Developmental Assessment of Sexual Reproduction inButomus umbellatus(Butomaceae): Female Reproductive Component

Flowering plants often produce ovules that do not develop intoseeds. Lack of pollination, insufficient resources, environmentalconstraints and incompatibility reactions are often consideredto be causal factors. Pre-pollination and post-fertilizationdevelopmental irregularities (DI) are less commonly implicatedas causal factors, usually because information on them is limited.The results of a detailed developmental assessment of sexualreproduction inB. umbellatususing self- and cross-pollinatedglasshouse and open-pollinated field-grown plants, reveal ahigh degree of pre-pollination and post-fertilization DI. Pre-pollinationDI account for a large fraction of the species' low reproductivepotential. Post-fertilization DI represent another crucial reductionin the species' reproductive output. Seed set inB. umbellatusisless than 1%. In the female reproductive component, these DIinclude embryo sacs with hypertrophied or highly vacuolate eggs,collapsed synergids, collapsed egg apparati and embryo sacsthat are empty, uninucleate or with disorganized mass of nuclei;there are also ovules with no embryo sacs. Post-fertilizationDI include zygotes that are hypertrophied, highly vacuolateand collapsed, and malformed embryos. The lack of an obviousadaptive significance to the array of DI inB. umbellatussuggeststhat these are unlikely to be due to self-incompatibility reactions,and physiological or environmental constraints. SinceB. umbellatusisa long-lived species, it is highly possible that disadvantageousmutations have accumulated in its clonal lineages causing aconsiderable load in terms of faulty meiosis resulting in defectivemeiotic products, a series of DI, and therefore, limited sexualreproduction. Butomus umbellatus; flowering rush; sexual reproduction; developmental assessment; developmental irregularities; abnormal embryo sacs; CLSM     

Pistil Structure and Pollen Tube Pathways in Leptospermum myrsinoides and L. continentale (Myrtaceae)

Pistil structure and pollen tube growth were investigated inLeptospermum myrsinoides and L. continentale (Myrtaceae). BothL. myrsinoides and L. continentale pistils consist of an ovarywith five locules, a style and a five-lobed dry, papillate stigma.A centrally located stigmatic cleft is present but extends onlyto the base of the stigma. Pollen germinates and grows intercellularlythrough the stigma into the central transmitting tissue of thestyle. Pollen tubes do not grow down the stigmatic cleft. Atthe base of the style the transmitting tissue separates intofive, each tract leading through the placenta to one of thefive locules. The pollen tubes continue to grow intercellularlythrough these five tracts entering the locules between the lobesof the placenta. Pollen tubes are smooth-walled and straightwhilst in the transmitting tissue of the style but produce shortlateral branches at regular intervals when in the locules. Branchingcontinues until pollen tubes enter ovules. It is suggested thatthe observed branching in the locules is a result of pollentubes following a chemotropic or thigmotropic pathway to theovules. This behaviour was consistent in all pistils examinedand no difference was observed in the behaviour of self- orcross-pollen tubes in the style or ovary.Copyright 1994, 1999Academic Press Leptospermum myrsinoides Schldl., Leptospermum continentale J. Thompson, pistil structure, pollen tube pathway, pollen tube branching     

Genetic Variation in Sorghum for the Inhibition of Maize Pollen Tube Growth

Aniline blue fluorescence was used to study the growth of maizepollen tubes in the stigmas of 13 diverse sorghum accessions.In 12, only short maize pollen tubes were formed, but in thesingle exception (Sorghum nervosum Nr481) maize pollen tubesgrew at least as far as the base of the style. The S. bicolorgenotypes S9B and CMS (a cytoplasmic male sterile line) werehybridized with Nr481, and analysis of maize pollen tube growthin F₁ plants, and BC₁ plants using Nr481 as the recurrent parent,suggested that differences in inhibition of pollen tube growthwere due to variation at a single locus, which we propose todesignate lap (Inhibition of alien pollen tubes). AccessionNr481 appears to be homozygous for a recessive allele permittingmaize pollen tube growth. Attempts were made to produce sorghumx maize hybrids using Nr481 and CMS derivatives which were knownto allow maize pollen tube growth to the base of the style.A putative hybrid endosperm was obtained in one Nr481 x Seneca60 maize cross, but this was not repeatable and no hybrid plantswere produced. A fundamental problem may be the large size ofthe maize pollen tube, which could have difficulty growing throughthe sorghum ovary and in entering the micropyle. Sorghum bicolor spp. bicolor (L.) Moench, Zea mays L, sorghum, maize, pollen tube growth, hybridization barriers     

