Immunolocalisation of arabinogalactan proteins and pectins in Actinidia deliciosa pollen

Summary. The cell wall composition of germinating pollen grains of Actinidia deliciosa was studied by immunolocalization with monoclonal antibodies against arabinogalactan proteins (AGPs) and pectins. In ungerminated pollen, the JIM8 epitope (against a subset of AGPs) was located in the intine and in the cytoplasm, while the MAC207 epitope (against AGPs) was only located in the exine. After germination, the JIM8 and MAC 207 epitopes were located in the cytoplasm and in the pollen tube wall. The Yariv reagent that binds to AGPs was added to the germination medium inducing a reduction or inhibition in pollen germination. This indicates that AGPs are present in the growing pollen tube and play an important role in pollen germination. To identify the nature of the pectins found in pollen grains and tubes, four monoclonal antibodies were used. The JIM5 epitope (against unesterified pectins) was located in the intine, more intensely in the pore region, and along the pollen tube wall, and the JIM7 epitope (against methyl-esterified pectins) was also observed in the cytoplasm. After germination, the JIM5 epitope was located in the pollen tube wall; although, the tube tip was not labelled. The JIM7 epitope was located in the entire pollen tube wall. LM5 (against galactans) showed a labelling pattern similar to that of JIM5 and the pattern of LM6 (against arabinans) was similar to that of JIM7. Pectins show different distribution patterns when the degree of esterification is considered. Pollen tube wall pectins are less esterified than those of the pollen tube tip. The association of AGPs with pectins in the cell wall of the pollen grain and the pollen tube may play an important role in the maintenance of cell shape during pollen growth and development.Correspondence and reprints: Instituto de Biologia Molecular e Celular, Universidade do Porto, Rua do Campo Alegre, 823, 4150-180 Porto, Portugal.     

Immunolocalization of the cell wall components inPinus densiflora pollen

Summary In order to compare cell wall formation in gymnosperm pollen with that in angiosperm pollen, the distribution of cell wall constituents in the pollen grain and pollen tube ofPinus densiflora was studied immunocytochemically with monoclonal antibodies JIM 5 (against non- or poorly esterified pectin), JIM 7 (against highly esterified pectin), JIM 13 (against arabinogalactan proteins, AGPs), and LM 2 (against AGPs containing glucuronic acid). In the pollen grain wall, only the outer layer of the intine was labeled with JIM 5 and weakly with JIM 7. The tube wall was scarcely labeled with JIM 5 and very weakly labeled with JIM 7. In contrast, the whole of both the intine and the tube wall was strongly labeled with JIM 13 and LM 2, and the generative-cell wall was also labeled only with LM 2. The hemicellulose B fraction, which is the main polysaccharide fraction from the pollen tube wall, reacted strongly with JIM 13 and especially LM 2, but not with antipectin antibodies. These results demonstrate that the wall constituents and their localization inP. densiflora pollen are considerably different from those reported in angiosperm pollen and suggest that the main components of the cell wall ofP. densiflora pollen are arabinogalactan and AGPs containing glucuronic acid.Abbreviations AGPs arabinogalactan proteins - ELISA enzymelinked immunosorbent assay - MAbs monoclonal antibodies     

Immunolocalization and possible roles of pectins during pollen growth and callose plug formation in angiosperms

To elucidate the possible roles of pectins during the growth of angiosperm pollen, we studied the distribution and changes in the properties of pectin in the pollen grains and tubes of Camellia japonica, Lilium longiflorum, and five other species at different growth stages by immunoelectron microscopy with monoclonal antibodies JIM5, against de-esterified pectin, and JIM7, against esterified pectin. We also studied the localization of arabinogalactan proteins, which are regarded as pectin-binding proteins, with monoclonal antibodies JIM13 and LM2, against arabinogalactan proteins. Similar results were obtained for all species: JIM5 labeled the intine and part of the callose layer in germinated pollen grains, and labeled the outer layer of the tube wall, the Golgi vesicles, and the callose plug in the pollen germinated in vitro, but did not label any part of immature pollen grains. In contrast, JIM7 labeled the intine of both immature and mature pollen grains, labeled the Golgi vesicles around the Golgi bodies, and strongly labeled the outer layer of the cell wall and the Golgi vesicles in the tube tip region. On the other hand, the distribution of arabinogalactan proteins detected with JIM13 was different for each species, and does not suggest a close relationship between pectin and arabinogalactan proteins. LM2 scarcely reacted with the specimens. We discuss the contribution of pectins to tube wall formation and fertilization and deduce a mechanism of callose plug formation.     

