Coordination of cell proliferation and cell fate decisions in the angiosperm shoot apical meristem.

A unique feature of flowering plants is their ability to produce organs continuously, for hundreds of years in some species, from actively growing tips called apical meristems. All plants possess at least one form of apical meristem, whose cells are functionally analogous to animal stem cells because they can generate specialized organs and tissues. The shoot apical meristem of angiosperm plants acts as a continuous source of pluripotent stem cells, whose descendents become incorporated into organ primordia and acquire different fates. Recent studies are unveiling some of the molecular pathways that specify stem cell fate in the center of the shoot apical meristem, that confer organ founder cell fate on the periphery, and that connect meristem patterning elements with events at the cellular level. The results are providing important insights into the mechanisms through which shoot apical meristems integrate cell fate decisions with cellular proliferation and global regulation of growth and development.     

生长素与植物根尖干细胞巢的维持

干细胞巢的维持与后代细胞的分化是多细胞高等生物个体发育的基础。生长素对植物茎尖和根尖分生组织的形态建成, 尤其是对位于植物这2个末端的分生组织中心的干细胞巢的活性维持起着至关重要的作用。该文综述了近几年在植物根尖干细胞发育领域的研究进展, 主要阐释了PLT蛋白途径、SCR-SHR蛋白途径以及环境因子多信号调控模块维持植物根尖分生组织中干细胞巢稳定的机制, 揭示了生长素可以通过就近合成、极性运输以及信号转导3种方式参与这些信号模块的调控, 从而维持生长素在根尖静止中心细胞附近干细胞巢的浓度梯度, 精确地平衡植物干细胞巢中细胞的增殖与分化。     

A quantitative and dynamic model for plant stem cell regulation

Plants maintain pools of totipotent stem cells throughout their entire life. These stem cells are embedded within specialized tissues called meristems, which form the growing points of the organism. The shoot apical meristem of the reference plant Arabidopsis thaliana is subdivided into several distinct domains, which execute diverse biological functions, such as tissue organization, cell-proliferation and differentiation. The number of cells required for growth and organ formation changes over the course of a plants life, while the structure of the meristem remains remarkably constant. Thus, regulatory systems must be in place, which allow for an adaptation of cell proliferation within the shoot apical meristem, while maintaining the organization at the tissue level. To advance our understanding of this dynamic tissue behavior, we measured domain sizes as well as cell division rates of the shoot apical meristem under various environmental conditions, which cause adaptations in meristem size. Based on our results we developed a mathematical model to explain the observed changes by a cell pool size dependent regulation of cell proliferation and differentiation, which is able to correctly predict CLV3 and WUS over-expression phenotypes. While the model shows stem cell homeostasis under constant growth conditions, it predicts a variation in stem cell number under changing conditions. Consistent with our experimental data this behavior is correlated with variations in cell proliferation. Therefore, we investigate different signaling mechanisms, which could stabilize stem cell number despite variations in cell proliferation. Our results shed light onto the dynamic constraints of stem cell pool maintenance in the shoot apical meristem of Arabidopsis in different environmental conditions and developmental states.     

WOX蛋白家族调控干细胞发育分子机制的研究进展

WOX蛋白家族是植物特有的一类转录因子家族, 是植物胚胎建成、干细胞维持和器官发生等发育过程中的重要调控因子。越来越多的研究表明, 作为干细胞维持的关键因子之一, WOX蛋白家族通过相似或特异的调控网络参与植物初生分生组织(茎尖和根尖分生组织)和次生分生组织(维管分生组织)等各级干细胞的维持和分化。该文综述了近年来WOX蛋白家族调控干细胞发育分子机制的研究进展, 并对其在单、双子叶植物中功能的保守性进行了比较和分析。     

Live-imaging stem-cell homeostasis in the Arabidopsis shoot apex

A precise spatio-temporal regulation of growth and differentiation is crucial to maintain a stable population of stem cells in the shoot apical meristems (SAMs) of higher plants. The real-time and simultaneous observations of dynamics of cell identity transitions, growth patterns, and signaling machinery involved in cell-cell communication is crucial to gain a mechanistic view of stem-cell homeostasis. In this article, I review recent advances in understanding the regulatory dynamics of stem-cell maintenance in Arabidopsis thaliana and discuss future challenges involved in transforming the static maps of genetic interactions into a dynamic framework representing functional molecular and cellular interactions in living SAMs.     

Stem-cell niches: nursery rhymes across kingdoms

Despite the large evolutionary distance between the plant and animal kingdoms, stem cells in both reside in specialized cellular contexts called stem-cell niches. Although stem-cell-specification factors have been recruited from plant-specific gene families, maintenance factors that repress stem-cell differentiation are conserved between plants and animals. Recent evidence indicates that stem cells in multicellular organisms can be specified by kingdom-specific patterning mechanisms that connect to a related core of epigenetic stem-cell factors.     

