Early neural cell death: dying to become neurons

The importance of programmed cell death (PCD) during vertebrate development has been well established. During the development of the nervous system in particular, neurotrophic cell death in innervating neurons matches the number of neurons to the size of their target field. However, PCD also occurs during earlier stages of neural development, within populations of proliferating neural precursors and newly postmitotic neuroblasts, all of which are not yet fully differentiated. This review addresses early neural PCD, which is distinct from neurotrophic death in differentiated neurons. Although early neural PCD is observed in a range of organisms, from Caenorhabditis elegans to mouse, the role and the regulation of early neural PCD are not well understood. The regulation of early neural PCD can be inferred from the function of factors such as bone morphogenetic proteins (BMPs), Wnts, fibroblast growth factors (FGFs), and Sonic Hedgehog (Shh), which regulate both early neural development and PCD occurring in other developmental processes. Cell number control, removal of damaged or misspecified cells (spatially or temporally), and selection are the proposed roles early neural PCDs play during neural development. Data from developmental PCD in C. elegans and Drosophila provide insights into the possible signaling pathways integrating PCD with other processes during early neural development and the roles they might play.     

Early events in murine erythroleukemia cells induced to differentiate: Variation of the cell cycle parameters in relation to p53 accumulation

Among the early events of induced differentiation of murine erythroleukemia cells that we studied was the variations of cell distribution in the cell cycle as a function of the time of induction. Flow-cytofluorimetry measurements of DNA content and BrdU incorporation allowed for a precise determination of the variations of the cell cycle parameters. Cells underwent a transient arrest in both G1 and G2 + M between 6 to 16 h of induction. The progression of the cells through S phase seems not to be affected during this period. After this time cells escaped from G1 and reentered the S phase. We described previously [S. Khochbin et al. (1988) J. Mol. Biol. 200, 55-64], that p53 decreased continuously during the induction of MELC and remained at a steady-state level after 18 to 20 h of induction. In order to look for a possible redistribution of the protein along the cell cycle during the induction process, we measured the accumulation of the protein along the cell cycle. In noninduced cells there were four steps in the accumulation of the protein throughout the cell cycle: the amount of p53 was constant during G1 and it increased as cells progressed through S phase, which is characterized by an increased accumulation at the G1/S transition and a more moderate accumulation during progression through the rest of the S phase. A constant level in G2/M, approximately twice that obtained in G1, was achieved. There was no change in this distribution that correlated with the various modifications of the cell cycle in induced cells. It seems then, that p53 is associated neither with the progression of the cells in the S phase nor with the resumption of the DNA synthesis after the G1 block.     

Speedy/Ringo C regulates S and G2 phase progression in human cells

Cyclin-dependent kinases (CDKs) control cell cycle transitions and progression. In addition to their activation via binding to cyclins, CDKs can be activated via binding to an unrelated class of cell cycle regulators termed Speedy/Ringo (S/R) proteins. Although mammals contain at least five distinct Speedy/Ringo homologues, the specific functions of members of this growing family of CDK activators remain largely unknown. We investigated the cell cycle roles of human Speedy/Ringo C in HEK293 cells. Down-regulation of Speedy/Ringo C by RNA interference delayed S and G2 progression whereas ectopic expression had the opposite effect, reducing S and G2/M populations. Double thymidine arrest and release experiments showed that overexpression of Speedy/Ringo C promoted late S phase progression. Using a novel three-color FACS protocol to determine the length of G2 phase, we found that the suppression of Speedy/Ringo C by RNAi prolonged G2 phase by ~30 min whereas ectopic expression of Speedy/Ringo C shortened G2 phase by ~25 min. In addition, overexpression of Speedy/Ringo C disrupted the G2 DNA damage checkpoint, increased cell death and caused a cell cycle delay at the G1-to-S transition. These observations indicate that CDK-Speedy/Ringo C complexes positively regulate cell cycle progression during the late S and G2 phases of the cell cycle.     