Electrophoretic profiling and immunocytochemical detection of pectins and arabinogalactan proteins in olive pollen during germination and pollen tube growth

Background and Aims

Cell wall pectins and arabinogalactan proteins (AGPs) are important for pollen tube growth. The aim of this work was to study the temporal and spatial dynamics of these compounds in olive pollen during germination.

Methods

Immunoblot profiling analyses combined with confocal and transmission electron microscopy immunocytochemical detection techniques were carried out using four anti-pectin (JIM7, JIM5, LM5 and LM6) and two anti-AGP (JIM13 and JIM14) monoclonal antibodies.

Key Results

Pectin and AGP levels increased during olive pollen in vitro germination. (1 → 4)-β-d-Galactans localized in the cytoplasm of the vegetative cell, the pollen wall and the apertural intine. After the pollen tube emerged, galactans localized in the pollen tube wall, particularly at the tip, and formed a collar-like structure around the germinative aperture. (1 → 5)-α-l-Arabinans were mainly present in the pollen tube cell wall, forming characteristic ring-shaped deposits at regular intervals in the sub-apical zone. As expected, the pollen tube wall was rich in highly esterified pectic compounds at the apex, while the cell wall mainly contained de-esterified pectins in the shank. The wall of the generative cell was specifically labelled with arabinans, highly methyl-esterified homogalacturonans and JIM13 epitopes. In addition, the extracellular material that coated the outer exine layer was rich in arabinans, de-esterified pectins and JIM13 epitopes.

Conclusions

Pectins and AGPs are newly synthesized in the pollen tube during pollen germination. The synthesis and secretion of these compounds are temporally and spatially regulated. Galactans might provide mechanical stability to the pollen tube, reinforcing those regions that are particularly sensitive to tension stress (the pollen tube–pollen grain joint site) and mechanical damage (the tip). Arabinans and AGPs might be important in recognition and adhesion phenomena of the pollen tube and the stylar transmitting cells, as well as the egg and sperm cells.     

Distribution of unesterified and esterified pectins in cell walls of pollen tubes of flowering plants

Immunocytochemical localization of polygalacturonic acid (pectin) and methyl-esterified pectin in the walls of pollen tubes of 20 species of flowering plants grown in vitro was investigated by using monoclonal antibodies (MAbs) JIM5 and JIM7 and by means of confocal laser scanning microscopy (CLSM). In general, periodic annular deposits of pectins were found coating the tube wall in species possessing solid styles, and a more uniform pectin sheath in tube walls in species having hollow styles or no styles. We hypothesize that the periodic ring-like structure of the pectin sheath reinforces pollen tubes for passing through the transmitting tract in the style. Esterified pectin which prevents Ca²⁺-induced gelification of pectate is located predominantly at the apex. This implies that pectin esterification is related to tip wall loosening that is required for cell wall expansion during tip growth of pollen tubes. The occurrence of unesterified pectins in other areas of pollen tube walls suggests that de-esterification of pectin following tip expansion leads to a more rigid form of pectin that contributes to the construction of the pollen tube wall.     

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.     

Localization of pectins in the pollen tube wall of Ornithogalum virens L. Does the pattern of pectin distribution depend on the growth rate of the pollen tube?

Monoclonal antibodies that recognize pectins were used for the localization of esterified (JIM7) and acidic, unesterified (JIM5) forms of pectin in pollen tube walls of Ornithogalum virens L. (x = n = 3). The results indicated that the distribution of the two forms of pectin in the pollen tube wall depended on the medium (liquid or solid) used for pollen germination. In pollen tubes grown in the liquid medium, the localization of JIM7 was limited to the very tip of the pollen tube, whereas the localization of JIM5 indicated a uniform distribution of unesterified pectins in the very tip of the tube and along the subapical parts of the tube wall. In tubes germinated on the medium stabilized with agar (1–2%) the localization of JIM7 and JIM5 indicated the presence of both forms of pectin in the tube tip and along the whole length of the pollen tube wall in a ring-like pattern. Thus, the localization of esterified pectins in the sub-apical part of the pollen tube wall, below the apex of the tube, is described for the first time. Measurements of the growth rates of pollen tubes growing on the two types of medium indicated that oscillations in tube growth rate occur but these do not coincide with the pattern of pectin distribution in the tube wall. Our results complement the previous data obtained for the localization of JIM5 and JIM7 in pollen tube walls of other plant species. (Y.-Q. Li et al. 1994, Sex Plant Reprod 7: 145–150) and provide new insight into an understanding of the construction of the pollen tube wall and the physiology of pollen grain germination. Received: 25 January 1999 / Accepted: 23 June 1999     

