Microtubules and microfilaments coordinate to direct a fountain streaming pattern in elongating conifer pollen tube tips

This study investigates how microtubules and microfilaments control organelle motility within the tips of conifer pollen tubes. Organelles in the 30-m-long clear zone at the tip of Picea abies (L.) Karst. (Pinaceae) pollen tubes move in a fountain pattern. Within the center of the tube, organelles move into the tip along clearly defined paths, move randomly at the apex, and then move away from the tip beneath the plasma membrane. This pattern coincides with microtubule and microfilament organization and is the opposite of the reverse fountain seen in angiosperm pollen tubes. Application of latrunculin B, which disrupts microfilaments, completely stops growth and reduces organelle motility to Brownian motion. The clear zone at the tip remains intact but fills with thin tubules of endoplasmic reticulum. Applications of amiprophosmethyl, propyzamide or oryzalin, which all disrupt microtubules, stop growth, alter organelle motility within the tip, and alter the organization of actin microfilaments. Amiprophosmethyl inhibits organelle streaming and collapses the clear zone of vesicles at the extreme tip together with the disruption of microfilaments leading into the tip, leaving the plasma membrane intact. Propyzamide and oryzalin cause the accumulation of membrane tubules or vacuoles in the tip that reverse direction and stream in a reverse fountain. The microtubule disruption caused by propyzamide and oryzalin also reorganizes microfilaments from a fibrillar network into pronounced bundles in the tip cytoplasm. We conclude that microtubules control the positioning of organelles into and within the tip and influence the direction of streaming by mediating microfilament organization.Electronic Supplementary Material Supplementary material is available in the online version of this article at Abbreviations APM Amiprophosmethyl - FITC Fluorescein isothiocyanate - LATB Latrunculin B     

Side branch formation and orientation in the caulonema of the moss,Funaria hygrometrica: Experiments with inhibitors and with centrifugation

Summary Colchicine treatment ofFunaria caulonemata, usually does not inhibit initiation of a side branch or its incipient elongation but does prevent movement of chloroplasts and the nucleus into the outgrowth. After colchicine and after cytochalasin B treatment side branches are formed about at the normal age of the cells; because of the inhibition of the apical cell they arise at an abnormal position,i.e., not in the third but in the second cell of a filament. After D₂O treatment the organelles are dislocated toward the basal cross wall. The site of side branch formation is then obviously determined by the position of the nucleus. Cells with an irreversibly reversed longitudinal polar axis can be found; by centrifugation in proximal direction the sites of side branch initiation likewise are displaced into the proximal region of the cell, especially if the remigration of the nucleus is inhibited by colchicine. High concentrations of Ca²⁺ ions induce the formation of side branch cells, without any outgrowth. The calcium ionophore A 23 187 influences the position of the nucleus and of the side branch only slightly. After these various treatments intercalary divisions frequently occur. The role and interrelationship of the nucleus and peripheral cytoplasm in establishing and maintaining the polar axes, and the role of microtubules are discussed.     

Cytology of budding and cleavage in tobacco mesophyll protoplasts cultivated in saline medium

Tobacco (Nicotiana tabacum L., cv. Maryland) mesophyll protoplasts cultivated in saline medium divide by bud formation, migration of one nucleus into the bud, and subsequent furrowing. This process was investigated light and electron microscopically. The cytoplasm of the growing bud is richer in dictyosomes, rough endoplasmic reticulum profiles, mitochondria, and small vacuoles than is the cytoplasm of the mother cell, but in early stages lacks plastids. Only patches of wall material are found; most of the cell surface appears naked. Oriented sections of the cleavage furrow do not reveal a contractile ring of microfilaments under the fixation conditions used. The furrow is flanked by numerous microtubules, and is rich in coated vesicles. Nuclear division appears normal, but the phragmoplast vesicles appear empty, and the phragmoplast seems to disintegrate again later. The nucleus migrating into the bud does not show any signs of associated contractile structures. The results demonstrate that, in principle, higher plant cells are capable of a mode of division usually said to be yeast-like. The events of karyokinesis and cell plate formation are not therefore obligatorily linked processes.     

