内质网应激与自噬及其交互作用影响内皮细胞凋亡

内质网应激是普遍存在于真核细胞中的应激-防御机制。在内环境稳态遭到破坏的情况下,未折叠蛋白质反应的3条信号通路,分别通过增强蛋白质折叠能力、减少蛋白质生成和促进内质网相关蛋白质降解等途径缓解细胞内压力。同时,也通过多种分子信号机制调控细胞凋亡。自噬是一种生理性的降解机制。通过形成自噬泡并与溶酶体结合摄取并水解胞内受损细胞器和蛋白质等,清除代谢废物,维持细胞正常功能。自噬缺陷或过度激活均可导致细胞凋亡或非程序性死亡。自噬的程度和细胞内压力水平有关。内质网应激通过未折叠蛋白质反应和Ca²⁺浓度变化及其相关分子信号调控自噬。自噬又可反馈性调节内质网应激反应,二者相互作用,在内皮细胞凋亡过程中发挥重要作用。未来内质网应激和自噬可作为药物靶点为内皮相关性疾病提供诊疗策略。     

蛋白质乙酰化修饰在细胞自噬中的作用进展

蛋白质翻译后修饰与细胞自噬的关系是近几年来的研究热点.自噬的发生需要多类蛋白质协同完成.在此过程中,蛋白质的乙酰化修饰对细胞自噬起着十分重要的调节作用.本文就近年来的研究从两个角度进行了总结:一方面总结了蛋白质乙酰化修饰与自噬关系的功能性研究,主要涉及组蛋白、转录因子以及与乙酰辅酶A代谢过程中相关酶的研究进展;另一方面概括了细胞自噬过程中蛋白质乙酰化修饰组学的研究进展.乙酰化酶/去乙酰化酶是蛋白质乙酰化修饰水平的主要调控者,阐明酶与底物的关系将是深入探讨乙酰化修饰与细胞自噬关系的关键所在.这些研究结果必将为揭开细胞自噬机制提供理论基础.     

线粒体自噬在缺氧条件下适应机制的研究进展

由于线粒体能敏感地感受机体内氧浓度的变化,缺氧时会影响线粒体氧化磷酸化过程中电子传递链的正常功能,抑制ATP生成,产生大量活性氧(ROS)。ROS蓄积导致氧化损伤细胞内脂质、DNA和蛋白质等大分子物质,线粒体肿胀,通透性转换孔开放,释放细胞色素C等促凋亡因子,最终严重影响细胞的存活。因此这些功能异常或受损线粒体是缺氧应激状态下细胞是否存活的危险因素,及时清除这些线粒体,对维持线粒体质量、数量及细胞稳态具有重要意义。线粒体自噬是近年来发现的细胞适应缺氧的一种防御性代谢过程,它通过自噬途径选择性清除损伤、衰老和过量产生ROS的线粒体,促进线粒体更新和循环利用,确保细胞内线粒体功能稳定,保护缺氧应激下细胞的正常生长发挥重要的调节作用。本文就线粒体自噬在缺氧条件下发生过程、参与相关蛋白及调节机制等方面研究进行了综述。     

细胞自噬与肿瘤耐药

细胞自噬是一种细胞自我降解的过程,在适应代谢应激、保持基因组完整性及维持内环境稳定方面发挥重要作用. 在肿瘤治疗中,凋亡耐受是产生肿瘤耐药的重要机制. 细胞自噬可防止抗肿瘤药诱导的凋亡,促进肿瘤耐药. 然而,自噬性细胞死亡可能是凋亡耐受肿瘤细胞的一种死亡方式. 因此,细胞自噬对肿瘤细胞的耐药性有双重影响. 本文综述了细胞自噬的分子机制、细胞自噬与凋亡的关系、细胞自噬与肿瘤耐药以及治疗的主要研究进展.     

