Molecular mechanisms of cell death and phagocytosis in Drosophila

The genetic tools available in Drosophila have facilitated our understanding of how apoptosis is regulated and executed in the context of the developing organism. All embryonic apoptosis is initiated by the activity of three genes, rpr, grim and hid. Each of these genes is independently regulated, allowing developmental apoptosis to be finely controlled. These initiators in turn activate the core apoptotic machinery, including the caspases. Drosophila counterparts to other conserved components of the apoptotic machinery have been recently identified, and we discuss how these may be integrated into the process of normal developmentally regulated cell death. We also outline the role that phagocytosis plays in the final stages of apoptosis and consider the molecular mechanisms guiding the elimination of apoptotic corpses.     

Steroidogenesis and apoptosis in the mammalian ovary

Ovarian cell death is an essential process for the homeostasis of ovarian function in human and other mammalian species. It ensures the selection of the dominant follicle and the demise of excess follicles. In turn, this process minimizes the possibility of multiple embryo development during pregnancy and assures the development of few, but healthy embryos. Degeneration of the old corpora lutea in each estrous/menstrual cycle by programmed cell death is essential to maintain the normal cyclicity of ovarian steroidogenesis. Although there are multiple pathways that can determine cell death or survival, crosstalk among endocrine, paracrine and autocrine factors, as well as among protooncogenes, tumor suppressor genes, survival genes and death genes, plays an important role in determining the fate of ovarian somatic and germ cells. The establishment of immortalized rat and human steroidogenic granulosa cell lines and the investigation of pure populations of primary granulosa cells allows systematic studies of the mechanisms that control steroidogenesis and apoptosis in granulosa cells. We have discovered that during initial stages of granulosa cell apoptosis progesterone production does not decrease. In contrast, we found that it is elevated up to 24h following the onset of the apoptotic stimuli exerted by starvation, cAMP, p53 or TNF-alpha stimulation, before total cell collapse. These observations raise the possibility for an alternative unique apoptotic pathway, one not involving mitochondrial Cyt C release associated with the destruction of mitochondrial structure and steroidogenic function. Using mRNA from apoptotic cells and affymetrix DNA microarray technology we discovered that granzyme B, a protease that normally resides in T cytotoxic lymphocytes and natural killer cells of the immune system is expressed and activated in granulosa cells. Thus, the apoptotic signals could bypass mitochondrial signals for apoptosis, which can preserve their steroidogenic activity until complete cell destruction. This unique apoptotic pathway assures cyclicity of estradiol and progesterone release in the estrous/menstruous cycle even during the initial stages of apoptosis.     

Down-regulation of p21WAF1 promotes apoptosis in senescent human fibroblasts: involvement of retinoblastoma protein phosphorylation and delay of cellular aging

It has been suggested that genes which exercise checkpoint control during cell cycle traverse are equally important to the process of apoptotic cell death. In this study, we show that the key cell cycle regulatory gene p21(WAF1) is also involved in the execution of apoptosis. p21(WAF1) expression was down-regulated during NaBu-induced apoptosis of senescent normal diploid human 2BS fibroblasts. Conversely, when p21(WAF1) expression was actively suppressed in 2BS cells by a stably transfected antisense p21(WAF1) construct, apoptosis was accelerated and senescence was delayed, as shown by several markers of cell aging. Down-regulation of p21(WAF1) by antisense caused an increase in the phosphorylation and inactivation of pRb. Phosphorylation of pRb was further enhanced upon induction of apoptosis by NaBu. Our results suggest that p21(WAF1), acting through the phosphorylation of pRb, regulates whether 2BS cells cease to proliferate and become senescent but resistant to apoptosis, or whether they accelerate proliferation while becoming more susceptible to apoptotic stimuli.     

