Adhesion and guidance in compatible pollination

The mechanisms of compatible pollination are less studied than those of incompatible pollination and yet most of the angiosperms show self-compatibility. From the release of pollen from anthers to the penetration of the micropyle by the pollen tube tip, there are numerous steps where the interaction between pollen and the pistil can be regulated. Recent studies have documented some diverse ways in which pollen tubes carrying sperm cells are guided to the ovules through the pistil extracellular matrices of the transmitting tract. What is still missing is an understanding of pollen tube cell biology in vivo. A recent finding supports the role of the synergids in the crucial guidance cue for the pollen tube tip at the micropyle, but experimental evidence for other 'guidepost' cells in the pistil is still lacking. The fact that the pollen tube must first travel through the matrices of the stigma and style before it can respond to the cue from the ovule makes it likely that there is a hierarchy of signalling events in pollen-pistil interactions starting at the stigma and ending at the micropyle. On the pistil side, several model systems have been used in the discovery of molecules implicated in either physical or chemical guidance. In lily, which has a hollow style, adhesion molecules (pectin and SCA) are implicated in guidance. SCA alone is also capable of inducing pollen chemotropism in an in vitro assay, suggesting that this peptide plays a dual role in lily pollination: chemotactic in the stigma and haptotactic (adhesion mediated) in the style.     

Adhesion molecules in lily pollination

Adhesion occurs both between pollen tubes and between the pollen tube and transmitting tract epidermis (TTE) in lily. The stylar matrix secreted by the TTE can be isolated and used in an in vitro adhesion assay for pollen tubes. This bioassay was used to isolate two stigma/stylar adhesion molecules in lily: a pectic polysaccharide and a small cysteine-rich, basic protein we named SCA (stigma/stylar cysteine-rich adhesin). Both molecules were purified and used in an adhesion assay. Adhesion in the assay can be disrupted by treatment of the pectin with polygalacturonase and of SCA with proteinase K. The two molecules bind to each other in a pH-dependent fashion, and this binding is necessary for the adhesion assay to work. Antibodies to each of the molecules show their localization at the sites of pollen tube adhesion in the style. Pollen does not produce SCA but does bind this protein in vivo and in vitro. In vivo functional analyses are necessary to establish the roles of these molecules in lily pollination. Received: 29 October 2000 / Accepted: 17 April 2001     

A lily stylar pectin is necessary for pollen tube adhesion to an in vitro stylar matrix

Pollen tube cells adhere to the wall surface of the stylar transmitting tract epidermis in lily. This adhesion has been proposed as essential for the proper delivery of the sperm cells to the ovule. An in vitro adhesion bioassay has been used to isolate two stylar molecules required for lily pollen tube adhesion. The first molecule was determined to be a small, cysteine-rich protein with some sequence similarity to lipid transfer proteins and now called stigma/stylar cysteine-rich adhesin (SCA). The second, larger, molecule has now been purified from style fragments and characterized. Chemical composition, specific enzyme degradations, and immunolabeling data support the idea that this molecule required for pollen tube adhesion is a pectic polysaccharide. In vitro binding assays revealed that this lily stylar adhesive pectin and SCA are able to bind to each other in a pH-dependent manner.     

Expression studies of SCA in lily and confirmation of its role in pollen tube adhesion

During pollination the pollen tube grows into the style and toward the ovary via the transmitting tract. In lily the growth of pollen tubes involves tube cell adhesion to transmitting tract cells. We reported two molecules involved in this adhesion event. One is a pectic polysaccharide and the other, a 9 kDa basic protein named SCA for stigma/stylar cysteine-rich adhesin. SCA, which shows some identity with LTP (lipid transfer protein), was localized to the transmitting tract epidermis of the style where pollen tubes adhere. The present studies on the expression of SCA indicate that the protein has a similar expression pattern with LTP1 in Arabidopsis and that the protein is abundant in both the stigma and the style. For further proof of its role in pollen tube adhesion the activity of Escherichia coli-expressed protein has been studied in an in vitro adhesion assay system.     

