MAPK对高等植物细胞分裂和生长的调节

综述了MAPKs参与植物细胞周期调控的最新进展 ,植物激素与MAPK ,MAPK与植物细胞有丝分裂 ,以及MAPK与植物细胞分裂和生长的调控等三方面 ,阐述MAPK参与调控高等植物细胞分化和有丝分裂的机制。     

The plant cell body: a cytoskeletal tool for cellular development and morphogenesis

Summary Certain aspects of cellular behaviour in relation to growth and development of plants can be understood in terms of the cell body concept proposed by Daniel Mazia in 1993. During the interphase of the mitotic cell cycle, the plant cell body is held to consist of a nucleus and a perinuclear microtubule-organizing centre from which microtubules radiate into the cytoplasm. During mitosis and cytokinesis in meristematic cells, and also during the period of growth in post-mitotic cells immediately beyond the meristem, the plant cell body undergoes various characteristic morphological transformations, many of which are proposed as being related to changing structural connections with the actin-based component of the cytoskeleton and with specialized, plasma-membrane-associated sites at the cell periphery. In post-mitotic cells, these transformations of the plant cell body coincide with, and probably provide conditions for, the various pathways of development which such cells follow. They are also responsible, for the acquisition of new cellular polarities. Events in which the plant cell body participates include the formation of a mitotic spindle, phragmoplast, and new cell division wall, the rearrangement of a diffuse type of cell wall growth into tip growth (as occurs, e.g., during the initiation and subsequent development of root hairs), and the growth and division that occurs in reactivated vacuolate cells. If more evidence can be marshalled in support of the existence and properties of the plant cell body, then this concept could prove useful in interpreting the cytological bases of a range of developmental events in plants.Abbreviations CMT cortical microtubule - EMT endoplasmic microtubule - ER endoplasmic reticulum - MF microfilament - MT microtubule - MTOC microtubule-organizing centre - PPB preprophase band (of microtubules) - QC quiescent centre - VSC vesicle supply centre     

Interaction of purified DNA with plant protoplasts of different cell cycle stage: The concept of a competent phase for plant cell transformation

Summary The polycation mediated attachment of purified tritiated DNA to plant protoplasts has been measured by quantitative microautoradiography. The automated grain counting technique used, also provides information on the cell cycle stage of individual protoplasts, which circumvents the need to synchronize the plant cell population before preparation of protoplasts. With protoplasts from asynchronously dividing suspension cultures of Nicotiana syhestris (NS-1), S-phase protoplasts appear to be inefficient binders of ³H-DNA, as compared with G₁ or G₂ protoplasts. Protoplasts derived from a tumour line of Crepis capillaris (CAPT) exhibit ³H-DNA binding at all cell cycle phases, but Sphase protoplasts appear to be preferential binders. These differences are discussed with reference to cell cycle kinetics, membrane charge variation and the possibility of increasing the efficiency of genetic transformation of higher plant cells in culture.     

细胞周期调控的一个重要元素-CDC48

细胞周期调控研究已成为当前生物学领域的一大热门课题,对哺乳动物和酵母细胞周期调控的研究已经非常深入且日臻成熟;植物细胞周期调控研究起步相对较晚但近些年来在该领域也取得了很大的进展。CDC48是真核生物中普遍存在的一个重要的细胞周期调节基因,其蛋白产物CDC48也是研究较为成熟的一个周期蛋白,国外生物学者对该基因已经开展多年研究,而国内尚未见任何报道。主要论述近几年来有关真核生物酵母、哺乳动物和植物CDC48的研究现状及发展趋势。     

Physiological functions of plant cell coverings

The cell coverings of plants have two important functions in plant life. Plant cell coverings are deeply involved in the regulation of the life cycle of plants: each stage of the life cycle, such as germination, vegetative growth, reproductive growth, and senescence, is strongly influenced by the nature of the cell coverings. Also, the apoplast, which consists of the cell coverings, is the field where plant cells first encounter the outer environment, and so becomes the major site of plant responses to the environment. In the regulation of each stage of the life cycle and the response to each environmental signal, some specific constituents of the cell coverings, such as xyloglucans in dicotyledons and 1,3,1,4-β-glucans in Gramineae, act as the key component. The physiological functions of plant cell coverings are sustained by the metabolic turnover of these components. The components of the cell coverings are supplied from the symplast, but then they are modified or degraded in the apoplast. Thus, the metabolism of the cell coverings is regulated through the cross-talk between the symplast and the apoplast. The understanding of physiological functions of plant cell coverings will be greatly advanced by the use of genomic approaches. At the same time, we need to introduce nanobiological techniques for clarifying the minute changes in the cell coverings that occur in a small part within each cell. Electronic Publication     

