细胞程序性死亡与生态适应

细胞程序性死亡是多细胞有机生命周期中正常的组成部分,细胞程序性死亡过程的存在对生物体是一种保护机制。它是在生物进化过程中形成的,也是生物对环境的适应方式之一。     

细胞程序性死亡通路的研究进展

细胞程序性死亡(programmed cell death,PCD)一直被看做是细胞凋亡(apoptosis).随着细胞生物学研究的深入,新的细胞死亡途径逐渐被揭示出来,如胀亡、自噬、副凋亡等.这些通路有些是caspase依赖的,有些不依赖于caspase途径.在细胞程序性死亡过程中,各种通路不是单独起作用的,而是相互交联的,有彼此重叠的机制出现.目前,Clarke形态学分类法是得到大多数学者认可的细胞程序性死亡的分类方式.按照该分类法,可将PCD分为3大类,即:Ⅰ型细胞程序性死亡、Ⅱ型细胞程序性死亡和Ⅲ型细胞程序性死亡.     

细胞凋亡与细胞程序性死亡

细胞凋亡与程序性死亡是多细胞动物生命过程中必不可少的正常过程,它与细胞增殖具有同样重要意义。细胞凋亡与程序性死亡失控不仅扰乱发育,还导致病变。因此,这一领域的研究受到生命科学研究者的广泛重视,进展很快。本文从凋亡的定义、形态学特点、诱导、生物化学背景、基因调控等５个方面综合分析了近年来国内外的研究进展。     

细菌的细胞程序性死亡

细胞凋亡 (ａｐｏｐｔｏｓｉｓ)也称为细胞程序性死亡 (ｐｒｏｇｒａｍｍｅｄｃｅｌｌｄｅａｔｈ ,ＰＣＤ) ,是由细胞自身的程序性自杀机制激活的细胞死亡现象。在多细胞真核生物中 ,程序性的细胞死亡是由细胞表面的死亡受体介导 ,通过一系列的半胱氨酸蛋白酶 (ｃａｓｐａｓｅｓ)作用而启动[1] ,维系个体结构稳定、功能平衡和生长发育所必需的基本生物学过程。一般存在于个体的发育过程中 ,导致细胞功能和形态学上的改变 ,如蛋白质的水解、ＤＮＡ和ＲＮＡ的降解、细胞的收缩 ,以及细胞碎裂形成凋亡小体 (ａｐｏｐｔｏｔｉｃｂｏｄｉｅｓ)等 …     

植物中的细胞程序性死亡

细胞程序性死亡(PCD)对于维持植物的正常生长发育非常重要,目前已成为植物学研究的一个热点。本文综合评述了近年来植物PCD研究的某些进展,包括植物PCD的特征,植物的营养生长、生殖生长以及与环境互作过程中存在的各种PCD及其证据,植物PCD发生的分子机制及其调控等等。对植物PCD研究中有待进一步解决的问题和可能意义提出了自己的见解。     

植物中的细胞程序性死亡

细胞程序性死亡（ＰＣＤ）对于维持植物的正常生长发育非常重要,目前已成为植物学研究的一个热点。本文综合评述了近年来植物ＰＣＤ研究的某些进展,包括植物ＰＣＤ的特征,植物的营养生长、生殖生长以及与环境互作过程中存在的各种ＰＣＤ及其证据,植物ＰＣＤ发生的分子机制及其调控等等。对植物ＰＣＤ研究中有待进一步解决的问题和可能意义提出了自己的见解。     

植物细胞程序性死亡的研究进展

细胞程序性死亡（PCD）是生物进化过程中受自身基因控制并受多种因子调控的一种细胞主动的死亡过程。PCD在植物的正常生长发育、对环境胁迫的反应和病原体入侵引发的过敏反应中起重要的作用。简要综述了植物PCD的特征、与此相关的蛋白和活性氧在PCD过程中的作用。     

植物在逆境胁迫中的细胞程序性死亡

细胞程序性死亡(programmed cell death,PCD)是一种由基因控制的、主动的细胞死亡过程,它对植物正常生长发育起重要作用.在逆境胁迫因子如病原体、高盐、低氧、低温、热激和金属离子等作用下,植物为了抵御不良环境的侵害,以活性氧、Ca2+、乙烯和NO等为信号因子,诱导植物体的特定部位发生PCD,形成细胞主动死亡,从而避免逆境对其他组织进一步伤害,并使植物获得对不良环境的适应性.对植物PCD的一般特征、环境胁迫因子及诱导PCD信号分子等进行了综述,为在逆境条件下深入研究植物细胞程序性死亡提供参考.     

植物发育过程中的细胞程序性死亡

细胞程序性死亡(PCD)是植物发育过程中必不可少的一部分,近年来对植物发育过程中的细胞程序性死亡机制的研究已经广泛开展。植物发育过程中的PCD对植物自身形态建成和组织分化有重要意义。一般认为动、植物的PCD有很大的相似性,但植物发育过程也有着独特的PCD机制,例如依靠有裂解功能的液泡来参与PCD。通过比较植物和其他生物发育过程中的PCD,可对植物发育过程中PCD的特征有着更深入的了解。说明植物发育过程中PCD的研究将在理论和生产上有重大意义。     

植物细胞程序性死亡研究进展

植物细胞死亡分为坏死和程序性死亡。细胞程序性死亡是具有信号或一系列分子参与,并且由细胞内在的死亡程序介导的有序过程。它在植物生长发育和抵御外界胁迫中具有重要作用。简要介绍了植物PCD的特征,对植物PCD中的信号分子和类caspase的作用等进行了综述,并对植物PCD存在的问题进行分析和展望,为深入研究植物PCD提供参考。     

Chlamydia and programmed cell death

Discordant views regarding host cell death induction by Chlamydia are likely owing to the different methods used for evaluation of apoptosis. Apoptotic and non-apoptotic death owing to both caspase-dependent and -independent activation of the Bax protein occur late in the productive growth cycle. Evidence also suggests that Chlamydia inhibits apoptosis during productive growth as part of its intracellular survival strategy. This is in part owing to proteolytic degradation of the BH3-only family of pro-apoptotic proteins in the mitochondrial pathway. Chlamydia also inhibits apoptosis during persistent growth or in phagocytes, but induces apoptosis in T cells, which suggests that apoptosis has an immunomodulatory role in chlamydial infections. The contribution of apoptosis in disease pathogenesis remains a focus for future research.     