自噬的相关分子机制

细胞自噬是真核生物中高度保守的一类生物学途径,它通过降解细胞浆内不同组分,维持细胞自身平衡并帮助细胞在应激情况下生存。自噬在生物体生长发育、免疫防御、肿瘤抑制及神经退行性疾病中都有重大的意义。哺乳动物细胞中,自噬过程主要由自噬相关蛋白（Atg）所形成的一系列复合物所调控,这些蛋白质分别在自噬的启动、自噬泡的形成、延伸及成熟和降解过程中发挥重要的作用。在此,本文针对一些重要的自噬相关蛋白质对近年来自噬分子机制的研究进展做一总结。     

自噬的相关分子机制北大核心CSCD

细胞自噬是真核生物中高度保守的一类生物学途径,它通过降解细胞浆内不同组分,维持细胞自身平衡并帮助细胞在应激情况下生存。自噬在生物体生长发育、免疫防御、肿瘤抑制及神经退行性疾病中都有重大的意义。哺乳动物细胞中,自噬过程主要由自噬相关蛋白(Atg)所形成的一系列复合物所调控,这些蛋白质分别在自噬的启动、自噬泡的形成、延伸及成熟和降解过程中发挥重要的作用。在此,本文针对一些重要的自噬相关蛋白质对近年来自噬分子机制的研究进展做一总结。     

细胞自噬与肿瘤发生的关系

细胞自噬(autophagy)是将细胞内受损、变性或衰老的蛋白质以及细胞器运输到溶酶体进行消化降解的过程.正常生理情况下,细胞自噬利于细胞保持自稳状态;在发生应激时,细胞自噬防止有毒或致癌的损伤蛋白质和细胞器的累积,抑制细胞癌变;然而肿瘤一旦形成,细胞自噬为癌细胞提供更丰富的营养,促进肿瘤生长.因此,在肿瘤发生发展的过程中,细胞自噬的作用具有两面性.尽管大多数抑癌蛋白可以激活细胞自噬这一结论被广泛接受,但p53作为重要的抑癌蛋白,在细胞核和细胞浆不同的亚细胞定位中对细胞自噬有着截然相反的调控.对于细胞自噬和癌症发生之间关系亟待深入的研究,这将会有助于人类更好地认识并最终攻克癌症.本文将针对细胞自噬与肿瘤发生过程中主要的信号调节通路展开介绍.     

细胞自噬与肿瘤

自噬是广泛存在于真核细胞内的一种细胞分解自身构成成分的生命现象.细胞内的双层膜结构与溶酶体结合后其内包裹的受损、变形或衰老细胞器蛋白质等被水解酶类降解.细胞自噬具有多种生理功能,生命体借此维持蛋白质代谢平衡及细胞环境稳定,这一过程在细胞清除废物、结构重建、生长发育调节中发挥重要作用. 细胞自噬也与肿瘤的存活和死亡等过程密切相关. 近年来对细胞自噬的研究有了较大的深入,本文主要对自噬体的形态和发生过程及其分子机制、信号调节通路、自噬研究的检测方法,以及自噬与细胞凋亡和肿瘤发生的关系等方面进行概述,以期较全面地了解细胞自噬作用和最新研究动态.     

自噬发生中的ROS调节机制

活性氧是细胞代谢中产生的有很强反应活性的分子,易将邻近分子氧化,并参与细胞内多种信号转导途径,对相关生理过程进行调控．自噬是真核细胞通过溶酶体机制对自身组分进行降解再利用的过程,在细胞应激及疾病发生等过程中发挥重要作用．本文对活性氧和自噬相关调节进行分类介绍,根据新近研究进展,从活性氧参与的自噬性死亡、自噬性存活以及线粒体自噬3方面探讨了相关信号转导机制,对活性氧作为信号分子参与的自噬调控途径做一总结和介绍．     

ULK1蛋白激酶通过自噬及非自噬途径介导的生理、病理和疾病研究进展

ULK1 (unc-51 like autophagy activating kinase 1)是一种哺乳动物丝/苏氨酸激酶,其作为自噬起始复合物的关键分子可介导细胞发生经典自噬反应。经典自噬反应是细胞通过由一系列自噬相关蛋白质介导的自噬溶酶体途径,将废弃或受损的蛋白质、细胞器经过自噬体的包裹后与溶酶体结合,继而使蛋白质、细胞器在溶酶体内降解。因此, ULK1介导的经典自噬反应是细胞质量控制的重要组成部分。除了介导经典自噬反应以外,ULK1也发挥着独立于自噬反应之外的重要作用,比如:促进细胞凋亡、强化磷酸戊糖途径、调控固有免疫反应等。此外, ULK1在糖脂代谢、红细胞形成、内质网应激、肿瘤、神经系统疾病中也发挥着重要作用。鉴于ULK1的重要性,本综述围绕ULK1蛋白激酶参与的经典自噬反应和不依赖自噬的反应及其介导的生理、病理和疾病过程展开论述。     

The amplified cancer gene LAPTM4B promotes tumor growth and tolerance to stress through the induction of autophagy

Autophagy is a fundamental salvage pathway that encapsulates damaged cellular components and delivers them to the lysosome for degradation and recycling. This pathway usually conducts a protective cellular response to nutrient deprivation and various stresses. Tumor cells live with metabolic stress and use autophagy for their survival during tumor progression and metastasis. Genomic instability in tumor cells may result in amplification of crucial gene(s) for autophagy and upregulate the autophagic pathway. We demonstrate that a cancer-associated gene, LAPTM4B, plays an important role in lysosomal functions and is critical for autophagic maturation. Its amplification and overexpression promote autophagy, which renders tumor cells resistant to metabolic and genotoxic stress and results in more rapid tumor growth.     