Lily (<Emphasis Type="Italic">Lilium longiflorum</Emphasis> L.) pollen protoplast adhesion is increased in the presence of the peptide SCA

The style of lily produces a specialized extracellular matrix (ECM) in the transmitting tract epidermis that functions to guide pollen tubes to the ovary. This adhesive ECM contains low esterified pectins and a peptide, SCA (stigma/stylar cysteine-rich adhesin). Together they form a matrix to which pollen tubes adhere as they grow through the style. Pollen tubes also adhere to each other but only when grown in vivo, not in vitro. Pollen does not produce detectable SCA, but when SCA is added to an in vitro growth medium, it binds to pollen tubes that have esterified and low-esterified pectins in their walls. Since adhesion of the pollen tube to the stylar matrix requires tip growth, we hypothesized that the pectin wall at the pollen tube tip interacted with the SCA protein to initiate adhesion with the stylar pectin [Lord (2000) Trends Plant Sci 5:368–373]. Here, we use a pollen protoplast system to examine the effect of SCA on protoplast adhesion when it is added to the growth medium in the absence of the stylar pectin. We found that SCA induces a 2-fold increase in protoplast adhesion when it is added at the start of protoplast culture. This effect is less when SCA is added to the medium after the cell wall on the protoplast has begun to regenerate. We show that among the first components deposited in the new wall are arabinogalactan proteins (AGPs) and highly esterified pectins. We see no labeling for low esterified pectins even after 3 days of culture. In the pollen protoplast culture, adhesion occurs in the absence of the low esterified pectin. The newly formed wall on the protoplast mirrors that of the pollen tube tip in lily, which is rich in AGPs and highly esterified pectins. Thus, the protoplast system may be useful for isolating the pollen partner for SCA in this adhesion event.     

Pollen tube growth and guidance: roles of small, secreted proteins

BACKGROUND: Pollination is a crucial step in angiosperm (flowering plant) reproduction. Highly orchestrated pollen-pistil interactions and signalling events enable plant species to avoid inbreeding and outcrossing as a species-specific barrier. In compatible pollination, pollen tubes carrying two sperm cells grow through the pistil transmitting tract and are precisely guided to the ovules, discharging the sperm cells to the embryo sac for fertilization. SCOPE: In Lilium longiflorum pollination, growing pollen tubes utilize two critical mechanisms, adhesion and chemotropism, for directional growth to the ovules. Among several molecular factors discovered in the past decade, two small, secreted cysteine-rich proteins have been shown to play major roles in pollen tube adhesion and reorientation bioassays: stigma/style cysteine-rich adhesin (SCA, approx. 9·3 kDa) and chemocyanin (approx. 9·8 kDa). SCA, a lipid transfer protein (LTP) secreted from the stylar transmitting tract epidermis, functions in lily pollen tube tip growth as well as in forming the adhesive pectin matrix at the growing pollen tube wall back from the tip. Lily chemocyanin is a plantacyanin family member and acts as a directional cue for reorienting pollen tubes. Recent consecutive studies revealed that Arabidopsis thaliana homologues for SCA and chemocyanin play pivotal roles in tip polarity and directionality of pollen tube growth, respectively. This review outlines the biological roles of various secreted proteins in angiosperm pollination, focusing on plant LTPs and chemocyanin.     

Two SCA (stigma/style cysteine-rich adhesin) isoforms show structural differences that correlate with their levels of in vitro pollen tube adhesion activity

Lily pollen tubes grow adhering to an extracellular matrix produced by the transmitting tract epidermis in a hollow style. SCA, a small ( approximately 9.4 kDa), basic protein plus low esterified pectin from this extracellular matrix are involved in the pollen tube adhesion event. The mode of action for this adhesion event is unknown. We partially separated three SCA isoforms from the lily stigma in serial size exclusion column fractions (SCA1, 9370 Da; SCA2, 9384 Da; SCA3, 9484 Da). Peptide sequencing analysis allowed us to determine two amino acid variations in SCA3, compared with SCA1. For SCA2, however, there are more sequence variations yet to be identified. Our structural homology and molecular dynamics modeling results show that SCA isoforms have the plant nonspecific lipid transfer protein-like structure: a globular shape of the orthogonal 4-helix bundle architecture, four disulfide bonds, an internal hydrophobic and solvent-inaccessible cavity, and a long C-terminal tail. The Ala(71) in SCA3, replacing the Gly(71) in SCA1, has no predictable effect on structure. The Arg(26) in SCA3, replacing the Gly(26) in SCA1, is predicted to cause structural changes that result in a significantly reduced volume for the internal hydrophobic cavity in SCA3. The volume of the internal cavity fluctuates slightly during the molecular dynamics simulation, but overall, SCA1 displays a larger cavity than SCA3. SCA1 displays higher activity than SCA3 in the in vitro pollen tube adhesion assay. No differences were found between the two SCAs in a binding assay with pectin. The larger size of the hydrophobic cavity in SCA1 correlates with its higher adhesion activity.     