AN ULTRASTRUCTURAL BASIS FOR HYPHAL TIP GROWTH IN PYTHIUM ULTIMUM

Hyphae of the fungus Pythium ultimum extend by tip growth. The use of surface markers demonstrates that cell expansion is limited to the curved portion of the hyphal apex. Growing and non-growing regions are reflected in internal organization as detected by light and electron microscopy. The young hypha consists of three regions: an apical zone, a subapical zone and a zone of vacuolation. The apical zone is characterized by an accumulation of cytoplasmic vesicles, often to the exclusion of other organelles and ribosomes. Vesicle membranes are occasionally continuous with plasma membrane. The subapical zone is non-vacuolate and rich in a variety of protoplasmic components. Dictyosomes are positioned adjacent to endoplasmic reticulum or nuclear envelope, and vesicles occur at the peripheries of dictyosomes. A pattern of secretory vesicle formation by dictyosomes is described which accounts for the formation of hyphal tip vesicles. Farther from the hyphal apex the subapical zone merges into the zone of vacuolation. As hyphae age vacuolation increases, lipid accumulations appear, and the proportional volume of cytoplasm is reduced accordingly. The findings are integrated into a general hypothesis to explain the genesis and participation of cell components involved directly in hyphal tip growth: Membrane material from the endoplasmic reticulum is transferred to dictyosome cisternae by blebbing; cisternal membranes are transformed from ER-like to plasma membrane-like during cisternal maturation; secretory vesicles released from dictyosomes migrate to the hyphal apex, fuse with the plasma membrane, and liberate their contents into the wall region. This allows a plasma membrane increase at the hyphal apex equal to the membrane surface of the incorporated vesicles as well as a contribution of the vesicle contents to surface expansion.     

Side branch formation and orientation in the caulonema of the moss,Funaria hygrometrica: Normal development and fine structure

Summary The regular branching of theFunaria caulonema filaments is partly related to rhythms in nuclear and cell division. The formation and development of the branches were studied by light and electron microscopy with particular attention directed to the distribution of microtubules and the polar organization of the cytoplasm. The new side branch breaks through the wall of the mother cell. The site of branch development is determined by the position of the nucleus of the mother cell. In protonemata which grow in vertically placed Petri dishes gravity influences the position of nuclei and side branches, and also the direction of oblique cross walls in the caulonema filaments to a certain extent.     

Electron tomographic characterization of a vacuolar reticulum and of six vesicle types that occupy different cytoplasmic domains in the apex of tip-growing <Emphasis Type="Italic">Chara</Emphasis> rhizoids

We provide a 3D ultrastructural analysis of the membrane systems involved in tip growth of rhizoids of the green alga Chara. Electron tomography of cells preserved by high-pressure freeze fixation has enabled us to distinguish six different types of vesicles in the apical cytoplasm where the tip growth machinery is accommodated. The vesicle types are: dark and light secretory vesicles, plasma membrane-associated clathrin-coated vesicles (PM-CCVs), Spitzenkoerper-associated clathrin-coated vesicles (Sp-CCVs) and coated vesicles (Sp-CVs), and microvesicles. Each of these vesicle types exhibits a distinct distribution pattern, which provides insights into their possible function for tip growth. The PM-CCVs are confined to the cytoplasm adjacent to the apical plasma membrane. Within this space they are arranged in clusters often surrounding tubular plasma membrane invaginations from which CCVs bud. This suggests that endocytosis and membrane recycling are locally confined to specialized apical endocytosis sites. In contrast, exocytosis of secretory vesicles occurs over the entire membrane area of the apical dome. The Sp-CCVs and the Sp-CVs are associated with the aggregate of endoplasmic reticulum membranes in the center of the growth-organizing Spitzenkoerper complex. Here, Sp-CCVs are seen to bud from undefined tubular membranes. The subapical region of rhizoids contains a vacuolar reticulum that extends along the longitudinal cell axis and consists of large, vesicle-like segments interconnected by thin tubular domains. The tubular domains are encompassed by thin filamentous structures resembling dynamin spirals which could drive peristaltic movements of the vacuolar reticulum similar to those observed in fungal hyphae. The vacuolar reticulum appears to serve as a lytic compartment into which multivesicular bodies deliver their internal vesicles for molecular recycling and degradation. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Structural and functional compartmentalization in pollen tubes