Viruses and the autophagy machinery

Autophagy is a major intracellular pathway for degradation and recycling of long-lived proteins and cytoplasmic organelles that plays an essential role in maintenance of homeostasis in response to starvation and other cellular stresses. Autophagy is also important for a variety of other processes including restriction of intracellular pathogen replication. Our understanding of the fascinating relationship between viruses and the autophagy machinery is still in its infancy but it is clear that autophagy is a newly recognized facet of innate and adaptive immunity against viral infection. Although the autophagy pathway is emerging as a component of host defense, certain viruses have developed strategies to counteract these antiviral mechanisms, and others appear to have co-opted the autophagy machinery as proviral host factors favoring viral replication. The complex interplay between autophagy and viral infection will be discussed in this review.     

To be or not to be, the level of autophagy is the question: dual roles of autophagy in the survival response to starvation

Autophagy is an evolutionally conserved lysosomal pathway used to degrade and turn over long-lived proteins and cytoplasmic organelles. Since autophagy was discovered, it has been thought to act as a pro-survival response to several stresses, especially starvation, at the cell and organism levels by providing recycled metabolic substrates to maintain energy homeostasis. However, several recent studies suggest that autophagy also plays a pro-death role through an autophagic cell death pathway mostly at the cellular level. The mechanism by which autophagy could perform these seemingly opposite roles as a pro-survival and a pro-death mechanism remained elusive until recently. Using C. elegans as a model system, we found that physiological levels of autophagy promote optimal survival of C. elegans during starvation, but either insufficient or excessive levels of autophagy render C. elegans starvation-hypersensitive. Furthermore, we found that muscarinic acetylcholine receptor signaling is important in modulating the level of autophagy during starvation, perhaps through DAP kinase and RGS-2. Our recent study provides in vivo evidence that levels of autophagy are critical in deciding its promotion of either survival or death: Physiological levels of autophagy are pro-survival, whereas insufficient or excessive levels of autophagy are pro-death.     

Genes for plant Autophagy: Functions and interactions

Autophagy, or self-consuming of cytoplasmic constituents in a lytic compartment, plays a crucial role in nutrient recycling, development, cell homeostasis, and defense against pathogens and toxic products. Autophagy in plant cells uses a conserved machinery of core Autophagy-related (Atg) proteins. Recently, research on plant autophagy has been expanding and other components interacting with the core Atg proteins are being revealed. In addition, growing evidence suggests that autophagy communicates with other cellular pathways such as the ubiquitin-proteasome system, protein secretory pathway, and endocytic pathway. An increase in our understanding of plant autophagy will undoubtedly help test the hypothesized functions of plant autophagy in programmed cell death, vacuole biogenesis, and responses to biotic, abiotic, and nutritional stresses. In this review, we summarize recent progress on these topics and suggest topics for future research, after inspecting common phenotypes of current Arabidopsis atg mutants.     

Links between ER stress and autophagy in plants

Autophagy is a major pathway for the delivery of proteins or organelles to be degraded in the vacuole and recycled. It can be induced by abiotic stresses, senescence, and pathogen infection. Recent research has shown that autophagy is activated by ER stress. Here we review the major progress that has been made in the study of autophagy and ER stress in plants, and describe the links between ER stress and autophagy to guide further study on how autophagy is regulated in response to ER stress.     

