Abstract: During plant sexual reproduction, pollen germination and tube growth require development under tight spatial and temporal control for the proper delivery of the sperm cells to the ovules. Pollen tubes are fast growing tip-polarized cells able to perceive multiple guiding signals emitted by the female organ. Adhesion of pollen tubes via cell wall molecules may be part of the battery of signals. In order to study these processes, we investigated the cell wall characteristics of in vitro-grown Arabidopsis (Arabidopsis thaliana) pollen tubes using a combination of immunocytochemical and biochemical techniques. Results showed a well-defined localization of cell wall epitopes. Low esterified homogalacturonan epitopes were found mostly in the pollen tube wall back from the tip. Xyloglucan and arabinan from rhamnogalacturonan I epitopes were detected along the entire tube within the two wall layers and the outer wall layer, respectively. In contrast, highly esterified homogalacturonan and arabinogalactan protein epitopes were found associated predominantly with the tip region. Chemical analysis of the pollen tube cell wall revealed an important content of arabinosyl residues (43%) originating mostly from (1→5)-α-l-arabinan, the side chains of rhamnogalacturonan I. Finally, matrix-assisted laser desorption ionization time-of-flight mass spectrometry analysis of endo-glucanase-sensitive xyloglucan showed mass spectra with two dominant oligosaccharides (XLXG/XXLG and XXFG), both being mono O-acetylated, and accounting for over 68% of the total ion signals. These findings demonstrate that the Arabidopsis pollen tube wall has its own characteristics compared with other cell types in the Arabidopsis sporophyte. These structural features are discussed in terms of pollen tube cell wall biosynthesis and growth dynamics.
Abstract: Plant sexual reproduction involves the growth of tip-polarized pollen tubes through the female tissues in order to deliver the sperm nuclei to the egg cells. Despite the importance of this crucial step, little is known about the molecular mechanisms involved in this spatial and temporal control of the tube growth. In order to study this process and to characterize the structural composition of the extracellular matrix of the male gametophyte,
immunocytochemical and biochemical analyses of Arabidopsis pollen tube wall have been carried out. Results showed a well defined localization of cell wall epitopes with highly esterified homogalacturonan and arabinogalactanprotein mainly in the tip region, weakly methylesterified homogalacturonan back from the tip and xyloglucan and (1→5)- α-L-arabinan all along the tube. Here, we present complementary data regarding (1) the ultrastructure of the pollen tube cell wall and (2) the immunolocalization of homogalacturonan and arabinan epitopes in 16 h-old pollen tubes and in the stigma and the transmitting tract of the female organ. Discussion regarding the pattern of the distribution of the cell wall epitopes and the possible mechanisms of cell adhesion between the pollen tubes and the female tissues is provided.
Abstract: Aristida pungens, a perennial grass widely distributed on the Algerian arid regions, may potentially be the source of raw cell wall material to promote a local development in North Africa. Hemicelluloses, the main matrix cell wall polymers of this species were isolated from leaves with 14% KOH aqueous solution, characterized and converted as plastic material. The extraction procedure yielded two hemicellulose fractions (A and B) accounting for 3.5 and 10.1% of the starting leaf material, respectively. GC and 13C NMR showed the presence of xylose as the main component with arabinosyl residues. Both analyses indicate that hemicelluloses from A. pungens leaves are arabinoxylans. Arabinoxylans were transformed into hydrophobic plastics by grafting of lauroyl chloride. The resulting materials were characterized by FT-IR and 1H NMR spectroscopies, with both mechanical and thermogravimetric analysis.
Abstract: Carrageenans isolated from the cell wall of Gigartina pistillata (Gmelin) Stackhouse were investigated using two extraction methods. The first one involved sequential extraction with increasing temperatures starting from 20°C up to 100°C by 20°C increment. The second method was carried out by using successive ethanol concentrations ranging from 80, 60, 40, 20 and 0%. Chemical characterization of the different fractions by GC, HPLC and FT-IR spectroscopy revealed that low extraction temperature or high ethanol concentration contained mainly the kappa-carrageenan type. In contrast, high extraction temperatures or low ethanol concentrations yielded enriched lambda-carrageenan fractions.