Ultrastructural immunolocalization of periodic pectin depositions in the cell wall ofNicotiana tabacum pollen tubes

Summary The monoclonal antibody (MAb) JIM5, marking acidic pectins, was used to localize ultrastructurally pectin molecules in the pollen tube wall ofNicotiana tabacum. Longitudinal sections of LR-White embedded pollen tubes were exposed to antibody treatment; accumulations of pectins were identified by counting the density of the gold particles representing the pectin epitopes along the pollen tube wall. Significant accumulations of gold grains were marked and the distances between them were measured. In many pollen tubes a more or less regular distribution of the accumulations was observed along the tube indicating a periodical deposition of pectin. The distances between the accumulations were 4–6 m. Most of the label was found in the inner part of the outer layer of the bilayered cell wall. These findings correspond to and confirm the earlier observation by our group reporting ring-shaped periodical deposits in pollen tubes after immunofluorescence labelling with the MAb JIM5 under the confocal laser scanning microscope.Abbreviations Ab antibody - MAb monoclonal antibody     

Immunocytochemical localization of pectins in the maturing anther of Allium cepa L.

Distribution of pectins in cell walls of maturing anther of Allium cepa L. was investigated. The monoclonal antibodies against defined epitopes of pectin were used: JIM5 recognizing unesterified pectin and JIM7 recognizing esterified pectin. It has been found that the cell walls of all anther tissues mainly contain esterified pectins. In the somatic tissues only small amounts of unesterified pectins are present in the cell wall junctions and adjacent middle lamellae and in the cell walls of the connective tissue. Thickening of the epiderm cell walls and growth of trabeculae in endothecium are completed through deposition of esterified pectins. In the cell walls of the middle layer and tapetum, unesterified pectins have been found only prior to their disintegration. The primary wall of microsporocytes is made up mainly of esterified pectins. Unesterified pectins occur outside microsporocytes only prior to the callose isolation stage. The presence of esterified pectins has also been detected on the surface of the callose wall surrounding dividing microsporocytes. Lysis of those pectins takes place after microsporogenesis, simultaneously with the lysis of the callosic walls. Before these processes pectins are unesterified. In the sporoderm of pollen grains mainly esterified pectins occur. They have been localized in the intine and aperture. The level of unesterified pectins in the intine is markedly lower.     

Localization of pectins and arabinogalactan-proteins in lily (Lilium longiflorum L.) pollen tube and style, and their possible roles in pollination