Tubulin and Male-gamete Interconnections in the Pollen Tubes of the Grass Alopecurus pratensis

Tubulin was localized in pollen tubes of the grass Alopecuruspratensis by immunofluorescence using a rat monoclonal yeastantitubulin as a primary antibody. In tubes fixed in activegrowth with paraformaldehyde fixative and permeabilized withdetergent, the two male gametes were found to be linked by tubulin-containingcytoplasmic bridges. The connections appeared to persist throughoutthe growth of the tube, but they were highly mutable, the distancebetween the gamete pair varying greatly, the gametes sometimesactually overlapping in the tube. Systems of longitudinally disposed, discrete microtubule strandscomparable with those seen in generative cells of species withbicellular pollen grains were not observed in the gametes. However,an envelope of antitubulin-binding material was apparent atthe cell boundary in many instances, possibly to be interpretedas a sheath of closely packed microtubules seen in profile.Irregular masses, probably representing pools of unpolymerizedor partly polymerized tubulin, were also present in most ofthe gametes. Alopecurus pratensis, tubulin, pollen tubes, grass male gametes     

Pollen tube growth: where does the energy come from?

This review focuses on the energy metabolism during pollen maturation and tube growth and updates current knowledge. Pollen tube growth is essential for male reproductive success and extremely fast. Therefore, pollen development and tube growth are high energy-demanding processes. During the last years, various publications (including research papers and reviews) emphasize the importance of mitochondrial respiration and fermentation during male gametogenesis and pollen tube elongation. These pathways obviously contribute to satisfy the high energy demand, and there are many studies which suggest that respiration and fermentation are the only pathways to generate the needed energy. Here, we review data which show for the first time that in addition plastidial glycolysis and the balancing of the ATP/NAD(P)H ratio (by malate valves and NAD⁺ biosynthesis) contribute to satisfy the energy demand during pollen development. Although the importance of energy generation by plastids was discounted during the last years (possibly due to the controversial opinion about their existence in pollen grains and pollen tubes), the available data underline their prime role during pollen maturation and tube growth.     

Growth and development of conifer pollen tubes

Conifer pollen tubes are an important but underused experimental system in plant biology. They represent a major evolutionary step in male gametophyte development as an intermediate form between the haustorial pollen tubes of cycads and Ginkgo and the structurally reduced and faster growing pollen tubes of flowering plants. Conifer pollen grains are available in large quantities, most can be stored for several years, and they grow very well in culture. The study of pollen tube growth and development furthers our understanding of conifer reproduction and contributes towards our ability to improve on their productivity. This review covers taxonomy and morphology to cell, developmental, and molecular biology. It explores recent advances in research on conifer pollen and pollen tubes in vivo, focusing on pollen wall structure, male gametophyte development within the pollen wall, pollination mechanisms, pollen tube growth and development, and programmed cell death. It also explores recent research in vitro, including the cellular mechanisms underlying pollen tube elongation, in vitro fertilization, genetic transformation and gene expression, and pine pollen tube proteomics. With the ongoing sequencing of the Pinus taeda genome in several labs, we expect the use of conifer pollen tubes as an experimental system to increase in the next decade.     

Haustorial Role of Pollen Tubes

In angiosperms, the pollen tube is siphonogamous and its mainfunction is to carry the male gametes for double fertilization.In some taxa, as in Cucurbitaceae, the tube branches after enteringthe ovule, prior to fertilization. The tube may even swell andform a bulla. During post-fertilization development of the ovule,a portion of the tube may persist in the micropyle, or in theembryo sac, or in both, sometimes even in the micropyle of themature seed. Haustorial function has been presumed in a numberof taxa. In Grevillea, following fertilization, the pollen tube branchesat the micropyle, and the branches grow intercellularly intothe ovarian tissue where further branching occurs. A haustorialrole of the pollen tube is presumed from circumstantial evidence.In gymnosperms (for example, Cycas, Zamia and Ginkgo) the pollentube is nonsiphonogamous, arises from the distal (upper) poleof pollen grain, and grows laterally in the apical region ofthe nucellus. The tube branches in Cycas and Ginkgo but remainsunbranched in Zamia. These pollen tube branches are enucleate,and are not concerned with the transport of male gametes forfertilization. However, the haustorial role has been well documented.In Podocarpus, the pollen tube is siphonogamous and arises fromthe proximal (lower) pole of pollen grain. After traversingthe nucellus, the tube forms a bulla at the point of contactwith the female gametophyte, and several branches originatefrom the bulla. The pollen tube branches grow along the innersurface of the nucellus and the outer surface of the femalegametophyte. The haustorial role of the pollen tube branchesis uncertain. Procedures for convincingly demonstrating thehaustorial role of pollen tubes are discussed. Angiosperms, gymnosperms, pollen tube, bulla, fertilization, haustorial role     

