The microsporidian spore invasion tube. III. Tube extrusion and assembly

The polar filaments within microsporidian spores discharges as tubes with subsecond velocity. Populations of discharging tubes of Glugea hertwigi spores pulse-labeled with latex particles for 1-3 s were consistently devoid of label at the distal ends; discharging tubes were completely labeled after 30- to 60-s exposure to latex. This experiment indicates that discharge tubes grow at the tip. Completely assembled discharge tubes consisted of single, empty cylinders; however, incompletely discharged tubes had a cylinder-within-a-cylinder profile at the distal ends. This observation indicates that the discharge tube material emerges at the distal end by an eversion process. Finally, studies with cinematic Nomarski interference optics of spore tubes extruding across a water-air interphase indicate that all the material emerging from the growing tip of the tube is incorporated into the wall of the discharge tube. Evidence indicates that the polar filament of undischarged spores is a homogeneous coil of polar tube protein equivalent to the polar tube protein in discharged tubes.     

Circular F-actin bundles and a G-actin gradient in pollen and pollen tubes of Lilium davidii

The distribution of and relationship between F-actin and G-actin were investigated in pollen grains and pollen tubes of Lilium davidii Duch. using a confocal laser scanning microscope after fluorescence and immunofluorescence labeling. Circular F-actin bundles were found to be the main form of microfilament cytoskeleton in pollen grains and pollen tubes. Consistent with cytoplasmic streaming in pollen tubes, there were no obvious F-actin bundles in the 10- to 20-microm tip region of long pollen tubes, only a few short F-actin fragments. Labeling with fluorescein isothiocyanate (FITC)-DNase I at first established the presence of a tip-focused gradient of intracellular G-actin concentration at the extreme apex of the tube, the concentration of G-actin being about twice as high in the 10- to 20-microm region of the tip as in other regions of the pollen tube. We also found that the distribution of G-actin was related negatively to that of the F-actin in pollen tubes of L. davidii. Caffeine treatment caused the G-actin tip-focused gradient to disappear, and F-actin to extend into the pollen tube tip. Based on these results, we speculate that the circular F-actin bundles may be the track for bidirectional cytoplasmic streaming in pollen tubes, and that in the pollen tube tip most of the F-actin is depolymerized into G-actin, leading to the absence of F-actin bundles in this region.     

Microtubules and microfilaments are both responsible for pollen tube elongation in the coniferPicea abies (Norway spruce)

Summary InPicea abies (Norway spruce), microtubules and actin microfllaments both form a dense matrix throughout the tube mainly parallel to the direction of elongation. In these conifer pollen tubes the organization of this matrix is different from that in angiosperms. This study tests our hypothesis that differences in cytoskeletal organization are responsible for differences in tube growth and physiology. Pollen grains were germinated in media containing cytoskeletal disrupters and analyzed for germination, tube length, tube branching, and tip swelling. Disruption of microtubules significantly inhibits tube elongation and induces tube branching and tip swelling. Tip swelling is probably caused by disruption of the microtubules in the tip that are perpendicular to the direction of elongation. Confocal microscopy indicates that colchicine and propyzamide cause fragmentation of microtubules throughout the tube. Oryzalin and amiprophosmethyl cause a complete loss of microtubules from the tip back toward the tube midpoint but leave microtubules intact from the midpoint back to the grain. Disruption of microfilaments by cytochalasins B and D and inhibition of myosin by N-ethylmaleimide or 2,3-butanedione monoxime stops tube growth and inhibits germination. Microfilament disruption induces short branches in tubes, probably originating from defective microfilament organization behind the tip. In addition, confocal microscopy coupled with microinjection of fluorescein-labeled phalloidin into actively growing pollen tubes indicates that microfllament bundles extend into the plastid-free zone at the tip but are specifically excluded from the growing tip. We conclude that microtubules and microfilaments coordinate to drive tip extension in conifer pollen tubes in a model that differs from angiosperms.     

Calcium channel blocker and calmodulin antagonists affect the gradient of free calcium ions in lily pollen tubes.

