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。     

自噬与泛素化蛋白降解途径的分子机制及其功能

细胞内所有的蛋白质和大多数的细胞外蛋白都在不断的进行更新,即它们在不断地被降解,并被新合成的蛋白质取代。细胞内蛋白的降解主要通过两个途径,即自噬和泛素蛋白酶体系统。自噬是一种由溶酶体介导的细胞内过多或异常蛋白质的降解机制。在细胞内主要有3种类型的自噬,即分子伴侣介导的自噬、微自噬和巨自噬。泛素蛋白酶体系统是由泛素介导的一种高度复杂的蛋白降解机制,它参与降解细胞内许多蛋白质并且这个过程具有高度特异性。细胞内蛋白质的降解参与调节许多细胞过程,包括细胞周期、DNA修复、细胞生长和分化、细胞质量的控制、病原生物的感染反应和细胞凋亡等。许多严重的人类疾病被认为是由于蛋白质降解系统的紊乱而引起的。文章综述了自噬和泛素化途径及其分子机制,以及蛋白质降解系统紊乱的病理学意义。     

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.     

自噬和泛素-蛋白酶体系统之间的交联

自噬和泛素-蛋白酶体系统作为细胞内最重要的两大降解途径,对细胞稳态及细胞正常生理功能的维持都具有十分重要的作用。目前,越来越多的证据显示,这两大降解途径之间存在多种交联方式。首先,自噬和泛素-蛋白酶体系统都能以泛素作为共同标签,从而将泛素化底物降解;其次,泛素化的蛋白酶体可以通过自噬被清除,自噬相关蛋白质也可以通过蛋白酶体系统被降解;再次,这两条途径在细胞内能协同降解同一种底物;最后,它们之间可以相互调节活性,任一条途径被干扰都将影响另一条途径的活性。自噬和泛素-蛋白酶体系统之间的交联对细胞稳态的维持至关重要。交联失调不仅导致细胞功能异常,还可引起多种疾病的发生。本文主要对自噬和泛素-蛋白酶体系统之间的交联方式及其分子机制进行阐述,有助于深入了解细胞的分解代谢过程,进一步理解细胞稳态的维持机制,继而加深对相关疾病病理机制的认识。     

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。     

综述: 细胞自噬在肿瘤发生发展中的作用

自噬是保守的细胞防御机制,又是程序性细胞死亡机制．在多种人类肿瘤中存在细胞自噬活性改变．自噬活性降低促进肿瘤的发生和进展．综述了近年来细胞自噬在肿瘤中的研究进展,从基因组不稳定性、炎-癌链转化和演进、致瘤微生 物感染和宿主免疫应答、细胞凋亡途径与自噬的交叉调节等角度探讨自噬抑制肿瘤的机理,以及细胞自噬在肿瘤治疗中的作用．     

自噬在帕金森病发病中的作用

自噬是广泛存在于真核细胞内的一种溶酶体依赖性的降解途径,主要起着调节性的作用以保护细胞免遭感染、癌症、神经变性、老化,以及心脏疾病等在内的各种病理性损伤,与细胞的存活、分化、发育和内环境稳态的维持密切相关.近来的研究表明,自噬在清除与神经变性疾病相关的错误折叠蛋白和易聚集蛋白方面起关键作用,尤其在帕金森病的发生、发展过程中发挥重要作用.     

细胞自噬与凋亡的交互作用

细胞自唾又称Ⅱ型程序性细胞死亡,参与了多种疾病的发生和发展。自唆与凋亡之间存在着复杂的交互调控——二者能被多种应激刺激共同激活、共享多个调节分子,甚至互相协调转化等。全面深入研究自噬与凋亡之间的交互作用机制,将为肿瘤等疾病的认知及治疗带来突破性进展。     

自噬蛋白NDP52与细菌感染的研究进展

自噬（autophagy）是哺乳动物清除入侵细菌的主要途径,可保卫宿主细胞免受细菌的损伤。核点蛋白52（nuclear dot protein 52,NDP52）——核点家族成员之一,是除p62/SQSTM1和NBR1等之外最新发现的自噬关键蛋白。它连接自噬体表面的微管相关蛋白1轻链3（microtubule associ-ated protein 1 light chain 3,LC3）,将披上＂泛素大衣＂的病原菌（如沙门氏菌和化脓性链球菌）递送至自噬体内加以清除。这一发现有助于人们深入了解自噬抵抗病原微生物感染的具体分子机制,为预防和治疗细菌感染提供了新靶点。     

受体相互作用蛋白3（RIP3）调控细胞自噬的研究进展

受体相互作用蛋白3(receptor-interacting protein 3,RIP3)是一种丝氨酸-苏氨酸蛋白激酶，因其参与细胞自噬的调控而受到广泛关注。本文就RIP3在细胞自噬的发展和调控机制中的作用进行了总结。RIP3可参与mTOR信号通路的调节，同时与多种自噬所必须的蛋白发生相互作用，包括GNAI3/RGSI9、P62和TFEB等，从而其在自噬启动、自噬体形成和自噬溶酶体成熟等多个阶段发挥正向或负向调控作用，为进一步探究RIP3对细胞程序性死亡的调控机制及相关疾病治疗的潜在分子靶标筛选提供参考。     

