The role of PENNYWISE and POUND-FOOLISH in the maintenance of the shoot apical meristem in Arabidopsis

Growth of the aerial part of the plant is dependent upon the maintenance of the shoot apical meristem (SAM). A balance between the self-renewing stem cells in the central zone (CZ) and organogenesis in the peripheral zone (PZ) is essential for the integrity, function, and maintenance of the SAM. Understanding how the SAM maintains a balance between stem cell perpetuation and organogenesis is a central question in plant biology. Two related BELL1-like homeodomain proteins, PENNYWISE (PNY) and POUND-FOOLISH (PNF), act to specify floral meristems during reproductive development. However, genetic studies also show that PNY and PNF regulate the maintenance of the SAM. To understand the role of PNY and PNF in meristem maintenance, the expression patterns for genes that specifically localize to the peripheral and central regions of the SAM were examined in Arabidopsis (Arabidopsis thaliana). Results from these experiments indicate that the integrity of the CZ is impaired in pny pnf plants, which alters the balance of stem cell renewal and organogenesis. As a result, pools of CZ cells may be allocated into initiating leaf primordia. Consistent with these results, the integrity of the central region of pny pnf SAMs can be partially restored by increasing the size of the CZ. Interestingly, flower specification is also reestablished by augmenting the size of the SAM in pny pnf plants. Taken together, we propose that PNY and PNF act to restrict organogenesis to the PZ by maintaining a boundary between the CZ and PZ.     

The inhibition and stimulation of DNA synthesis in shoot apices ofChenopodium rubrum L. during photoperiodic induction of flowering

Three short-day inductive cycles bring about inhibition followed by transitional enhancement of growth, not only in roots and leaves but also in different zones of shoot apical meristem, as shown by measurement of DNA synthesis using³H-thymidine autoradiography. The first inductive cycle resulted in marked inhibition of the cells of the central zone (CZ), rib meristem (RM), and peripheral zone (PZ). Subsequent enhancement of DNA synthesis occurs in RM during the second inductive cycle, but in CZ only in the third cycle. The growth activation in PZ is counteracted by decrease in apical dominance which results in further inhibition of leaf primordia and increases in bud primordia. In plants induced only by one cycle, which later reverse the vegetative pattern of growth and differentiation, increased DNA synthesis in RM and CZ was not observed. The significance of inhibitory and stimulatory processes in particular zones of the shoot apex is discussed considering flower morphogenesis.     

Automated tracking of stem cell lineages of Arabidopsis shoot apex using local graph matching

Shoot apical meristems (SAMs) of higher plants harbor stem‐cell niches. The cells of the stem‐cell niche are organized into spatial domains of distinct function and cell behaviors. A coordinated interplay between cell growth dynamics and changes in gene expression is critical to ensure stem‐cell homeostasis and organ differentiation. Exploring the causal relationships between cell growth patterns and gene expression dynamics requires quantitative methods to analyze cell behaviors from time‐lapse imagery. Although technical breakthroughs in live‐imaging methods have revealed spatio‐temporal dynamics of SAM‐cell growth patterns, robust computational methods for cell segmentation and automated tracking of cells have not been developed. Here we present a local graph matching‐based method for automated‐tracking of cells and cell divisions of SAMs of Arabidopsis thaliana. The cells of the SAM are tightly clustered in space which poses a unique challenge in computing spatio‐temporal correspondences of cells. The local graph‐matching principle efficiently exploits the geometric structure and topology of the relative positions of cells in obtaining spatio‐temporal correspondences. The tracker integrates information across multiple slices in which a cell may be properly imaged, thus providing robustness to cell tracking in noisy live‐imaging datasets. By relying on the local geometry and topology, the method is able to track cells in areas of high curvature such as regions of primordial outgrowth. The cell tracker not only computes the correspondences of cells across spatio‐temporal scale, but it also detects cell division events, and identifies daughter cells upon divisions, thus allowing automated estimation of cell lineages from images captured over a period of 72 h. The method presented here should enable quantitative analysis of cell growth patterns and thus facilitating the development of in silico models for SAM growth.     

