Programmed Cell Death in Relation to Petal Senescence in Ornamental Plants

Cell death is a common event in all types of plant organisms. Understanding the phenomenon of programmed cell death (PCD) is an important area of research for plant scientists because of its role in senescence and the post-harvest quality of ornamentals, fruits, and vegetables. In the present paper, PCD in relation to petal senescence in ornamental plants is reviewed. Morphological, anatomical, physiological,and biochemical changes that are related to PCD in petals, such as water content, sink-source relationships,hormones, genes, and signal transduction pathways, are discussed, Several approaches to improving the quality of post-harvest ornamentals are reviewed and some prospects for future research are given.     

高等植物的PCD研究进展(一)

植物细胞程序性死亡(programmed cell death,PCD)已成为当前生物学的研究热点之一。植物PCD普遍存在于植物器官和个体生长发育过程及与环境相互作用过程中,具有重要的生物学意义。在高等植物生长发育过程中,根冠细胞、导管细胞、绒毡层细胞、胚乳细胞、胚柄细胞、糊粉细胞、大孢子细胞、助细胞和反足细胞等细胞在一定程度上均发生了PCD。另外,衰老也涉及PCD。本文综述了最近几年来与发育有关的PCD研究进展,主要包括高等植物细胞死亡的形式、起因及其PCD的形态、生化特征及高等植物营养器官(根、茎和叶)和生殖器官(花、果实和种子)在其生长发育过程中的PCD。文章最后还对植物PCD的进化和生物学意义作了进一步的讨论。 Abstract：Plant programmed cell death(PCD),the details of which are becoming a focus of intensive research in biology, is a ubiquitous phenomenon and plays an improtant biological role in the develpoment of organs and whole organisms and in interactions with the environment.During higher plant development,root cap cells,tracheary elements(TEs),tapetalcells,endosperm cells,suspensor cells,aleurone cells,megaspore cells,help cells and antipodal cells,etc.undergo PCD to some degree.In addition,senescence also involves PCD.This paper mainly reviewed PCD research progress in higher plant development in recent years,including forms and causes of cell death and PCD morphological and biochemical features in higher plants;PCD in development of nutritive organs(root ,stem and leaf) and reproductive organs(flower ,fruit and seed),evolution and biological rloes of plant PCD were further discussed in the paper.     

Plant organ senescence – regulation by manifold pathways

Senescence is the final stage of plant ontogeny before death. Senescence may occur naturally because of age or may be induced by various endogenous and exogenous factors. Despite its destructive character, senescence is a precisely controlled process that follows a well‐defined order. It is often inseparable from programmed cell death (PCD), and a correlation between these processes has been confirmed during the senescence of leaves and petals. Despite suggestions that senescence and PCD are two separate processes, with PCD occurring after senescence, cell death responsible for senescence is accompanied by numerous changes at the cytological, physiological and molecular levels, similar to other types of PCD. Independent of the plant organ analysed, these changes are focused on initiating the processes of cellular structural degradation via fluctuations in phytohormone levels and the activation of specific genes. Cellular structural degradation is genetically programmed and dependent on autophagy. Phytohormones/plant regulators are heavily involved in regulating the senescence of plant organs and can either promote [ethylene, abscisic acid (ABA), jasmonic acid (JA), and polyamines (PAs)] or inhibit [cytokinins (CKs)] this process. Auxins and carbohydrates have been assigned a dual role in the regulation of senescence, and can both inhibit and stimulate the senescence process. In this review, we introduce the basic pathways that regulate senescence in plants and identify mechanisms involved in controlling senescence in ephemeral plant organs. Moreover, we demonstrate a universal nature of this process in different plant organs; despite this process occurring in organs that have completely different functions, it is very similar. Progress in this area is providing opportunities to revisit how, when and which way senescence is coordinated or decoupled by plant regulators in different organs and will provide a powerful tool for plant physiology research.     

植物衰老中的编程性细胞死亡

本文通过对植物衰老和动植物中编程性细胞死亡(PCD)的研究,阐述了植物衰老中PCD存在的依据,澄清了植物衰老和PCD的关系,提出了植物衰老中可能的PCD发生途径,为调控植物衰老的遗传操作提供依据.     