The distribution of intracellular free calcium ions ([Ca2+]i) was measured in pollen tubes of Lilium longiflorum using video imaging microscopy and the calcium sensitive indicators fura-2 and quin-2. The mean [Ca2+]i in growing pollen tubes measured with fura-2 shows a maximum of 1.7 to 2.6 microM in the tube tip and decreases almost exponentially to 60 to 100 nM at 100 microns behind the tip. Using quin-2, the maximum [Ca2+]i was also found in the tube tip but with a lower Ca2+ concentration, namely 1 microM. Addition of the calcium channel blocker La3+ caused a decrease of the [Ca2+]i maximum in the tube tip, indicating a heterogeneous distribution of Ca2+ channels along the plasma membrane of pollen tubes. The [Ca2+]i increased after addition of vanadate or compound 48/80. This suggests an involvement of a calmodulin-dependent Ca2+ pump in generation of the Ca2+ gradient in lily pollen tubes. The high [Ca2+]i found in the tube tip with fura-2 seems to indicate the real Ca2+ concentration and is probably responsible for vesicle fusion, fragmentation of actin filaments, and inhibition of cytoplasmic streaming.     

Development and cellular organization ofPinus sylvesfris pollen tubes

The organization ofPinus sylvestris pollen tubes during growth was studied by video microscopy of living cells and by electron microscopy after freeze-fixation and freeze-substitution (FF-FS). Pollen germinated and the tubes grew slowly for a total period of about 7 days. Some of the grains formed two tubes, while 10–50% of the tubes ramified. These features are in accordance with development in vivo. The cytoplasmic hyaline cap at the tip disappeared during the 2nd or 3rd day of culture. Aggregates of starch grains progressively migrated from the grain into the tube and later into the branches. Vacuoles first appeared at day 2 and eventually filled large parts of the tube. The tube nucleus was located at variable distances from the tip. Some of the organelles showed linear movements in a mostly circulatory pattern, but the majority of the organelles showed brownian-like movements. Rhodamine-phalloidin-stained actin filaments had a gross axial orientation and were found throughout the tube including at the tip. The ultrastructure of pollen tubes was well preserved after FF-FS, but signs of shrinkage were visible. The secretory vesicles in growing tips were not organized in a vesicle cone, and coated pits had a low density with only local accumulations, which is in accordance with slow growth. The mitochondria contained small cristae and a darkly stained matrix and were located more towards the periphery of the tube, indicating low respiratory activity and low oxygen levels. The dictyosomes carried typical trans-Golgi networks, but some contained less than the normal number of cisternae. Other elements of the cytoplasm were irregularly spaced rough endoplasmic reticulum, many multivesicular bodies, lipid droplets and two types of vacuoles. The typical organization associated with tip growth in angiosperm pollen tubes, e.g.Nicotiana tabacum, was not present inP. sylvestris pollen tubes. The different morphology may relate to the growth rate and not to the type of growth.     

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     

KINKY POLLEN encodes a SABRE-like protein required for tip growth in Arabidopsis and conserved among eukaryotes

In higher plants, pollen tubes and root hairs share an ancient growth process named tip growth. We have isolated three allelic Arabidopsis mutant lines showing kinky-shaped pollen tubes and, when homozygous, showing shorter and thicker root hairs. The ultrastructure of pollen tubes in these kinky pollen (kip) mutants is similar to that of the wild type; however, time-lapse studies suggest that aberrant pollen tube shape is caused by periodic growth arrests alternated with phases of tube axis reorientation. The KIP gene encodes a protein of 2587 amino acids that is predicted to be targeted to the secretory pathway. KIP mRNA was detected in all organs investigated but was most abundant in pollen and roots. KIP has putative homologues in many eukaryotes, including mammals and yeast, and is similar to the Arabidopsis SABRE gene, whose mutation causes a dwarf phenotype. The phenotype of the kip/sab double mutant suggests related functions for both genes, however, the KIP protein is mostly required for tip-growth.     

ROP GTPase regulation of pollen tube growth through the dynamics of tip-localized F-actin

Pollen tubes expand by tip growth and extend directionally toward the ovule to deliver sperms during pollination. They provide an excellent model system for the study of cell polarity control and tip growth, because they grow into uniformly shaped cylindrical cells in culture. Mechanisms underlying tip growth are poorly understood in pollen tubes. It has been demonstrated that ROP1, a pollen-specific member of the plant-specific Rop subfamily of Rho GTPases, is a central regulator of pollen tube tip growth. Recent studies in pollen from Arabidopsis and other species have revealed a ROP-mediated signalling network that is localized to the apical PM region of pollen tubes. The results provide evidence that the localization of this signalling network establishes the site for tip growth and the localized activation of this signalling network regulates the dynamics of tip F-actin. These results have shown that the ROP1-mediated dynamics of tip F-actin is a key cellular mechanism behind tip growth in pollen tubes. Current understanding of the molecular basis for the regulation of the tip actin dynamics will be discussed.     