New insights into the apoptotic process in mollusks: characterization of caspase genes in Mytilus galloprovincialis

Apoptosis is an essential biological process in the development and maintenance of immune system homeostasis. Caspase proteins constitute the core of the apoptotic machinery and can be categorized as either initiators or effectors of apoptosis. Although the genes encoding caspase proteins have been described in vertebrates and in almost all invertebrate phyla, there are few reports describing the initiator and executioner caspases or the modulation of their expression by different stimuli in different apoptotic pathways in bivalves. In the present work, we characterized two initiator and four executioner caspases in the mussel Mytilus galloprovincialis. Both initiators and executioners showed structural features that make them different from other caspase proteins already described. Evaluation of the genes' tissue expression patterns revealed extremely high expression levels within the gland and gills, where the apoptotic process is highly active due to the clearance of damaged cells. Hemocytes also showed high expression values, probably due to of the role of apoptosis in the defense against pathogens. To understand the mechanisms of caspase gene regulation, hemocytes were treated with UV-light, environmental pollutants and pathogen-associated molecular patterns (PAMPs) and apoptosis was evaluated by microscopy, flow cytometry and qPCR techniques. Our results suggest that the apoptotic process could be tightly regulated in bivalve mollusks by overexpression/suppression of caspase genes; additionally, there is evidence of caspase-specific responses to pathogens and pollutants. The apoptotic process in mollusks has a similar complexity to that of vertebrates, but presents unique features that may be related to recurrent exposure to environmental changes, pollutants and pathogens imposed by their sedentary nature.     

Fungal apoptosis: function, genes and gene function

Cells of all living organisms are programmed to self-destruct under certain conditions. The most well known form of programmed cell death is apoptosis, which is essential for proper development in higher eukaryotes. In fungi, apoptotic-like cell death occurs naturally during aging and reproduction, and can be induced by environmental stresses and exposure to toxic metabolites. The core apoptotic machinery in fungi is similar to that in mammals, but the apoptotic network is less complex and of more ancient origin. Only some of the mammalian apoptosis-regulating proteins have fungal homologs, and the number of protein families is drastically reduced. Expression in fungi of animal proteins that do not have fungal homologs often affects apoptosis, suggesting functional conservation of these components despite the absence of protein-sequence similarity. Functional analysis of Saccharomyces cerevisiae apoptotic genes, and more recently of those in some filamentous species, has revealed partial conservation, along with substantial differences in function and mode of action between fungal and human proteins. It has been suggested that apoptotic proteins might be suitable targets for novel antifungal treatments. However, implementation of this approach requires a better understanding of fungal apoptotic networks and identification of the key proteins regulating apoptotic-like cell death in fungi.     

细胞凋亡信号途径与免疫系统之间的串流

细胞凋亡作为一种生命体的主要细胞死亡方式,在清除多余或受感染细胞中发挥重要作用.尽管在组织或胚胎正常发育过程中,细胞凋亡诱导免痉反应比较温和,但在病毒感染或者对死亡受体(death receptor.DR)进行刺激时凋亡可以触发强烈的天然和获得性免疫反应.凋亡信号途径中的分子与免疫系统有着复杂的相互作用.本文综述了有关凋亡性死亡在诱导炎症,维持免疫系统动态平衡,促进免疫应答以及凋亡信号途径和免疫系统抗病毒机制相互关系等方面的研究成果,分析细胞凋亡所诱发免疫效应的机制.     

Programmed cell death in the development of the vertebrate inner ear

Programmed cell death is known to be an essential process for accurate ontogeny during the normal development of the inner ear. The inner ear is a complex sensory organ responsible for equilibrium and sound detection in vertebrates. In all vertebrates, the inner ear develops from a single ectodermic patch on the surface of the embryo's head, which undergoes a series of morphological changes to give rise to the complex structure of the adult inner ear. Enlargement and morphogenesis of the inner ear primordium is likely to depend on cellular division, growth, migration, differentiation and apoptosis. Here we describe the regions of programmed cell death that contribute to the final morphological aspect of the adult inner ear. The few studies that focus on the molecules that control this process during inner ear development indicate that the molecules and intracellular signaling pathways activated during the apoptotic response in the inner ear are similar to the previously described for the nervous system. In this review, we will describe some of the growth factors and key pathways that regulate pro- and anti-apoptotic signals and how they cross talk to determine the apoptotic or survival fate of cells in the development of the inner ear.     

