How pollen tubes grow

Sexual reproduction of flowering plants depends on delivery of the sperm to the egg, which occurs through a long, polarized projection of a pollen cell, called the pollen tube. The pollen tube grows exclusively at its tip, and this growth is distinguished by very fast rates and reaches extended lengths. Thus, one of the most fascinating aspects of pollen biology is the question of how enough cell wall material is produced to accommodate such rapid extension of pollen tube, and how the cell wall deposition and structure are regulated to allow for rapid changes in the direction of growth. This review discusses recent advances in our understanding of the mechanism of pollen tube growth, focusing on such basic cellular processes as control of cell shape and growth by a network of cell wall-modifying enzymes, molecular motor-mediated vesicular transport, and intracellular signaling by localized gradients of second messengers.     

Signaling in pollen-pistil interactions.

A complex set of cell interactions is required to achieve fertilization. The pollen grain must be recognized by the pistil, take up water, and grow a pollen tube directionally through the style in order to deliver the sperm to the ovule. In many families of flowering plants, self-fertilization can be prevented by recognition mechanisms that allow self-pollen rejection by the pistil. The self-incompatibility response is under the genetic control of a single multi-allelic locus, the (Self-incompatibility) locus. There are two major classes of self-incompatibility systems. Gametophytic self-incompatibility has been well characterized in the Solanaceae and in the Papaveraceae, while sporophytic self-incompatibility has been well characterized in the Brassicaceae. In this review article, we present recent advances in understanding the signals mediating pollen recognition and pollen tube growth, in both compatible and incompatible interactions.     

The regulation of vesicle trafficking by small GTPases and phospholipids during pollen tube growth

Polarized and directional growth of pollen tubes is the only means by which immotile sperm of flowering plants reach the deeply embedded female gametes for fertilization. Vesicle trafficking is among the most critical cellular activities for pollen tube growth. Vesicle trafficking maintains membrane homeostasis during rapid tube growth and provides polarity information by regulating protein/lipid compositions of different membrane compartments. In this review, we will focus on two classes of factors that orchestrate vesicle trafficking, small GTPases and phospholipids. We discuss the features of small GTPases and phospholipids that make them ideal components to regulate vesicle trafficking, review recent advances in understanding their involvement in vesicle trafficking, and propose directions for future research.     

The effect of exogenous Ca2+ ions on pollen grain germination and pollen tube growth

Summary The involvement of exogenous calcium ions in the regulation of pollen tube formation has been investigated in Haemanthus albiflos L. and Oenothera biennis L. by following the changes that occur in pollen germination, tube growth, and ⁴⁵⁺Ca²⁺ uptake and distribution upon application of Verapamil (an inhibitor of calcium channels), lanthanum (a Ca²⁺ substitute), and ruthenium red (believed to raise the intracellular calcium level). It was found that exogenous Ca²⁺ takes part in the formation of the calcium gradient present in germinating pollen grains and growing pollen tubes. Ca²⁺ ions enter the cells through calcium channels. Raising or reducing ⁴⁵Ca²⁺ uptake causes disturbances in the germination of the pollen grains and in the growth of the pollen tubes.     

The formation and function of the female reproductive tract in flowering plants

In angiosperms, sexual reproduction requires a sperm cell, contained within a pollen tube, to fertilize the egg cell. The pollen tubes are capable of growth but have a difficult journey, as egg cells are buried within the ovary of the carpel. Several tissues, known collectively as the reproductive tract, develop within the carpel to facilitate the journey of the pollen tube. The genes involved in the formation and function of the reproductive tract have largely remained a mystery but are crucial for successful fertilization. This review summarizes recent advances in our understanding of the genetic control of reproductive tract development.     

Growth and development of conifer pollen tubes

Conifer pollen tubes are an important but underused experimental system in plant biology. They represent a major evolutionary step in male gametophyte development as an intermediate form between the haustorial pollen tubes of cycads and Ginkgo and the structurally reduced and faster growing pollen tubes of flowering plants. Conifer pollen grains are available in large quantities, most can be stored for several years, and they grow very well in culture. The study of pollen tube growth and development furthers our understanding of conifer reproduction and contributes towards our ability to improve on their productivity. This review covers taxonomy and morphology to cell, developmental, and molecular biology. It explores recent advances in research on conifer pollen and pollen tubes in vivo, focusing on pollen wall structure, male gametophyte development within the pollen wall, pollination mechanisms, pollen tube growth and development, and programmed cell death. It also explores recent research in vitro, including the cellular mechanisms underlying pollen tube elongation, in vitro fertilization, genetic transformation and gene expression, and pine pollen tube proteomics. With the ongoing sequencing of the Pinus taeda genome in several labs, we expect the use of conifer pollen tubes as an experimental system to increase in the next decade.     