In lily, adhesion of the pollen tube to the transmitting-tract epidermal cells (TTEs) is purported to facilitate the effective movement of the tube cell to the ovary. In this study, we examine the components of the extracellular matrices (ECMs) of the lily pollen tubes and TTEs that may be involved in this adhesion event. Several monoclonal antibodies to plant cell wall components such as esterified pectins, unesterified pectins, and arabinogalactan-proteins (AGPs) were used to localize these molecules in the lily pollen tube and style at both light microscope (LM) and transmission electron microscope (TEM) levels. In addition, (-d-Glc)₃ Yariv reagent which binds to AGPs was used to detect AGPs in the pollen tube and style. At the LM level, unesterified pectins were localized to the entire wall in in-vivo- and in-vitro-grown pollen tubes as well as to the surface of the stylar TTEs. Esterified pectins occurred at the tube tip region (with some differences in extent in in-vivo versus in-vitro tubes) and were evenly distributed in the entire style. At the TEM level, esterified pectins were detected inside pollen tube cell vesicles and unesterified pectins were localized to the pollen tube wall. The in-vivo pollen tubes adhere to each other and can be separated by pectinase treatment. At the LM level, AGP localization occurred in the tube tip of both in-vivo- and in-vitro-grown pollen tubes and, in the case of one AGP probe, on the surface of the TTEs. Another AGP probe localized to every cell of the style except the surface of the TTE. At the TEM level, AGPs were mainly found on the plasma membrane and vesicle membranes of in-vivo-grown pollen tubes as well as on the TTE surface, with some localization to the adhesion zone between pollen tubes and style. (-d-Glc)₃ Yariv reagent bound to the in-vitro-grown pollen tube tip and significantly reduced the growth of both in-vitro- and in-vivo-grown pollen tubes. This led to abnormal expansion of the tube tip and random deposition of callose. These effects could be overcome by removal of (-d-Glc)₃ Yariv reagent which resulted in new tube tip growth zones emerging from the flanks of the arrested tube tip. The possible roles of pectins and AGPs in adhesion during pollination and pollen tube growth are discussed.Abbreviations AGP arabinogalactan-protein - ECM extracellular matrix - Glc glucose - MAbs monoclonal antibodies - LM light microscope - Man mannose - TEM transmission electron microscope - TTE transmitting tract epidermal cell The authors thank Michael Georgiady for assistance with the preparation of material for the TEM immunolocalization, Diana Dang for her help with the pectinase experiment, and Kathleen Eckard for assistance in all aspects of this study. The MAbs were the generous gifts of Dr. J.P. Knox. G.Y. Jauh thanks Dr. E.A. Nothnagel for assistance in making the Yariv reagent and for the gift of the control (-d-Man)₃ Yariv reagent. This work is in partial fulfilment of the dissertation requirements for a PhD degree in Botany and Plant Sciences for G.Y. Jauh at the University of California, Riverside. This work was supported by National Science Foundation grant 91-18554 and an R.E.U. grant to E.M.L.     

Localization of arabinogalactan proteins in anther,pollen, and pollen tube of <Emphasis Type="Italic">Nicotiana tabacum</Emphasis> L.

Summary. Western blot analysis indicated the presence of two epitopes recognized by the anti-arabinogalactan protein antibodies JIM13 and LM2 and the absence of the JIM4 epitope in mature tobacco anthers. Immunoenzyme localization of arabinogalactan proteins (AGPs) with JIM13 showed that AGPs accumulate mainly at the early stages of anther development. AGP content and distribution were also investigated at the ultrastructural level in pollen tubes grown in vivo and in vitro. Abundant AGPs were present in the transmitting tissue of styles, and the AGP content of the extracellular matrix changed during pollen tube growth. In pollen tubes, immunogold particles were mainly distributed in the cell wall and cytoplasm, especially around the peripheral region of the generative-cell wall. β-D-Glucosyl Yariv reagent, which specifically binds to AGPs, caused slow growth of pollen tubes and reduced immunogold labeling of AGPs with JIM13 in vitro. These data suggest that AGPs participate in male gametogenesis and pollen tube growth and may be important surface molecules in generative and sperm cells. Correspondence and reprints: Key Laboratory of the Ministry of Education for Plant Developmental Biology, College of Life Sciences, Wuhan University, Wuhan 430072, People’s Republic of China.     

Cellular localization and levels of pectins and arabinogalactan proteins in olive (Olea europaea L.) pistil tissues during development: implications for pollen–pistil interaction

Cell wall components in the pistil are involved in cell–cell recognition, nutrition and regulation of pollen tube growth. The aim of this work was to study the level, whole-organ distribution, and subcellular localization of pectins and arabinogalactan proteins (AGPs) in the olive developing pistil. Western blot analyses and immunolocalization with fluorescence and electron microscopy were carried out using a battery of antibodies recognizing different types of pectin epitopes (JIM7, JIM5, LM5, and LM6) and one anti-AGPs antibody (JIM13). In the olive pistil, highest levels of acid esterified and de-esterified pectins were observed at pollination. Moreover, pollination was accompanied by a slight decrease of the galactose-rich pectins pool, whereas arabinose-rich pectins were more abundant at that time. An increased expression of AGPs was also observed during pollination, in comparison to the pistil at the pre-anthesis stage. After pollination, the levels of pectins and AGPs declined significantly. Inmunofluorescence localization of pectins showed their different localization in the olive pistil. Pectins with galactose residues were located mainly in the cortical zones of the pistil, similar to the neutral pectins, which were found in the parenchyma and epidermis. In turn, the neutral pectins, which contain arabinose residues and AGPs, were localized predominantly in the stigmatic exudate, in the cell wall of secretory cells of the stigma, as well as in the transmitting tissue of the pistil during the pollination period. The differences in localization of pectins and AGPs are discussed in relation to their roles during olive pistil developmental course.     