Apoptosis and its functional significance in molluscs

Programmed cell death leading to apoptosis is essential for normal development and homeostasis in plants and throughout the animal kingdom. Although there are differences in apoptotic mechanisms between lower animals and vertebrates, crucial biochemical components of the programmed cell death pathways remained remarkably conserved throughout evolution. Despite decades of studies on the neurobiology and development of mollusks, comparatively little is known about the mechanisms of apoptosis in this phylum. In this review, an attempt is made to summarize data obtained on mollusks so far, and to discuss the molecular mechanisms, the functional and ecological significance of apoptosis and the advantages of snail preparations as tools for programmed cell death research. A definitive comparison of the data obtained on mollusks with those obtained on the more widely studied vertebrates, will contribute to the better understanding of the apoptotic process in general and of its evolutionary development.     

A role for E2F1 in the induction of apoptosis during thymic negative selection.

Thymic negative selection is the process in which maturing thymocytes that express T-cell receptors recognizing self are eliminated by apoptotic cell death. The molecular mechanism by which this occurs is poorly understood. Notably, genes involved in cell death, even thymocyte death, such as Fas, Fas-ligand, p53, caspase-1, caspase-3, and caspase-9, and Bcl-2 have been found to not be required for normal thymic negative selection. We have demonstrated previously that E2F1-deficient mice have a defect in thymocyte apoptosis. Here we show that E2F1 is required for normal thymic negative selection. Furthermore, we observed an E2F1-dependent increase of p53 protein levels during the process of thymic clonal deletion, which suggests that E2F1 regulates activation-induced apoptosis of self-reactive thymocytes by a p53-dependent mechanism. In contrast, other apoptotic pathways operating on developing thymocytes, such as glucocorticoid-induced cell death, are not mediated by E2F1. The T lymphocytes that escape thymic negative selection migrate to the peripheral immune system but do not appear to be autoreactive, indicating that there may exist E2F1-independent mechanisms of peripheral tolerance, which protect mice from developing an autoimmune response. We expect that E2F1-deficient mice will provide a useful tool for understanding the molecular mechanism of and the immunological importance of thymic negative selection.     

Involvement of protective autophagy in TRAIL resistance of apoptosis-defective tumor cells

Targeting TRAIL receptors with either recombinant TRAIL or agonistic DR4- or DR5-specific antibodies has been considered a promising treatment for cancer, particularly due to the preferential apoptotic susceptibility of tumor cells over normal cells to TRAIL. However, the realization that many tumors are unresponsive to TRAIL treatment has stimulated interest in identifying apoptotic agents that when used in combination with TRAIL can sensitize tumor cells to TRAIL-mediated apoptosis. Our studies suggest that various apoptosis defects that block TRAIL-mediated cell death at different points along the apoptotic signaling pathway shift the signaling cascade from default apoptosis toward cytoprotective autophagy. We also obtained evidence that inhibition of such a TRAIL-mediated autophagic response by specific knockdown of autophagic genes initiates an effective mitochondrial apoptotic response that is caspase-8-dependent. Currently, the molecular mechanisms linking disabled autophagy to mitochondrial apoptosis are not known. Our analysis of the molecular mechanisms involved in the shift from protective autophagy to apoptosis in response to TRAIL sheds new light on the negative regulation of apoptosis by the autophagic process and by some of its individual components.     

Apocytochrome c blocks caspase-9 activation and Bax-induced apoptosis

Complex networks of signaling pathways control the apoptotic response and, therefore, cell survival. However, these networks converge on a common machinery, of which the caspase cysteine proteases are key components. Diverse apoptotic stimuli release holocytochrome c from mitochondria, allowing holocytochrome c to bind apoptotic protease activating factor-1 (Apaf-1), which in turn binds caspase-9 both activating this caspase and forming an Apaf-1/caspase-9 holoenzyme. Cytochrome c lacking heme (the apo form) cannot support caspase activation, although the reason for this has not been studied. Here we show that apocytochrome c still binds Apaf-1 and that it can block holo-dependent caspase activation in a cell-free system. In addition we show that overexpression of apocytochrome c blocks Bax-induced apoptosis in cells. Thus it is possible to modulate cell survival by interfering with the Apaf-1/cytochrome c interaction. Given the key role played by Apaf-1/cytochrome c in the apoptotic process, and the role of apoptosis in degenerative disease, this interaction may serve as a novel therapeutic target.     