Effects of forest fragmentation on male and female reproductive success in<Emphasis Type="Italic"> Cestrum parqui</Emphasis> (Solanaceae)

In this paper we evaluate the effects of forest fragmentation on male (pollen removal, pollen load, and pollen tubes) and female reproductive success (fruit- and seed-set) of Cestrum parqui, a self-incompatible, pollination-specialist plant species. We also measure focal individual conspecific density to account for possible density-related effects that could influence the response variables. We calculate an index which incorporates male and female fitness and gives an integrated assessment of overall reproductive success. Forest fragmentation strongly affected the amount of pollen grains on stigmas and number of pollen tubes as well as seed-set, decreasing from continuous forest to small forest fragments, whereas focal individual conspecific density failed to explain any of the variability for the studied variables. Declines in overall reproductive success (i.e. male and female) in small forest fragments are ascribed to decreases in both the quality and quantity of pollination. Self-incompatibility coupled with a specialist pollination system may be particularly important traits determining the negative fragmentation effects observed in C. parqui. Logarithmic regression models described the behaviour of the variables along the fragmentation size gradient, allowing us to detect a threshold below which the effects of fragmentation begin to negatively affect reproductive success in C. parqui. Our results emphasize the importance of evaluating both components of the total plant fitness, as well as including simultaneously several aspects of pollination and reproduction processes when assessing the effects of forest fragmentation on plant reproductive success.     

Boron deficiency alters cytosolic Ca2+ concentration and affects the cell wall components of pollen tubes in Malus domestica

• Boron (B) is essential for normal plant growth, including pollen tube growth. B deficiency influences various physiological and metabolic processes in plants. However, the underlying mechanism of B deficiency in pollen tube growth is not sufficiently understood. In the present research, the influence of B deficiency on apple (Malus domestica) pollen tube growth was studied and the possible regulatory mechanism evaluated.
• Apple pollen grains were cultured under different concentrations of B. Scanning ion‐selective electrode technique, fluorescence labelling and Fourier‐transform infrared (FTIR) analysis were used to detect calcium ion flux, cytosolic Ca²⁺ concentration ([Ca²⁺]cyt), actin filaments and cell wall components of pollen tubes.
• B deficiency inhibited apple pollen germination and induced retardation of tube growth. B deficiency increased extracellular Ca²⁺ influx and thus led to increased [Ca²⁺]cyt in the pollen tube tip. In addition, B deficiency modified actin filament arrangement at the pollen tube apex. B deficiency also altered the deposition of pollen tube wall components. Clear differences were not observed in the distribution patterns of cellulose and callose between control and B deficiency treated pollen tubes. However, B deficiency affected distribution patterns of pectin and arabinogalactan proteins (AGP). Clear ring‐like signals of pectins and AGP on control pollen tubes varied according to B deficiency. B deficiency further decreased acid pectins, esterified pectins and AGP content at the tip of the pollen tube, which were supported by changes in chemical composition of the tube walls.
• B appears to have an active role in pollen tube growth by affecting [Ca²⁺]cyt, actin filament assembly and pectin and AGP deposition in the pollen tube. These findings provide valuable information that enhances our current understanding of the mechanism regulating pollen tube growth.

     

Differential roles of microtubule and actin-myosin cytoskeleton in the growth of Pinus pollen tubes

The behavior and role of the microtubule (MT) and actin-myosin components of the cytoskeleton during pollen tube growth in two species of Pinus were studied using anti--tubulin, rhodamine-phalloidin, anti-myosin, and the appropriate inhibitors. Within germinated pollen tubes MTs were arranged obliquely or transversely, but in elongated tubes they were arranged along the tube's long axis. MTs were localized in the tube tip region, excluding the basal part. Altered growth was found in pollen tubes treated with colchicine; the tips of many pollen tubes incubated in the liquid medium were branched and/or rounded, and those in the agar medium were divided into many branches. Both the branching and the rounding were considered to be caused by the disturbance of polarizing growth of the tube due to MT disorganization with colchicine treatment. Actin filaments (F-actin) were found in the major parts of many pollen tubes along their long axis, excluding the tip region. In a few tubes, however, F-actin was distributed throughout the tube. The areas in the pollen tube containing F-actin were filled with abundant cytoplasmic granules, but the areas without F-actin had very few granules. The tube nucleus, which migrated from the grain area into the tube, was closely associated with F-actin. Germination of pollen grains treated with cytochalasin B was little affected, but further tube elongation was inhibited. Myosin was identified on cytoplasmic granules and to a lesser extent on the tube nucleus in the pollen tubes. Several granules were attached to the nuclear envelope. Tube growth was completely inhibited by N-ethylmaleimide treatment. In generative cells that were retained in the pollen grain, both MT and F-actin networks were observed. Myosin was localized on the cytoplasmic granules but not on the cell surface. In conclusion, it was shown that actin-myosin and MTs were present in gymnospermous Pinus pollen tubes and it is suggested that the former contributed to outgrowth of the tubes and the latter contributed to polarized growth. Several differences in the behavior of cytoskeletal elements in generative cells compared to angiosperms were revealed and are discussed.     