The wall ofPinus sylvestris L. pollen tubes

Summary The wall ofPinus sylvestris pollen and pollen tubes was studied by electron microscopy after both rapid-freeze fixation and freeze-substitution (RF-FS) and chemical fixation. Fluorescent probes and antibodies (JIM7 and JIM5) were used to study the distribution of esterified pectin, acidic pectin and callose. The wall texture was studied on shadow-casted whole mounts of pollen tubes after extraction of the wall matrix. The results were compared to current data of angiosperms. TheP. sylvestris pollen wall consists of a sculptured and a nonsculptured exine. The intine consists of a striated outer layer, that stretches partly over the pollen tube wall at the germination side, and a striated inner layer, which is continuous with the pollen tube wall and is likely to be partly deposited after germination. Variable amounts of callose are present in the entire intine. No esterified pectin is detected in the intine and acidic pectin is present in the outer intine layer only. The wall of the antheridial cell contains callose, but no pectin is detectable. The wall between antheridial and tube cell contains numerous plasmodesmata and is bordered by coated pits, indicating intensive communication with the tube cell. Callose and esterified pectin are present in the tip and the younger parts of the pollen tubes, but both ultimately disappear from the tube. Sometimes traces in the form of bands remain present. No acidic pectin is detected in either tip or tube. The wall of the pollen tube tip has a homogenous appearance, but gradually attains a fibrillar character at aging, perhaps because of the disappearance of callose and pectin. No secondary wall formation or callose lining can be seen wilh the electron microscope. The densily of the cellulose microfibrils (CMF) is much lower in the tip than in the tube. Both show CMF in all but axial and nontransverse orientations. In conclusion,P. sylvestris and angiosperm pollen tubes share the presence of esterified pectin in the tip, the oblique orientations of the CMF, and the gradual differentiation of the pollen tube wall, indicating a possible relation to tip growth. The presence of acidic pectin and the deposition of a secondary-wall or callose layer in angiosperms but not inP. sylvestris indicales that these characteristics are not related to tip growth, but probably represent adaptations to the fast and intrastylar growth of angiosperms.Abbreviations CMF cellulose microfibrils - II inner intine - NE nonsculptured exine - OI outer intine - RF-FS rapid-freeze fixation freeze-substitution - SE sculptured exine - SER smooth endoplasmic reliculum - SV secretory vesicles     

Arabinogalactan proteins, pollen tube growth, and the reversible effects of Yariv phenylglycoside

Arabinogalactan proteins (AGPs) are abundant complex macromolecules involved in both reproductive and vegetative plant growth. They are secreted at pollen tube tips in Lilium longiflorum. Here, we report the effect of the (beta-D-glucosyl)3 Yariv phenylglycoside, known to interact with AGPs, on pollen tube extension in several plant species. In Annona cherimola the Yariv reagent clearly inhibited pollen tube extension within 1-2 h of treatment, as demonstrated previously for L. longiflorum, but had no effect on Lycopersicon pimpinellifolium, Aquilegia eximia, and Nicotiana tabacum. With the monoclonal antibody JIM13 we also examined these same species for evidence that they secreted AGPs at their pollen tube tips. Only A. cherimola showed evidence of AGPs at the pollen tube tip as does lily. The Yariv reagent causes arrest of tube growth in both A. cherimola and lily, but its removal from the medium allows regeneration of new tip growth in both species. We show that the site of the new emerging tip in lily can be predicted by localization of AGP secretion. Labeling with JIM13 appeared on the flanks of the arrested tip 1 h after removal of the Yariv reagent from the growth medium. After 4 h, many of the Yariv reagent-treated pollen tubes had regenerated new pollen tubes with the tips brightly labeled by JIM13 and with a collar of AGPs left at the emergence site. During this recovery, esterified pectins colocalized with AGPs. Secretion at the site of the new tip may be important in the initial polarization event that occurs on the flanks of the arrested tube tip and results in a new pollen tube.     

