Programmed cell death of Pinus nucellus in response to pollen tube penetration

In ovules of Pinus densiflora, pollen tubes elongate and branch into the nucellar tissue in the direction of the female gametophyte. After pollination, nucellar cells located around the pollen grain and tube die off. We showed here that the nuclei of the nucellar cells were stained by TUNEL (terminal deoxynucleotidyl transferase-mediated dUTP-fluorescein nick end labeling). The number of TUNEL-positive cells increased during pollen tube growth. The tips of pollen tube branches protruded into the nucellar cells to form a convex-concave junction. At this junction, the cell membrane of nucellar cells was separated from the cell wall and the protoplast shrank. Small vesicles and amorphous materials were released from the protoplast into the space between the cell membrane and wall. Vacuoles were collapsed, chromatin was condensed, and mitochondria and plastids were deteriorated in the shrunken protoplast. Agarose gel analysis of DNA isolated from the ovules showed a DNA ladder, suggesting that the nuclear DNA had undergone internucleosomal cleavage. These results suggest that nucellar cells undergo programmed cell death in response to pollen tube penetration with some features resembling apoptosis and other features peculiar to nucellar cells.     

Calcium changes in ovules and embryo sacs of Plumbago zeylanica L.

Calcium was localized in ovules of Plumbago zeylanica from 1 day before anthesis to 3 days after anthesis using potassium antimonate and transmission electron microscopy in pollinated and emasculated flowers. At 1 day before anthesis, embryo sacs (containing an egg cell, a central cell and zero to three accessory cells) appear mature and contain abundant calcium precipitates (ppts), in contrast to nucellar cells. At anthesis, the vacuoles of nucellar cells have enlarged, and micropylar cells, in particular, are heavily labeled with calcium ppts. As pollen tubes elongate through ovular tissues, ppts diminish in ovular cells and become concentrated in the pollen tube cell wall. After fertilization, the calcium ppts sharply diminish in fertilized ovules; in unfertilized ovules, calcium ppts remain abundant up to 3 days after anthesis (when unfertilized ovules are shed). The distribution of calcium in the ovule changes in apparent response to fertilization, suggesting that calcium content may be related to the attraction and receipt of the pollen tube. In contrast with conventionally-organized embryo sacs with synergids, Plumbago accumulates calcium in the egg cell. Received: 30 December 1999 / Revision accepted: 24 March 2000     

CYTOLOGICAL BASIS FOR CYTOPLASMIC INHERITANCE IN PSEUDOTSUGA MENZIESII. I. POLLEN TUBE AND ARCHEGONIAL DEVELOPMENT

Douglas fir (Pseudotsuga menziesii (Mirb.) Franco) ovules were used to study the method of pollen tube formation and penetration of the nucellus, the movement of the body cell down the pollen tube and development of the archegonia. No pollination drop forms but nucellar tip cells produce a minute secretion that may initiate pollen tube formation. Pollen tubes penetrate the nucellus causing degeneration of nucellar cells in contact with the pollen tube tip. The body cell becomes highly lobed and the tube cytoplasm forms thin sheets between the lobes. This may be the mechanism by which the large body cell is pulled down the narrow pollen tube. Body cell plastids and mitochondria remain unaltered during pollen tube growth, whereas tube cell organelles show signs of degeneration. The pollen tube penetrates the megaspore wall and settles in the archegonial chamber. During pollen elongation and pollen tube growth the egg matured. Egg cell plastids were transformed into large inclusions which filled the periphery of the egg while mitochondria migrated to the perinuclear zone. The neck cells, ventral canal cell and archegonial jacket cells are described. The significance of the body cell and egg cell ultrastructure is discussed in light of recent restriction fragment length polymorphism studies of plastid and mitochondrial inheritance in the Pinaceae.     