The Role of Calcium in the Fertilization Process in Flowering Plants

The fertilization process in flowering plants in a broad sense includes a progamic phase preceding the phase of double fertilization. To our present knowledge, calcium as a second messenger in the signal transduction plays important roles in all the links of this process. The present review attempts to highlight the recent advances in this research field, including: calcium in relation to in vitro pollen tube growth (distribution of calcium in pollen tube tip; regulation of pollen tube growth by calcium; calcium oscillation in pollen tube); distribution of calcium in pistil and its relation to in vivo pollen tube growth (calcium in relation to pollen-pistil recognition; pollen tube growth in pistil; pollen tube entry into embryo sac and the discharge and transportation of sperms); and calcium in relation to sperm-egg fusion and egg cell activation. In conclusion the author summarizes into several main view points, and gives recommendation for further researches on this topic.     

A novel pollen tube growth assay utilizing a transmitting tract-ablated Nicotiana tabacum style

Sexual plant reproduction requires multiple pollen–pistil interactions from the stigma (pollen adhesion, hydration, and germination) to the ovary (fertilization). Understanding the factors that regulate pollen tube growth is critical to understanding the processes essential to sexual reproduction. Many pollen tube growth assays (PTGAs) have shorter and slower pollen tube growth when compared to pollen tube growth through the style. The identification and study of factors that regulate pollen tube growth have been impeded by a lack of an efficient and reproducible PTGA. The objective of this research is to develop a robust assay for Nicotiana tabacum pollen tube growth in an environment that supports sustained and normal growth yet is amenable to testing the effects of specific factors. In this paper, we introduce a novel PTGA, which uses pistils from N. tabacum that lack a mature transmitting tract (TT) due to tissue-specific ablation. The TT-ablated style supports normal pollen tube growth and the hollow structure of the style allows modification of the growth environment by direct injection of test material. This PTGA is robust and allows for rapid and accurate measurement of pollen tube length and pollen tube morphology, supporting pollen tube growth from 20 to 35°C and at pH ranging from 4.8 to 7.6. Use of the ablated style for a PTGA is a novel method for the culture of pollen tubes with sustained growth in vivo while permitting the application of treatments to the growing pollen tubes.     

钙在有花植物受精过程中的作用

钙作为第二信使在植物信号转导中的作用一直是植物生理学、细胞生物学和发育生物学研究的热点。近年已有不少综述和专著从不同角度对此作了详细评论［1～5］。虽然这些文章中只有部分内容涉及本文的主题———钙在植物受精中的作用,但是它们所论述的关于钙信使系统在植物...     

Gametophytic pollen tube guidance

The concept of a pollen tube attractant was proposed in the late nineteenth century when pollen tubes were found to grow toward excised pistil tissues on medium. Since then, for about 140 years, plant biologists have tried to identify the pollen tube attractants. However, no molecule has been convincingly demonstrated to be the true attractant that actually controls the navigation of pollen tubes in the pistil. The past decade has seen substantial progress in this field in terms of our understanding of the various mechanisms of pollen tube guidance. It was suggested that diffusible pollen tube attractants might provide localized signals that affect the directional growth of the pollen tube, especially in the last phase of guidance by the target female gametophyte. Here, we review the mechanisms of pollen tube guidance, with special focus on the gametophytic guidance and the attractant. The necessary and appropriate conditions required by the true attractant will be discussed. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Emerging role of ER quality control in plant cell signal perception

The endoplasmic reticulum quality control (ER-QC) is a conserved mechanism in surveillance of secreted signaling factors during cell-to-cell communication in eukaryotes. Recent data show that the ER-QC plays important roles in diverse cell-to-cell signaling processes during immune response, vegetative and reproductive development in plants. Pollen tube guidance is a precisely guided cell-cell communication process between the male and female gametophytes during plant reproduction. Recently, the female signal has been identified as small secreted peptides, but how the pollen tube responds to this signal is still unclear. In this review, we intend to summarize the role of ER-QC in plants and discuss the recent advances regarding our understanding of the mechanism of pollen tube response to the female signals.     

内钙拮抗剂TMB-8对白皮松花粉管细胞壁构建的影响

应用荧光显微技术、激光共聚焦扫描显微技术、单克隆抗体免疫荧光标记技术以及傅里叶变换显微红外光谱分析(FTIR)等手段,研究了内钙拮抗剂TMB-8对白皮松花粉管胞内Ca2+分布、花粉管生长以及细胞肇构建等的影响.结果表明,白皮松花粉管经TMB-8处理后,胞内的Ca2+浓度下降,花粉管内典型的Ca2+浓度梯度消失,花粉萌发...     

Understanding pollen tube growth: the hydrodynamic model versus the cell wall model

Scientific progress stimulates the evolution of models used to understand and conceptualize biological behaviors. The widely accepted cell wall model of pollen tube growth explains stochastic growth of the apical pectin wall, but fails to explain the mechanism driving oscillations in growth and cell signaling. Recent advances led to the formulation of a new hydrodynamic model that explains the mechanism that drives both stochastic and oscillatory growth, as well as oscillations in cell signaling and ion fluxes. A critical analysis of evidence that has been used to challenge the validity of the hydrodynamic model yields new information on turgor pressure, cell mechanical properties and nonlinear dynamics in pollen tube growth. These results may have broader significance for plant cell growth.     

