Different effects of inorganic and triethyl lead on growth and ultrastructure of lily pollen tubes

Summary Pollen tubes ofLilium longiflorum growingin vitro were treated for 1 h with inorganic lead (Pb) and with triethyl lead (TriEL) and studied by light and electron microscopy. Pb was considerably more toxic in relation to inhibition of pollen tube growth (EC₅₀=6 M Pb) than was TriEL (EC₅₀=60 M TriEL). On the other hand, at almost the entire concentration range tested (25-500 M) TriEL caused aberrant tubes and tube swellings. Pb did not cause tube swellings, even at highly growth-impairing concentrations. Pb (60 M) predominantly affected the ultrastructure of the growing cell walls without impairing the distribution of the cell organelles in the tube tips. In contrast, 50 and 100 M TriEL did not visibly influence cell wall ultrastructure but it severely damaged dictyosomes; 100 M TriEL also disturbed the original order of cell organelles in the tube tips. Cortical microtubules were selectively and completely destructed by TriEL at concentrations (50 M) where no effect on polar organization of the tube tips occurred but they remained unimpaired by 60 M Pb, indicating selective and effective interaction of TriEL with these cell organelles.Abbreviations EC⁵⁰ effective lead concentration causing 50% inhibition of pollen tube growth - MTs microtubules - Pb inorganic lead - TriAL trialkyl lead - TriEL triethyl lead     

The actin microfilament network within elongating pollen tubes of the gymnospermPicea abies (Norway spruce)

Summary Actin microfilaments form a dense network within pollen tubes of the gymnosperm Norway spruce (Picea abies). Microfilaments emanate from within the pollen grain and form long, branching arrays passing through the aperture and down the length of the pollen tube to the tip. Pollen tubes are densely packed with large amyloplasts, which are surrounded by branching microfilament bundles. The vegetative nucleus is suspended within the elongating pollen tube within a complex array of microfilaments oriented both parallel to and perpendicular with the growing axis. Microfilament bundles branch out along the nuclear surface, and some filaments terminate on or emanate from the surface. Microfilaments in the pollen tube tip form a 6 m thick, dense, uniform layer beneath the plasma membrane. This layer ensheathes an actin depleted core which contains cytoplasm and organelles, including small amyloplasts, and extends back 36 m from the tip. Behind the core region, the distinct actin layer is absent as microfilaments are present throughout the pollen tube. Organelle zonation is not always maintained in these conifer pollen tubes. Large amyloplasts will fill the pollen tube up to the growing tip, while the distinct layer of microfilaments and cytoplasm beneath the plasma membrane is maintained. The distinctive microfilament arrangement in the pollen tube tips of this conifer is similar to that seen in tip growth in fungi, ferns and mosses, but has not been reported previously in seed plants.     

Isolation and characterization of plant myosin from pollen tubes of lily

Summary A plant myosin was isolated from pollen tubes of lily,Lilium longiflorum. Pollen tubes were homogenized in low ionic strength solution containing casein, and myosin from this crude extract was purified by co-precipitation with F-actin prepared from chicken breast muscle, followed by hydroxylapatite column and gel filtration column chromatography. Upon SDS-PAGE on 6% polyacrylamide gel, only 170 kDa polypeptide was detected in the purified myosin fraction. Furthermore, with immunoblotting using antiserum raised against 170 kDa polypeptide, only the 170 kDa component crossreacted in the crude sample of pollen tube proteins. This antiserum did not crossreact with the heavy chain of skeletal muscle myosin. The ATPase activity of pollen tube myosin was stimulated up to 60-fold by F-actin prepared from chicken breast muscle. The translocation velocity of rhodamine-phalloidin-labeled F-actin on a glass surface covered with pollen tube myosin ranged from 6.0 to 9.8 m/s with an average of 7.7 m/s. This velocity was similar to or a little faster than that of the cytoplasmic streaming that occurred in pollen tubes. These results suggested that myosin composed of a 170 kDa heavy chain produces the motive force for cytoplasmic streaming in pollen tube of lily.Abbreviations ATP adenosine-5-triphosphate - DTT dithiothreitol - EGTA ethyleneglycol-bis-(-aminoethylether)N,N,N,N-tetraacetic acid - PAGE polyacrylamide gel electrophoresis - PIPES piperazin-N,N-bis-(2-ethanesulfonic acid) - PMSF phenylmethylsulfonyl fluoride - SDS sodium dodecylsulfate     

Growth and morphogenesis inSaprolegnia ferax: Is turgor required?