Changes of calcium distribution in ovules ofTorenia fournieri during pollination and fertilization

Summary Calcium distribution in ovules ofTorenia fournieri was studied by electron energy loss spectroscopy and transmission electron microscopic visualization of calcium antimonate precipitates. High calcium levels were found in the ovules ofT. fournieri. Calcium is situated mainly in extracellular regions before fertilization, including the surface of embryo sac, in the mucilage, and among the cells of the egg apparatus. Intracellular calcium was found only in the nucellar cells around the embryo sac and in the epidermis of the central axis and funiculus. After pollination, a labyrinthine structure (coralloid-like cell wall formation) develops on the micropylar surfaces of the egg apparatus that contain high levels of calcium. Calcium levels increase in the degenerating synergid after the penetration of the pollen tube. Calcium-antimonate precipitates are abundant in vacuoles of the disrupted synergid and pollen tube cytoplasm.Abbreviations EELS electron energy loss spectroscopy - EDX energy-dispersive X-ray microanalysis - LS labyrinthine structure     

Pollen tube reuses intracellular components of nucellar cells undergoing programmed cell death in Pinus densiflora

Through the process known as programmed cell death (PCD), nucelli of Pinus densiflora serve as the transmitting tissue for growth of the pollen tube. We sought to clarify the processes of degradation of nucellar cell components and their transport to the pollen tube during PCD in response to pollen tube penetration of such nucelli. Stimulated by pollination, synthesis of large amounts of starch grains occurred in cells in a wide region of the nucellus, but as the pollen tube penetrated the nucellus, starch grains were degraded in amyloplasts of nucellar cells. In cells undergoing PCD, electron-dense vacuoles with high membrane contrast appeared, assumed a variety of autophagic structures, expanded, and ultimately collapsed and disappeared. Vesicles and electron-dense amorphous materials were released inside the thickened walls of cells undergoing PCD, and those vesicles and materials reaching the pollen tube after passing through the extracellular matrix were taken into the tube by endocytosis. These results show that in PCD of nucellar cells, intracellular materials are degraded in amyloplasts and vacuoles, and some of the degraded material is supplied to the pollen tube by vesicular transport to support tube growth.     

Structural aspects of in vitro pollen tube growth and micropylar penetration inGasteria verrucosa (Mill.) H. Duval andLilium longiflorum Thunb.

Summary In vitro penetration of the micropyle of freshly isolatedGasteria verrucosa ovules by pollen tube was monitored on agar medium. 40–60% of the micropyles were penetrated, comparable with in vivo penetration percentages. When germinated on agar,Gasteria pollen tube elongation lasts for up to 8 h while plasma streaming continues for about 20–24 h. The generative cell divides between 7 and 20 h after germination, and after 20 h the pollen tube arrives at one of the synergids. The sperm cells arrive after 22 h. The whole process takes more time in vitro than in vivo. In fast growing pollen tubes, a pulsed telescope-like growth pattern of tube elongation is observed. The formation of pollen tube wall material precedes tube elongation and probably prevents regular enlargement of the pollen tube tip-zone. Rapid stretching of the new pollen tube wall material follows, probably due to gradually increased osmotic pressure and the use of lateral wall material below the tip. The stretching ceases when the supplies of plasma membrane and excretable wall material are exhausted. Multiple pollen tube penetration of the micropyle occurs in vitro as it does in vivo. Most pollen tube growth ceases within the micropyle but, if it continues, the pollen tubes curl. Inside the micropyle the pollen tube shows haustorial growth. At the ultrastructural level, the wall thickening of in vitro pollen tubes is quite similar to that in vivo. Before transfer of pollen tube cytoplasm a small tube penetrates one of the synergids. Sperm nuclei with condensed chromatin are observed in the pollen tube and the synergid. In vivo prometaphase nuclei are found in the most chalazal part of a synergid, against the egg cell nucleus and nucleus of the central cell at a later stage. Using media forLilium ovule culture,Gasteria ovules were kept alive for at least 6 weeks. Swelling of the ovule depends on pollen tube penetration. The conditions for fertilization to occur after in vitro ovular pollination seem to be present.     