RB-dependent S-phase response to DNA damage

The retinoblastoma tumor suppressor protein (RB) is a potent inhibitor of cell proliferation. RB is expressed throughout the cell cycle, but its antiproliferative activity is neutralized by phosphorylation during the G(1)/S transition. RB plays an essential role in the G(1) arrest induced by a variety of growth inhibitory signals. In this report, RB is shown to also be required for an intra-S-phase response to DNA damage. Treatment with cisplatin, etoposide, or mitomycin C inhibited S-phase progression in Rb(+/+) but not in Rb(-/-) mouse embryo fibroblasts. Dephosphorylation of RB in S-phase cells temporally preceded the inhibition of DNA synthesis. This S-phase dephosphorylation of RB and subsequent inhibition of DNA replication was observed in p21(Cip1)-deficient cells. The induction of the RB-dependent intra-S-phase arrest persisted for days and correlated with a protection against DNA damage-induced cell death. These results demonstrate that RB plays a protective role in response to genotoxic stress by inhibiting cell cycle progression in G(1) and in S phase.     

植物细胞程序死亡的机理及其与发育的关系

细胞程序死亡（ＰＣＤ）是在植物体发育过程中普遍存在的,在发育的特定阶段发生的自然的细胞死亡过程,这一死亡过程是由某些特定基因编码的“死亡程序”控制的。ＰＣＤ的细胞分化的最后阶段。细胞分化的临界期就牌死亡程序执行中的某个阶段。ＰＣＤ包含启动期和清除期三个阶段,其间ＣＡＳＰＡＳＥ家族起着重要作用。ＰＣＤ在细胞和组织的平衡、特化,以及组织分化、器官建成和对病原体的反应等植物发育过程中起着重要作用。ＰＣＤ     

Heat-shock gene expression and cell cycle changes during mammalian embryonic development

Synchronized regulation of cell division during gastrulation is essential for the regional proliferation of cells and pattern formation of the early CNS. The neural plate and neuroectoderm cells are a rapidly dividing and differentiating population of cells with a unique and rapid heat-shock response. Heat shock and the heat-shock genes were studied during neural plate development in a whole rat embryo culture system at 9.5-11.5 days. A lethal heat shock can cause cell death and severe developmental defects to the forebrain and eye during organogenesis. Heat shock can also result in acquired thermotolerance whereby cell progression is delayed at the G1/S and S/G2 boundaries of the cell cycle. This delay in cell cycle progression caused an overall lengthening of the cell cycle time of at least 2 hr. The heat shock genes may therefore function as cell cycle regulators in neuroectoderm induction and differentiation. The kinetics and expression of the hsp genes were examined in neuroectodermal cells by flow cytometry and Northern analysis. The levels of hsp mRNA 27, 71, 73, and 88 were identified following exposure at 42°C (nonlethal), 43deg;C (lethal) and 42deg;/43deg;C (thermotolerant) heat shock. Examination of hsp gene expression in the neural plate showed tight regulation in the cell cycle phases. Hsp 88 expression was enhanced at Go and hsp71 induction at G2 + M of the cell cycle. Cells exposed to a thermotolerant heat shock of 42deg;C induced hsp71 mRNA expression in all phases of the cell cycle with the mRNA levels of hsp27, 73, and 88 increased but relatively constant. Following a lethal heat shock, dramatic changes in hsp expression were seen especially enhanced hsp71 induction in late S phase. The regulated expression of hsps during the cell cycle at various phases could play a unique and important role in the fate and recovery of neuroectoderm cells during early mammalian embryo development. © 1993Wiley-Liss, Inc.     

hREV3基因对细胞增殖周期的影响

应用反义阻断REV3基因表达的人胚肾上皮细胞(HEK-293-M-REV3-)来研究人类REV3基因对细胞增殖周期的影响, 评价该基因在哺乳类细胞突变形成中的作用, 探讨其与肿瘤形成的关系。文章应用流式细胞技术分别对在自发或不同理化诱发条件[(紫外线, UVB)和(甲基甲烷磺酸酯, MMS)]下, 对体外培养的HEK-293-M-REV3-细胞进行细胞增殖周期和DNA含量的影响进行检测, 并计算细胞的增殖指数。结果显示: 自发状态下, HEK-293-M-REV3-细胞与对照组细胞相比S期延长; 而UVB和MMS不同理化因素诱导时, HEK-293-M-REV3-细胞的G2~M期或S期比例明显比对照组增加, PI值也相应增加。因此可以推测, 当REV3基因低表达时, 细胞无论在自发还是诱发情况下突变频率均降低, 原因可能与细胞周期的改变有关, 进而再引起DNA复制叉阻滞、合成减少, 导致细胞死亡或凋亡。     