吞噬凋亡细胞的机制

被吞噬细胞吞噬是多数凋亡细胞的命运.凋亡细胞表面膜磷脂酰丝氨酸的暴露、膜碳水化合物的改变及表面糖蛋白的重新分布和聚集导致被吞噬细胞识别与摄取.吞噬细胞的多种受体参与吞噬过程,有些受体参与栓系凋亡细胞,有些激发巨吞饮的摄取机制.吞噬的摄取过程因吞噬细胞和凋亡细胞的类型差异而不同.至少有7种线虫吞噬基因及其哺乳动物同源物组成两条部分重叠而又平行的摄取信息传导通路.吞噬基因的突变可以改变凋亡细胞的进程.吞噬功能的缺陷将影响机体正常的免疫应答.     

Isolation of cell death-associated cDNAs from involuting mouse mammary epithelium

Although apoptosis is important in determining cell fate and maintaining tissue homeostasis, the initiation and control of apoptotic cell death in epithelium is not well understood. Post-lactationai involution of the mammary gland provides both an important developmental process and a normal physiological setting for studying apoptosis of epithelium. We used a differential screening strategy, based on previous studies correlating morphology with gene expression and nucleic acid integrity during mammary gland involution, to isolate genes involved in the regulation and execution of apoptotic cell death in regressing mammary epithelium. This screening strategy yielded a large number of genes the expression of which is significantly altered during mammary gland involution. These include genes associated with cell death processes, tissue remodelling and mesenchymal differentiation. In addition, a number of novel genes have been isolated. We have used Northern analysis and in situ hybridisation to study the expression of a selection of these putative death-associated genes during post-lactational mouse mammary gland involution.     

Plasma membrane depolarization without repolarization is an early molecular event in anti-Fas-induced apoptosis

The movement of intracellular monovalent cations has previously been shown to play a critical role in events leading to the characteristics associated with apoptosis. A loss of intracellular potassium and sodium occurs during apoptotic cell shrinkage establishing an intracellular environment favorable for nuclease activity and caspase activation. We have now investigated the potential movement of monovalent ions in Jurkat cells that occur prior to cell shrinkage following the induction of apoptosis. A rapid increase in intracellular sodium occurs early after apoptotic stimuli suggesting that the normal negative plasma membrane potential may change during cell death. We report here that diverse apoptotic stimuli caused a rapid cellular depolarization of Jurkat T-cells that occurs prior to and after cell shrinkage. In addition to the early increase in intracellular Na(+), (86)Rb(+) studies reveal a rapid inhibition of K(+) uptake in response to anti-Fas. These effects on Na(+) and K(+) ions were accounted for by the inactivation of the Na(+)/K(+)-ATPase protein and its activity. Furthermore, ouabain, a cardiac glycoside inhibitor of the Na(+)/K(+)-ATPase, potentiated anti-Fas-induced apoptosis. Finally, activation of an anti-apoptotic signal, i.e. protein kinase C, prevented both cellular depolarization in response to anti-Fas and all downstream characteristics associated with apoptosis. Thus cellular depolarization is an important early event in anti-Fas-induced apoptosis, and the inability of cells to repolarize via inhibition of the Na(+)/K(+)-ATPase is a likely regulatory component of the death process.     

Secondary necrosis in multicellular animals: an outcome of apoptosis with pathogenic implications

In metazoans apoptosis is a major physiological process of cell elimination during development and in tissue homeostasis and can be involved in pathological situations. In vitro, apoptosis proceeds through an execution phase during which cell dismantling is initiated, with or without fragmentation into apoptotic bodies, but with maintenance of a near-to-intact cytoplasmic membrane, followed by a transition to a necrotic cell elimination traditionally called “secondary necrosis”. Secondary necrosis involves activation of self-hydrolytic enzymes, and swelling of the cell or of the apoptotic bodies, generalized and irreparable damage to the cytoplasmic membrane, and culminates with cell disruption. In vivo, under normal conditions, the elimination of apoptosing cells or apoptotic bodies is by removal through engulfment by scavengers prompted by the exposure of engulfment signals during the execution phase of apoptosis; if this removal fails progression to secondary necrosis ensues as in the in vitro situation. In vivo secondary necrosis occurs when massive apoptosis overwhelms the available scavenging capacity, or when the scavenger mechanism is directly impaired, and may result in leakage of the cell contents with induction of tissue injury and inflammatory and autoimmune responses. Several disorders where secondary necrosis has been implicated as a pathogenic mechanism will be reviewed.     