CHEMOTROPIC ACTIVITY AND THE PATHWAY OF THE POLLEN TUBE IN LILY,

A study of the pollen tube pathway in Lilium leucanthum var. centifolium and in L. regale reveals that the entire pathway from stigma to ovule is lined with cytologically unique stigmatoid cells. Assays for chemotropic activity of tissues and exudates along the pathway of pollinated or unpollinated pistils showed that onset of chemotropic activity progressed basipetally (and, when pollinated, in advance of the pollen tubes), commencing at the stigma 3-5 days before anthesis and appearing in the ovules 1-2 days after anthesis. Activity persists about 10 days in ovules of pollinated pistils and for 14-16 days in ovules of non-pollinated pistils. Attempts to localize the source of the chemotropic factor showed that gynoecial tissues bearing stigmatoid cells are chemo-tropically active while slices of style or ovary wall lacking stigmatoid cells are inactive. When ovules were sliced transversely and the micropylar and chalazal halves assayed, only the micropylar half showed activity. We suggest that the ovules and the stigmatoid tissue along the pollen tube pathway are the sources of the chemotropic factor responsible for the directional growth of the pollen tube.     

Nucellar beak structure and pollen tube growth in Cucurbitaceae

The nucellar beak is a proboscis-like outgrowth of the nucellus at the micropylar end, being the obligatory path for the pollen tube entering the ovule. Among the few angiosperm families with nucellar beak, Cucurbitaceae is remarkable because the pollen tube may develop at least two types of growth within the nucellar beak: tubular and ampulliform. Wondering about the possibility that Cucurbitaceae ovules may express some histological variation that could be related to pollen tube growth within the nucellar beak, we performed a compared anatomical and histochemical study of the nucellar beak and the pollen tube growth of ten species of Cucurbitaceae. Results show that Cucurbitaceae ovules are diverse in size and proportions (of integuments, nucellar body, and nucellar beak), and they have at least four types of nucellar beak histology: pectic-tracked, secretory-like, amylaceous, and mixed. Amylaceous and mixed nucellar beaks are related to the ampulliform growth of the pollen tube, which could have appeared independently in most derived tribes of Cucurbitaceae, although information about nucellar beak structure in the basal tribes is still needed. In addition, the understanding of the relation between amylaceous nucellar beaks and the ampulliform growth of the pollen tube, whose function is still to be discovered, might open the possibility of a unique model of pollen tube-ovule co-evolution in angiosperms.     

Effects of ovular secretions on pollen in Pseudotsuga menziesii (Pinaceae)

Effects of ovular secretions on pollen grains were examined in Pseudotsuga menziesii. The exine is cast off in the micropylar canal. A membranelike structure covers parts of pollen grains and appears to protect them. The outer intine consists of fibrous materials, but it also shows a thicker filamentous appearance in some ovules during pollen elongation. The inner intine is electron-dense. Its fibrous nature is occasionally visible. Dissolution of the outer intine varies in amount and manner in ovules from different trees. The plasma membrane near the pollen wall alternatively appears normal and distorted. These different morphologies of the outer intine and of the plasma membrane are considered to result from secretions from the ovule. The outer intine may contain electron-dense globules that are formed in the tube cell and traverse the inner intine. Pollen tube formation appears to be triggered by a secretion from the ovule. Cross-pollinated grains are less distorted compared with self-pollinated grains.     

Cytinus hypocistis L. embryogenesis: Some biological and ultrastructural aspects of fertilization and embryo development

Abstract

The present paper examines some biological and ultrastructural aspects of fertilization and early development of the embryo in Cytinus hypocistis, a parasitic plant belonging to the Rafflesiaceae. The probable functions of a mucilaginous substance contained in the ovary and embedding the numerous pollen tubes coming from the style are discussed.