Genetic regulation of plant shoot stem cells

This article describes the main features of plant stem cells and summarizes the results of studies of the genetic control of stem cell maintenance in the apical meristem of the shoot. It is demonstrated that the WUS-CLV gene system plays a key role in the maintenance of shoot apical stem cells and the formation of adventitious buds and somatic embryos. Unconventional concepts of plant stem cells are considered.     

Shoot apical meristem maintenance: the art of a dynamic balance

The aerial structure of higher plants derives from cells at the tip of the stem, in the shoot apical meristem (SAM). Throughout the life of a plant, the SAM produces stem tissues and lateral organs, and also regenerates itself. For correct growth, the plant must maintain a constant flow of cells through the meristem, where the input of dividing pluripotent stem cells offsets the output of differentiating cells. This flow depends on extracellular signaling within the SAM, governed by a spatial regulatory feedback loop that maintains a reservoir of stem cells, and on factors that prevent meristem cells from differentiating prematurely. The terminating floral meristem incorporates the spatial regulation scheme into a temporal regulation pathway involving flower patterning factors.     

early in short days 4, a mutation in Arabidopsis that causes early flowering and reduces the mRNA abundance of the floral repressor FLC

The plant shoot is derived from the apical meristem, a group of stem cells formed during embryogenesis. Lateral organs form on the shoot of an adult plant from primordia that arise on the flanks of the shoot apical meristem. Environmental stimuli such as light, temperature and nutrient availability often influence the shape and identity of the organs that develop from these primordia. In particular, the transition from forming vegetative lateral organs to producing flowers often occurs in response to environmental cues. This transition requires increased expression in primordia of genes that confer floral identity, such as the Arabidopsis gene LEAFY. We describe a novel mutant, early in short days 4 (esd4), that dramatically accelerates the transition from vegetative growth to flowering in Arabidopsis: The effect of the mutation is strongest under short photoperiods, which delay flowering of Arabidopsis: The mutant has additional phenotypes, including premature termination of the shoot and an alteration of phyllotaxy along the stem, suggesting that ESD4 has a broader role in plant development. Genetic analysis indicates that ESD4 is most closely associated with the autonomous floral promotion pathway, one of the well-characterized pathways proposed to promote flowering of Arabidopsis: Furthermore, mRNA levels of a floral repressor (FLC), which acts within this pathway, are reduced by esd4, and the expression of flowering-time genes repressed by FLC is increased in the presence of the esd4 mutation. Although the reduction in FLC mRNA abundance is likely to contribute to the esd4 phenotype, our data suggest that esd4 also promotes flowering independently of FLC. The role of ESD4 in the regulation of flowering is discussed with reference to current models on the regulation of flowering in Arabidopsis.     

Stem cell function during plant vascular development

While many regulatory mechanisms controlling the development and function of root and shoot apical meristems have been revealed, our knowledge of similar processes in lateral meristems, including the vascular cambium, is still limited. Our understanding of even the anatomy and development of lateral meristems (procambium or vascular cambium) is still relatively incomplete, let alone their genetic regulation. Research into this particular tissue type has been mostly hindered by a lack of suitable molecular markers, as well as the fact that thus far very few mutants affecting plant secondary development have been described. The development of suitable molecular markers is a high priority in order to help define the anatomy, especially the location and identity of cambial stem cells and the developmental phases and molecular regulatory mechanisms of the cambial zone. To date, most of the advances have been obtained by studying the role of the major plant hormones in vascular development. Thus far auxin, cytokinin, gibberellin and ethylene have been implicated in regulating the maintenance and activity of cambial stem cells; the most logical question in research would be how these hormones interact during the various phases of cambial development.     

WUSCHEL介导的固有免疫: 植物干细胞抵御病毒侵害的新机制

植物茎顶端分生组织干细胞是具有持续分化潜能的细胞团, 是植物体地上部所有组织和器官的来源。由于植物行固着生长模式, 其无法通过移动来趋利避害, 因此保护植物干细胞免受病毒和其它病原体侵害对于植物正常生长发育至关重要。尽管人们很早就观察到植物茎顶端干细胞区域与其它部位相比具有极强的抗病毒特性, 但很长时间以来对于植物干细胞如何抵御病毒侵染却知之甚少。近日, 中国科学技术大学赵忠团队阐明了拟南芥(Arabidopsis thaliana)茎顶端干细胞通过WUS蛋白介导的固有免疫反应抵御病毒侵害的机制。WUS能被黄瓜花叶病毒诱导表达, 并抑制病毒在茎尖中央区和周边区积累。WUS通过直接抑制S-腺苷-L-甲硫氨酸依赖的甲基转移酶(SAM MTase)基因的转录, 影响rRNA的加工和核糖体的稳定性, 使病毒蛋白质合成受阻, 从而阻止病毒的复制与传播。该研究揭示了植物体的一种保守且广谱抗病毒策略, 具有重要的理论意义和应用价值。     

Formation and maintenance of the shoot apical meristem

Development in higher plants is characterized by the reiterative formation of lateral organs from the flanks of shoot apical meristems. Because organs are produced continuously throughout the life cycle, the shoot apical meristem must maintain a pluripotent stem cell population. These two tasks are accomplished within separate functional domains of the apical meristem. These functional domains develop gradually during embryogenesis. Subsequently, communication among cells within the shoot apical meristem and between the shoot apical meristem and the incipient lateral organs is needed to maintain the functional domains within the shoot apical meristem.     