Apoptosis in polycystic kidney disease

Apoptosis is the process of programmed cell death. It is a ubiquitous, controlled process consuming cellular energy and designed to avoid cytokine release despite activation of local immune cells, which clear the cell fragments. The process occurs during organ development and in maintenance of homeostasis. Abnormalities in any step of the apoptotic process are associated with autoimmune diseases and malignancies. Polycystic kidney disease (PKD) is the most common inherited kidney disease leading to end-stage renal disease (ESRD). Cyst formation requires multiple mechanisms and apoptosis is considered one of them. Abnormalities in apoptotic processes have been described in various murine and rodent models of PKD as well as in human PKD kidneys. The purpose of this review is to outline the role of apoptosis in progression of PKD as well as to describe the mechanisms involved. This article is part of a Special Issue entitled: Polycystic Kidney Disease.     

Drug discovery opportunities from apoptosis research

Cell suicide is a normal process that participates in a wide variety of physiological processes, including tissue homeostasis, immune regulation, and fertility. Physiological cell death typically occurs by apoptosis, as opposed to necrosis. Defects in apoptotic cell-death regulation contribute to many diseases, including disorders associated with cell accumulation (e.g. cancer, autoimmunity, inflammation and restenosis) or where cell loss occurs (e.g. stroke, heart failure, neurodegeneration, AIDS and osteoporosis). At the center of the apoptosis machinery is a family of intracellular proteases, known as 'caspases', that are responsible directly or indirectly for the morphological and biochemical events that characterize apoptosis. Multiple positive and negative regulators of these cell-death proteases have been discovered in the genomes of mammals, amphibians, insects, nematodes, and other animal species, as well as a variety of animal viruses. Inputs from signal-transduction pathways into the core of the cell-death machinery have also been identified, demonstrating ways of linking environmental stimuli to cell-death responses or cell-survival maintenance. Knowledge of the molecular mechanisms of apoptosis has provided important insights into the causes of multiple diseases where aberrant cell-death regulation occurs and has revealed new approaches for identifying small-molecule drugs for more effectively treating these illnesses.     

Cell shrinkage and monovalent cation fluxes: role in apoptosis

The loss of cell volume or cell shrinkage has been a morphological hallmark of the programmed cell death process known as apoptosis. This isotonic loss of cell volume has recently been term apoptotic volume decrease or AVD to distinguish it from inherent volume regulatory responses that occurs in cells under anisotonic conditions. Recent studies examining the intracellular signaling pathways that result in this unique cellular characteristic have determined that a fundamental movement of ions, particularly monovalent ions, underlie the AVD process and plays an important role on controlling the cell death process. An efflux of intracellular potassium was shown to be a critical aspect of the AVD process, as preventing this ion loss could protect cells from apoptosis. However, potassium plays a complex role as a loss of intracellular potassium has also been shown to be beneficial to the health of the cell. Additionally, the mechanisms that a cell employs to achieve this loss of intracellular potassium vary depending on the cell type and stimulus used to induce apoptosis, suggesting multiple ways exist to accomplish the same goal of AVD. Additionally, sodium and chloride have been shown to play a vital role during cell death in both the signaling and control of AVD in various apoptotic model systems. This review examines the relationship between this morphological change and intracellular monovalent ions during apoptosis.     

斑马鱼胚胎发育中细胞凋亡的研究进展

细胞凋亡是细胞在基因调控下发生的主动消亡过程,在脊椎动物胚胎发育过程中非常重要。斑马鱼作为一种十分理想的发育分子生物学研究模型,在有关细胞凋亡在诸如形态发生、性别分化等方面功能之活体在位研究中日益受到重视。目前,斑马鱼胚胎发育中主要凋亡通路研究已进行了不少工作,特别是caspase及其它凋亡调控基因在斑马鱼中已被成功克隆,通过转基因斑马鱼胚胎中胁迫诱导细胞凋亡并研究其信号通路以及斑马鱼胚胎形态发生的异常改变,为阐明这些凋亡调控基因与发育之间的关系提供了一个强有力的手段。