It was ascertained that pollen tubes pass through the micropyle and enter a synergid pushing, their way through the nucellar cells that show swollen walls owing to a probable enzymatic action whose function is to facilitate pollen tube penetration. It was hypothesized that the secretion of such enzymes is attributable to the numerous pollen present in the ovary or entering the mycropyle.

Since, in all the ovules observed, synergid degeneration was never found before the arrival of the pollen tube, this degeneration was interpreted as being caused by the material disharged by the pollen tube, rather than being an essential prerequisite for pollen tube penetration into the synergid.

Pollen tube content was observed to be made up of an intensely electron-dense substance surrounding many lipidic globules and numerous polysaccharide vesicles that fuse with the pollen tube wall, clearly contributing to its growth.

The sequence of the first divisions of the developing embryo was followed and the extreme reduction of the embryo is confirmed.

In Cytinus hypocistis starch is totally absent from all the sells belonging to the female gamethophyte as well as to those belonging to the embryo, but lipidic globules are very frequent; it is therefore supposed that these bodies constitute good material for the nutrition of the zygote and early embryo.     

Ultrastructural research on cell wall regeneration by cultured pollen protoplasts of Lilium longiflorum

Summary Protoplasts from pollen grains of Lilium longiflorum regenerate amorphous cellulosic cell walls in culture, during which some precursors of cellulose are polymerized, thus producing progressively harder cellulosic cell walls as the period of culture continues. It is presumed that the components of the cell wall regenerated during 1 week in culture differ from those of the intine of the pollen grain wall. The regenerated cell wall is formed by means of large smooth vesicles; in addition, numerous coated vesicles and pits aid in wall regeneration. The pollen tube that germinates from the 8-day-old cultured protoplast has numerous Golgi bodies and many vesicles which build the pollen tube wall. The tube wall has two layers just like a normal pollen tube wall.     

An Ultrastructural Study on Pollen Protoplasts and Pollen Tubes Germinated From Them in Gladiolus gandavensis

Large quantities of protoplasts were isolated enzymatically from the mature pollen grains in Gladiolus gandavensis. Regeneration of cell wall and germination of pollen tubes were performed during culture of purified pollen protoplasts in Ks medium supplemented with 32% sucrose, 0.1 mg/1 2,4-D, 1 mg/1 NAA and 0.2 mg/1 6-BA, with a germination rate up to 47.7%. The materials were fixed gently with gradually increasing concentration of glutaraldehyde, followed by osmium, then preembedded in a thin layer of agar and surveyed under an inverted microscope so as to select desired specimens for subsequent procedure. Small agar blocks containing specimens were dehydrated through ethanal-propylene oxide series, embedded in Araldite and ultratomed. Electron microscopic observations show that the pollen protoplasts are surrounded by a smooth plasma membrane and with ultrastructurally intact cytoplasm, a vegetative nucleus and a generative cell. After 8h of culture, wall regeneration commences resulting in a multilayered, fibrillar wall structure which is different from the intine. No exine is formed. Numerous vesicles participate actively in the wall formation. The wall is uneven in thickness around its periphery; a thickened area somewhat resembling to germ furrow is formed, from which pollen tube emerges. The tubes contain abundant plastids, mitochondria and dictyosomes. Vesicles are released out of the plasma membrane and involved in tube wall formation. After 18h of culture, the vegetative nucleus and generative cell have migrated into the tube. Technical points of preparing pollen protoplast specimens for ultastructural studies and the fearnres of wall regeneration in pollen protoplast culture are discussed.     