Abstract: Lily pollen tubes grow adhering to an extracellular matrix produced by the transmitting tract epidermis in a hollow style. SCA, a small (∼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 Ala71 in SCA3, replacing the Gly71 in SCA1, has no predictable effect on structure. The Arg26 in SCA3, replacing the Gly26 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.
Abstract: Activities of two de-N-glycosylation enzymes, PNGase (peptide N 4(N-acetyl-glucosaminyl)asparagine amidase) and ENGase (endo N-acetyl-β-D-glucosaminidase), involved in the release of N-glycans from N-glycoproteins, were monitored in several organs of tomato plants (Lycopersicon esculentum, Mill., cv. Dombito) with a fluorescence-HPLC procedure using a resofurin-labelled N-glycopeptide substrate. PNGase and ENGase activities were detected in every organ assayed but with quantitative differences. The highest activities were found in the youngest parts of the plant, i.e. apical buds, flowers and leaf blades. PNGase activities were consistently higher than ENGase activities (three-fold in average). Both de-N-glycosylation activities were associated with high levels of proteins and protease activities. During fruit growth and ripening, these three parameters decreased notably. The ubiquitous detection of these enzyme activities in the different organs is probably associated with the previously characterized unconjugated N-glycans in tomato. The possible role of PNGase and ENGase degradation products (i.e. unconjugated N-glycans) are discussed in relation with their biological functions in plant development.
Abstract: 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.
Abstract: In plant reproduction, pollination is an essential process that delivers the sperm through specialized extracellular matrices (ECM) of the pistil to the ovule. Although specific mechanisms of guidance for pollen tubes through the pistil are not known, the female tissues play a critical role in this event. Many studies have documented the existence of diffusible chemotropic factors in the lily stigma that can induce pollen tube chemotropism in vitro, but no molecules have been isolated to date. In this study, we identified a chemotropic compound from the stigma by use of biochemical methods. We purified a lily stigma protein that is active in an in vitro chemotropism assay by using cation exchange, gel filtration, and HPLC. Tryptic digestion of the protein yielded peptides that identified the protein as a plantacyanin (basic blue protein), and this was confirmed by cloning the cDNA from the lily stigma. Plantacyanins are small cell wall proteins of unknown function. The measured molecular mass by electrospray ionization ion source MS is 9,898 Da, and the molecular mass of the mature protein (calculated from the cDNA) is 9,900.2 Da. Activity of the lily plantacyanin (named chemocyanin) is enhanced in the presence of stigma/stylar cysteine-rich adhesin, previously identified as a pollen tube adhesin in the lily style.
Abstract: 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 (β-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.
Abstract: 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.
Abstract: 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.
Abstract: Agarocolloids were extracted from field samples of Gracilaria gracilis, Gracilariopsis longissima and the newly reported Gracilaria cf. vermiculophylla harvested at different periods of the year near Roscoff (France). Native and alkali modified extracts were characterized by GLC, HPLC and FT-IR spectroscopy. The main components of agarocolloids isolated by freeze-thawing method, were 3,6-anhydrogalactose and galactose. In addition, minor components (6-O-methyl-galactose, 4-O-methyl-galactose and sulfate groups ranging from 4.4 up to 6.6% [w/w]) were detected. The highest rate of 6-O-methylgalactose was observed in agarocolloids from vermiculophylla (14 mole%). Sulfates were mainly branched on C4 of the D-galactose in gracilis and Gs. longissima agarocolloids. G. vermiculophylla agaroids isolated by EtOH and NaCl precipitations from the syneresis water were characterized by a high sulfation on C6 of galactose and a low sulfation on C2 of 3,6-anhydrogalactose. Native agarocolloid gel strengths from Gracilaria species were clearly higher than those of Gracilariopsis. Alkali treatments reduced the sulfate levels but increased slightly the gel strengths. An approximation of the polymer sizes carried out with colorimetric assays indicated that the polymer sizes were higher in G. gracilis than observed in Gs. longissima.