In vitro germination and growth of lily pollen tubes is affected by calcium inhibitor with reference to calcium distribution

The calcium inhibitors A23187, EGTA and La³⁺ inhibit pollen grain germination and growth of pollen tubes of Lilium davidii var. unicolor at different concentrations. Treatment with 10⁻⁴ or 10⁻⁵ M ionophores A23187 reduced germination rate and resulted in distortion of pollen tube. Addition of 2 or 10 mM of the chelator EGTA disturbed the direction of pollen tube growth and extended the diameter of pollen tube as observed by light and confocal microscopy. The Ca²⁺-channel blocker lanthanum chloride (La³⁺) restrained germination or markedly caused transformation of pollen tube. Furthermore, all treatments led to disappearance of any calcium gradient. Calcium distribution in pollen grain and pollen tube was altered as shown by confocal microscopy for each treatment. This indicates that the inhibitors influence pollen development by affecting the calcium gradient which may play a critical role in germination and tube growth. Fourier transform infrared (FTIR) spectra indicated slight increases in contents of amide I and a substantial decrease in the content of aliphatic esters and saturated esters in treated pollen tubes compared with normal pollen tubes. The FTIR analysis confirmed that EGTA and La³⁺ weakened the accumulation of ester in pollen tubes, which may be associated with an increased content of amide I.     

Pollen and pistil in the progamic phase

The progamic phase, the period of pollen tube growth through the pistil, is a period of specific interactions between the male gametophyte and the pistil. Understanding of pollen germination and pollen tube growth are relevant for the study of pollen-pistil interactions and for understanding the function of components specifically accumulated in the transmitting tissue cell walls and intercellular matrix that may interact with pollen tubes. Received: 18 January 2001 / Accepted: 19 June 2001     

An Image Skeletonization-Based Tool for Pollen Tube Morphology Analysis and Phenotyping

The mechanism underlying pollen tube growth involves diverse genes and molecular pathways. Alterations in the regulatory genes or pathways cause phenotypic changes reflected by cellular morphology, which can be captured using fluorescence microscopy. Determining and classifying pollen tube morphological phenotypes in such microscopic images is key to our understanding the involvement of genes and pathways. In this context, we propose a computational method to extract quantitative morphological features, and demonstrate that these features reflect morphological differences relevant to distinguish different defects of pollen tube growth. The corresponding software tool furthermore includes a novel semi-automated image segmentation approach, allowing to highly accurately identify the boundary of a pollen tube in a microscopic image.     

Signals and targets of the self-incompatibility response in pollen of Papaver rhoeas

Self-incompatibility (SI) in Papaver rhoeas involves an allele-specific recognition between stigmatic S-proteins and pollen, resulting in inhibition of incompatible pollen. A picture of some of the signalling events and mechanisms involved in this specific inhibition of pollen tube growth is beginning to be built up. This highly specific response triggers a Ca(2+)-dependent signalling cascade in incompatible pollen when a stigmatic S-protein interacts with it. Rapid increases in cytosolic free Ca(2+) concentration ([Ca(2+)](i)) can now be attributed (at least in part) to Ca(2+) influx. The rapid loss of the pollen apical Ca(2+) gradient within approximately 1-2 min is accompanied by the inhibition of pollen tube tip growth. Concomitant with this time-frame, hyper-phosphorylation of p26, a soluble pollen phosphoprotein is detected. Characterization of p26 reveals that it is a soluble inorganic pyrophosphatase, which suggests a possible direct functional role in pollen tube growth. Slightly later, a putative MAP kinase (p52) is thought to be activated. Finally, preliminary evidence that programmed cell death (PCD) may be triggered in this response is described. A key target for these signals, the actin cytoskeleton, has also been identified. In this article the current understanding of some of the components of this signalling cascade and how they are beginning to throw some light on possible mechanisms involved in this SI-induced inhibition of pollen tube growth, is discussed.     

Nucellar beak structure and pollen tube growth in Cucurbitaceae

The nucellar beak is a proboscis-like outgrowth of the nucellus at the micropylar end, being the obligatory path for the pollen tube entering the ovule. Among the few angiosperm families with nucellar beak, Cucurbitaceae is remarkable because the pollen tube may develop at least two types of growth within the nucellar beak: tubular and ampulliform. Wondering about the possibility that Cucurbitaceae ovules may express some histological variation that could be related to pollen tube growth within the nucellar beak, we performed a compared anatomical and histochemical study of the nucellar beak and the pollen tube growth of ten species of Cucurbitaceae. Results show that Cucurbitaceae ovules are diverse in size and proportions (of integuments, nucellar body, and nucellar beak), and they have at least four types of nucellar beak histology: pectic-tracked, secretory-like, amylaceous, and mixed. Amylaceous and mixed nucellar beaks are related to the ampulliform growth of the pollen tube, which could have appeared independently in most derived tribes of Cucurbitaceae, although information about nucellar beak structure in the basal tribes is still needed. In addition, the understanding of the relation between amylaceous nucellar beaks and the ampulliform growth of the pollen tube, whose function is still to be discovered, might open the possibility of a unique model of pollen tube-ovule co-evolution in angiosperms.