Adhesion and cell movement during pollination: cherchez la femme

Pollination involves an interaction between the female tissues (stigma, style and ovary) and the male gametophyte or the pollen tube cell, which contains the sperm cells. Freezing methods now allow us to visualize the extracellular matrices that guide pollen tubes to the ovary. Adhesion of the pollen tube to these specialized extracellular matrices might be a mechanism of guidance and tube cell movement in the style. In lily, the stylar adhesion molecules are a pectin and a small, basic cysteine-rich protein, both of which are necessary to induce tube cell adhesion to an artificial, in vitro style matrix.     

A lipid transfer-like protein is necessary for lily pollen tube adhesion to an in vitro stylar matrix

Flowering plants possess specialized extracellular matrices in the female organs of the flower that support pollen tube growth and sperm cell transfer along the transmitting tract of the gynoecium. Transport of the pollen tube cell and the sperm cells involves a cell adhesion and migration event in species such as lily that possess a transmitting tract epidermis in the stigma, style, and ovary. A bioassay for adhesion was used to isolate from the lily stigma/stylar exudate the components that are responsible for in vivo pollen tube adhesion. At least two stylar components are necessary for adhesion: a large molecule and a small (9 kD) protein. In combination, the two molecules induced adhesion of pollen tubes to an artificial stylar matrix in vitro. The 9-kD protein was purified, and its corresponding cDNA was cloned. This molecule shares some similarity with plant lipid transfer proteins. Immunolocalization data support its role in facilitating adhesion of pollen tubes to the stylar transmitting tract epidermis.     

钙在被子植物受精过程中的作用

近年来,花粉管中的钙信号和生理功能的研究取得了明显的进展,同时在雌蕊系统中有关钙分布的研究也初步显示了其时、空特征与被子植物的受精作用密切相关。该文总结了花粉萌发和花粉管生长过程中外源钙和内源钙的作用机制,结合雌蕊组织中钙分布的特征,进一步探讨了钙在被子植物受精过程中的功能。     

Pistil Exudate Production and Pollen Tube Growth in Lilium longiflorum Thunb.

Exudate production in the pistil of Lilium longiflorum was studiedin relation to pollen tube growth, using scanning electron microscopy(SEM), transmission electron microscopy and light microscopy.In contrast with conventional fixation for SEM, during whichthe exudate of L. longiflorum largely washes away, the exudateremains present through freezing in case of cryo-SEM. Usingthe latter method we observed that exudate production on thestigma and in the style started before anthesis. Just underneaththe stigma the exudate was first accumulated at the top of eachsecretory cell, followed by a merging of those accumulationsas exudate production proceeded. Exudate is also produced bythe placenta. It was however not possible to determine whetherany of this fluid originated from the micropyle. Apart fromthe cell shape and the cuticle present in between the secretorycells, the ultrastructure of the secretory cells covering theplacenta was comparable to those of the stylar canal. The transferwall of the secretory cells of the placenta originated fromfusing Golgi vesicles but the endoplasmic reticulum seemed tohave an important role as well. After pollination the pollen tubes grew across the stigma andentered the style through one of the slits in the three stigmalobes. The pollen tubes grew straight downward through the styleand were covered by exudate. As the pollen tubes approachedthe ovary their growth was restricted to the areas with secretorycells. In the cavity the pollen tubes formed a bundle and theybent from this bundle in between the ovules towards the micropylarside. There they bent again to stay close to the secretory cells.After bud pollination the pollen tube growth was retarded. Laterarriving pollen tubes had a tendency to grow close to the secretorycells of the style, which resulted in a growth between thesecells and preceding pollen tubes. If there was still a littleexudate produced, it resulted in a lifting up of the pollentubes, out of the exudate. The relationship between exudateproduction and pollen tube growth is discussed. Both the speedand the guidance of the pollen tube seemed determined by theproperties of the exudate.Copyright 1994, 1999 Academic Press Cryo-scanning electron microscopy, exudate, Lilium longiflorum, lily, ovary, pollination, pollen tube growth, secretory cell, stigma, style     

