述。     

自噬在急性心肌梗死发病中作用的研究进展

自噬是生物细胞内普遍存在且高度保守的一种生理过程,其通过溶酶体融合降解细胞内的大分子组分、受损的细胞器以及侵入胞内的病原菌,以达到维持细胞稳态的目的。自噬在多种疾病的发生发展中也发挥十分重要的作用,尤其是心血管疾病。自噬对其病程的发展可以发挥两种截然不同的作用。适当的自噬作用可以降低炎症反应和氧化应激促进细胞的存活,以及通过减少泡沫细胞的形成而对维持心血管的正常功能起一个保护作用;但过度的自噬作用会对细胞造成不可逆的损伤,诱导细胞发生不依赖于caspase的自噬性细胞死亡,增加局部的炎症反应,从而促进动脉粥样硬化病变的发展。本文就自噬在急性心肌梗死发生发展中作用的研究进展进行了综述,探讨自噬成为预防及治疗心血管疾病新靶标的可能性。     

Phagocytosis of cells dying through autophagy evokes a pro-inflammatory response in macrophages

Autophagy as a natural part of cellular homeostasis usually takes place unnoticed by neighboring cells. However, its co-occurrence with cell death may contribute to the clearance of these dying cells by recruited phagocytes. Autophagy associated with programmed cell death has recently been reported to be essential for presentation of phoshatidylserine (PS) on the cell surface (Qu et al. 2007) that has a key role in the clearance of apoptotic cells. Recently, we have demonstrated that upon triggering cell death by autophagy in MCF-7 cells, the corpses were efficiently phagocytosed by both human macrophages and non-dying MCF-7 cells. Death as well as engulfment could be prevented by inhibiting autophagy. Based on our data, two molecular mechanisms have been proposed for the uptake of cells which die through autophagy: a PS-dependent pathway which was exclusively used by the living MCF-7 cells acting as non-professional phagocytes, and a PS-independent uptake mechanism that was active in macrophages acting as professional phagocytes. Several lines of evidence suggest that macrophages utilize calreticulin-mediated recognition, tethering, tickling and engulfment processes. Phagocytic uptake of cells dying through autophagy by macrophages leads to a pro-inflammatory response characterized by the induction and secretion of IL-6, TNFalpha, IL-8 and IL-10.     

Autophagy in filamentous fungi

Autophagy is a ubiquitous, non-selective degradation process in eukaryotic cells that is conserved from yeast to man. Autophagy research has increased significantly in the last ten years, as autophagy has been connected with cancer, neurodegenerative disease and various human developmental processes. Autophagy also appears to play an important role in filamentous fungi, impacting growth, morphology and development. In this review, an autophagy model developed for the yeast Saccharomyces cerevisiae is used as an intellectual framework to discuss autophagy in filamentous fungi. Studies imply that, similar to yeast, fungal autophagy is characterized by the presence of autophagosomes and controlled by Tor kinase. In addition, fungal autophagy is apparently involved in protection against cell death and has significant effects on cellular growth and development. However, the only putative autophagy proteins characterized in filamentous fungi are Atg1 and Atg8. We discuss various strategies used to study and monitor fungal autophagy as well as the possible relationship between autophagy, physiology, and morphological development.     

Does Autophagy Contribute To Cell Death?

Autophagy (specifically macroautophagy) is an evolutionarily conserved catabolic process where the cytoplasmic contents of a cell are sequestered within double membrane vacuoles, called autophagosomes, and subsequently delivered to the lysosome for degradation. Autophagy can function as a survival mechanism in starving cells. At the same time, extensive autophagy is commonly observed in dying cells, leading to its classification as an alternative form of programmed cell death. The functional contribution of autophagy to cell death has been a subject of great controversy. However, several recent loss-of-function studies of autophagy (Atg) genes have begun to address the roles of autophagy in both cell death and survival. Here, we review the emerging evidence in favor of and against autophagic cell death, discuss the possible roles that autophagic degradation might play in dying cells, and identify salient issues for future investigation.     

Eat your heart out: Role of autophagy in myocardial ischemia/reperfusion

Autophagy is an important process in the heart which is responsible for the normal turnover of long lived proteins and organelles. Inhibition of autophagy leads to the accumulation of protein aggregates and dysfunctional organelles which can cause cell death. Autophagy occurs at low basal levels under normal conditions in the heart, but is rapidly upregulated in response to stress such as nutrient deprivation, hypoxia, and pressure overload. Autophagy is a prominent feature of myocardial ischemia and reperfusion. Although enhanced autophagy is often seen in dying cardiac myocytes, the functional significance of autophagy under these conditions is not clear. Upregulation of autophagy has been reported to protect cardiac cells against death as well as be the cause of it. Here, we review the evidence that autophagy can have both beneficial and detrimental roles in the myocardium, and discuss potential mechanisms by which autophagy provides protection in cells.     