Role of autophagy in breast cancer

Autophagy is an evolutionarily conserved process of cytoplasm and cellular organelle degradation in lysosomes. Autophagy is a survival pathway required for cellular viability during starvation; however, if it proceeds to completion, autophagy can lead to cell death. In neurons, constitutive autophagy limits accumulation of polyubiquitinated proteins and prevents neuronal degeneration. Therefore, autophagy has emerged as a homeostatic mechanism regulating the turnover of long-lived or damaged proteins and organelles, and buffering metabolic stress under conditions of nutrient deprivation by recycling intracellular constituents. Autophagy also plays a role in tumorigenesis, as the essential autophagy regulator beclin1 is monoallelically deleted in many human ovarian, breast, and prostate cancers, and beclin1(+/-) mice are tumor-prone. We found that allelic loss of beclin1 renders immortalized mouse mammary epithelial cells susceptible to metabolic stress and accelerates lumen formation in mammary acini. Autophagy defects also activate the DNA damage response in vitro and in mammary tumors in vivo, promote gene amplification, and synergize with defective apoptosis to accelerate mammary tumorigenesis. Thus, loss of the prosurvival role of autophagy likely contributes to breast cancer progression by promoting genome damage and instability. Exploring the yet unknown relationship between defective autophagy and other breast cancer promoting functions may provide valuable insight into the pathogenesis of breast cancer and may have significant prognostic and therapeutic implications for breast cancer patients.     

Role of Autophagy in Breast Cancer

Autophagy is an evolutionarily conserved process of cytoplasm and cellular organelle degradation in lysosomes. Autophagy is a survival pathway required for cellular viability during starvation; however, if it proceeds to completion, autophagy can lead to cell death. In neurons, constitutive autophagy limits accumulation of polyubiquitinated proteins and prevents neuronal degeneration. Therefore, autophagy has emerged as a homeostatic mechanism regulating the turnover of long-lived or damaged proteins and organelles, and buffering metabolic stress under conditions of nutrient deprivation by recycling intracellular constituents. Autophagy also plays a role in tumorigenesis, as the essential autophagy regulator beclin1 is monoallelically deleted in many human ovarian, breast, and prostate cancers, and beclin1^+/- mice are tumor-prone. We found that allelic loss of beclin1 renders immortalized mouse mammary epithelial cells susceptible to metabolic stress and accelerates lumen formation in mammary acini. Autophagy defects also activate the DNA damage response in vitro and in mammary tumors in vivo, promote gene amplification, and synergize with defective apoptosis to accelerate mammary tumorigenesis. Thus, loss of the prosurvival role of autophagy likely contributes to breast cancer progression by promoting genome damage and instability. Exploring the yet unknown relationship between defective autophagy and other breast cancer-promoting functions may provide valuable insight into the pathogenesis of breast cancer and may have significant prognostic and therapeutic implications for breast cancer patients.

Addendum to:

Autophagy Mitigates Metabolic Stress and Genome Damage in Mammary Tumorigenesis

V. Karantza-Wadsworth, S. Patel, O. Kravchuk, G. Chen, R. Mathew, S. Jin and E. White

Genes Dev 2007; 21:1621-35     

几个能量代谢相关蛋白在HeLa细胞自噬过程中表达下调

自噬是真核细胞中的一种保守的代谢信号通路。人们已经知道自噬与肿瘤发生等疾病密切相关,但对于自噬的分子机制仍然不是很清楚。鉴定更多的自噬相关蛋白对于进一步阐明自噬的分子机制具有重要意义。该研究使用饥饿法处理HeLa细胞,通过电镜观察以及检测自噬标记蛋白LC3-I的转换,证实HeLa细胞发生了明显的自噬。之后,使用双向电泳结合串联质谱分析鉴定细胞自噬时发生变化的蛋白质。结果发现果糖二磷酸醛缩酶A、GAPDH和ATP合成酶O亚基的量在HeLa细胞发生自噬后明显降低。实时定量PCR结果证明饥饿诱导后,这三种蛋白的mRNA水平都发生了明显的下降。使用自噬抑制剂3-Methyladenine预处理HeLa细胞后再行饥饿,三种蛋白mRNA的表达水平与正常细胞相当而明显高于饥饿诱导的细胞。结果表明这三种蛋白在饥饿诱导的自噬中表达下调,其分子机制还有待进一步研究。     

细菌与自噬的抗争——死亡或重生

自噬是一种高度保守的细胞内成分的降解过程,不仅维持细胞的代谢稳定,还与机体对抗各种病原菌感染有着密切关系。自噬能协助机体清除病原体,但有些细菌进化出多种策略干扰自噬信号通路或抑制自噬体与溶酶体融合形成自噬溶酶体来逃避自噬的降解,甚至利用自噬来促进其生长增殖。文中从自噬的分子机制出发,讨论多种致病菌与宿主细胞自噬关系的最新进展,以及自噬与病原菌感染的作用和意义,以期为病原菌感染导致的自噬研究提供参考。