Abstract: The cellulose synthesis inhibitor 2,6-dichlorobenzonitrile (DCB) and the DCB analogs 2-chloro-6-fluorobenzonitrile, 3-amino-2,6-dichlorobenzonitrile, and 5-dimethylamino-naphthalene-1-sulfonyl-(3-cyano-2, 4-dichloro)aniline (DCBF) inhibited extracellular adhesive production in the marine diatom Achnanthes longipes, resulting in a loss of motility and a lack of permanent adhesion. The effect was fully reversible upon removal of the inhibitor, and cell growth was not affected at concentrations of inhibitors adequate to effectively interrupt the adhesion sequence. Video microscopy revealed that the adhesion sequence was mediated by the export and assembly of polymers, and consisted of initial attachment followed by cell motility and eventual production of permanent adhesive structures in the form of stalks that elevated the diatom above the substratum. A. longipes adhesive polymers are primarily composed of noncellulosic polysaccharides (B.A. Wustman, M.R. Gretz, and K.D. Hoagland [1997] Plant Physiol 113: 1059–1069). These results, together with the discovery of DCB inhibition of extracellular matrix assembly in noncellulosic red algal unicells (S.M. Arad, O. Dubinsky, and B. Simon [1994] Phycologia 33: 158–162), indicate that DCB inhibits synthesis of noncellulosic extracellular polysaccharides. A fluorescent probe, DCBF, was synthesized and shown to inhibit adhesive polymer production in the same manner as DCB. DCBF specifically labeled an 18-kD polypeptide isolated from a membrane fraction. Inhibition of adhesion by DCB and its analogs provides evidence of a direct relationship between polysaccharide synthesis and motility and permanent adhesion.
Abstract: Protoplasts were isolated enzymatically from the red alga Gracilaria verrucosa using only two enzymes: agarase prepared from marine bacteria and commercial cellulase. Yields of protoplasts were dependent on the donor material and by choosing young blades or algae in a state of higher growth rate, the production of protoplasts reached a maximum of 107 protoplasts per gram of fresh tissue. Cell viability was better with NaCI used as osmoticum than with sorbitol in the culture medium and on reducing culture media to normal osmolarity in 4 d. 25% of the cultured protoplasts were able to regenerate a cell wall (i.e. cellulose) within 7 d as confirmed by staining with calcofluor white although only a few protoplasts were able to divide. During the first 24 h of culture, the synthesized agar contained higher amounts of L-galactose-6-sulphate than the cell wall of thalli. The amount of agar in the protoplasts, however, did not increase, indicating that the protoplasts synthesize a qualitatively differentcell wall.
Abstract: Unlike carrageenans, agars have not been studied very extensively by infrared spectroscopy, in so far as the structures of this kind of polygalactanes are not as well defined as carrageenans. However, in a previous work we have carried out a vibrational analysis of both carrageenans and agars and some important assignments of the main absorptions have been made. Consequently, the present work has been undertaken in order to identify agars without any extraction directly in various seaweeds using the infrared microspectrometry method. The main advantage of this method is that the sample consists only of a dehydrated algal section. The red algaeGradlaria verrucosa has been the subject of the present study. In the first place, spectra of extracted agars were recorded, as they can help us to confirm the nature of the compound identified by this technique. In a second stage, spectra of different parts of the sections have been carried out. The comparison between the resulting spectra with those of the extracted polysaccharides, has demonstrated, firstly that the best results are obtained from the cortical area, because, as expected, the agar is mainly located in the cell wall of this area of the algae. Indeed, the feature bands of agars are all observed, especially the intense ones between 1000 and 1100 cm–1 and the more characteristic absorptions in the wavenumbers range below 1000 cm–1 so as the ones at 988, 965, 930, 890, 870, 771 and 741 cm–1. Secondly, it may be also identified in smaller amounts in the medullar area, the cells are greater than in the cortical area and the cytoplasm is preponderent. However, in the latter case a coexisting polysaccharide, present in a considerable quantity and called floridean starch (Its structure is not very well known, as it varies from one algae to another), masks the spectra of agar, as its spectrum is very similar to those of polygalactanes.
Abstract: Tip growth is a type of cellular growth that is represented in many and diverse cell types, which are important to plant breeding (pollen tubes), agriculture (root hairs) and plant and animal pathology (fungal hyphae). Also moss and fern protonemata as well as algal zygotes and yeasts exhibit the features unique for tip growth: directable apical linear growth which renders the cell able to penetrate its growth environment. In this volume various cell biological aspects of this particular growth phenomenon are discussed, such as the initiation and maintenance of an anisotropically growing cell, the function of cytoskeletal elements, extracellular matrix and turgor, the regulation of ion homeostasis, the mechanism of signalling events, and the interaction of the cell with the environment.