Signals that regulate stem cell activity during plant development

Plant stem cells are used continuously to generate new structures during the entire life-span of the organism. In the adult plant, stem cells are found in specialized structures called meristems. The meristems contain the stem cell niche together with rapidly dividing daughter cells that will ultimately differentiate into specific cell types. Some of the master genes that orchestrate the establishment and maintenance of the stem cell niche have now been identified in both the root and the shoot. Recent results show that these genes also determine the fate of the stem cells and that feedback signals from differentiated cells are involved in stem cell specification. These advances have provided a framework to understand how short-range and long-range signals are integrated to specify and position the stem cell niche in the meristems, and how the differentiation potential of plant stem cells is controlled.     

The Arabidopsis OBERON1 and OBERON2 genes encode plant homeodomain finger proteins and are required for apical meristem maintenance

Maintenance of the stem cell population located at the apical meristems is essential for repetitive organ initiation during the development of higher plants. Here, we have characterized the roles of OBERON1 (OBE1) and its paralog OBERON2 (OBE2), which encode plant homeodomain finger proteins, in the maintenance and/or establishment of the meristems in Arabidopsis. Although the obe1 and obe2 single mutants were indistinguishable from wild-type plants, the obe1 obe2 double mutant displayed premature termination of the shoot meristem, suggesting that OBE1 and OBE2 function redundantly. Further analyses revealed that OBE1 and OBE2 allow the plant cells to acquire meristematic activity via the WUSCHEL-CLAVATA pathway, which is required for the maintenance of the stem cell population, and they function parallel to the SHOOT MERISTEMLESS gene, which is required for preventing cell differentiation in the shoot meristem. In addition, obe1 obe2 mutants failed to establish the root apical meristem, lacking both the initial cells and the quiescent center. In situ hybridization revealed that expression of PLETHORA and SCARECROW, which are required for stem cell specification and maintenance in the root meristem, was lost from obe1 obe2 mutant embryos. Taken together, these data suggest that the OBE1 and OBE2 genes are functionally redundant and crucial for the maintenance and/or establishment of both the shoot and root meristems.     

Cells within the nodal region of carnation shoots exhibit a high potential for adventitious shoot formation

Adventitious shoot formation was studied with leaf, stem and axillary bud explants of carnation (Dianthus caryophyllus L.). The shoot regeneration procedures were applicable for a wide range of cultivars and shoot regeneration percentages were high for all explant types. Using axillary bud explants, shoot regeneration efficiency was independent of the size of the bud and of its original position in the plant. In contrast, shoot regeneration from stem and leaf explants was strongly dependent on their original position on the plant. The most distal explants (just below the apex) showed the highest level of shoot regeneration. The adventitious shoot primordia developed at the periphery of the stem segment and at the base of leaf explants. In axillary bud, stem and leaf explants, shoot regeneration originated from node cells, located at the transition area between leaf and stem tissue. Moreover, a gradient in shoot regeneration response was observed, increasing towards the apical meristem.Abbreviations BA benzyladenine - NAA naphthaleneacetic acid     

Regulation of shoot branching patterns by the basal root system: towards a predictive model

This study aimed to underpin the development of a generic predictivemodel of the regulation of shoot branching by roots in nodallyrooting perennial prostrate-stemmed species using knowledgegained from physiological studies of Trifolium repens. Experiment1 demonstrated that the net stimulatory influence from the basalrooted region of the plant on growth of newly emerging axillarybuds on the primary stem decreased as their phytomeric distancefrom the basal root system increased. Experiment 2 found thatat any one time the distribution of net root stimulus (NRS)to the apical bud on the primary stem and all lateral brancheswas fairly uniform within a single plant. Thus, although NRSavailability was uniform throughout the shoot system at anypoint in time, it progressively decreased as shoot apical budsgrew away from the basal root system. Based on these findings,a preliminary predictive model of the physiological regulationof branching pattern was developed. This model can explain thedecline in growth rate of buds on a primary stem as it growsaway from its basal root system but not the rapid progressivedecline in secondary branch development on successive lateralbranches. Thus knowledge of NRS availability to emerging budsis not, by itself, a sufficient basis from which to constructa predictive model. In addition, it seems that the ability ofan emerging bud to become activated in response to its localNRS availability is, at least in part, directly influenced bythe activation level of its parent apical bud. The experimentaltesting of this hypothesis, required for continued developmentof the model, is proceeding. Key words: Axillary bud outgrowth, branch development, bud activation, intra-plant variation, nodal roots, prostrate clonal herbs, root signals, Trifolium repens Received 11 September 2007; Revised 25 November 2007 Accepted 18 January 2008