Cauliflower mosaic virus 35 S promoter directs S phase specific expression in plant cells

Summary An experimental system to study cell cycle specific gene expression in plant cells was developed using protoplasts from tobacco cells synchronized by aphidicolin treatment. Chimeric plasmids consisting either of the chloramphenicol acetyltransferase (CAT) gene downstream of the cauliflower mosaic virus (CaMV) 35 S promoter or the nopaline synthase (nos) promoter were introduced into synchronized protoplasts of four cell cycle stages by electroporation. In the case of the CaMV 35 S promoter cyclic oscillation of CAT activity was observed which paralleled the cell cycle of the recipient cells. The peak of CAT activity was found in the S phase, while no such cyclic change was observed in the case of the nos promoter. This system clearly shows that it is feasible to search for a cell cycle specific promoter. The significance of these observations is discussed in relation to the study of plant cells.     

Completion of the sexual cycle and demonstration of genetic recombination in Ustilago maydis in vitro

The heterobasidiomycetes responsible for plant smuts obligatorily require their hosts for the completion of the sexual cycle. Accordingly, the sexual cycle of these fungi could so far be studied only by infecting host plants. We have now induced Ustilago maydis, the causative agent of corn smut, to traverse the whole life cycle by growing mixtures of mating-compatible strains of the fungus on a porous membrane placed on top of embryogenic cell cultures of its host Zea mays. Under these conditions, mating, karyogamy and meiosis take place, and the fungus induces differentiation of the plant cells. These results suggest that embryogenic maize cells produce diffusible compounds needed for completion of the sexual cycle of U. maydis, as the plant does for the pathogen during infection. Received: 16 February 1999 / Accepted: 30 June 1999     

Optimizing conditions for tobacco BY-2 cell cycle synchronization

Summary Tobacco BY-2 cells have become a major tool in plant cell biological research, in part due to the availability of a cell cycle synchronization protocol. This method, pioneered by Nagata and coworkers, involves sequential treatments with aphidicolin (a DNA synthesis inhibitor) and propyzamide (a microtubule inhibitor which arrests mitosis). The effects of these inhibitors are reversible, allowing the cell culture to progress into M phase synchronously. However, attempts to reproduce high levels of synchrony with published protocols have not been uniformly successful. This paper describes critical parameters for cell cycle synchronization and documents the kinetics and variation typically found in using this protocol.     

Okadaic Acid as a Probe to Analyse the Cell Cycle Progression in Plant Cells

Previously we have demonstrated the dynamic change of microtubules (MTs) during cell cycle progression using highly synchronized tobacco BY-2 cells and characterized the specific transition points of MT organization (Hasezawa and Nagata, 1991). In this study the effect of okadaic acid (OA), a specific inhibitor of protein phosphatase 1 and 2A, on such changes of MTs during cell cycle was examined. These experiments revealed that cell cycle was arrested before the formation of the preprophase band (PPB), at anaphase and at the border of M/G₁. Although the block at the anaphase seemed to be analogous to that observed in animal cells (Yamashita et al., 1990), the other two blocks were specific to plant cells. It is interesting that these two blocks coincided with the transition points of MT organization, as revealed in the previous study (Hasezawa and Nagata, 1991). Thus it is proposed that phosphorylation is involved in MT organization, although the effect of OA has been shown mainly to be the activation of cdc-2/histone H1 kinase in animal cells. Another inhibitor of protein phosphatase 1 and 2A, calyculin A (CLA), showed very similar effects on the cell cycle progression. The use of such inhibitors to dissect the cell cycle progression of plant cells is discussed.     