Eukaryotic cellular functions are achieved by concerted activities in the cytosol and functions compartmentalized in the nucleus and other membrane-bound organelles. Moreover, the cytosol and nucleoplasm are populated with mega molecular ensembles that are specialized for different metabolic and biochemical processes. Pollen tubes are unique plant cells with a dramatic growth polarity. Tube growth is restricted to the tip and is supported by a polarized cytoplasmic organization. The apical region of elongating pollen tubes is a domain occupied exclusively by transport vesicles to support the secretion and endocytic activity needed for the rapid cell expansion at the apex. Larger organelles are predominantly segregated to the cytoplasm distal to the subapical region. Underlying the organelle compartmentalization is an elaborate actin cytoskeleton with distinct structural and dynamics properties at the tip, in the subapical region, and in the cytoplasm subtending it. Cytoplasmic domains with differential ionic conditions and spatially restricted localization of molecules in pollen tubes may also be important for regulating the polar cell growth process. The polarized cellular organization in pollen tubes drives an extremely efficient cell growth process that is responsive to extracellular signals, including directional cues. It may be an amplified framework of the cytoplasmic architecture that supports growth in other plant cell types that involves considerably more subtle and transient differential cell expansion.     

Growth and ultrastructure ofArabidopsis root hairs: therhd3 mutation alters vacuole enlargement and tip growth

The root hairs of plants are tubular projections of root epidermal cells and are suitable for investigating the control of cellular morphogenesis. In wild-typeArabidopsis thaliana (L.) Heynh, growing root hairs were found to exhibit cellular expansion limited to the apical end of the cell, a polarized distribution of organelles in the cytoplasm, and vesicles of several types located near the growing tip. Therhd3 mutant produces short and wavy root hairs with an average volume less than one-third of the wild-type hairs, indicating abnormal cell expansion. The mutant hairs display a striking reduction in vacuole size and a corresponding increase in the relative proportion of cytoplasm throughout hair development. Bead-labeling experiments and ultrastructural analyses indicate that the wavy-hair phenotype of the mutant is caused by asymmetric tip growth, possibly due to abnormally distributed vesicles in cortical areas flanking the hair tips. It is suggested that a major effect of therhd3 mutation is to inhibit vacuole enlargement which normally accompanies root hair cell expansion.     

Electron microscopic study of spermiogenesis in the free-living marine nematode <Emphasis Type="Italic">Leptosomatides marinae</Emphasis> Platonova 1976 (Enoplida: Leptosomatidae)

The ultrastructure of spermatocytes, spermatids and spermatozoa of the free-living marine nematode Leptosomatides marinae was studied by transmission electron microscopy. In early spermatids, the number of mitochondria, cisterns of the rough endoplasmic reticulum (RER) and dictyosomes increased; the number of membranous organelles (MOs) was insignificant. Later, dictyosomes and MOs filled the cytoplasm. The cytoplasm became distinctly segregated in late spermatids and the MOs concentrated around the nucleus; the mitochondria and organelles of synthesis settled on the cell periphery. Later, a densely packed conglomerate was formed from the central nucleus and a mass of MOs surrounded by an extensive zone of the cytoplasm containing mitochondria and organelles of synthesis. Early spermatozoa had an elongated nucleus surrounded by a layer of cytoplasm containing mitochondria, polarized MOs and bundles of filamentous material, which can be interpreted as fibrous bodies (FBs). The formed spermatozoa had elongated nuclei surrounded by a transparent halo; the cell periphery was a dense matrix, in which MOs and sparse mitochondria were submerged; no FBs were revealed in that phase. In general, the spermatozoa of L. marinae have the main attributes common to the Enoplida spermatozoa, availability of nuclear environment and development of the specific organelles, MOs and FBs, which are not united in complexes.     