Developmental Morphology and Histogenesis of Reproductive Structures of the Millet,Panicum miliaceum L. Histogenesis of the Inflorescence and Flower

The branches of successive orders of the inflorescence of Panicum miliaceum L. arise in the axils of the bracts of the branches of next lower order. Their initiation is evidenced by periclinal division of sub-hypodermal cells. The primordia of branches arise in initiation like a normal axillary bud. The floral histogenesis of Panicum miliaceum L. is similar to that of Triticum. Primordia of the spikelet, flower and stamen are initiated by the activity of the periclinal division of the sub-hypodermal cell or cells. Sometimes, periclinal divisions also occur in a few hypodermal cells during these primordial developments; such divisions are more frequent in the formation of the flower and stamen primordia than in the formation of the spikelet primordia. The periclinal division of the dermatogen ceils never occurs in the formation of these organs. Glumes and lemma are initiated in the periclinal division of the dermatogen and hypodermal cell or cells. The primordia of the palea, lodicule and carpel are initiated by means of the periclinal division in the dermatogen cell or cells. In the formation of the palea and carpel, periclinal divisions also occur in hypodermat cells, but their derivatives are protruding into the bases of the primordia and do not constitute the tissues of the palea and carpel. The growing point of the flower axis develops into the ovule. The integuments arise from the periclinal division of dermatogen cells. The periclinal division of dermatogen cells is characteristic of the initiation of the phylloid organs in the Gramineae.     

Sex-specific cell division during development of unisexual flowers in the dioecious plant Silene latifolia

We analyzed cell division patterns during the differentiation of unisexual flowers of the dioecious plant Silene latifolia using in situ hybridization with histone H4 and cyclin A1 genes. The gene expression patterns indicated that the activation of cell divisions in whorls 3 and 4 was reversed in young male and female flower buds. During maturation of flower buds, a remarkable reduction in cell division activity occurred in the male gynoecium primordium and female stamen primordia. Our analyses showed that differential activation and reduction of cell division strongly correlated with sex-specific promotion and cessation in the sex differentiation of unisexual flowers.     

利用流式细胞仪研究拟南芥叶发育过程中细胞周期的调控

叶的形态建成依赖于细胞不断地分裂增殖和不同类型细胞的特化。在叶发育早期,叶细胞主要通过旺盛的有丝分裂来增加原基中细胞的数目。随着叶片的生长,叶细胞自顶部向基部逐渐退出有丝分裂进入内复制来增加细胞的倍性,同时伴随细胞的扩展和分化。本文介绍利用流式细胞仪研究双子叶模式植物拟南芥叶发育过程中细胞周期调控的方法和具体研究实例。我们发现至少存在3种类型的细胞周期异常的拟南芥叶发育突变体。此外,我们还介绍利用流式细胞仪测定DNA复制效率的方法。     

Reaction-diffusion pattern in shoot apical meristem of plants

A fundamental question in developmental biology is how spatial patterns are self-organized from homogeneous structures. In 1952, Turing proposed the reaction-diffusion model in order to explain this issue. Experimental evidence of reaction-diffusion patterns in living organisms was first provided by the pigmentation pattern on the skin of fishes in 1995. However, whether or not this mechanism plays an essential role in developmental events of living organisms remains elusive. Here we show that a reaction-diffusion model can successfully explain the shoot apical meristem (SAM) development of plants. SAM of plants resides in the top of each shoot and consists of a central zone (CZ) and a surrounding peripheral zone (PZ). SAM contains stem cells and continuously produces new organs throughout the lifespan. Molecular genetic studies using Arabidopsis thaliana revealed that the formation and maintenance of the SAM are essentially regulated by the feedback interaction between WUSHCEL (WUS) and CLAVATA (CLV). We developed a mathematical model of the SAM based on a reaction-diffusion dynamics of the WUS-CLV interaction, incorporating cell division and the spatial restriction of the dynamics. Our model explains the various SAM patterns observed in plants, for example, homeostatic control of SAM size in the wild type, enlarged or fasciated SAM in clv mutants, and initiation of ectopic secondary meristems from an initial flattened SAM in wus mutant. In addition, the model is supported by comparing its prediction with the expression pattern of WUS in the wus mutant. Furthermore, the model can account for many experimental results including reorganization processes caused by the CZ ablation and by incision through the meristem center. We thus conclude that the reaction-diffusion dynamics is probably indispensable for the SAM development of plants.     