镉胁迫引起烟草悬浮细胞程序性死亡

镉胁迫会造成烟草悬浮细胞大规模死亡。通过TUNEL技术和琼脂糖凝胶电泳技术的检测发现,这种细胞死亡伴随有典型的DNA“梯形带”出现,表明这种由Cd胁迫引起的细胞死亡是一种程序性死亡。受胁迫细胞氧化性增强及细胞中丙二醛(MDA)水平升高,说明Cd胁迫时会在细胞中造成大量活性氧(ROS),暗示烟草细胞的程序性死亡可能与ROS有关。     

Specific checkpoints regulate plant cell cycle progression in response to oxidative stress

The effects of oxidative stress on plant cell cycle progression were studied both in cell suspensions and in planta . Oxidative stress of variable severity was imposed by the addition of different concentrations of the methyl-quinone, menadione, into the growth media. In cell suspensions, flow cytometry analyses demonstrated that low concentrations (20–50 μM) of menadione impaired the G1/S transition, slowed DNA replication, and delayed the entry into mitosis. Furthermore, cells in G1 were more sensitive to menadione-mediated oxidative stress than cells in S phase. Cell cycle arrest was associated with an inhibition of the activity of cyclin-dependent kinases, cell cycle gene expression, and a concomitant activation of stress genes. Menadione-mediated oxidative stress was shown to have very similar effects on tobacco plants, suggesting that a general regulation mechanism takes place in plants. These results define an oxidative stress checkpoint pathway that modulates both the expression of the core cell cycle genes and oxidative defence genes. Redox sensing could be of key importance in controlling cell cycle progression in environmental stress conditions.     

Programmed cell death in cell cultures

In plants most instances of programmed cell death (PCD) occur in a number of related, or neighbouring, cells in specific tissues. However, recent research with plant cell cultures has demonstrated that PCD can be induced in single cells. The uniformity, accessibility and reduced complexity of cell cultures make them ideal research tools to investigate the regulation of PCD in plants. PCD has now been induced in cell cultures from a wide range of species including many of the so-called model species. We will discuss the establishment of cell cultures, the fractionation of single cells and isolation of protoplasts, and consider the characteristic features of PCD in cultured cells. We will review the wide range of methods to induce cell death in cell cultures ranging from abiotic stress, absence of survival signals, manipulation of signal pathway intermediates, through the induction of defence-related PCD and developmentally induced cell death.     

Viral induced yeast apoptosis

In an analogous system to mammals, induction of an apoptotic cell death programme (PCD) in yeast is not only restricted to various exogenous factors and stimuli, but can also be triggered by viral killer toxins and viral pathogens. In yeast, toxin secreting killer strains are frequently infected with double-stranded (ds)RNA viruses that are responsible for killer phenotype expression and toxin secretion in the infected host. In most cases, the viral toxins are either pore-forming proteins (such as K1, K2, and zygocin) that kill non-infected and sensitive yeast cells by disrupting cytoplasmic membrane function, or protein toxins (such as K28) that act in the nucleus by blocking DNA synthesis and subsequently causing a G1/S cell cycle arrest. Interestingly, while all these virus toxins cause necrotic cell death at high concentration, they trigger caspase- and ROS-mediated apoptosis at low-to-moderate concentration, indicating that even low toxin doses are deadly by triggering PCD in enemy cells. Remarkably, viral toxins are not solely responsible for cell death induction in vivo, as killer viruses themselves were shown to trigger apoptosis in non-infected yeast. Thus, as killer virus-infected and toxin secreting yeasts are effectively protected and immune to their own toxin, killer yeasts bear the intrinsic potential to dominate over time in their natural habitat.     