Summary The oomyceteSaprolegnia ferax, unlike most walled organisms, does not regulate turgor. When hyphae were subjected to water stress by the addition of sucrose or other solutes to the growth medium, turgor pressure diminished progressively; yet the hyphae continued to extend with deposition of a more plastic apical wall. Even when turgor was no longer measurable with a micropipet-based pressure probe (0.02 MPa or less, compared with 0.4 MPa in unsupplemented medium) they produced regular hyphal tubes and tips. Such turgorless hyphae extended as rapidly, or more rapidly, than normal ones, but they were wider and their tips blunter. Despite the loss of turgor, hyphae put forth branches and cysts germinated. The organization of actin microfilaments was essentially normal, and the response to cytochalasin A was similar in turgorless and standard hyphae. However, as turgor diminished the hyphae's capacity to penetrate solid media was progressively impaired; aerial hyphae were no longer produced, and zoospore formation was inhibited. The results contradict the common belief that turgor supplies the driving force for hyphal extension, tip morphogenesis, and branching. Evidently, these functions do not intrinsically require hydrostatic pressure. Turgorless hyphae are, however, crippled by their inability to exploit solid media.Abbreviations PEG-300 polyethylene glycol-300 - Rh-Phal rhodamine phalloidin - F-actin filamentous actin - DMSO dimethyl sulfoxide - PYG peptone, yeast extract, glucose - MPa megapascals     

Introduction of impermeable molecules into pollen grains by electroporation

Summary Electroporation was used to introduce plasma membrane impermeable molecules into the cytoplasm of pollen grains ofLilium longiflorum. Ungerminated pollen grains were exposed to the fluorescent dye quin2 or FITC-labelled dextrans and electroporated with exponentially decaying voltage pulses of 250 to 2000 V/cm and time constants of 0.01 to 10 s. The number of electroporated pollen grains increased with the strength and duration of the voltage pulses, and with the osmolarity of the external medium. Optimal results were obtained with pulses of 1000 V/cm and 10 s time constant, and with 900 mM mannitol in the electroporation buffer. The size of the pores produced in the plasma membrane by electroporation allowed uptake of 40 kDa dextran but not 70 kDa dextran. The rate of germination of pollen grains was low immediately after electroporation, but increased with time in pollen growth medium. The conditions of electroporation reported here may be used to load genetic material into pollen grains for the production of transgenic plants.Abbreviations PGM pollen growth medium - FDA fluorescein diacetate - FITC fluorescein isothiocyanate     

Callus proliferation from the protoplasts of embryogenic cells of Quercus serrata

Embryogenic culture was induced from the immature embryos of Quercus serrata using Marashige and Skoog's medium (MS) containing 0.1 M each of 2,4-d and BAP, and subcultured for seven months before isolation of protoplasts by using 1% Cellulase RS in 0.6 M mannitol solution. Efficient colony formation was obtained when protoplasts were cultured in a liquid MS medium containing 0.6 M mannitol, 3% sucrose and combination of 0.1 M or 1 M each of 2,4-d and BAP. Excluding ammonium nitrate from the MS medium resulted in the decrease of the percentage of colony formation. From colonies, both agar culture and liquid culture were sustained in the MS media without mannitol containing no plant growth regulator, or containing 0.1 M of BAP in combination with 0.1 M or 1 M of 2,4-d.Abbreviations BAP 6-benzylaminopurine - 2,4-d 2,4-dichlorophenoxyacetic acid - MS medium after Murashige & Skoog (1962).     