Distribution of pectins in cell walls of maize coleoptiles and evidence against their involvement in auxin-induced extension growth

Summary Aiming to elucidate the possible involvement of pectins in auxin-mediated elongation growth the distribution of pectins in cell walls of maize coleoptiles was investigated. Antibodies against defined epitopes of pectin were used: JIM 5 recognizing pectin with a low degree of esterification, JIM 7 recognizing highly esterified pectin and 2F4 recognizing a pectin epitope induced by Ca²⁺. JIM 5 weakly labeled the outer third of the outer epidermal wall and the center of filled cell corners in the parenchyma. A similar labeling pattern was obtained with 2F4. In contrast, JIM 7 densely labeled the whole outer epidermal wall except the innermost layer, the middle lamellae, and the inner edges of open cell corners in the parenchyma. Enzymatic de-esterification with pectin methylesterase increased the labeling by JIM 5 and 2F4 substantially. A further increase of the labeling density by JIM 5 and 2F4 and an extension of the labeling over the whole outer epidermal wall could be observed after chemical de-esterification with alkali. This indicates that both methyl- and other esters exist in maize outer epidermal walls. Thus, in the growth-controlling outer epidermal wall a clear zonation of pectin fractions was observed: the outermost layer (about one third to one half of wall thickness) contains unesterified pectin epitopes, presumably cross-linked by Ca²⁺ extract. Tracer experiments with³H-myo-inositol showed rapid accumulation of tracer in all extractable pectin fractions and in a fraction tightly bound to the cell wall. A stimulatory effect of IAA on tracer incorporation could not be detected in any fraction. Summarizing the data a model of the pectin distribution in the cell walls of maize coleoptiles was developed and its implications for the mechanism of auxin-induced wall loosening are discussed.Abbreviations CDTA trans-1,2-diaminocyclohexane-N,N,N,N-tetraacetic acid - CWP cell-wall pellet - IAA indole-3-acetic acid - LSE low-salt extract - TCA trichloroacetic acid; Tris tris-(hydroxy-methyl)aminoethane     

Subcellular distribution of arabinogalactan proteins in pollen grains and tubes as revealed with a monoclonal antibody raised against stylar arabinogalactan proteins

Summary Monoclonal antibody PCBC3, raised against stylar extracts fromNicotians, alata flowers, was deduced from enzyme-linked immunosorbent assays and inhibition of immuno-gold labelling on tissue sections to bind specifically to carbohydrate epitopes on arabinogalactan proteins (AGPs) but not to other arabinose-containing cell wall polysaccharides. When pollen grains ofN. tabacum were hydrated in fixative, PCBC3 bound to vesicles in the vicinity of the endoplasmic reticulum but, when grains were hydrated for 20 min in culture medium before fixation, binding was restricted to the plasma membrane. The generative-cell plasma membrane was also labelled in grains ofLycopersicon peruvianum. In pollen tubes ofN. tabacum grown in liquid culture, the AGPs detected by PCBC3 were located in several regions, including the plasma membrane, tubular-vesicular structures (plasmalemmasomes) at and under the plasma membrane, and multilamellar bodies within vacuoles, features generally associated with endocytosis. Labelling was not evident in secretory vesicles or the plasma membrane at the pollen-tube tip. The AGPs detected with PCBC3 were also present in pollen-tube walls, near the interface between the inner, callosic layer and the outer, fibrillar, pectic layer. Pollen tubes ofN. tabacum grown in medium lacking added CuSO₄ produce a wall with an abnormally thickened fibrillar layer, and this layer was uniformly labelled with PCBC3. The disposition of wall AGPs thus changes in pollen tubes of different morphologies.Abbreviations AGP arabinogalactan protein - -L-Araf -L-arabinofuranose - ELISA enzyme-linked immunosorbent assay - MAb monoclonal antibody - PBS phosphate-buffered saline     

Immunocytochemical localization of esterified and unesterified pectins in unpollinated and pollinated styles of Petunia hybrida Hort

Localization of pectins in the style of Petunia hybrida before and after pollination was investigated by immunocytochemistry using two primary monoclonal antibodies specific to highly (JIM7) and weakly (JIM5) methylesterified pectins. In the unpollinated style, esterified pectins occurred mainly in the cell walls of cortex tissue, while unesterified pectins were present mainly in the extracellular matrix (ECM) of the transmitting tract. After pollination no remarkable differences were found in pectin distribution in the ground tissue of the style. On the other hand, in the transmitting tract a reduction in the quantity of unesterified pectins was observed. Unesterified pectins in the extracellular regions of the transmitting tissue decreased before the penetration of the pollen tubes, indicating that pollination induces a reduction in the amount of unesterified pectins in the transmitting-tract ECM. The correlation between the degradation of strongly Ca2+-binding pectins and the growing level of those ions in the extracellular regions of the transmitting tract in the pollinated pistil of P. hybrida (M. Lenartowska et al. 1997) suggests that this process may constitute a mechanism for creating an optimum calcium medium for in vivo-growing pollen tubes. Both pectin categories were localized in pollen tubes. Esterified pectin epitopes were localized mainly in the vesicles of the tip cytoplasm. Unesterified pectin epitopes were found in the external fibrillar wall of pollen tubes.     