Autophagy in embryonic erythroid cells: its role in maturation

Yolk sac-derived embryonic erythroid cells differentiate synchronously in the peripheral blood of Syrian hamster. The stage of differentiation on day 10 of gestation is equivalent to polychromatophilic erythroblast stage and that on day 13 is equivalent to the reticulocyte stage in adult animals. The cytoplasm of embryonic erythroid cells became scant and devoid of most organelles on day 12 of gestation. In addition, there were very few non-erythroid cells in circulation before day 13. Thus the embryonic erythroid cells serve a pure and synchronous system to study the mechanisms of terminal differentiation. The number of mitochondria in the embryonic erythroid cells decreased to about 10% of the initial number during the period between day 10 and day 12 of gestation. In contrast, the frequency of autophagy of mitochondria increased 4.6-fold in the same period. The cytochrome c content of the cell decreased as the mitochondria became extinct. However, release of cytochrome c into the cytoplasm was not detectable through day 10-13 of gestation, suggesting that the mitochondria were digested within a closed compartment. Decomposed mitochondria and ferritin particles were detected in lysosomes by electron microscopy on and after day 12 of gestation, which also suggested digestion in a closed compartment. Mitochondrial ATP synthase subunit c, which is known to be a protease-refractory protein, was retained in the cells even after the disappearance of mitochondria, indicating that most of the mitochondria were not extruded from the cells. The digestion of mitochondria in autolysosomes may allow the cells to escape from rapid apoptotic cell death through concomitant removal of mitochondrial death-promoting factors such as cytochrome c.     

Autophagy and cell death

Autophagy exerts dual functions in cancer, acting as both a tumor suppressor, for example, by preventing the accumulation of damaged proteins and organelles, and as a tumor promoter that supports tumor growth. Many anticancer therapies engage autophagy as part of a cellular response. However, the question of whether or not autophagic activity in cells undergoing cell death is the cause of death or whether it is actually an attempt to support survival in response to cellular stress conditions has been discussed with great controversy.     

Programmed cell death in plants: distinguishing between different modes

Programmed cell death (PCD) in plants is a crucial componentof development and defence mechanisms. In animals, differenttypes of cell death (apoptosis, autophagy, and necrosis) havebeen distinguished morphologically and discussed in these morphologicalterms. PCD is largely used to describe the processes of apoptosisand autophagy (although some use PCD and apoptosis interchangeably)while necrosis is generally described as a chaotic and uncontrolledmode of death. In plants, the term PCD is widely used to describemost instances of death observed. At present, there is a vastarray of plant cell culture models and developmental systemsbeing studied by different research groups and it is clear fromwhat is described in this mass of literature that, as with animals,there does not appear to be just one type of PCD in plants.It is fundamentally important to be able to distinguish betweendifferent types of cell death for several reasons. For example,it is clear that, in cell culture systems, the window of timein which ‘PCD’ is studied by different groups varieshugely and this can have profound effects on the interpretationof data and complicates attempts to compare different researcher'sdata. In addition, different types of PCD will probably havedifferent regulators and modes of death. For this reason, inplant cell cultures an apoptotic-like PCD (AL-PCD) has beenidentified that is fairly rapid and results in a distinct corpsemorphology which is visible 4–6 h after release of cytochromec and other apoptogenic proteins. This type of morphology, distinctfrom autophagy and from necrosis, has also been observed inexamples of plant development. In this review, our model systemand how it is used to distinguish specifically between AL-PCDand necrosis will be discussed. The different types of PCD observedin plants will also be discussed and the importance of distinguishingbetween different forms of cell death will be highlighted. Key words: Apoptosis, apoptosis-like programmed cell death (AL-PCD), Arabidopsis, autophagy, mitochondria, necrosis, programmed cell death (PCD) Received 5 June 2007; Revised 13 September 2007 Accepted 20 September 2007     

Amino Acid Deprivation Induces Both Apoptosis and Autophagy in Murine C2C12 Muscle Cells

Apoptosis and autophagy are closely interconnected types of programmed cell death. In the present study, mouse C2C12 muscle cells were starved in Earle’s Balanced Salt Solution or treated with TNF-α and cycloheximide to induce autophagy and apoptosis, respectively. The majority of starved C2C12 cells underwent autophagy, as shown by LC3 processing, formation of autophagic vesicles and bulk degradation of long-lived proteins. However, some cells showed features of apoptosis including caspase-3 cleavage, chromatin condensation, DNA fragmentation and annexin V labeling. Caspase-3 cleavage was also induced in culture medium without serum, suggesting that serum withdrawal rather than amino acid deprivation triggered apoptosis. Starvation eliminated multiple pro-apoptotic proteins, but upregulated caspase-8, and rendered starved C2C12 cells much more susceptible to TNF-α/cycloheximide-induced apoptosis than non-starved cells. Our data suggest that amino acid deprivation of C2C12 cells induces a complex form of cell death with hallmarks of both apoptosis and autophagy.     

Cell cycle phase-specific death response of tobacco BY-2 cell line to cadmium treatment

The character of programmed cell death (PCD) in plants differs in connection with the context, triggering factors and differentiation state of the target cells. To study the interconnections between cell cycle progression and cell death induction, we treated synchronized tobacco BY-2 cells with cadmium ions that represent a general abiotic stressor influencing both dividing and differentiated cells in planta. Cadmium induced massive cell death after application in all stages of the cell cycle; however, both the progression and the forms of the cell death differed pronouncedly. Apoptosis-like PCD induced by cadmium application in the S and G2 was characterized by pronounced internucleosomal DNA fragmentation. In contrast, application of cadmium in M and G1 phases was not accompanied by DNA cleavage, indicating suppression of autolysis and non-programmed character of the death. We interpret these results in the context of the situation in planta, where the induction of apoptosis-like PCD in the S and G2 phase might be connected with a need to preserve genetic integrity of dividing meristematic cells, whereas suppression of PCD response in differentiated cells (situated in G1/G0 phase) might help to avoid death of the whole plant, and thus enable initiation of the recovery and adaptation processes.