Manipulation of leaf shape by modulation of cell division

The role of cell division as a causal element in plant morphogenesis is debatable, with accumulating evidence supporting the action of cell division-independent mechanisms. To directly test the morphogenic function of cell division, we have utilised a microinduction technique to locally and transiently manipulate the expression in transgenic plants of two genes encoding putative effectors of the cell cycle, a tobacco A-type cyclin and a yeast cdc25. The results show that local expression of these genes leads to modulation of cell division patterns. Moreover, whereas altered cell division in the apical meristem had no influence on organogenesis, local induction of cell proliferation on the flanks of young leaf primordia led to a dramatic change in lamina development and, thus, leaf shape. These data indicate that the role of cell division in plant morphogenesis is context dependent and identify cell division in the leaf primordium as a potential target for factors regulating leaf shape.     

A wheat histone H3 promoter confers cell division-dependent and -independent expression of the gus A gene in transgenic rice plants

To investigate developmental regulation of wheat histone H3 gene expression, the H3 promoter, which has its upstream sequence to ?1711 (relative to the cap site as +1), was fused to the coding region of the gus A gene (?1711H3/GUS) and introduced into a monocot plant, rice. Detailed histochemical analysis revealed two distinct types of GUS expression in transgenic rice plants; one is cell division-dependent found in the apical meristem of shoots and roots and in young leaves, and another is cell division-independent detected in flower tissues including the anther wall and the pistil. In this study, replication-dependent expression occurring in non-dividing cells which undergo endoreduplication could not be discriminated from strict replication-independent expression. The observed expression pattern in different parts of roots suggested that the level of the H3/GUS gene expression is well correlated with activity of cell division in roots. To identify 5′ sequences of the H3 promoter necessary for an accurate regulation of the GUS expression, two constructs containing truncated promoters, ?908H3/GUS and ?185H3/GUS, were analyzed in transiently expressed protoplasts, stably transformed calli and transgenic plants. The results indicated that the region from ?909 to ?1711 contains the positive cis-acting element(s) and that the proximal promoter region (up to ?185) containing the conserved hexamer, octamer and nonamer motifs is sufficient to direct both cell division-dependent and -independent expression. The use of the meristem of roots regenerated from transformed calli for the analysis of cell division-dependent expression of plant genes is discussed.     

The integration of cell proliferation and growth in leaf morphogenesis

A number of recent publications have assessed the outcome on leaf development of targeted manipulation of cell proliferation. The results of these investigations have awakened interest in the long-standing debate in plant biology on the precise role of cell division in morphogenesis. Does cell proliferation drive morphogenesis (cell theory) or is it subservient to a mechanism which acts at the whole organ level to regulate morphogenesis (organismal theory)? In this review, the central role of growth processes (distinct from cell proliferation) in morphogenesis is highlighted and the limitations in our understanding of the basic mechanisms of plant growth control are highlighted. Finally, an attempt is made to demonstrate how sequential local co-ordination of growth might provide an interpretation of some of the recent observations on cell proliferation and leaf morphogenesis.     

Cell proliferation, protein turnover, and the decay of thermotolerance in CHO cells

The rates of cell proliferation, total protein and heat shock protein turnover, and thermotolerance decay were determined in exponential-phase CHO cells. Following a mild heat treatment of 44 degrees C for 10 min, the rate of total protein turnover slightly exceeded the rate of cell proliferation. Heated cells doubled approximately every 16 h and labeled total protein turned over with a half-time of 14 h. The turnover rate of heat shock proteins (10-h half-time) somewhat exceeded the total protein turnover rate and was similar to the thermotolerance decay rate. These data indicate that the turnover of total and heat shock proteins and thermotolerance occurs as a result of both cell division-dependent and division-independent processes.     

The Tangled1 gene is required for spatial control of cytoskeletal arrays associated with cell division during maize leaf development.

The cytoskeleton plays a major role in the spatial regulation of plant cell division and morphogenesis. Arrays of microtubules and actin filaments present in the cell cortex during prophase mark sites to which phragmoplasts and associated cell plates are guided during cytokinesis. During interphase, cortical microtubules are believed to influence the orientation of cell expansion by guiding the pattern in which cell wall material is laid down. Little is known about the mechanisms that regulate these cytoskeleton-dependent processes critical for plant development. Previous work showed that the Tangled1 (Tan1) gene of maize is required for spatial regulation of cytokinesis during maize leaf development but not for leaf morphogenesis. Here, we examine the cytoskeletal arrays associated with cell division and morphogenesis during the development of tan1 and wild-type leaves. Our analysis leads to the conclusion that Tan1 is required both for the positioning of cytoskeletal arrays that establish planes of cell division during prophase and for spatial guidance of expanding phragmoplasts toward preestablished cortical division sites during cytokinesis. Observations on the organization of interphase cortical microtubules suggest that regional influences may play a role in coordinating cell expansion patterns among groups of cells during leaf morphogenesis.     