Patterns of auxin transport and gene expression during primordium development revealed by live imaging of the Arabidopsis inflorescence meristem

BACKGROUND: Plants produce leaf and flower primordia from a specialized tissue called the shoot apical meristem (SAM). Genetic studies have identified a large number of genes that affect various aspects of primordium development including positioning, growth, and differentiation. So far, however, a detailed understanding of the spatio-temporal sequence of events leading to primordium development has not been established. RESULTS: We use confocal imaging of green fluorescent protein (GFP) reporter genes in living plants to monitor the expression patterns of multiple proteins and genes involved in flower primordial developmental processes. By monitoring the expression and polarity of PINFORMED1 (PIN1), the auxin efflux facilitator, and the expression of the auxin-responsive reporter DR5, we reveal stereotypical PIN1 polarity changes which, together with auxin induction experiments, suggest that cycles of auxin build-up and depletion accompany, and may direct, different stages of primordium development. Imaging of multiple GFP-protein fusions shows that these dynamics also correlate with the specification of primordial boundary domains, organ polarity axes, and the sites of floral meristem initiation. CONCLUSIONS: These results provide new insight into auxin transport dynamics during primordial positioning and suggest a role for auxin transport in influencing primordial cell type.     

Cell cycling and cell enlargement in developing leaves of Arabidopsis.

Cell cycling plays an important role in plant development, including: (1) organ morphogenesis, (2) cell proliferation within tissues, and (3) cell differentiation. In this study we use a cyclin::beta-glucuronidase reporter construct to characterize spatial and temporal patterns of cell cycling at each of these levels during wild-type development in the model genetic organism Arabidopsis thaliana (Columbia). We show that a key morphogenetic event in leaf development, blade formation, is highly correlated with localized cell cycling at the primordium margin. However, tissue layers are established by a more diffuse distribution of cycling cells that does not directly involve the marginal zone. During leaf expansion, tissue proliferation shows a strong longitudinal gradient, with basiplastic polarity. Tissue layers differ in pattern of proliferative cell divisions: cell cycling of palisade mesophyll precursors is prolonged in comparison to that of pavement cells of the adjacent epidermal layers, and cells exit the cycle at different characteristic sizes. Cell divisions directly related to formation of stomates and of vascular tissue from their respective precursors occur throughout the period of leaf extension, so that differing tissue patterns reflect superposition of cycling related to cell differentiation on more general tissue proliferation. Our results indicate that cell cycling related to leaf morphogenesis, tissue-specific patterns of cell proliferation, and cell differentiation occurs concurrently during leaf development and suggest that unique regulatory pathways may operate at each level.     

穗花牡荆花芽分化过程中形态和生理指标变化

以穗花牡荆为研究材料,通过探究其花芽分化进程和生理特性,为花期调控技术提供成花机理。采用物候期观察和石蜡切片相结合的方法并测定花芽分化过程中相关生理指标,研究花发育过程中的形态和生理变化。结果表明,穗花牡荆花芽分化为一年多次分化型,其进程可划分为七个时期：未分化期、总轴花序原基分化期、初级分轴花序原基分化期、次级分轴花序原基分化期、小花原基分化期、花器官分化前期和花器官分化后期。同一植株不同位置花芽及同一花序中不同单花分化的进程不同,第一季花期后各阶段的花芽分化形态常存在重叠。花芽分化过程中不同时期叶片和花芽的可溶性糖和可溶性蛋白质含量均有上升下降的变化,总体上叶片中营养物质含量高于花芽保证营养供应。花芽分化过程中,IAA、ABA、CTK和GA3整体水平上先升后降有利于花芽分化进行。研究认为,花芽中大量的可溶性糖和蛋白质积累及较高的碳氮比,有利于穗花牡荆花芽形态分化顺利完成。低水平的GA3/ABA和IAA/CTK有利于花序的形成,ABA/CTK和ABA/IAA比值升高促进小花原基和小花萼片原基的分化, GA3/CTK、GA3/ABA和GA3/IAA比值升高促进花瓣原基、雄雌蕊原基发育。     