ULTRASTRUCTURE OF GLANDULAR OVARIAN TRICHOMES OF CYPRIPEDIUM CALCEOLUS AND C. REGINAE (ORCHIDACEAE)

Trichomes on the orchid ovary are a possible site of synthesis and secretion of the floral scent. Scanning electron microscopy of these trichomes shows a bulbous cell on a two-celled stalk. Thin sections of the tip cell revealed the morphology of an active, secretory cell with unusual coated vesicles in the extra-cellular deposition. Abundant smooth endoplasmic reticulum (ER) aggregated beneath the plasma membrane in the apical region of the cell and the limited dictyosomes in the cell suggest direct secretion by ER. Numerous lipid droplets are present in the apical area. Plastids, found only in the basal region of this cell, are more round in profile than typical chloroplasts and contain only a few unstacked thylakoids and a limited membranous reticulum. In addition to the normal plastid envelope, a double layer of membrane (probably ER) is tightly appressed to each dense, starch-free plastid. Highly specialized morphology and subcellular localization of organelles suggest the secretory nature of these trichomes.     

Polarity and growth of caulonema tip cells of the moss Funaria hygrometrica

In the caulonema tip cells of Funaria hygrometrica, chloroplasts, mitochondria, and dictyosomes have differences in structure which are determined by cell polarity. In contrast to the slowly growing chloronema tip cells the apical cell of the caulonema contains a tip body. Colchicine stops tip growth; it causes the formation of subapical cell protrusions, redistribution of the plastids, and a loss of their polar differentiation. Cytochalasin B inhibits growth and affects the position of cell organelles. After treatment with ionophore A23 187, growth is slower and shorter and wider cells are formed. D₂O causes a transient reversion of organelle distribution but premitotic nuclei are not dislocated. In some tip cells the reversion of polarity persists; they continue to grow with a new tip at their base. During centrifugation, colchicine has only a slight influence on the stability of organelle anchorage. The former polar organization of most cells is restored within a few hours after centrifugation, and the cells resume normal growth. In premitotic cells the nucleus and other organelles cannot be retransported, they often continue to grow with reversed polarity. Colchicine retards the redistribution of organelles generally and increases the number of cells that form a basal outgrowth. The interrelationship between the peripheral cytoplasm and the nucleus and the role of microtubules in maintaining and reestablishing cell polarity are discussed.Abbreviations DMSO dimethylsulfoxide - CB cytochalasin B Dedicated to Prof. Dr. A. Pirson on the occasion of his 70. birthday     

Ultrastructure of freeze-substituted pollen tubes ofLilium longiflorum

Summary In view of the importance of the lily pollen tube as an experimental model and the improvements in ultrastructural detail that can now be attained by the use of rapid freeze fixation and freeze substitution (RF-FS), we have reexamined the ultrastructure of these cells in material prepared by RF-FS. Several previously unreported details have been revealed: (1) the cytoplasm is organized into axial slow and fast lanes, each with a distinct structure; (2) long, straight microtubule (MT) and microfilament (MF) bundles occur in the cytoplasm of the fast lanes and are coaligned with every organelle present; (3) the cortical cytoplasm contains complexes of coaligned MTs, MFs, and endoplasmic reticulum (ER); (4) the cortical ER is arranged in a tight hexagonal pattern and individual elements are closely appressed to the plasma membrane with no space between; (5) mitochondria and ER extend into the extreme apex along the flanks of the pollen tube, and vesicles and ER are packed into an inverted cone-shaped area at the center of the apex; (6) MF bundles in the tip region are fewer, finer, and in random orientation in comparison to those of the fast lanes; (7) the generative cell (GC) cell wall complex contains patches of plasmodesmata; (8) The GC cytoplasm contains groups of spiny vesicles that are closely associated with and seem to be fusing with or pinching off from mitochondria, and (9) the vegetative nucleus (VN) contains internal MT-like structures as well as numerous cytoplasmic MTs associated with its membrane and also located between the VN and GC.Abbrevations CF chemical fixation - ER endoplasmic reticulum - GC generative cell - MF microfilament - MT microtubule - PD plasmodesmata - PM plasma membrane - RF-FS rapid freeze fixation-freeze substitution - VN vegetative nucleus     