INFLUENCE OF THE PISTIL ON POLLEN TUBE KINETICS IN PEACH (PRUNUS PERSICA)

Pollen tube growth has been studied in peach and has been related to changes in the pistil structures which the pollen tube has to traverse in its way from the stigma down to the ovule. Growth of the pollen tubes along the pistil is not continuous. While pollen tubes reach the base of the style 7 days after pollination, fertilization does not take place until 12 days later. Pollen tubes stop for 5 days at the top of the obturator and they further stop for 3 days before entering the ovule. The pollen tube growth is heterotrophic; starch, present all along the pistilar tract at anthesis, vanishes as the pollen tubes pass by. Discontinuous pollen tube growth appears to be controlled by the pistil. At anthesis the pistil is not fully matured. Maturation of the pistil implies a number of secretory processes that occur in a basipetal way starting from the stigma down to the style and ending in the ovule. Some of these secretions at the stigma and the style are triggered by pollination; others appear to be a maturative stage of the pistil and are produced in a discrete way. The fact that the pollen tube depends on these secretions together with the fact that these secretions are not continuously produced confer upon the pistil a role of controlling pollen tube kinetics and point out that, for a successful fertilization, male gametophyte development and pistil maturation need to by synchronized.     

Plantacyanin plays a role in reproduction in Arabidopsis

Plantacyanins belong to the phytocyanin family of blue copper proteins. In the Arabidopsis (Arabidopsis thaliana) genome, only one gene encodes plantacyanin. The T-DNA-tagged mutant is a knockdown mutant that shows no visible phenotype. We used both promoter-beta-glucuronidase transgenic plants and immunolocalization to show that Arabidopsis plantacyanin is expressed most highly in the inflorescence and, specifically, in the transmitting tract of the pistil. Protein levels show a steep gradient in expression from the stigma into the style and ovary. Overexpression plants were generated using cauliflower mosaic virus 35S, and protein levels in the pistil were examined as well as the pollination process. Seed set in these plants is highly reduced mainly due to a lack of anther dehiscence, which is caused by degeneration of the endothecium. Callose deposits occur on the pollen walls in plants that overexpress plantacyanin, and a small percentage of these pollen grains germinate in the closed anthers. When wild-type pollen was used on the overexpression stigma, seed set was still decreased compared to the control pollinations. We detected an increase in plantacyanin levels in the overexpression pistil, including the transmitting tract. Guidance of the wild-type pollen tube on the overexpression stigma is disrupted as evidenced by the growth behavior of pollen tubes after they penetrate the papillar cell. Normally, pollen tubes travel down the papilla cell and into the style. Wild-type pollen tubes on the overexpression stigma made numerous turns around the papilla cell before growing toward the style. In some rare cases, pollen tubes circled up the papilla cell away from the style and were arrested there. We propose that when plantacyanin levels in the stigma are increased, pollen tube guidance into the style is disrupted.     

柚雌蕊不同部位抽提液对自交不亲和阻抑效果的研究

以‘土柚’（Citrus grandis ‘Tuyou’）作对照,采用荧光显微技术对‘琯溪蜜柚’（Citrus grandis‘Guanxi-miyou’）、‘度尾蜜柚’（Citrus grandis ‘Duweimiyou’）两个品种花粉在本品种和异品种雌蕊不同部位抽提液中花粉萌发和花粉管伸长状态进行了观察。结果表明：‘琯溪蜜柚’和‘度尾蜜柚’子房抽提液对自身花粉管伸长阻抑最明显,并产生严重的弯曲;柱头抽提液对自身花粉管伸长稍有影响,出现中度弯曲;花柱抽提液中自身花粉管伸长正常,仅有轻微弯曲。然而,对于异品种的花粉以及自交亲和的‘土柚’,其子房、花柱和柱头抽提液对花粉管伸长没有这种阻抑效应。     