罗汉果花芽分化过程中形态及其激素水平变化特征

采用石蜡切片和酶联免疫法(ELISA)对罗汉果雄性、雌性、两性花芽分化过程的形态和激素水平变化进行观测,为罗汉果开花调控和品种选育提供科学依据。结果表明:(1)罗汉果雄性、雌性、两性花的花芽分化过程均可分为花芽未分化期、花芽分化初期、花序分化期、萼片原基分化期、花瓣原基分化期、雄蕊原基分化期和雌蕊原基分化期7个阶段。雄蕊原基分化期前,3种花芽分化过程无明显差异,各时期形态特征均依次为:茎端呈圆锥状(花芽未分化期)→茎端经半球形变成扁平状(花芽分化初期)→距茎端5~7节位处分化出穗状花序(花序分化期)→小花原基周围形成5个萼片原基(萼片原基分化期)→萼片原基内侧形成5个花瓣原基(花瓣原基分化期)。雄蕊和雌蕊原基分化期,3种花芽分化过程存在明显差异,雄蕊原基内侧出现雌蕊原基后,雄花芽雄蕊原基继续发育成雄蕊,雌蕊原基停滞生长,退为一个小突起;雌花芽雌蕊原基继续发育成雌蕊,雄蕊原基生长缓慢,退化为小花丝;两性花芽雌蕊和雄蕊原基均继续发育,形成外观正常的雌蕊和雄蕊。(2)内源激素脱落酸(ABA)、赤霉素(GAs)和玉米素核苷(ZR)含量在3种花芽分化过程中变化规律相似,即ABA含量在花芽生理分化期降低,花芽形态分化期升高,而GAs和ZR含量则基本保持不变;吲哚乙酸(IAA)含量在3种花芽分化过程中变化存在明显差异,雌花芽IAA含量在花芽生理分化期升高,花芽形态分化期逐渐降低,而雄性和两性花芽的IAA含量则基本保持不变。ABA/GAs、ABA/IAA、ZR/IAA和ZR/GAs激素含量比值在3种花芽分化过程中变化规律相似,ABA/GAs在花芽生理分化期降低,花芽形态分化期升高,而BA/IAA、ZR/IAA和ZR/GAs则基本保持不变。研究认为,罗汉果花芽分化过程经历一个"两性期",高ABA含量和ABA/GAs比值有利于罗汉果花芽分化,IAA可能对罗汉果花性分化具有重要作用。     

Cloning and expression analysis of a Petunia hybrida flower specific mitotic-like cyclin

A cyclin cDNA clone (Pethy;CycB1;1) was isolated from a Petunia hybrida ovary specific cDNA library. Sequence comparison revealed that Pethy;CYCB1;1 protein is highly homologous to mitotic B1 cyclins. Northern analysis and in situ hybridisation experiments showed that its expression is developmentally regulated and restricted to flower organs. We have attempted to define some of the cell division patterns which contribute to shaping each floral organ by analysing Pethy;CycB1;1 expression on Petunia flower sections. While in sepals, epidermis and parenchyma cell division patterns were comparable, there were two distinct cell division patterns in petals. In the epidermis, Pethy;CYCB1;1 expression was found both at the petal tip and along epidermis, whereas in the parenchyma only at the petal tips. In reproductive organs cell divisions were detected only in sporophytic tissues. No signals were detected inside meiotic cells.     

慈姑匍匐茎的起源和球茎的膨大研究

匍匐茎的发生一般见于主茎倒二或倒三叶原基的叶腋部位。在匍匐茎发生区域的主茎一侧,匍匐茎原始细胞的基部形成壳状区;壳状区的形成对匍匐茎原基的外凸起一定作用。匍匐茎无居间分生组织;它的伸长依靠顶端分生组织细胞的横向分裂,使轴向细胞数目增多,并使细胞的轴向延伸。球茎的膨大是通过匍匐茎第8—10节基本分生组织的细胞有丝分裂,增加细胞数目,然后细胞体积的扩大来实现的。球茎中的淀粉一般为单粒淀粉;匍匐茎中的淀粉由单粒和复合两种淀粉粒组成。     

A Sequential Study of Cell Divisions and Expansion Patterns on a Single Developing Shoot Apex of Vinca major

During the growth of a single developing vegetative apex ofVinca major, both the orientation and frequency of cell divisions,and the pattern of cell expansion, were observed using a non-destructivereplica technique. Micrographs taken at daily intervals illustratethat the central region of the apical dome remains relativelyinactive, except for a phase of cell division which occurs after2 d of growth. The majority of growth takes place at the proximalregions of the dome from which develop the successive pairsof leaves. The developing leaf primordia are initiated by aseries of divisions which occur at the periphery of the centraldome and are oriented parallel to the axis of the subsequentleaves. The cells which develop into the outer leaf surfaceof the new leaves undergo expansion and these cells divide allowingfor the formation of the new leaf. This paper describes thefirst high-resolution sequential study of cell patterns in asingle developing plant apex. Sequential development, cell division, expansion patterns, SEM, Vinca major, apical dome, leaf primordium, leaf initiation     