Erythrocyte programmed cell death

Eryptosis, the suicidal death of erythrocytes, is characterised by cell shrinkage, membrane blebbing and cell membrane phospholipid scrambling with phosphatidylserine exposure at the cell surface. Phosphatidylserine-exposing erythrocytes are recognised by macrophages, which engulf and degrade the affected cells. Reported triggers of eryptosis include osmotic shock, oxidative stress, energy depletion, ceramide, prostaglandin E(2), platelet activating factor, hemolysin, listeriolysin, paclitaxel, chlorpromazine, cyclosporine, methylglyoxal, amyloid peptides, anandamide, Bay-5884, curcumin, valinomycin, aluminium, mercury, lead and copper. Diseases associated with accelerated eryptosis include sepsis, malaria, sickle-cell anemia, beta-thalassemia, glucose-6-phosphate dehydrogenase (G6PD)-deficiency, phosphate depletion, iron deficiency, hemolytic uremic syndrome and Wilsons disease. Eryptosis may be inhibited by erythropoietin, adenosine, catecholamines, nitric oxide (NO) and activation of G-kinase. Most triggers of eryptosis except oxidative stress are effective without activation of caspases. Their signalling involves formation of prostaglandin E(2) with subsequent activation of cation channels and Ca2+ entry and/or release of platelet activating factor (PAF) with subsequent activation of sphingomyelinase and formation of ceramide. Ca2+ and ceramide stimulate scrambling of the cell membrane. Ca2+ further activates Ca2+-sensitive K+ channels leading to cellular KCl loss and cell shrinkage and stimulates the protease calpain resulting in degradation of the cytoskeleton. Eryptosis allows defective erythrocytes to escape hemolysis. On the other hand, excessive eryptosis favours the development of anemia. Thus, a delicate balance between proeryptotic and antieryptotic mechanisms is required to maintain an adequate number of circulating erythrocytes and yet avoid noneryptotic death of injured erythrocytes.     

Cancer and programmed cell death

A report on the 15th Lorne Cancer Conference, Lorne, Australia, 13-16 February 2003.     

Conventional calpains and programmed cell death

The evidence on the crucial role of a family of calcium-dependent cysteine proteases called calpains in programmed cell death is rich and still growing. However, understanding of the mechanisms of their functions in apoptosis is not full yet. Calpains have been implicated in both physiological and pathological cell death control, especially in various malignancies, but also in the immune system development and function. There is also growing evidence on calpain involvement in apoptosis execution in certain pathological conditions of the central nervous system, in cardiovascular diseases, etc. Understanding of the clinical significance of calpain activation pathways, after intense studies of the influence of calpain activity on drug-induced apoptosis, seems especially important lately, as calpains have become noticed as potential therapeutic targets. To allow pharmacological targeting of these enzymes, thorough knowledge of their patterns of activation and further interactions with already known apoptotic pathways is necessary. A comprehensive summary of both well established and recently obtained information in the field is an important step that may lead to future advances in the use of calpain-targeted agents in the clinic.     

Microgravity-induced programmed cell death in astrocytes

Cultured astrocytes were submitted to simulated microgravity using a Fokker clinostat under continuous rotation (60 rpm) for 15', 30', 1h, 20h and 32h. Samples processing included (i) nuclear stainings using Propidium Iodide and 4,6-diamidino-2-phenilindole, dihydro chloride, (ii) immunohistochemical identification of Caspase-7, (iii) identification of DNA fragmentation using the terminal dUTP nick end labelling and (iv) Scanning Electron Microscope analysis. After 30' at simulated microgravity the glial cells showed morphological evidence of apoptosis: cell shrinkage, chromatin condensation, nuclear blebs and fragmentation. The enzyme caspase-7 was present and DNA fragmentation was evident. After 32h the density of the cell population was much lower than that observed in controls.     

Molecular mechanisms of programmed cell death

Programmed cell death is currently under active investigation. A recent meeting focused on the molecular machinery of programmed cell death and on its role in the pathogenesis of human diseases.     

Developmentally programmed cell death in Drosophila

During the development of metazoans, programmed cell death (PCD) is essential for tissue patterning, removal of unwanted cells and maintaining homeostasis. In the past 20 years Drosophila melanogaster has been one of the systems of choice for studies involving developmental cell death, providing an ideal genetically tractable model of intermediary complexity between Caenorhabditis elegans and mammals. The lessons learned from studies using Drosophila indicate both the conserved nature of the many cell death pathways as well as novel and unexpected mechanisms. In this article we review the understanding of PCD during Drosophila development, highlighting the key mechanisms that are evolutionarily conserved as well as apparently unusual pathways, which indicate divergence, but provide evidence of complexity acquired during organismic evolution. This article is part of a Special Section entitled: Cell Death Pathways. Guest Editors: Frank Madeo and Slaven Stekovic.