植物衰老中的编程性细胞死亡

本文通过对植物衰老和动植物中编程性细胞死亡(PCD)的研究,阐述了植物衰老中PCD存在的依据,澄清了植物衰老和PCD的关系,提出了植物衰老中可能的PCD发生途径,为调控植物衰老的遗传操作提供依据。     

Apoptotic-like programmed cell death in plants

Programmed cell death (PCD) is now accepted as a fundamental cellular process in plants. It is involved in defence, development and response to stress, and our understanding of these processes would be greatly improved through a greater knowledge of the regulation of plant PCD. However, there may be several types of PCD that operate in plants, and PCD research findings can be confusing if they are not assigned to a specific type of PCD. The various cell-death mechanisms need therefore to be carefully described and defined. This review describes one of these plant cell death processes, namely the apoptotic-like PCD (AL-PCD). We begin by examining the hallmark 'apoptotic-like' features (protoplast condensation, DNA degradation) of the cell's destruction that are characteristic of AL-PCD, and include examples of AL-PCD during the plant life cycle. The review explores the possible cellular 'executioners' (caspase-like molecules; mitochondria; de novo protein synthesis) that are responsible for the hallmark features of the cellular destruction. Finally, senescence is used as a case study to show that a rigorous definition of cell-death processes in plant cells can help to resolve arguments that occur in the scientific literature regarding the timing and control of plant cell death.     

Senescence and programmed cell death: substance or semantics?

The terms senescence and programmed cell death (PCD) have led to some confusion. Senescence as visibly observed in, for example, leaf yellowing and petal wilting, has often been taken to be synonymous with the programmed death of the constituent cells. PCD also obviously refers to cells, which show a programme leading to their death. Some scientists noted that leaf yellowing, if it has not gone too far, can be reversed. They suggested calling leaf yellowing, before the point of no return, 'senescence' and the process after it 'PCD'. However, this runs into several problems. It is counter to the historical definitions of senescence, both in animal and plant science, which stipulate that senescence is programmed and directly ends in death. It would also mean that only leaves and shoots show senescence, whereas several other plant parts, where reversal has not (yet) been shown, have no senescence, but only PCD. This conflicts with ordinary usage (as in root and flower senescence). Moreover, a programme can be reversible and therefore it is not counter to logic to regard the cell death programme as potentially reversible. In green leaf cells a decision to die, in a programmed way, has been taken, in principle, before the cells start to remobilize their contents (that is, before visible yellowing) and only rarely is this decision reversed. According to the arguments developed here there are no good reasons to separate a senescence phase and a subsequent PCD phase. Rather, it is asserted, senescence in cells is the same as PCD and the two are fully synchronous.     

植物程序性细胞死亡检测技术

程序性细胞死亡(PCD)是细胞死亡的方式之一,在植物发育及逆境响应等方面起着重要作用。主要介绍检测植物PCD的细胞学、生物化学、分子生物学及生理学方法,以及流式细胞仪在植物PCD检测中的应用。 Abstract:Programmed cell death (PCD) is an active way for plant cells marching to death,which plays an important role in plant development and stress responses.Cytological,biochemical,molecular and physiological methods for measuring plant PCD were reviewed.Application of flow cytometer to plant PCD research was also covered.     

The technology of ethylene control: use and removal in post-harvest handling of horticultural commodities

A meeting of the Post-Harvest Biology Group of the Association of Applied Biologists on 26 April 1984 discussed the significance of ethylene in the post-harvest handling of horticultural commodities. The natural production of ethylene by crops and the risks of accidental exposure were surveyed. The effects of ethylene on plants were described in terms of ability to respond (responsiveness) and the relationship between response and concentration of ethylene (sensitivity). Sensitivity is related to the properties of ethylene receptors and may be common to all plant tissues. The varying responses to ethylene of fruits, vegetables and ornamentals were described. The limited studies of production and action of ethylene under temperature and atmosphere conditions of normal post-harvest handling were reviewed. Methods of applying and removing ethylene were evaluated in terms of their practicality and applicability. The methodology of ethylene measurement was briefly considered. The potential for further research on post-harvest significance of ethylene was discussed.     