Cellular Differentiation and Leaf Morphogenesis in Arabdopsis

A focused approach that exploits a single plant species, namely, Arabidopsis thaliana, as a means to understand how leaf cells differentiate and the factors that govern overall leaf morphogenesis has begun to generate a significant body of knowledge in this model plant. Although many studies have concentrated on specific cell types and factors that control their differentiation, some degree of consensus is starting to be reached. However, an understanding of specific mechanisms by which cells differentiate in relation to their position, that appears to be an overriding factor in this process, is not yet in place for cell types in the Arabidopsis leaf. It is clear that perturbations in cellular development within the leaf do not necessarily have a general effect on morphogenesis. Environmental factors, particularly light, have been known to affect leaf cell differentiation and expansion, and endogenous hormones also appear to play an important role, through mechanisms that are beginning to be uncovered. It is likely that continued identification of genes involved in leaf development and their regulation in relation to positional information or other cues will lead to a clearer understanding of the control of differentiation and morphogenesis in the Arabidopsis leaf.     

Leaf shape: genetic controls and environmental factors

In recent years, many genes have been identified that are involved in the developmental processes of leaf morphogenesis. Here, I review the mechanisms of leaf shape control in a model plant, Arabidopsis thaliana, focusing on genes that fulfill special roles in leaf development. The lateral, two-dimensional expansion of leaf blades is highly dependent on the determination of the dorsoventrality of the primordia, a defining characteristic of leaves. Having a determinate fate is also a characteristic feature of leaves and is controlled by many factors. Lateral expansion is not only controlled by general regulators of cell cycling, but also by the multi-level regulation of meristematic activities, e.g., specific control of cell proliferation in the leaf-length direction, in leaf margins and in parenchymatous cells. In collaboration with the polarized control of leaf cell elongation, these redundant and specialized regulating systems for cell cycling in leaf lamina may realize the elegantly smooth, flat structure of leaves. The unified, flat shape of leaves is also dependent on the fine integration of cell proliferation and cell enlargement. Interestingly, while a decrease in the number of cells in leaf primordia can trigger a cell volume increase, an increase in the number of cells does not trigger a cell volume decrease. This phenomenon is termed compensation and suggests the existence of some systems for integration between cell cycling and cell enlargement in leaf primordia via cell-cell communication. The environmental adjustment of leaf expansion to light conditions and gravity is also summarized.     

Developmental processes of leaf morphogenesis in<Emphasis Type="Italic">arabidopsis</Emphasis>

The leaf is a suitable subject with which to study plant morphogenesis because of its diversity of shape. Although mechanisms for leaf initiation and lateral morphogenesis have been suggested, the exact means for determining shape remain unclear. Many genes involved in those developmental processes have now been identified. Here, we summarize the early events in the genetic regulation ofArabidopsis leaf formation, including initiation, dorsoventrality, and the spatial and temporal control of cell proliferation and enlargement. We focus on recent progress within the model plantArabidopsis, placing special emphasis on our own findings.     

Polygalacturonase45 cleaves pectin and links cell proliferation and morphogenesis to leaf curvature in Arabidopsis thaliana

Regulating plant architecture is a major goal in current breeding programs. Previous studies have increased our understanding of the genetic regulation of plant architecture, but it is also essential to understand how organ morphology is controlled at the cellular level. In the cell wall, pectin modification and degradation are required for organ morphogenesis, and these processes involve a series of pectin-modifying enzymes. Polygalacturonases (PGs) are a major group of pectin-hydrolyzing enzymes that cleave pectin backbones and release oligogalacturonides (OGs). PG genes function in cell expansion and separation, and contribute to organ expansion, separation and dehiscence in plants. However, whether and how they influence other cellular processes and organ morphogenesis are poorly understood. Here, we characterized the functions of Arabidopsis PG45 (PG45) in organ morphogenesis using genetic, developmental, cell biological and biochemical analyses. A heterologously expressed portion of PG45 cleaves pectic homogalacturonan in vitro, indicating that PG45 is a bona fide PG. PG45 functions in leaf and flower structure, branch formation and organ growth. Undulation in pg45 knockout and PG45 overexpression leaves is accompanied by impaired adaxial–abaxial polarity, and loss of PG45 shortens the duration of cell proliferation in the adaxial epidermis of developing leaves. Abnormal leaf curvature is coupled with altered pectin metabolism and autogenous OG profiles in pg45 knockout and PG45 overexpression leaves. Together, these results highlight a previously underappreciated function for PGs in determining tissue polarity and regulating cell proliferation, and imply the existence of OG-based signaling pathways that modulate plant development.     

Leaf development and evolution

The number of publications on “leaf morphogenesis” has increased annually since the early 1990s, when the Arabidopsis ‘model plant’ concept began being applied to studies of mechanisms of leaf morphogenesis. Nearly 20 years have passed since then, and a great leap in the understanding of leaf organogenesis has been made. As a result, so-called evo/devo studies on leaf development have joined the trend in leaf morphogenesis/development studies in the latter part of the present decade. This article is a brief overview of the progress made in the research to date and an introduction to the articles that appear in this special issue.     

Cell cycle control and plant morphogenesis: is there an essential link?