Free IAA in stigmas and styles during pollen germination and pollen tube growth of Nicotiana tabacum

Although many studies have emphasized the importance of auxin in plant growth and development, the thorough understanding of its effect on pollen–pistil interactions is largely unknown. In this study, we investigated the role of free IAA in pollen–pistil interactions during pollen germination and tube growth in Nicotiana tabacum L. through using histo and subcellular immunolocalization with auxin monoclonal antibodies, quantification by HPLC and ELISA together with GUS staining in DR5::GUS -transformed plants. The results showed that free IAA in unpollinated styles was higher in the apical part and basal part than in the middle part, and it was more abundant in the transmitting tissue (TT). At the stage of pollen germination, IAA reached its highest content in the stigma and was mainly distributed in TT. After the pollen tubes entered the styles, the signal increased in the part where pollen tubes would enter and then rapidly declined in the part where pollen tubes had penetrated. Subcellular localization confirmed the presence of IAA in TT cells of stigmas and styles. Accordingly, a schematic diagram summarizes the changing pattern of free IAA level during flowering, pollination and pollen tube growth. Furthermore, we presented evidence that low concentration of exogenous IAA could, to a certain extent, facilitate in vitro pollen tube growth. These results suggest that IAA may be directly or indirectly involved in the pollen–pistil interactions. Additionally, some improvements of the IAA immunolocalization technique were made.     

Adhesion of lily pollen tubes on an artificial matrix

 We proposed that pollination in lily is a case of cell adhesion and cell movement, but experimental evidence for the adhesion event is lacking. In this study, we developed an artificial extracellular matrix that mimics the in vivo lily stylar transmitting tract. This artificial matrix was created by applying the transmitting tract exudate extracted from lily styles onto a nitrocellulose membrane. When in vitro-grown pollen tubes were applied to the matrix, they adhered by their tips to the area of the stylar exudate which is rich in arabinogalactan proteins. Once they adhered, they grew on the in vitro artificial matrix at rates faster than normal. This is the first experimental evidence demonstrating the adhesion of in vitro-grown pollen tubes, an event that has been described as common in vivo. The adhesion event is stylar exudate specific, concentration dependent, and is affected by the developmental age of the pollen tube. This bioassay for pollen tube adhesion will be used to isolate the adhesive molecules from the stylar exudate. Received: 9 December 1996 / Revision accepted: 5 May 1997     

Arabidopsis hapless mutations define essential gametophytic functions

In flowering plants, the egg develops within a haploid embryo sac (female gametophyte) that is encased within the pistil. The haploid pollen grain (male gametophyte) extends a pollen tube that carries two sperm cells within its cytoplasm to the embryo sac. This feat requires rapid, precisely guided, and highly polarized growth through, between, and on the surface of the cells of the stigma, style, and ovary. Pollen tube migration depends on a series of long-range signals from diploid female cells as well as a short-range attractant emitted by the embryo sac that guides the final stage of tube growth. We developed a genetic screen in Arabidopsis thaliana that tags mutant pollen with a cell-autonomous marker carried on an insertion element. We found 32 haploid-disrupting (hapless) mutations that define genes required for pollen grain development, pollen tube growth in the stigma and style, or pollen tube growth and guidance in the ovary. We also identified genomic DNA flanking the insertion element for eleven hap mutants and showed that hap1 disrupts AtMago, a gene whose ortholog is important for Drosophila cell polarity.     

From pollination to fertilization in fruit trees

The phase that elapses from pollination to fertilization is re-examined giving special attention to pollen pistil interaction in compatible matings. Pollination induces an activation of the pistil. A number of changes take place in the different tissues of this organ that appear to support male gametophyte development and to assist fertilization. Thus pollination induces stigma secretion, the release of starch from the transmitting tissue and prolongs embryo sac viability. It appears that even those pollen grains that do not achieve fertilization have a synergistic role supporting others to do so.The pistil also has an effect on pollen tube growth. Pollen tube growth along the pistil is not continuous, accelerations and decelerations take place depending on the different tissues they traverse. The fact that pollen tube growth is heterotrophic, at the expenses of the pistil reserves, and that these reserves are not continuously produced confers the pistil with a role controlling pollen tube growth kinetics.