Endocytotic uptake of fluorescent dextrans by pollen tubes grown in vitro

Summary Pollen tubes grow by tip growth, with high levels of exocytosis at the apex. The commercial availability of FITC labelled -linked dextrans provides a source of biologically inert tracers for endocytotic activity in pollen tubes. Growing tubes ofNicotiana andTradescantia were transferred to media containing 1% FD-4 for varying period of time before washing in control media and observation in a fluorescence microscope. Fluorescent material appeared to enter the pollen tubes only at the tip region, and to accumulate in vacuoles, starting with smaller vacuoles near the tip and spreading to the main vacuolated part of the tube. Mature tubes, with callose plugs, were only labelled up to the first complete plug from the tip, younger tubes without plugs were labelled into the pollen grain vacuole. The fluorescent material within the pollen tubes was shown to represent uptake of intact high molecular weight dextran by the following criteria: (i) free FITC and low molecular weight dextrans could not be detected in any of the media or pollen tubes using thin layer chromatography and (ii) pollen tube growth rates were unaffected by the fluorescent dextran, but were severely inhibited by low levels of free FITC. It was concluded that the dextrans entered the tubes by endocytosis, possibly in the tip region, and were then transferred to the vacuole system of the pollen tube.Abbreviations FITC fluorescein isothiocyanate - FD fluorescent dextran     

Involvement of the ubiquitin/proteasome pathway in the organisation and polarised growth of kiwifruit pollen tubes

We recently reported the involvement of the ubiquitin pathway in microgametophyte development, and a direct role for the 26S proteasome in regulating pollen tube emergence in kiwifruit. Here we show that the ubiquitin/proteasome proteolytic pathway is involved not only in early kiwifruit pollen tube organisation, but also in maintaining polarised growth of tubes. By immunofluorescence analysis we show that ubiquitin and ubiquitin-protein conjugates are distributed mainly at the apex of emerging tubes, in both untreated pollen grains and pollen grains treated with MG132, an inhibitor of proteasome function. In the latter case, polysiphonous germination occurred and all the emerging areas were highly fluorescent. By adding MG132 to pollen when normal tube growth had already been established, accumulation of ubiquitin-protein conjugates, as well as a drastic reduction in tube growth and dramatic modifications of tube tip morphology were observed. Significantly, differential interference contrast microscopy analysis demonstrated that the clear zone was largely reduced or absent, and the nuclei were disconnected in their movements, reaching, in some cases, the extreme apex of the tip. These findings provide evidence that the ubiquitin- and proteasome-dependent proteolytic system could modulate the abundance and/or activity of key regulatory proteins involved in pollen tube emergence and polarised growth.     

Arabidopsis pollen-specific glycerophosphodiester phosphodiesterase-like genes are essential for pollen tube tip growth

In angiosperms, pollen tube growth is critical for double fertilization and seed formation. Many of the factors involved in pollen tube tip growth are unknown. Here, we report the roles of pollen-specific GLYCEROPHOSPHODIESTER PHOSPHODIESTERASE-LIKE (GDPD-LIKE) genes in pollen tube tip growth. Arabidopsis thaliana GDPD-LIKE6 (AtGDPDL6) and AtGDPDL7 were specifically expressed in mature pollen grains and pollen tubes and green fluorescent protein (GFP)-AtGDPDL6 and GFP-AtGDPDL7 fusion proteins were enriched at the plasma membrane at the apex of forming pollen tubes. Atgdpdl6 Atgdpdl7 double mutants displayed severe sterility that was rescued by genetic complementation with AtGDPDL6 or AtGDPDL7. This sterility was associated with defective male gametophytic transmission. Atgdpdl6 Atgdpdl7 pollen tubes burst immediately after initiation of pollen germination in vitro and in vivo, consistent with the thin and fragile walls in their tips. Cellulose deposition was greatly reduced along the mutant pollen tube tip walls, and the localization of pollen-specific CELLULOSE SYNTHASE-LIKE D1 (CSLD1) and CSLD4 was impaired to the apex of mutant pollen tubes. A rice pollen-specific GDPD-LIKE protein also contributed to pollen tube tip growth, suggesting that members of this family have conserved functions in angiosperms. Thus, pollen-specific GDPD-LIKEs mediate pollen tube tip growth, possibly by modulating cellulose deposition in pollen tube walls.     