The regulation of turgor pressure during sucrose mobilisation and salt accumulation by excised storage-root tissue of red beet

The changes in turgor pressure that accompany the mobilisation of sucrose and accumulation of salts by excised disks of storage-root tissue of red beet (Beta vulgaris L.) have been investigated. Disks were washed in solutions containing mannitol until all of their sucrose had disappeared and then were transferred to solutions containing 5 mol·m^-3 KCl+5 mol·m^-3 NaCl in addition to the mannitol. Changes in solute contents, osmotic pressure and turgor pressure (measured with a pressure probe) were followed. As sucrose disappeared from the tissue, reducing sugars were accumulated. For disks in 200 mol·m^-3 mannitol, the final reducing-sugar concentration equalled the initial sucrose concentration so there was no change in osmotic pressure or turgor pressure. At lower mannitol concentrations, there was a decrease in tissue osmotic pressure which was caused by a turgor-driven leakage of solutes. At concentrations of mannitol greater than 200 mol·m^-3, osmotic pressure and turgor pressure increased because reducing-sugar accumulation exceeded the initial sucrose concentration. When salts were provided they were absorbed by the tissue and reducing-sugar concentrations fell. This indicated that salts were replacing sugars in the vacuole and releasing them for metabolism. The changes in salf and sugar concentrations were not equal because there was an increase in osmotic pressure and turgor pressure. The amount of salt absorbed was not affected by the external mannitol concentration, indicating that turgor pressure did not affect this process. The implications of the results for the control of turgor pressure during the mobilisation of vacuolar sucrose are discussed.To whom correspondence should be addressed.     

Germination of trinucleated pollen: formulation of a new medium for Capsella bursa-pastoris

Summary In Brewbaker and Kwack's medium (BK) only 16% of the pollen grains germinated, and these produced pollen tubes having a maximum length of 25 m. With a solution based on Monnier's medium 47% germination and 160-mlong pollen tubes were observed. Calcium was shown to be essential for germination; the optimal concentration was 880 mg/l calcium chloride. The optimal concentrations of magnesium sulphate and boric acid were 360 and 50 mg/l, respectively. Germination at pH 4.0 but also pH 8.0 and the presence of vitamins B1 and B6 (1 mg/l each) were stimulatory. Polyethylene glycol (PEG) was superior to sucrose as an osmoticum and germination and tube length were significantly improved using PEG 4000 at a concentration of 120 g/l (0.03 M). Equimolar concentrations of PEG 400 and PEG 600 gave inferior results. Combining PEG with sucrose in the medium did not improve germination or increase tube length.     

Microtubules are involved in maintaining the cellular polarity in pollen tubes ofNicotiana sylvestris

Summary The polarity of a growing pollen tube is clearly reflected by a distinct zonation of the cytoplasmic content. The vegetative nucleus and the generative cell (GC) are located in the tip region of the tube, and the basal cytoplasmic portion is highly vacuolated. Using pollen tubes ofNicotiana sylvestris Spegazz. & Comes grown in vitro, we examined the effects of varying concentrations of the microtubule inhibitors colchicine and propham. The depolymerization of the cortical microtubules by 25 M colchicine led to a disorganization of the cytoplasm, i.e., vacuolization of the tip region, and to a deranged position of both the vegetative nucleus and the generative cell. The same concentration of colchicine inhibited tube growth by 10–20% of the control. Mitosis of the GC was not affected. Only from concentrations of 200 M the configuration of the GC's microtubules was altered and an inhibition of mitosis was observed. At this concentration the disorganization of the cytoplasm was always reversible, but neither inhibition of mitosis nor derangement of the nuclear positioning was. At 1,800 M colchicine, pollen tube growth was inhibited by 50% of the control. Using propham, the same three steps of action were observed, although propham proved to be about a hundred times more effective than colchicine. We conclude that the cortical microtubules of the pollen tube are involved in maintaining cellular polarity, probably as a part of a heterogeneous cytoskeletal network including also microfilaments and membranous elements. Nuclear positioning seems to be dependent on both, the tube's cortical and the GC's microtubules. A possible involvement of the extracellular matrix in maintaining intracytoplasmic polarity is suggested.Abbreviations DAPI 4,6-diamidino-2-phenylindole - EGTA ethyleneglycol-bis-(aminoethyl ether) tetraacetic acid - GC generative cell - MF microfilament - MT microtubule - PEM-buffer 50 mM PIPES, 1 mM EGTA, 2 mM MgSO₄, pH 6.9 - PBS phosphate buffered saline - PIPES piperazine-bis-ethanesulphonic acid - PTG-test pollen tube growth test - VN vegetative nucleus Dedicated to Professor Peter Sitte on the occasion of his 65th birthday     

Germination of Pistacia vera L. pollen in liquid medium

Summary The osmotic effect of Polyethylene glycol (PEG) has been shown to be sufficient to induce the germination of Pistacia vera L. pollen in liquid medium. The prehydration of the pollen in a saturated atmosphere for approximately 10 h was necessary to obtain maximum in vitro germination. Imbibition of the pollen in water resulted in the rapid leakage of solutes into the medium. These solutes consisted of approximately 50% carbohydrates, of which sucrose (0.65 mol/mg), glucose (0.77 mol/mg) and fructose (0.78 mol/mg) were the major sugars; the remaining 50% comprised proteins with the following major molecular weights 63 kDa, 60 kDa, 59 kDa, 40 kDa, 36 kDa, 35.5 kDa, 31 kDa, other organic matter and minerals.     