Effects of mevinolin on cell cycle progression and viability of tobacco BY-2 cells

Mevinolin, an inhibitor of 3-hydroxy-3-methylglutaryl-CoA reductase, was used to study the importance of mevalonic acid (MVA) for cell cycle progression of tobacco (Nicotiana tabacum L.) BY-2 cells. After treatment with 5 microM mevinolin, the cell cycle progression was completely blocked and two cell populations accumulated (80% in phase G0/G1 and 20% in G2/M). The arrest could be released by subsequent addition of MVA. Effects were compared to those caused by aphidicolin, an inhibitor of alpha-like DNA polymerases that blocks cell cycle at the entry of the S phase. The 80% proportion of mevinolin-treated TBY-2 cells was clearly arrested before the aphidicolin-inducible block. By the aid of a double-blocking technique, it was shown that the mevinolin-induced cell arrest of highly synchronized cells was due to interaction with a control point located at the mitotic telophase/entry G1 phase. Depending on the developmental stage, mevinolin induced rapid cell death in a considerable percentage of cells. Mevinolin treatment led to a partial synchronization, as shown by the increase in mitotic index. The following decrease was correlated with the above-mentioned induction of cell death.     

Entamoeba histolytica: Differential gene expression during programmed cell death and identification of early pro- and anti-apoptotic signals

We have demonstrated that programmed cell death (PCD) in Entamoeba histolytica is induced in vitro by G418 aminoglycoside antibiotic. To ascertain if biochemical and morphological changes previously observed are paired to molecular changes that reflect a genetic program, we looked here for early differential gene expression during the induction of PCD.Using cDNA-amplified fragment length polymorphisms (AFLPs) and in silico derived analysis we showed in E. histolytica a differential gene expression during PCD induced by G418. The genes identified encoded for proteins homologous to Glutaminyl-tRNA synthase, Ribosomal Subunit Proteins 40S and 18S, Saposin-like, Silent Information Regulator-2 (Sir-2), and Grainins 1 and 2. Using real-time quantitative PCR (RT Q-PCR), we found that glutaminyl-tRNA synthetase, sir-2, grainins and saposin-like genes were strongly overexpressed after 30 min of PCD induction, while its expression dramatically decreased up to 60 min. On the other hand, overexpression of ribosomal genes increased only 7-fold of basal expression, showing a progressive down-regulation up to 90 min. glutaminyl-tRNA synthetase, sir-2 and grainins could act as negative regulators of PCD, trying to control the biochemical changes related to PCD activation. Overexpression of saposin-like gene could act as up-regulator of some cell death pathways. Our results give evidence of the first genes identified during the early stage of PCD in E. histolytica that could be implicated in regulation of apoptotic pathways.     

Crosstalk between elicitor-induced cell death and cell cycle regulation in tobacco BY-2 cells

The molecular links between cell cycle control and the regulation of programmed cell death are largely unknown in plants. Here we studied the relationship between the cell cycle and elicitor-induced cell death using synchronized tobacco BY-2 cells. Flow cytometry and fluorescence microscopy of nuclear DNA, and RNA gel-blot analyses of cell cycle-related genes revealed that the proteinaceous elicitor cryptogein induced cell cycle arrest at the G1 or G2 phase before the induction of cell death. Furthermore, the patterns of cell death induction and defence-related genes were different in different phases of the cell cycle. Constitutive treatment with cryptogein induced cell cycle arrest and cell death at the G1 or G2 phase. With transient treatment for 2 h, cell cycle arrest and cell death were only induced by treatment with the elicitor during the S or G1 phase. By contrast, the elicitor-induced production of reactive oxygen species was observed during all phases of the cell cycle. These results indicate that although recognition of the elicitor signal is cell cycle-independent, the induction of cell cycle arrest and cell death depends on the phase of the cell cycle.     