绵枣儿花芽分化的形态解剖学研究

为探明绵枣儿(Barnardia japonica)在哈尔滨地区的年生长节律以及花芽分化进程,该文以从长白山引种至东北林业大学花卉研究所苗圃内的绵枣儿为材料,采用田间观察法研究绵枣儿的年生长节律,并采用石蜡切片法观察其花芽分化各阶段的形态解剖学特征。结果表明:(1)绵枣儿在哈尔滨地区的生长节律大致可以分为四个时期,即花芽分化与发育期、开花期、结实期、休眠期。(2)绵枣儿花芽分化进程可以分为七个阶段,即4月中上旬,由于土壤温度较低,鳞茎仍处于未分化期; 4月下旬进入花序原基分化期; 5月上旬苞片原基分化; 5月下旬为小花原基分化期; 5月末至6月初花被片原基分化; 6月上旬进入雄蕊原基分化期; 6月下旬为雌蕊原基分化期。该研究明确了绵枣儿在哈尔滨地区的年生长节律和花芽分化各阶段的解剖学特性,为园林应用和新品种的选育提供了一定的科学依据。     

山鸡椒雄花花芽发育形态解剖特征观察

采用体视显微镜、扫描电镜和石蜡切片技术对山鸡椒（Litsea cubeba（Lour.） Pers.）雄花花芽分化发育的外部形态和内部解剖结构进行了观察研究。结果显示:（1）山鸡椒雄花花芽分化发生可分为5个时期,即未分化期、花序原基分化期、苞片原基分化期、花原基分化期和花器官分化期,其中花器官分化期又可细分为花被原基分化期、雄蕊原基分化期和雌蕊原基分化期;各相邻分化时期存在一定重叠现象;花期从翌年1月上旬至3月下旬。（2）雄花成熟结构中具有独特的雄蕊蜜腺,蜜腺绿色且形态不规则,着生于内轮雄蕊基部,分布于花丝两侧,夹在内外轮雄蕊的花丝之间,与内轮花丝紧密相连。（3）雄蕊花药四室,花药壁发育属于基本型;腺质绒毡层;小孢子母细胞减数分裂过程中胞质分裂属于连续型;成熟花粉为2-细胞花粉粒;成熟花粉粒外壁刺突较多,刺突基部膨大,外壁露出部分粗糙,无薄壁区,有少数小穿孔。（4）山鸡椒雄花中绝大多数雌蕊发育至腹缝线卷合形成子房室时停止,柱头发育不良或者败育,花柱缩短或缺失,不能受精,直到开花结束,即发生退化。本研究明确了山鸡椒雄花花芽发育发生各个阶段时间、形态变化特点及外部形态变化特征,山鸡椒小孢子发生、雄配子体发育至散粉期变化特点和规律以及雄花中退化雌蕊发育的进程,可为山鸡椒优良品种选育、调控花期和提高结实率提供一定的参考。     

Spindle polarity in S. cerevisiae: MEN can tell

Spatial coordination between the axis of the spindle and the division plane is critical in asymmetric cell divisions. In the budding yeast S. cerevisiae, orientation of the mitotic spindle responds to two intertwined programs dictating the position of the spindle poles: one providing the blueprint for built-in pole asymmetry, the other sequentially confining microtubule-cortex interactions to the bud and the bud neck. The first program sets a temporal asymmetry to limit astral microtubules to a single pole prior to spindle pole separation. The second enforces this polarity by allowing these early formed microtubules to undergo capture at the bud cell cortex while stopping newly formed microtubules once cortical capture shifts to the bud neck. The remarkable precision of this integrated program results in an invariant pattern of spindle pole inheritance in which the "old" spindle pole is destined to the bud. An additional layer of asymmetry is superimposed to couple successful chromosomal segregation between the mother and the bud with mitotic exit. This is based on the asymmetric localization to the committed daughter-bound pole of signaling components of the mitotic exit network. This system operates irrespective of intrinsic spindle polarity to ensure that it is always the pole translocating into the bud that carries the signal to regulate mitotic exit.