The effect of isolated components of Prunus avium L. styles on in vitro growth of pollen tubes

A number of components isolated from styles of P. avium cv. Napoleon (S ₃ S ₄) have been tested for their capacity to influence in vitro growth of pollen tubes from fresh and stored pollen (cv. Napoleon (S ₃ S ₄)). An antigenic glycoprotein (Antigen S) is a potent inhibitor of in-vitro pollen tube growth, causing a 65% reduction in tube length at a concentration of 20 g/ml. None of the other style components were effective inhibitors of pollen tube growth; neither were proteins of animal origin such as histone, serum albumin, cytochrome C, and the glycoproteins ovalbumin and thyroglobulin, effective inhibitors.     

Regulation der Nucleinsäuren-Synthese durch Polyamine in keimendem Pollen vonPetunia

Summary Putrescine, spermine, spermidine, and agmatine in concentrations between 5–15 g/ml inhibit pollen germination. Whereas spermine reduces pollen tube length, putrecine and agmatine do not affect pollen tube growth. Spermidine effects a small increase (about 5%) of pollen tube elongation. Spermine and spermidine can be found in pollen. Addition of spermine (7 or 10 g/ml) depresses protein synthesis, whilst spermidine does not affect protein synthesis. On the basis of uridine-5-T incorporation it could be shown that both spermine and spermidine increase RNA synthesis. On tho basis of thymidine-T incorporation in the first hpurs of germination it seems that DNA synthesis is also stimulated by spermine and spermidine present in the medium. A net increase of nucleic acids was found when spermidine was added to the germination substrate.These results are interpreted as suggesting that, in the pollen tubes investigated, polyamine concentration may be a factor in the regulation of nucleic acid synthesis, resulting in a prolonged synthesis of specific proteins and in this way influencing growth and the developmental pattern of pollen tubes.     

The effects of a triazole fungicide,propiconazole, on pollen germination,tube growth and cytoskeletal distribution in Tradescantia virginiana

The effects of propiconazole on germination and tube growth of Tradescantia virginiana pollen when incorporated in germination media at 0, 102, 136, or 170 l l^–1 were evaluated using light microscopy and immunocytochemistry. Propiconazole inhibited pollen germination, cytoplasmic streaming, and tube elongation. Treatments also induced abnormal tube morphology and cytoskeletal distribution. Tubes treated with propiconazole displayed weaker microfilament (Mf) signals along the pollen tubes, with amorphous staining. Microtubule (Mt) distribution was also severely affected. In treated tubes, the proximal portions had characteristically fragmented Mts. Fewer Mt bundles were seen in the subapical region, and these were located further from the apex. Propiconazole effects were generally concentration dependent. The results indicate that propiconazole affects both Mfs and Mts; however, the effects may be an indirect result of the drug's influence on membranes.     

The pollen tube: a soft shell with a hard core

Plant cell expansion is controlled by a fine‐tuned balance between intracellular turgor pressure, cell wall loosening and cell wall biosynthesis. To understand these processes, it is important to gain in‐depth knowledge of cell wall mechanics. Pollen tubes are tip‐growing cells that provide an ideal system to study mechanical properties at the single cell level. With the available approaches it was not easy to measure important mechanical parameters of pollen tubes, such as the elasticity of the cell wall. We used a cellular force microscope (CFM) to measure the apparent stiffness of lily pollen tubes. In combination with a mechanical model based on the finite element method (FEM), this allowed us to calculate turgor pressure and cell wall elasticity, which we found to be around 0.3 MPa and 20–90 MPa, respectively. Furthermore, and in contrast to previous reports, we showed that the difference in stiffness between the pollen tube tip and the shank can be explained solely by the geometry of the pollen tube. CFM, in combination with an FEM‐based model, provides a powerful method to evaluate important mechanical parameters of single, growing cells. Our findings indicate that the cell wall of growing pollen tubes has mechanical properties similar to rubber. This suggests that a fully turgid pollen tube is a relatively stiff, yet flexible cell that can react very quickly to obstacles or attractants by adjusting the direction of growth on its way through the female transmitting tissue.     