Programmierter Zelltod bei Bakterien

Programmed cell death (PCD) in bacteria In bacteria, cell death occurs under certain stressful conditions, and this process has been designated as programmed cell death (PCD). The biological basis of the PCD are two molecules, a stable toxin protein and an unstable antitoxin being either a short RNA molecule or a protein. The antitoxin has to be synthesized permanently to neutralize the toxin. Both components form a TA module. When the synthesis of the antitoxin is blocked or when it is degraded completely, the free toxin acts either bacteriostatic or bactericide. So far, five different mechanisms have been described of how the antitoxin neutralizes the toxin in the absence of stress. Sporulating Bacillus subtilis cells exert cannibalism that means they kill and lyse non‐sporulating cells to take up their nutrients. Streptococcus pneumoniae cells can carry out fratricide. They kill and lyse neighbouring cells, take up fragments of their chromosomal DNA and recombine them with their own DNA. This can result in the uptake of new genes. At the end, two examples of application of TA modules in biotechnology are described.     

Induction of DNA synthesis and apoptosis in cardiac myocytes by E1A oncoprotein

Beginning during the second half of gestation, increasing numbers of cardiac myocytes withdraw from the cell cycle such that DNA synthesis is no longer detectable in these cells by neonatal day 17 in vivo. The mechanisms that exclude these and other terminally differentiated cells from the cell division cycle are poorly understood. To begin to explore the molecular basis of the barrier to G1/S progression in cardiac myocytes, we used adenoviruses to express wild-type and mutant E1A proteins in primary cultures from embryonic day 20 rats. While most of these cardiac myocytes are ordinarily refractory to DNA synthesis, even in the presence of serum growth factors, expression of wild-type E1A stimulates DNA synthesis in up to 94% or almost all successfully transduced cells. Rather than complete the cell cycle, however, these cells undergo apoptosis. Apoptosis is limited to those cells that engage in DNA synthesis, and the kinetics of the two processes suggest that DNA synthesis precedes apoptosis. Mutations in E1A that disable it from binding Rb and related pocket proteins have little effect on its ability to stimulate DNA synthesis in cardiac myocytes. In contrast, mutants that are defective in binding the cellular protein p300 stimulate DNA synthesis 2.4-4.1-fold less efficiently, even in the context of retained E1A pocket protein binding. In the absence of ElA pocket protein binding, the usual situation in the cell, loss of p300 binding severely decreases the ability of ElA to stimulate DNA synthesis. These results suggest that the barrier to G1/S progression in cardiac myocytes is mediated. at least in part, by the same molecules that gate the G1/S transition in actively cycling cells, and that p300 or related family members play an important role in this process.     

Cell-cycle phase-dependence of drug-induced cycle progression delay.

The effect of adriamycin on cell cycle phase progression of CHO cells synchronized into the various phases of the cell cycle by elutriation was investigated by high resolution pulse cytophotometry. Cells treated in all phases of the cell cycle showed delay in their subsequent progression. In addition to the wellknown block of cells in the G2-phase, a delay in passage of cells from G1 to S and a decreased rate of transit through the S-phase were observed. A broadening of the DNA distributions of the treated cells was observed after cell division indicating induction of chromosomal abnormalities.     

Nitric oxide restrain root growth by DNA damage induced cell cycle arrest in Arabidopsis thaliana

Nitric oxide (NO) participates in the regulation of diverse functions in plant cells. However, different NO concentrations may trigger different pathways during the plant development. At basal levels of NO, plants utilize the NO signaling transduction pathway to facilitate plant growth and development, whereas higher concentrations trigger programmed cell death (PCD). Our results show that NO lower than the levels causing PCD, but higher than the basal levels induce DNA damage in root cells in Arabidopsis as witnessed by a reduction in root growth, rather than cell death, since cells retain the capacity to differentiate root hairs. The decrease in meristematic cells and increase in DNA damage signals in roots in responses to NO are in a dose dependent manner. The restraint of root growth is due to cell cycle arrest at G1 phase which is caused by NO induced DNA damage, besides a second arrest at G2/M existed in NO supersensitive mutant cue1. The results indicate that NO restrain root growth via DNA damage induced cell cycle arrest.