Rab11 GTPase-regulated membrane trafficking is crucial for tip-focused pollen tube growth in tobacco

Pollen tube growth is a polarized growth process whereby the tip-growing tubes elongate within the female reproductive tissues to deliver sperm cells to the ovules for fertilization. Efficient and regulated membrane trafficking activity incorporates membrane and deposits cell wall molecules at the tube apex and is believed to underlie rapid and focused growth at the pollen tube tip. Rab GTPases, key regulators of membrane trafficking, are candidates for important roles in regulating pollen tube growth. We show that a green fluorescent protein-tagged Nicotiana tabacum pollen-expressed Rab11b is localized predominantly to an inverted cone-shaped region in the pollen tube tip that is almost exclusively occupied by transport vesicles. Altering Rab11 activity by expressing either a constitutive active or a dominant negative variant of Rab11b in pollen resulted in reduced tube growth rate, meandering pollen tubes, and reduced male fertility. These mutant GTPases also inhibited targeting of exocytic and recycled vesicles to the pollen tube inverted cone region and compromised the delivery of secretory and cell wall proteins to the extracellular matrix. Properly regulated Rab11 GTPase activity is therefore essential for tip-focused membrane trafficking and growth at the pollen tube apex and is pivotal to reproductive success.     

DEVELOPMENT OF THE POLLEN TUBE OF ZAMIA FURFURACEA (ZAMIACEAE) AND ITS EVOLUTIONARY IMPLICATIONS

Compared with pollen tubes of conifers, gnetophytes, and angiosperms, the pollen tube of cycads is exclusively a vegetative structure, uninvolved with the siphonogamous conduction of sperm to an egg. The cycad pollen tube appears to function primarily to obtain nutrients for the extensive growth and development of the male gametophyte. Previous workers have suggested that, similar to an haustorial fungus, the cycad pollen tube penetrates the reproductive tissues of the sporophyte by enzymatically destroying nucellar cells. These earlier studies did not document the precise structural relationship between the growing male gametophyte and its “host” tissue, the nucellus. Pollen tube growth, and its relation to the nucellus, was examined in Zamia furfuracea with light and transmission electron microscopy. Following germination, the pollen tube of Zamia furfuracea grows intercellularly through the subepidermal layers of the micropylar apex of the nucellus. Electron micrographs clearly show additional localized outgrowths of the pollen tube penetrating the walls of individual nucellar cells. Intracellular haustorial growth ultimately leads to the complete destruction of each penetrated cell, and appears to induce the degeneration of proximal unpenetrated nucellar cells. This pattern of intracellular penetration of the sporophyte by the male gametophyte in Zamia furfuracea is fundamentally different from what has been described in any other major group of seed plants (where intercellular growth of the male gametophyte is the rule), and suggests that the heterotrophic and tissue-specific relationships that male gametophytes of seed plants have with their host sporophytes are substantially more diverse than had previously been known.     

Hydration, sporoderm breaking and germination of Cupressus arizonica pollen

I n vitro and in vivo rehydration and germination in Cupressus arizonica pollen were examined using light and scanning electron microscopy. Shed pollen has 12.6% water content, which reduced to 8.2% after dispersal, and this latter pollen survived for some months at room temperature and for years at −10 °C. Rehydration requires breaking of the sporoderm walls and depends on the composition and pH of the rehydration medium. Acidity restrains the breakage, while alkalinity promotes it. Pollen division follows exine shedding and requires the persistence of the mucilaginous layer; hence, pH values countering these outcomes prevent division. Division results in a large and a small cell separated by a callosic wall. A pollen tube develops from the innermost intine of the large cell, which is callosic, and extends into the mucilaginous middle intine. The percentage germination never exceeded 17% in all tested media. In vivo , pollen rehydrates and casts off the exine in the micropylar drop. Drop withdrawal brings pollen to the apical nucellar cells that degenerate in the meantime, and it leaves a deposit on the surface of the micropylar canal. After contaction of the nucellar cells, the pollen flattens and its mucilaginous layer shrinks and disappears. This occurs simultaneously with sealing of the micropylar canal. During this time, pollen divides asymmetrically without the callosic wall, and the larger cell develops a tube in the interface with the nucellus. Only some pollen grains accomplish adhesion to the nucellus and germinate. The in vitro and in vivo developmental stages are discussed.     