Enforced growth-rate fluctuation causes pectin ring formation in the cell wall of Lilium longiflorum pollen tubes

Normally growing lily (Lilium longiflorum Thunb.) pollen tubes cultured in standard sucrose medium display a relatively steady tip-growth pattern and a rather even pectin sheath in the cell wall. In an attempt to better understand pulsatory growth, observed in some species, e.g., Petunia, and its possible role in causing the formation of thickened cell wall rings, we have imposed marked fluctuations in the growth-rate of lily pollen tubes. The appropriate growth-perturbing conditions were achieved by modulating the medium osmolarity or by applying caffeine, a non-turgor inhibitor, in a specially designed incubation chamber with a controlled medium flow. The relatively non-esterified pectin deposition in the wall of the growth-interrupted pollen tubes was detected by immunofluorescence microscopy using a monoclonal antibody, JIM 5. The observations show that the periods of slow or inhibited growth correspond to the times when the thickened walls are deposited. Since the growth fluctuations were induced by both turgor- and non-turgor-related means, the proposed endogenous regulatory role of turgor pressure is questioned. Other factors, such as the tip-focused Ca²⁺ gradient which was demonstrated by ratiometric ion imaging, and the alteration in the extensibility of the cell wall, which correlated with pectin esterification/de-esterification, emerge as candidates for the regulation of growth fluctuations.     

Dynamic aspects of apical zonation in the angiosperm pollen tube

Summary In the apical 10–20 m of actively extending pollen tubes of Epilobium angustifolium, in a zone where the polysaccharide-containing wall precursor bodies (P-particles) dominate and where their movements on superficial observation seem to be random, there is in fact a concerted flux, acropetal movement taking place along the flanks of the tip zone, with a basipetal return flow along the centre. Detailed tracking of individuals shows that lipid globuli (diameters up to 1.5 m) and amyloplasts (dimensions up to 5.5 × 2.5 m) follow similar patterns of movement, but are sorted out in the sub-apical region, the smaller bodies penetrating further towards the apex. The findings are interpreted as indicating that the well-documented apical zonation of the pollen tube is maintained in the fluid circumstances of the growing tube by the filtering of cytoplasmic inclusions through the actin cytoskeleton, which, in conformity with recent fine-structural and other observations, is envisaged as consisting of a network of cross-linked microfilaments and microfilament aggregates at the tube tip giving place progressively to a system of more ordered, longitudinally oriented fibrils in the older parts of the tube. The implications for the operation of the actomyosin motility system and the tip growth mechanism are discussed.     

Gradients in water potential and turgor pressure along the translocation pathway during grain filling in normally watered and water-stressed wheat plants

The water relations parameters involved in assimilate flow into developing wheat (Triticum aestivum L.) grains were measured at several points from the flag leaf to the endosperm cavity in normally watered (Psi approximately -0.3 MPa) and water-stressed plants (Psi approximately -2 MPa). These included direct measurement of sieve tube turgor and several independent approaches to the measurement or calculation of water potentials in the peduncle, grain pericarp, and endosperm cavity. Sieve tube turgor measurements, osmotic concentrations, and Psi measurements using dextran microdrops showed good internal consistency (i.e. Psi = Psi(s) + Psi(p)) from 0 to -4 MPa. In normally watered plants, crease pericarp Psi and sieve tube turgor were almost 1 MPa lower than in the peduncle. This suggests a high hydraulic resistance in the sieve tubes connecting the two. However, observations concerning exudation rates indicated a low resistance. In water-stressed plants, peduncle Psi and crease pericarp Psi were similar. In both treatments, there was a variable, approximately 1-MPa drop in turgor pressure between the grain sieve tubes and vascular parenchyma cells. There was little between-treatment difference in endosperm cavity sucrose or osmotic concentrations or in the crease pericarp sucrose pool size. Our results re-emphasize the importance of the sieve tube unloading step in the control of assimilate import.     