Pectin secretion and distribution in the anther during pollen development in Lilium

Using the monoclonal antibodies JIM 5 and 7, pectin was immunolocalized and quantitatively assayed in three anther compartments of Lilium hybrida during pollen development. Pectin levels in both the anther wall and the loculus increased following meiosis, were maximal during the early microspore stages and declined during the remainder of pollen ontogenesis. In the microspores/pollen grains, pectin was detectable at low levels during the microspore stages but accumulated significantly during pollen maturation. During early microspore vacuolation, esterified pectin epitopes were detected both in the tapetum cytoplasm and vacuoles. In the anther loculus, the same epitopes were located simultaneously in undulations of the plasma membrane and in the locular fluid. At the end of microspore vacuolation, esterified pectin epitopes were present within the lipids of the pollenkitt, and released in the loculus at pollen mitosis. Unesterified pectin epitopes were hardly detectable in the cytoplasm of the young microspore but were as abundant in the primexine matrix as in the loculus. During pollen maturation, both unesterified and esterified pectin labelling accumulated in the cytoplasm of the vegetative cell, concurrently with starch degradation. In the mature pollen grain, unesterified pectin epitopes were located in the proximal intine whereas esterified pectin epitopes were deposited in the distal intine. These data suggest that during early microspore development, the tapetum secretes pectin, which is transferred to the primexine matrix via the locular fluid. Further, pectin is demonstrated to constitute a significant component of the pollen carbohydrate reserves in the mature grain of Lilium. Received: 3 July 2000 / Accepted: 19 October 2000     

Pectin distribution pattern in the apertural intine of Euphorbia peplus L. (Euphorbiaceae) pollen

The apertural inner layer (intine) of Euphorbia L. pollen grains has a characteristic but original structure that has paired thickenings, one on either side of the colpus. To determine the nature and role of this intine layer, pollen grains of Euphorbia peplus L. were germinated in vivo and in vitro. The germination process involves wall changes that facilitate formation of the pollen tube and its subsequent growth. In the thickenings of the intine of E. peplus, the unesterified pectin epitopes are more densely localised in the inner part of the middle intine. No such epitopes are located in the intine portion adjacent to the plasma membrane (cellulosic endintine). Unesterified pectin epitopes are also localised in the outer part of the intine but are restricted to the centre of the aperture, around and in the pore. The de-esterification of pectins is very advanced at the time of dehiscence and pollen germination. The stratification of the aperture intine may take the following pathway at the time of germination: the thin outer zone of the intine in the pore region becomes disorganised and undergoes dissolution with liberation of unesterified and esterified pectins; the middle intine thickenings undergo an important elastic modification, but without liberation of unesterified pectins; the cellulosic inner intine is the progenitor of the pollen tube wall. This special intine of E. peplus is an adaptation to the hydration process preceding germination, increasing intine and pollen grain wall elasticity.     

Immunocytochemical and chemical analyses of Golgi vesicles isolated from the germinated pollen ofCamellia japonica

As a first step towards studying the biochemical relationship between Golgi vesicles (GVs) and tube wall components, isolation of GVs from the growing pollen tubes ofCamellia japonica was attempted using a centrifugation method with mannitol. The isolated GV was identified ultrastructurally and immunocytochemically. The main components of the GV were proteins and carbohydrates. The main monosaccharides of GV polysaccharides were galactose, arabinose and uronic acid, and pectins and arabinogalactan proteins also were detected immunochemically. An antiserum against the isolated GVs reacted with the outer layer of the pollen tube wall and the intine layers of the grain wall as well as thein situ GVs in the pollen tube and the grain cytoplasm. We have thus successfully isolated GVs and shown that they contain pectic substances and arabinogalactan proteins which contribute to formation of the pollen tube primary wall.