Nitric oxide is involved in growth regulation and re-orientation of pollen tubes

Nitric oxide (NO) controls diverse functions in many cells and organs of animals. It is also produced in plants and has a variety of effects, but little is known about their underlying mechanisms. In the present study, we have discovered a role for NO in the regulation of pollen tube growth, a fast tip-growing cellular system. Pollen tubes must be precisely oriented inside the anatomically complex female ovary in order to deliver sperm. We hypothesized that NO could play a role in this guidance and tested this hypothesis by challenging the growth of pollen tubes with an external NO point source. When a critical concentration was sensed, the growth rate was reduced and the growth axis underwent a subsequent sharp reorientation, after which normal growth was attained. This response was abrogated in the presence of the NO scavenger CPTIO and affected by drugs interfering in the cGMP signaling pathway. The sensitivity threshold of the response was significantly augmented by sildenafil citrate (SC), an inhibitor of cGMP-specific phosphodiesterases in animals. NO distribution inside pollen tubes was investigated using DAF2-DA and was shown to occur mostly in peroxisomes. Peroxisomes are normally excluded from the tip of pollen tubes and little if any NO is found in the cytosol of that region. Our data indicate that the rate and orientation of pollen tube growth is regulated by NO levels at the pollen tube tip and suggest that this NO function is mediated by cGMP.     

A compartmental model analysis of integrative and self-regulatory ion dynamics in pollen tube growth

Sexual reproduction in higher plants relies upon the polarised growth of pollen tubes. The growth-site at the pollen tube tip responds to signalling processes to successfully steer the tube to an ovule. Essential features of pollen tube growth are polarisation of ion fluxes, intracellular ion gradients, and oscillating dynamics. However, little is known about how these features are generated and how they are causally related. We propose that ion dynamics in biological systems should be studied in an integrative and self-regulatory way. Here we have developed a two-compartment model by integrating major ion transporters at both the tip and shank of pollen tubes. We demonstrate that the physiological features of polarised growth in the pollen tube can be explained by the localised distribution of transporters at the tip and shank. Model analysis reveals that the tip and shank compartments integrate into a self-regulatory dynamic system, however the oscillatory dynamics at the tip do not play an important role in maintaining ion gradients. Furthermore, an electric current travelling along the pollen tube contributes to the regulation of ion dynamics. Two candidate mechanisms for growth-induced oscillations are proposed: the transition of tip membrane into shank membrane, and growth-induced changes in kinetic parameters of ion transporters. The methodology and principles developed here are applicable to the study of ion dynamics and their interactions with other functional modules in any plant cellular system.     

Calcium accumulations within the growing tips of pollen tubes

Pollen of L. longiflorum was grown in 45Ca-labeled medium and washed with nonradioactive medium. Whole, labeled pollen was then frozen and autoradiographed at -78 degrees C. The autoradiographs show striking accumulations of 45Ca in the growing tips of the pollen tubes. This result is obtained when the pollen is labeled for times as short as 1 min, or as long as 5 h. In most cases, the tip concentration is about two to four times greater than that in the bulk of the pollen tube, and extends for a length of about 20 mum. In autoradiographs of tubes longer than 1 mm, a small fraction of cells show a distinctly larger 45Ca accumulation, the tip containing more than 100 times that in the rest of the cell. The 1- to 5-h labeling experiments show that calcium is relatively concentrated within the cytoplasm of the growing tip. The 1- to 3-min labeling experiments suggest that calcium may enter the tip faster than it enters other regions. These patterns of calcium accumulation and flux may be related to the localized secretion of vesicles at the grow;ng tip.     

Randomised comparison of percutaneous endoscopic gastrostomy and nasogastric tube feeding in patients with persisting neurological dysphagia.

OBJECTIVE--To compare percutaneous endoscopic gastrostomy and nasogastric tube feeding in patients with persisting neurological dysphagia. DESIGN--Randomised 28 day study of inpatients requiring long term enteral nutrition. SETTING--Three Glasgow teaching hospitals. SUBJECTS--40 patients with dysphagia for at least four weeks secondary to neurological disorders: 20 patients (10 women) were randomised to nasogastric feeding and 20 (eight women) to endoscopic gastrostomy. MAIN OUTCOME MEASURES--Treatment failure (blocked or displaced tubes on three or more occasions or refusal to continue treatment); duration of feeding; intake of liquid diets; complications; nutritional status at end of trial. RESULTS--One patient in each group died before starting feeding. Treatment failure occurred in 18 of the 19 nasogastric patients and in none of the gastrostomy group. The mean (SE) duration of feeding for the nasogastric group was 5.2 (1.5) days. No complications occurred in the nasogastric group but three (16%) of the gastrostomy group developed minor problems (aspiration pneumonia (two patients) wound infection (one)). Gastrostomy patients received a significantly greater proportion of their prescribed feed (93% (2%)) compared with the nasogastric group, (55% (4%); p less than 0.001) and also gained significantly more weight after seven days of feeding (1.4 (0.5) kg v 0.6 (0.1) kg; p less than 0.05). Analyses at days 14, 21, and 28 were not possible due to the small numbers remaining in the nasogastric group. CONCLUSION--Percutaneous endoscopic gastrostomy tube feeding is a safe and effective method of providing long term enteral nutrition to patients with neurological dysphagia and offers important advantages over nasogastric tube feeding.     