Nucellar projection transfer cells in the developing wheat grain

Summary Transfer cells in the nucellar projection of wheat grains at 25 ±3 days after anthesis have been examined using light and electron microscopy. Within the nucellar tissue, a sequential increase in non-polarized wall ingrowth differentiation and cytoplasmic density was evident. Cells located near the pigment strand were the least differentiated. The degree of differentiation increased progressively in cells further removed from the pigment strand and the cells bordering the endosperm cavity had degenerated. Four stages of transfer cell development were identified at the light microscope level. Wall ingrowth differentiation followed a sequence from a papillate form through increased branching (antler-shaped ingrowths) which ultimately anastomosed to form a complex labyrinth. The final stage of wall ingrowth differentiation was compression which resulted in massive ingrowths. In parallel with wall ingrowth deposition cytoplasmic density increased. During wall deposition, paramural and multivesicular bodies were prominent and were in close association with the wall ingrowths. The degeneration phase involved infilling of cytoplasmic islets within the wall ingrowths. This was accompanied by complete loss of the protoplast. The significance of this transfer cell development for sucrose efflux to the endosperm cavity was assessed by computing potential sucrose fluxes across the plasma membrane surface areas of the nucellar projection cells. Transfer cell development amplified the total plasma membrane surface area by 22 fold. The potential sucrose flux, when compared with maximal rates of facilitated membrane transport of sugars, indicated spare capacity for sucrose efflux to the endosperm cavity. Indeed, when the total flux was partitioned between the nucellar projection cells at the three stages of transfer cell development, the fully differentiated stage III cells located proximally to the endosperm cavity alone exhibited spare transport capacity. Stage II cells could accommodate the total rate of sucrose transfer, but stage I cells could not. It is concluded that the nucellar projection tissue of wheat provides a unique opportunity to study transfer cell development and the functional role of these cells in supporting sucrose transport.Abbreviations CSPMSA cross sectional plasma membrane surface area - LPMSA longitudinal plasma membrane surface area - PTS tri-sodium 3-hydroxy-5,8,10-pyrenetrisulfonate     

EMBRYO SAC DEVELOPMENT IN THE CV. KS MALE-STERILE,FEMALE-STERILE LINE OF SOYBEAN (GLYCINE MAX)

Light microscopic observations were made on 22 ovules from fertile plants and 108 ovules from sterile plants of the cv. KS synaptic mutant, a highly male-sterile, female-sterile line of soybean [Glycine max (L.) Merr.] (2n = 2x = 40). Ovules of fertile siblings contained normal embryo sacs and embryos. Ovules from sterile plants contained various irregularities. The most consistent abnormality was the failure of the embryo sac to attain normal size. Small megasporocytes of irregular shape were seen; only one megasporocyte of normal shape and size was noted. No linear tetrads were found. However, two ovules contained nonlinear triads. A range from zero to 28 cells and nuclei, of various sizes, were identifiable in small megagametophytes and embryo sacs. Degeneration of these nuclei and cells was noted as early as the four-nucleate gametophyte stage. Other ovules contained degenerated nucellar centers without embryo sacs. Two ovules appeared to be normal. Late postpollination stages were marked by shrunken nucellus and integuments. The presence of pollen tube traces, endosperm, and aborting embryos in ovules of hand-pollinated flowers from sterile plants suggested that no incompatibility was involved. Degeneration of the gametophyte and embryo sac contents at many developmental stages indicated a wide array of effects, possibly resulting from meiotic irregularities similar to those seen in microsporogenesis of this mutant.     