Early effects of floral induction on cell division in the shoot apex of Silene

The changes in cell number, the relative proportions of interphase nuclei with different amounts of DNA, mitotic index and labelling index have been investigated in the shoot apex of Silene coeli-rosa L. (a long-day plant) during the first long day of photoinduction, and compared with the corresponding changes in plants in short days. 3 h after the start of induction the proportion of nuclei in the G2 phase of the cell cycle had increased, the mitotic index tended to be higher, and the labelling index was lower than in plants in short days. 8–9 h later the values for plants in the long day had become similar to those for plants in short days. No evidence was obtained for a synchronisation of cells in one phase of the cell cycle as a result of photoinduction. The results obtained were consistent with a temporary shortening of the cell cycle in the induced apices over the first long day which resulted in a greater increase in cell number by the end of the first day of photoinduction than in plants in short days.Abbreviations LD long day - SD short day     

Natural Pesticide Dihydrorotenone Arrests Human Plasma Cancer Cells at the G0/G1 Phase of the Cell Cycle

Dihydrorotenone (DHR) is a natural pesticide used for farming including organic produces. We recently found that DHR induces human plasma cell apoptosis by provoking endoplasmic reticulum stress. In the present study, we found that DHR arrested human plasma cancer cells at the G0/G1 phase of the cell cycle. Mechanistical studies demonstrated that cell cycle arrest was associated with downregulated cell cycle promotors including cyclin D2, cyclin D3, cyclin‐dependent kinases (CDK4, CKD6), and phosphorylated‐Rb. DHR inhibited cyclin D2 transactivation, thus inhibiting its mRNA expression. In addition, DHR upregulated the cell cycle repressors p21 and p53. DHR also increased the phosphorylation level of p53, suggesting the upregulated transactivation function of p53, which was confirmed by the induction of p21, a substrate of activated p53. Moreover, DHR downregulated AKT and ERK phosphorylation, an incentive of cell cycle progression. Therefore, these results collectively demonstrated that DHR disrupts the cell cycle progress, which suggests that DHR is toxic to human plasma cells. Caution is thus suggested when handling with this agent.     

Unique Tissue-Specific Cell Cycle in Physcomitrella

Abstract: The moss Physcomitrella patens (Hedw.) B.S.G. is a novel tool in plant functional genomics as it has an inimitable high gene targeting efficiency facilitating the establishment of gene/function relationships.
Here we report, based on flow cytrometric (FCM) data, that the basic nuclear DNA content per cell of Physcomitrella is 0.53 pg, equating to a genome size of 1 C = 511 Mbp. Furthermore, we describe a unique tissue-specific cell cycle change in this plant. Young plants consisting of only one cell type (chloronema) displayed one single peak of fluorescence in FCM analyses. As soon as the second cell type (caulonema) developed from chloronema, a second peak of fluorescence at half the intensity of the previous one became detectable, indicating that caulonema cells were predominantly at the G1/S transition, whereas chloronema cells were mainly accumulating at the G2/M transition. This conclusion was validated by further evidence: i) The addition of ammonium tartrate arrested Physcomitrella in the chloronema state and in G2/M. ii) Two different developmental mutants, known to be arrested in the chloronema/caulonema transition, remained in G2/M, regardless of age and treatment. iii) The addition of auxin or cytokinin induced the formation of caulonema, as well as decreasing the amount of cells in G2/M phase. Additionally, plant growth regulators promoted endopolyploidisation.
Thus, cell cycle and cell differentiation are closely linked in Physcomitrella and effects of plant hormones and environmental factors on both processes can be analysed in a straight forward way. We speculate that this unique tissue-specific cell cycle arrest may be the reason for the uniquely high rate of homologous recombination found in the Physcomitrella nuclear DNA.     

An overview of the KIN1/PAR-1/MARK kinase family

Members of the KIN1/PAR-1/MARK kinase family are conserved from yeast to humans and share a similar primary structural organization. Several kinases of this family appear to be at the crossroads of various biological functions including cell polarity, cell cycle control, intracellular signalisation, microtubules stability and protein stability. Here we present an overview of known roles of KIN1/PAR-1/MARK kinases including pEg3 a newly identified member which is regulated during the cell cycle and is a potential regulator of the cell cycle progression. Some common modes of action can be deciphered for this protein kinase family.     