Eat your heart out: Role of autophagy in myocardial ischemia/reperfusion

Autophagy is an important process in the heart which is responsible for the normal turnover of long lived proteins and organelles. Inhibition of autophagy leads to the accumulation of protein aggregates and dysfunctional organelles which can cause cell death. Autophagy occurs at low basal levels under normal conditions in the heart, but is rapidly upregulated in response to stress such as nutrient deprivation, hypoxia, and pressure overload. Autophagy is a prominent feature of myocardial ischemia and reperfusion. Although enhanced autophagy is often seen in dying cardiac myocytes, the functional significance of autophagy under these conditions is not clear. Upregulation of autophagy has been reported to protect cardiac cells against death as well as be the cause of it. Here, we review the evidence that autophagy can have both beneficial and detrimental roles in the myocardium, and discuss potential mechanisms by which autophagy provides protection in cells.     

细胞自噬在肿瘤化疗耐药中的作用

肿瘤有多种机制产生化疗药物耐药性．自噬是一种在正常细胞和病理细胞中普遍存在的生理机制,调控自噬的分子和信号传导通路错综复杂．自噬与凋亡有着独特的交叉联系,使得自噬在肿瘤化疗耐药性中发挥着促进或抑制耐药的双重作用．自噬在肿瘤耐药中的这种截然相反的作用与化疗给药浓度、细胞类型、自噬强度等因素有关,但具体机制尚未完全明确．然而,将自噬途径作为治疗肿瘤、降低化疗药物耐药性的靶点有着广阔的应用前景．     

Does autophagy contribute to cell death?

Autophagy (specifically macroautophagy) is an evolutionarily conserved catabolic process where the cytoplasmic contents of a cell are sequestered within double membrane vacuoles, called autophagosomes, and subsequently delivered to the lysosome for degradation. Autophagy can function as a survival mechanism in starving cells. At the same time, extensive autophagy is commonly observed in dying cells, leading to its classification as an alternative form of programmed cell death. The functional contribution of autophagy to cell death has been a subject of great controversy. However, several recent loss-of-function studies of autophagy (atg) genes have begun to address the roles of autophagy in both cell death and survival. Here, we review the emerging evidence in favor of and against autophagic cell death, discuss the possible roles that autophagic degradation might play in dying cells, and identify salient issues for future investigation.     

综述: 影响血管内皮细胞自噬的因素及其相关机制探讨

自噬对维持细胞自身的稳定及细胞成分更新、保持正常的生理状态起着至关重要的作用．机体在生理和病理过程中都存在自噬,基础状态下的自噬对细胞具有保护和修复作用,而自噬过度激活会引起细胞的损伤及死亡．近年来,对自噬的研究主要集中于肿瘤细胞,而对正常细胞的自噬研究较少．血管内皮细胞作为人体中最活跃的细胞之一,其功能变化与心血管疾病的发生和发展有密切相关．本文对影响血管内皮细胞自噬的因素及其相关机制进行综述．     

Autophagy is required for necrotic cell death in Caenorhabditis elegans

Autophagy is the main process for bulk protein and organelle recycling in cells under extracellular or intracellular stress. Deregulation of autophagy has been associated with pathological conditions such as cancer, muscular disorders and neurodegeneration. Necrotic cell death underlies extensive neuronal loss in acute neurodegenerative episodes such as ischemic stroke. We find that excessive autophagosome formation is induced early during necrotic cell death in C. elegans. In addition, autophagy is required for necrotic cell death. Impairment of autophagy by genetic inactivation of autophagy genes or by pharmacological treatment suppresses necrosis. Autophagy synergizes with lysosomal catabolic mechanisms to facilitate cell death. Our findings demonstrate that autophagy contributes to cellular destruction during necrosis. Thus, interfering with the autophagic process may protect neurons against necrotic damage in humans.     

Targeting autophagy for combating chemoresistance and radioresistance in glioblastoma

Autophagy is an evolutionarily conserved catabolic process that plays an essential role in maintaining cellular homeostasis by degrading unneeded cell components. When exposed to hostile environments, such as hypoxia or nutrient starvation, cells hyperactivate autophagy in an effort to maintain their longevity. In densely packed solid tumors, such as glioblastoma, autophagy has been found to run rampant due to a lack of oxygen and nutrients. In recent years, targeting autophagy as a way to strengthen current glioblastoma treatment has shown promising results. However, that protective autophagy inhibition or autophagy overactivation is more beneficial, is still being debated. Protective autophagy inhibition would lower a cell’s previously activated defense mechanism, thereby increasing its sensitivity to treatment. Autophagy overactivation would cause cell death through lysosomal overactivation, thus introducing another cell death pathway in addition to apoptosis. Both methods have been proven effective in the treatment of solid tumors. This systematic review article highlights scenarios where both autophagy inhibition and activation have proven effective in combating chemoresistance and radioresistance in glioblastoma, and how autophagy may be best utilized for glioblastoma therapy in clinical settings.