Some aspects of organization and histochemistry of the embryo sac ofScilla sibirica sato

Summary The present investigation deals with some of the organizational and histochemical aspects of the embryo sac ofScilla sibirica. Both the synergids and egg cell are invested by PAS-positive complete walls. The filiform apparatus comprises an elaborate system of fibrillar projections, showing extensive ramifications. The micropylar region of the embryo sac wall from where the filiform apparatus originates is composed of three distinct layers. On a histochemical basis it may be surmised that, unlike the egg cell, the synergids are metabolically very active. Two kinds of wall ingrowths (i) massive and highly branched very much akin to the filiform apparatus, and (ii) small tuberculate wall projections, are unique to the antipodal cells of S.sibirica. Small tuberculate projections have also been observed along the wall of the central cell adjacent to the nutrient-rich nucellar cells. The antipodals and the central cell show the presence of starch grains and abundant total proteins. All the cell types in the embryo sac ofS. sibirica are structurally so organized as to meet the requirements of its nutrition during pre- and postfertilization development. The presence of abundant PAS-positive granular substance in the cells of nucellar epidermis probably establishes a gradient which assists in the pollen tube growth.     

FURTHER CYTOLOGICAL STUDIES OF A PERIODIC ACID-SCHIFF'S SUBSTANCE IN THE OVULES OF PASPALUM ORBICULARE AND P. LONGIFOLIUM

A periodic acid-Schiff's substance present in the micropylar end of the ovules of Paspalum orbiculare and P. longifolium was further studied by light and electron microscopy of glutaraldehyde-osmium-fixed and freeze-substituted, osmium-fixed tissues. The PAS substance is water soluble and is found in intercellular spaces between the nucellus and inner integument, the inner and outer integuments, the outer integument and ovary wall, and in the micropyle. Structurally the substance consists of fibrils embedded in a dense, amorphous matrix and may be associated with membranous structures in special layers between the plasmalemma and the cell wall in nucellar and integumentary cells. Part of the water soluble substance is believed to be secreted from the nucellar and integumentary cells. A large amount of this substance may be formed as a result of the dissolution of about one third of the distal micopylar portion of the outer integument prior to anthesis. Many of the electron-dense fibrils seem to be fibrillar intercellular substances and others appear to originate from the cell walls, including the cuticle. Both the matrix and the fibrils may be chemically heterogeneous and together form a mucilagenous substance which may facilitate the final growth of pollen tubes in these two species.     

Sucrose synthase is associated with the cell wall of tobacco pollen tubes

Sucrose synthase (Sus; EC 2.4.1.13) is a key enzyme of sucrose metabolism in plant cells, providing carbon for respiration and for the synthesis of cell wall polymers and starch. Since Sus is important for plant cell growth, insights into its structure, localization, and features are useful for defining the relationships between nutrients, growth, and cell morphogenesis. We used the pollen tube of tobacco (Nicotiana tabacum) as a cell model to characterize the main features of Sus with regard to cell growth and cell wall synthesis. Apart from its role during sexual reproduction, the pollen tube is a typical tip-growing cell, and the proper construction of its cell wall is essential for correct shaping and direction of growth. The outer cell wall layer of pollen tubes consists of pectins, but the inner layer is composed of cellulose and callose; both polymers require metabolic precursors in the form of UDP-glucose, which is synthesized by Sus. We identified an 88-kD polypeptide in the soluble, plasma membrane and Golgi fraction of pollen tubes. The protein was also found in association with the cell wall. After purification, the protein showed an enzyme activity similar to that of maize (Zea mays) Sus. Distribution of Sus was affected by brefeldin A and depended on the nutrition status of the pollen tube, because an absence of metabolic sugars in the growth medium caused Sus to distribute differently during tube elongation. Analysis by bidimensional electrophoresis indicated that Sus exists as two isoforms, one of which is phosphorylated and more abundant in the cytoplasm and cell wall and the other of which is not phosphorylated and is specific to the plasma membrane. Results indicate that the protein has a role in the construction of the extracellular matrix and thus in the morphogenesis of pollen tubes.