Cell cycle analysis of tumour-derived cultures ofCrepis capillaris: A kinetic analogy with proliferation of animal tumour cells

Summary Analysis of the cell cycle by three methods has revealed unusual kinetics of proliferation in tumour derived suspensions ofCrepis capillaris. The different methods of analysis yield different estimates of cycle phase durations, and such discrepancies have been explained in terms of low growth fractions with rapid total cycle traverse. Specifically, confidence in the estimation of G₂ duration by the fraction of labelled mitosis analysis, and comparison with shorter G₂ estimates obtained by the two other methods, suggests that cells drop out in G₁. However, cells which do not drop out of the proliferative compartment traverse G₁ extremely rapidly. Extremely short cell cycle durations in which the G₁ phase is virtually non-existent are uncharacteristic of plant cell suspension cultures, in which the G₁ phase has previously been shown to be extended as compared with meristematic root tip cells. A model has been proposed in which a central core of rapidly dividing cells continuously loses cells into a subpopulation of resting or G₀ cells with the G₁ DNA content. Similarities between plant and animal tumours with respect to cell growth and division are discussed.     

核内再复制分子机制研究进展

核内再复制是指细胞没有经历有丝分裂而形成特殊的多倍体核的现象.这是由于细胞周期没有进入M期并多次重复进入S期所致,其主要特征是MPF失活及S期CDKs激酶活性呈周期性振荡.核内再复制现象普遍存在于动物和植物中,在高代谢活性组织的细胞及最终进行高度分化的细胞中最常见.对细胞迅速生长和增殖有着重要的意义.如何阻止细胞有丝分裂的进行,进而引发核内再复制的机制仍在研究中.本文对植物及哺乳动物细胞中核内再复制的产生、调控机制及体外诱导方式等进行了综合评述.     

The induction of DNA strand breaks at specific sites by N-nitroso-N-ethylurea depends on the phases of the cell cycle

Synchronized root meristems of Pisum sativum were treated at each phase of the cell cycle with 6.25 mM N-nitroso-N-ethylurea. DNA extracted from treated cells and run in agarose gel electrophoresis exhibits a series of discrete fragments with length below 2500 bp and a significant number of unspecific single-stranded breaks (or alkali-labile sites). Experiments with micrococcal nuclease indicated that the nucleosomal organization of the chromatin is not responsible for the generation of the discrete fragments: it seems that their appearance is associated with a preferable attack of the mutagen at specific sites, characteristics for the plant genome. Moreover, a cell cycle dependent release of the discrete fragments was found with maximum at G1-S and minimum at mitosis. The model experiments designed to clarify this observation suggest that it might be determined from the cell cycle dependent fluctuation in the accessibility of the chromatin DNA and/or the process of excision-repair.     

The role of protein kinases in the regulation of plant growth and development

We review the role of protein kinases in plant hormone-mediatedsignalling, nutrient signalling and cell cycle control and in the crosstalkbetween these different contributors to plant growth regulation. The areas ofhormone-mediated signalling covered include ABA-mediated responses to osmoticstress, wounding and pathogen attack, as well as ethylene and cytokininsignalling pathways. These areas involve members of several major protein kinasefamilies, including the SNFl-related protein kinase-2 (SnRK2) subfamily, thecalcium-dependent protein kinase (CDPK) family, the mitogen activated protein(MAP) kinase family, the glycogen synthase kinase (GSK)- 3/shaggy family and thereceptor-like protein kinase (RPK) family. In the section on nutrient signallingwe review the role of SnRK1 protein kinases in the global regulation of carbonmetabolism, including aspects of sugar sensing and assimilate partitioning, andwhat is known about nitrogen and sulphur nutrient signalling. In the cell cyclesection, we summarise progress in the elucidation of cell cycle control systemsin plants and discuss the interaction between cell cycle control anddevelopment. We expand further on the hypothesis of crosstalk between differentsignalling pathways in a separate section in which we discuss evidence forinteraction between plant growth regulators and the cell cycle, betweendifferent nutrient signalling pathways, between nutrient and cell cyclesignalling and between nutrient and ABA signalling.