Plant morphogenesis has some interesting features that may have consequences for the regulation of cell division. In particular, the immobility of plant cells implies the necessity for highly accurate controls, in contrast with the flexibility of many developmental processes in animals. An important question in plant development concerns the status of the relationship between plant morphogenesis and cell division. In this review, we discuss the current knowledge of the molecular mechanisms controlling the plant cell cycle and how this could be differentially regulated during plant morphogenesis. The plant genes involved are homologous to those of other higher eukaryotes, suggesting a similar cell cycle machinery. A variety of mechanisms control these genes, reflecting the complexity of internal and environmental signals to which plants should respond. This intricate network requires an upstream control mechanism to function as a failsafe system and to govern cell division and growth to produce the correct plant shape. BioEssays 21:29–37, 1999. © 1999 John Wiley & Sons, Inc.     

What is the role of cell division in leaf development?

An idea underlying a great deal of research and discussion in plant cell and developmental biology is that the spatial regulation of cell division plays a key role in plant development. In this article, the role of cell division in two aspects of leaf development is analysed: morphogenesis (leaf initiation, growth, and the generation of leaf shape) and histogenesis (the differentiation of leaf cells to form the various cell types that make up a functional leaf). The point of view that emerges from this analysis is that the rate and pattern of cell division is important for leaf development, but does not dictate leaf size, shape, or cell fate.     

Developmental genetics of leaf morphogenesis in dicotyledonous plants

A full understanding of the leaf is essential for a full understanding of plant morphology. However, leaf morphogenesis is still poorly understood, in particular in dicotyledonous plants, because of the complex nature of the development of leaves. Mutational analysis seems to be the most suitable strategy for investigations of such processes, and should allow us to dissect the developmental pathways into genetically programmed unit processes. The techniques of developmental genetics have been applied to the study of leaf morphogenesis in model plants, such asArabidopsis thaliana, and several key processes in leaf morphogenesis have been identified. The fundamental processes in leaf morphogenesis include the identification of leaf organs, determination of leaf primordia (occurrence of marginal meristem), and the polar or non-polar elongation of leaf cells. This review will focus on the genes that are essential for these processes and have been identified in mutational analyses. Mutational analyses of the photomorphogenesis is also briefly summarized from the perspective of the plasticity of leaf morphogenesis.     

植物叶片花青素的光破坏防御机制研究进展

植物花青素广泛分布在植物的根、茎、叶、花和果实等器官中,是植物形态建成过程中或响应逆境而产生的一种次生代谢物质.植物叶片中的花青素具有特殊的化学结构和光谱特性,在光破坏防御机制方面发挥了重要的作用,已经成为植物光合生理生态的研究热点.本文综述了近年来植物叶片花青素与光合作用的研究进展,从叶片花青素的分布、光谱特性及其与光合色素的关系等方面说明花青素对植物光合作用的影响,重点介绍了叶片花青素通过光吸收、抗氧化剂和渗透调节等在植物光破坏防御机制方面的作用,展望了今后的主要研究方向     

Genetics of plant cell shape

Plant cells have a variety of shapes crucial for their functions, yet the mechanisms that generate these shapes are poorly understood. Genetic dissection of the trichome (plant hair) branching pathway in Arabidopsis, has uncovered mechanisms and identified genes that control plant cell morphogenesis. The recent identification of one of these genes, ZWICHEL (ZWI), as a novel member of the kinesin superfamily of microtubule motors provides a starting point for the analysis of the plant cytoskeleton's role in a specific morphogenetic event.     

Plant architecture

Plant architecture is species specific, indicating that it is under strict genetic control. Although it is also influenced by environmental conditions such as light, temperature, humidity and nutrient status, here we wish to focus only on the endogenous regulatory principles that control plant architecture. We summarise recent progress in the understanding of the basic patterning mechanisms involved in the regulation of leaf arrangement, the genetic regulation of meristem determinacy, i.e. the decision to stop or continue growth, and the control of branching during vegetative and generative development.  Finally, we discuss the basis of leaf architecture and the role of cell division and cell growth in morphogenesis.     

Genetic evidence for polarities that regulate leaf morphogenesis

Leaf morphogenesis is a fundamental process of shoot morphogenesis, since the leaf is the basic organ of the shoot. However, leaf morphogenesis is still poorly understood, in particular in dicotyledonous plants, because of the complex nature of the development of leaves. Thus, the mechanisms regulating each process of the morphogenesis, such as leaf determination, establishment of dorsoventrality, and polarity recognition, remain unknown. Developmental genetics seems to prove the most suitable approach to such processes and should allow us to dissect the relevant developmental pathways into genetically programmed, unit processes. The techniques of developmental genetics have been applied to studes of leaf morphogenesis of model plants, such asArabidopsis thaliana andAntirrhinum majus, and have recently revealed several important steps in leaf morphogenesis. The review will focus on genetic evidence for polarities that regulate leaf morphogenesis. Hypothetical mechanisms for leaf morphogenesis will be also discussed, based on the genetic data. Receipt of the Botanical Society Award of Young Scientists, 1996.