Pollen of a Male-Sterile Mutant of Arabidopsis thaliana Isolated from a T-DNA Insertion Pool is Not Effectively Released from The Anther Locule

We have isolated a male-sterile mutant from a pool of T-DNAinsertional lines of Arabidopsis thaliana generated by an inplanta transformation procedure [Chang et al. (1994) Plant J.5: 551]. Pollen in this mutant is not effectively released fromanther locules after cleavage of the stomium. Most mutant pollengrains are round, in contrast to the tricolpate wild-type pollen,and some pollen grains show an abnormal surface structure. Manuallyreleased mutant pollen grains are not fertile and show defectsin pollen tube germination in vitro. Genetic analysis disclosedthat this lesion is due to a single recessive nuclear mutationlocated on chromosome 3 closely linked to the gl1 locus. Themutation locus is tightly linked to the inserted T-DNA. ¹Present address: CSIRO, Division of Plant Industry, GPO Box1600, Canberra, ACT 2601, Australia     

The Arabidopsis AGC kinases NDR2/4/5 interact with MOB1A/1B and play important roles in pollen development and germination

Pollen formation and pollen tube growth are essential for the delivery of male gametes into the female embryo sac for double fertilization. Little is known about the mechanisms that regulate the late developmental process of pollen formation and pollen germination. In this study, we characterized a group of Arabidopsis AGC kinase proteins, NDR2/4/5, involved in pollen development and pollen germination. The NDR2/4/5 genes are mainly expressed in pollen grains at the late developmental stages and in pollen tubes. They function redundantly in pollen formation and pollen germination. At the tricellular stages, the ndr2 ndr4 ndr5 mutant pollen grains exhibit an abnormal accumulation of callose, precocious germination and burst in anthers, leading to a drastic reduction in fertilization and a reduced seed set. NDR2/4/5 proteins can interact with another group of proteins (MOB1A/1B) homologous to the MOB proteins from the Hippo signaling pathway in yeast and animals. The Arabidopsis mob1a mob1b mutant pollen grains also have a phenotype similar to that of ndr2 ndr4 ndr5 pollen grains. These results provide new evidence demonstrating that the Hippo signaling components are conserved in plants and play important roles in sexual plant reproduction.     

Biochemical and Ultrastructural Changes in Pollen ofZea maysL. Grown Under Enhanced UV-B Radiation

The influence of ultraviolet-B (UV-B) radiation on the developmentof the male gametophyte was studied inZea maysL. cv. LG12 grownin a growth chamber under PAR light supplemented with UV-B radiationand compared with a second set of plants grown under PAR light.Pollen samples collected from both groups of plants were culturedon germination medium and it was found that UV-B had no effecton pollen germination. Total pollen protein content was notaffected but UV-B absorbing pigments increased. Some ultrastructuralalterations were observed in pollen and pollen tubes, in particularlarge amounts of electron dense deposits were seen throughoutthe cytoplasm and in association with the pollen wall. In maturespikes of UV-B treated plants, anthers retained numerous pollengrains in their loculi while anthers of control plants werealmost empty. UV-B treatment delayed flowering by 2–3d. These results show that UV-B treatment of maize plants interfereswith flowering, pollen ultrastructure and anther maturationeven though pollen germination is unaffected. The significantincrease of UV-B absorbing pigments in pollen grains could representa defence mechanism that enables plants to complete their reproductivecycle.Copyright 1998 Annals of Botany Company Zea maysL., maize, UV-B radiation, pollen.     

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.     