Programmed cell death during pollination-induced petal senescence in petunia

Petal senescence, one type of programmed cell death (PCD) in plants, is a genetically controlled sequence of events comprising its final developmental stage. We characterized the pollination-induced petal senescence process in Petunia inflata using a number of cell performance markers, including fresh/dry weight, protein amount, RNA amount, RNase activity, and cellular membrane leakage. Membrane disruption and DNA fragmentation with preferential oligonucleosomal cleavage, events characteristic of PCD, were found to be present in the advanced stage of petal senescence, indicating that plant and animal cell death phenomena share one of the molecular events in the execution phase. As in apoptosis in animals, both single-stranded DNase and double-stranded DNase activities are induced during petal cell death and are enhanced by Ca(2+). In contrast, the release of cytochrome c from mitochondria, one commitment step in signaling of apoptosis in animal cells, was found to be dispensable in petal cell death. Some components of the signal transduction pathway for PCD in plants are likely to differ from those in animal cells.     

Polyamines are common players in different facets of plant programmed cell death

Programmed cell death (PCD) is a process that occurs throughout the life span of every plant life, from initial germination of the seed to the senescence of the plant. It is a normal physiological milestone during the plant’s developmental process, but it can also be induced by external factors, including a variety of environmental stresses and as a response to pathogen infections. Changes in the morphology of the nucleus is one of the most noticeable during PCD but all the components of the plant cell (cytoplasm, cytoskeleton and organelles) are involved in this fascinating process. To date, relatively little is known about PCD in plants, but several factors, among which polyamines (PAs) and plant growth regulators, have been shown to play an important role in the initiation and regulation of the process. The role of PAs in plant PCD appears to be multifaceted acting in some instances as pro-survival molecules, whereas in others seem to be implicated in accelerating PCD. The molecular mechanism is still under study. Here we present some PCD plant models, focusing on the role of the enzyme responsible for PA conjugation to proteins: transglutaminase (TGase), an enzyme linked with the process of PCD also in some animal models. The role of PAs and plant TGase in the senescence and PCD in flowers, leaf and the self-incompatibility of pollen will be discussed and examined in depth.     

拟南芥AtDAD1 超量表达植株对H2O2抗性的研究

构建拟南芥AtDAD1超量表达载体,以农杆菌介导的方法转化拟南芥哥伦比亚生态型,比较AtDAD1超量表达植株和野生型植株表现型的差异,以及两者对H2O2抗性的不同。实验显示,AtDAD1转基因拟南芥生长较野生型拟南芥更为强壮,对高浓度H2O2有较强的耐受力。测定两者糖含量,发现AtDAD1转基因拟南芥叶片糖的含量明显高于野生型拟南芥叶片。以上结果表明,AtDAD1基因可能参与植物生长发育,并可能在拟南芥抵抗凋亡的过程中发挥重要的作用。     

Autophagy Negatively Regulates Cell Death by Controlling NPR1-Dependent Salicylic Acid Signaling during Senescence and the Innate Immune Response in Arabidopsis

Autophagy is an evolutionarily conserved intracellular process for vacuolar degradation of cytoplasmic components. In higher plants, autophagy defects result in early senescence and excessive immunity-related programmed cell death (PCD) irrespective of nutrient conditions; however, the mechanisms by which cells die in the absence of autophagy have been unclear. Here, we demonstrate a conserved requirement for salicylic acid (SA) signaling for these phenomena in autophagy-defective mutants (atg mutants). The atg mutant phenotypes of accelerated PCD in senescence and immunity are SA signaling dependent but do not require intact jasmonic acid or ethylene signaling pathways. Application of an SA agonist induces the senescence/cell death phenotype in SA-deficient atg mutants but not in atg npr1 plants, suggesting that the cell death phenotypes in the atg mutants are dependent on the SA signal transducer NONEXPRESSOR OF PATHOGENESIS-RELATED GENES1. We also show that autophagy is induced by the SA agonist. These findings imply that plant autophagy operates a novel negative feedback loop modulating SA signaling to negatively regulate senescence and immunity-related PCD.     