Stimulation of growth of culturedNicotiana tabacum W 38 pollen tubes by poly(ethylene glycol) and Cu(II) salts

Summary Growth of pollen tubes ofNicotiana tabacum W 38 in a defined liquid medium buffered at pH 5.9 and containing sucrose, amino-acids, boric acid, salts and an antibacterial agent was stimulated by the addition of poly(ethylene glycol) 6000 (PEG-6000) and Cu_(II) salts. In the absence of both these supplements, up to 50% of the hydrated pollen grains did not develop further, and the germinated tubes were slow-growing and abnormal, with thickened walls, kinked growth, and fragile, swollen tips containing granular cytoplasm. Addition of 10–15% (w/v) purified PEG-6000 increased germination to 80–90% and prevented the progressive bursting of pollen grains and tube tips, but growth was still slow and kinked and tips remained swollen. Addition of 30 M CuSO₄ did not stimulate germination or prevent tip bursting, but produced straight-growing tubes with smooth-sided tips resembling the tips of tubes growing through stylar tissue; the free Cu²⁺ concentration under these conditions was about 1.0 M due to chelation by amino-acids, and similar tube morphologies were obtained with 1.0–1.5 M added CuSO₄ when NH₄Cl replaced the amino-acids. When the medium containing amino-acids was supplemented with both 12.5% PEG-6000 and 30 M CuSO₄, long-term (48 h) growth of straight pollen tubes with smooth-sided tips, thin walls and long ladders of callose plugs was observed; growth occurred at 250 m/h, approximately 30–40% of the rate observed in the style. Although omission of CuSO₄ from this complete medium severely affected tube growth and callose plug deposition, it did not alter the timing of generative-nucleus division, and thus the different parameters associated with the second phase of pollen-tube growth can be uncoupled in culture. High levels of FeSO₄ (300 M) had a similar morphogenetic effect to CuSO₄, but addition of 300 M L-ascorbate or D-iso-ascorbate was required to prevent precipitation of Fe_(III) oxide and prolong the stimulation of pollen-tube growth; EDTA removed the morphogenetic effect of both CuSO₄ and FeSO₄. Further, an impure grade of PEG-4000 was contaminated with an organic morphogen that allowed continued slow growth of pollen tubes with smooth, straight-sided tips in the absence of added CuSO₄ or FeSO₄, with tube morphology unaffected by ascorbate or EDTA. However, the long-term morphogenetic effect of trace levels of CuSO₄ suggests that Cu_(II) salts play an important role in pollen-tube development in at least this species ofNicotiana.Abbreviations A₄₇₅ absorbance at 475 nm - DAPI 4,6-diamidino-2-phenylindole - EDTA ethylene-diamine N,N,N,N-tetraacetic acid - MES 2-(N-morpholino)-ethane sulphonic acid - OG ordinary grade of poly(ethylene glycol) - PEG poly(ethylene glycol) - SP Specially Purified for Biochemistry grade of poly(ethylene glycol)     

Effect of Osmotic Stress on Turgor Pressure in Mung Bean Root Cells

Turgor pressure in cells of the elongating region of intactmung bean roots was directly measured by using the pressure-probetechnique. After the external osmotic pressure had been increasedfrom 0 MPa to 0.5 MPa, turgor pressure rapidly decreased byabout 0.5 MPa from 0.65 MPa to 0.14 MPa and root elongationstopped. Subsequent turgor regulation was clearly confirmed,which followed the osmotic adjustment to maintain a constantdifference in the osmotic pressure between root-cell sap andthe external medium ( II). It took at least 6 h for turgor pressureto recover to an adjusted constant level of about 0.5 MPa dueto turgor regulation, but rootelongation resumed within onlyan hour after the osmotic treatment. Therefore, the resumptionof root elongation under osmotic stress could not have beendirectly connected with turgor regulation. Furthermore, sincethe amounts of decrease in turgor pressure just after applicationsof various degrees of osmotic stress could be interpreted inrelation to those in II, hydraulic conductivity between theinside and the outside of root cells must be large enough toattain water potential equilibrium rapidly in response to osmoticstress. We conclude that turgor pressure in the cells of theelongating region of mung bean roots is determined mainly by II because of water potential equilibrium. (Received January 27, 1987; Accepted May 21, 1987)     

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.