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.     

Cytoskeleton in Pollen and Pollen Tubes of Ginkgo biloba L.

The distribution of F-actin and microtubules was investigated in pollen and pollen tubes of Ginkgo biloba L. using a confocal laser scanning microscope after fluorescence and immunofluorescence labeling. A dense F-actin network was found in hydrated Ginkgo pollen. When Ginkgo pollen was germinating,F-actin mesh was found under the plasma membrane from which the pollen tube would emerge. After pollen germination, F-actin bundles were distributed axially in long pollen tubes of G. biloba. Thick F-actin bundles and network were found in the tip of the Ginkgo pollen tube, which is opposite to the results reported for the pollen tubes of some angiosperms and conifers. In addition, a few circular F-actin bundles were found in Ginkgo pollen tubes. Using immunofluorescence labeling, a dense microtubule network was found in hydrated Ginkgo pollen under confocal microscope. In the Ginkgo pollen tube, the microtubules were distributed along the longitudinal axis and extended to the tip. These results suggest that the cytoskeleton may have an essential role in the germination of Ginkgo pollen and tube growth.     

Rop1Ps promote actin cytoskeleton dynamics and control the tip growth of lily pollen tube

Rop, the small GTPase of the Rho family in plants, is believed to exert molecular control over dynamic changes in the actin cytoskeleton that affect pollen tube elongation characteristics. In the present study, microinjection of Rop1Ps was used to investigate its effects on tip growth and evidence of interaction with the actin cytoskeleton in lily pollen tubes. Microinjected wild type WT-Rop1Ps accelerated pollen tube elongation and induced actin bundles to form in the very tip region. In contrast, microinjected dominant negative DN-rop1Ps had no apparent effect on pollen tube growth or microfilament organization, whereas microinjection of constitutively active CA-rop1Ps induced depolarized growth and abnormal pollen tubes in which long actin bundles in the shank of the tube were distorted. Injection of phalloidin, a potent F-actin stabilizer that inhibits dynamic changes in the actin cytoskeleton, prevented abnormal growth of the tubes and suppressed formation of distorted actin bundles. These results indicate that Rop1Ps exert control over important aspects of tip morphology involving dynamics of the actin cytoskeleton that affect pollen tube elongation. Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.     

Pollen tubes of flavonol-deficient Petunia show striking alterations in wall structure leading to tube disruption

Despite the vital role that flavonols play in fertilization and pollen tube growth of a number of species such as petunia and maize, their function is still unclear. Pollen tubes of the flavonol-deficient transformant T17.02 of Petunia hybrida L. are able to germinate and start growing in vitro, but eventually disrupt at the tip approximately 2 h after germination. In order to establish the possible role of flavonols in this process, wild-type and flavonol-deficient pollen tubes were subjected to cytological and ultrastructural analyses and screened for differences. The results showed that before disruption of the flavonol-deficient pollen tubes, the structure of the primary wall at the tip dramatically changed from layered to granular. Secretory vesicles at the tip still fused with the wall but lost their capacity to melt into the wall and to form layers. Instead they remained as dark, electron-dense granular structures surrounded by an electron-translucent matrix. Apparently the matrix is not able to sustain the wall's coherence and as a consequence the tube disrupts. No other remarkable cytological or ultrastructural differences between the transformant and the wild-type pollen tubes could be found before tip disruption. Even a morphometric analysis of abundance and distribution of endoplasmic reticulum, dictyosomes and mitochondria did not reveal any significant difference. However, for the first time, obvious morphological differences were observed in the wall of the flavonol-deficient pollen tubes. We conclude that flavonols act on precursors of the pollen tube wall of petunia and interfere with a cross-linking system in the wall, possibly via extensins. Received: 23 February 1998 / Accepted: 13 August 1998