Polyols Regulate the Flower Senescence by Delaying Programmed Cell Death in Gladiolus

Programmed cell death (PCD) is associated with petal senescence, but little is known about the triggering or execution of the process of cell death in petals. In the present study, membrane disruption and DNA fragmentation, events characteristic of PCD, were found to be present in the advanced stage of petal senescence studied with ethylene-insensitive flowers of gladiolus, indicating that plant and animal cell death phenomena share one of the molecular events in the execution phase. When the gladiolus florets were treated with inositol both wilting and DNA fragmentation of petals were suppressed/delayed. The present study has provided the initial evidence that inositol has an inhibitory/suppressive effect on apoptotic cell death.     

A matrix metalloproteinase gene is expressed at the boundary of senescence and programmed cell death in cucumber

Cell-cell and extracellular cell matrix (ECM) interactions provide cells with information essential for controlling morphogenesis, cell-fate specification, and cell death. In animals, one of the major groups of enzymes that degrade the ECM is the matrix metalloproteinases (MMPs). Here, we report the characterization of the cucumber (Cucumis sativus L. cv Marketmore) Cs1-MMP gene encoding such an enzyme likely to play a role in plant ECM degradation. Cs1-MMP has all the hallmark motif characteristics of animal MMPs and is a pre-pro-enzyme having a signal peptide, propeptide, and zinc-binding catalytic domains. Cs1-MMP also displays functional similarities with animal MMPs. For example, it has a collagenase-like activity that can cleave synthetic peptides and type-I collagen, a major component of animal ECM. Cs1-MMP activity is completely inhibited by a hydroxamate-based inhibitor that binds at the active site of MMPs in a stereospecific manner. The Cs1-MMP gene is expressed de novo at the end stage of developmental senescence, prior to the appearance of DNA laddering in cucumber cotyledons leaf discs and male flowers. As the steady-state level of Cs1-MMP mRNA peaks late in senescence and the pro-enzyme must undergo maturation and activation, the protease is probably not involved in nutrient remobilization during senescence but may have another function. The physiological substrates for Cs1-MMP remain to be determined, but the enzyme represents a good candidate for plant ECM degradation and may be involved in programmed cell death (PCD). Our results suggest that PCD occurs only at the culmination of the senescence program or that the processes are distinct with PCD being triggered at the end of senescence.     

拟南芥AtDAD1超量表达植株对H2O2抗性的研究

构建拟南芥AtDAD1超量表达载体,以农杆菌介导的方法转化拟南芥哥伦比亚生态型,比较AtDAD1超量表达植株和野生型植株表现型的差异,以及两者对H₂O₂抗性的不同。实验显示,AtDAD1转基因拟南芥生长较野生型拟南芥更为强壮,对高浓度H₂O₂有较强的耐受力。测定两者糖含量,发现AtDAD1转基因拟南芥叶片糖的含量明显高于野生型拟南芥叶片。以上结果表明,AtDAD1基因可能参与植物生长发育,并可能在拟南芥抵抗凋亡的过程中发挥重要的作用。     

Caspase-like proteases and their role in programmed cell death in plants

The investigations performed over recent few years have proved the existence of caspase-like proteases in plants. Three groups of caspase-like proteases: metacaspases, legumain family proteases (VPEs) and saspases have been identified and characterized in plants so far. A considerable amount of evidence supports the role of these enzymes in programmed cell death (PCD) occurring during plant development, their organ senescence as well as hypersensitive response (HR) after pathogen attack. Current knowledge of these enzyme molecular and biochemical structures is summarized in the paper. The homology of caspase-like proteases to animal caspases has been also indicated. Some future perspectives of research concerning the signal pathway during PCD, the regulation of activity and mode of action of these proteases are presented in the article.     

被子植物有性生殖过程中的细胞程序死亡

细胞程序死亡是植物发育过程中的一种普遍现象。早就认识到高等植物生殖器官中一些细胞的死亡对植物有性生殖具有重要作用。这些细胞的死亡过程与动物组织中的细胞程序死亡基本相同。但植物体内诱导生殖细胞程序死亡的信号及其传导系统则显示出其特点 ,有些还表现出雌、雄性细胞的相互作用。探索植物生殖过程中的细胞程序死亡现象将有利于澄清植物生殖过程中的一些机理问题 ,使过去的细胞学研究结果深入到分子水平进行探讨