Effect of Water Loss on Germination Ability of Maize (Zea mays L.) Pollen

The correlation between water content and viability of maizepollen grains was studied on the basis of the germination abilityof pollen from a single cross hybrid. There was found to beclose correlation between viability of the grains and theirtolerance to desiccation. Most of the pollen grains in the hybridexamined survived a reduction by almost 50 per cent of the originalwater content without loss of normal function. With water lossgreater than this, less vigorous pollen grains died or losttheir ability to form pollen tubes. Consequently, when pollinationwas carried out using pollen with a water content reduced bymore than 50 per cent, only the most tolerant pollen grainssurvived to take part in the competition which precedes fertilization.Dry pollen grains required a longer period to establish adhesionto the stigma surface and to initiate pollen tubes than pollengrains with higher water content, but otherwise their behaviourwas normal. If more than 80 per cent of the original water contentwas lost, disturbances occurred in the physiology of the grainssurviving the treatment. This was exhibited as death or a reductionin rate of pollen tube growth. Drying of pollen by an amount which does not irreversibly damagethe more tolerant grains could possibly be used as a means ofpollen selection. Zea mays L., maize, pollen viability, pollen treatment, dehydration, pollen tube     

Brassinosteroids promote Arabidopsis pollen germination and growth

Pollen tubes are among the fastest tip-growing plant cells and represent an excellent experimental system for studying the dynamics and spatiotemporal control of polarized cell growth. However, investigating pollen tube tip growth in the model plant Arabidopsis remains difficult because in vitro pollen germination and pollen tube growth rates are highly variable and largely different from those observed in pistils, most likely due to growth-promoting properties of the female reproductive tract. We found that in vitro grown Arabidopsis pollen respond to brassinosteroid (BR) in a dose-dependent manner. Pollen germination and pollen tube growth increased nine- and fivefold, respectively, when media were supplemented with 10 µM epibrassinolide (epiBL), resulting in growth kinetics more similar to growth in vivo. Expression analyses show that the promoter of one of the key enzymes in BR biosynthesis, CYP90A1/CPD, is highly active in the cells of the reproductive tract that form the pathway for pollen tubes from the stigma to the ovules. Pollen tubes grew significantly shorter through the reproductive tract of a cyp90a1 mutant compared to the wild type, or to a BR perception mutant. Our results show that epiBL promotes pollen germination and tube growth in vitro and suggest that the cells of the reproductive tract provide BR compounds to stimulate pollen tube growth.     

Modification of the Pollen-Stigma Interaction in Brassica oleracea by Water

The presence of a film of distilled water on the stigma surfaceof freshly opened flowers results in complete inhibition ofpollen following both incompatible and compatible pollinationsin self-incompatible (SI) genotypes of Brassica oleracea, SIgenotypes of B. campestris and one self-compatible (SC) genotypeof B. campestris. The application of water to the stigmas afterpollination also resulted in a marked reduction in pollen germinationand tube penetration. An increase in the time intervals betweenthe application of pollen onto the stigma and the water treatmentprogressively reduced this inhibition. Pollen germination wasalso completely inhibited when stigmas from freshly-opened flowersof SI B. campestris and B. oleracea genotypes were washed inwater, dried and pollinated with pollen grains of either compatibility.The ability of stigmas to induce pollen germination and tubegrowth was restored over a period, the length of which was dependenton the incompatibility (S) genotype. Stigmas of B. napus (SC)and SC mutants of SI B. campestris were found to be affectedby washing, but stigmas of a SC variety of B. campestris andthe immature stigmas from buds of B. oleracea were found tobe considerably less affected. Microscopic examination of pollenplaced on washed stigmas reveals that grains, irrespective oftheir compatibility, fail to hydrate normally. When inducedto hydrate by raising atmospheric humidity, pollen grains onwashed stigmas did germinate, but most of the tubes failed topenetrate the papillar wall and very few entered the style.It is proposed that the water treatment mobilises componentsof the pellicle which reorganize to block the activity of molecules,present in both SC and SI individuals, responsible for establishingfull contact between the pellicle and pollen grain coating. Brassica, pellicle, pollen, recognition, self-incompatibility     

Arabinogalactan proteins 6 and 11 are required for stamen and pollen function in Arabidopsis

Successful male reproductive function in plants is dependent on the correct development and functioning of stamens and pollen. AGP6 and AGP11 are two homologous Arabidopsis genes encoding cell wall-associated arabinogalactan glycoproteins (AGPs). Both genes were found to be specifically expressed in stamens, pollen grains and pollen tubes, suggesting that these genes may play a role in male organ development and function. RNAi lines with reduced AGP6 and AGP11 expression were generated. These, together with lines harboring point mutations in the coding region of AGP6, were used to show that loss of function in AGP6 and AGP11 led to reduced fertility, at least partly as a result of inhibition of pollen tube growth. Our results also suggest that AGP6 and AGP11 play an additional role in the release of pollen grains from the mature anther. Thus, our study demonstrates the involvement of specific AGPs in pollen tube growth and stamen function.     

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.