Ultrastructure and microtubule organization of isolated generative cells ofAllemanda neriifolia at interphase and prophase

Summary The ultrastructure of isolated generative cells ofAllemanda neriifolia at interphase and prophase was studied. The microtubule organization of the isolated cells was also investigated by immunofluorescence microscopy with a monoclonal anti--tubulin. After the generative cells had been isolated from the growing pollen tubes by osmotic shock, most of the cells were at prophase and only a few were at interphase. The interphase cell is spindle shaped and contains an ellipsoidal nucleus. In addition to the usual organelles, the cytoplasm of the interphase cell contains numerous vesicles (each measuring 40–50 nm in diameter) and two sets of longitudinally oriented microtubule bundles — one in the cortical region and the other near the nucleus. Most of the prophase cells are spherical in shape. Based on the ultrastructure and the pattern of microtubule cytoskeleton organization three types of prophase cells can be recognized. (1) Early prophase cell, which contains the usual organelles, numerous vesicles, and a spherical nucleus with condensed chromosomes. Longitudinally oriented microtubule bundles can no longer be seen present in the early prophase cell. A new type of structure resembling a microtubule aggregate appears in the cytoplasm. (2) Mid prophase cell, which has a spherical nucleus containing chromosomes that appear more condensed than those seen in the early prophase cell. In addition to containing the usual organelles, the cytoplasm of this cell contains numerous apparently randomly oriented microtubules. Few vesicles are seen and microtubule aggregates are no longer present. (3) Late prophase cell, typified by the lack of a nuclear envelope. Consequently, the chromosomes become randomly scattered in the cytoplasm. Microtubules are still present and some become closely associated with the chromosomes. The changes in the ultrastructure and in the pattern of microtubule organization in the interphase and prophase cells are discussed in relation to the method of isolation of the generative cells.     

Development,structure, and occurrence of secretory trichomes ofPharbitis

Summary Secretory trichomes develop from epidermal cells on the leaf primordia and stem ofPharbitis nil. Following an initial growth phase, trichomes begin active secretion of a protein-carbohydrate mucilage. This mucilage covers the shoot apex and developing leaves ofPharbitis.The secretory cells possess cellular organelles in forms usually associated with actively secreting cells: many mitochondria, an elaborate network of rough endoplasmic reticulum (RER), many free ribosomes, and numerous dictyosomes. The role of the dictyosomes is twofold: 1. dictyosome vesicles bud coated vesicles which transport materials from the cell and, 2. dictyosome vesicles coalesce, forming large storage vesicles. The storage vesicles are surrounded by, and often in contact with, poculiform RER. The RER forms an interconnected network throughout the cytoplasm, extending from the nuclear envelope to the plasmalemma. Distended profiles of RER are frequently in direct contact with the plasmalemma. Thus, inPharbitis secretory trichomes, it is the coated vesicles and RER which are active in secretion export. These findings imply a secretory pathway which deviates from the usual pattern in glandular cells.Predoctoral fellow of National Science Foundation during part of the investigation.     

Microgametogenesis in Plumbago zeylanica (Plumbaginaceae). 1. Descriptive cytology and three-dimensional organization

The generative cell is initiated as a small, lenticular, unpolarized cell with a cell wall traceable to two origins: the external segment originates as intine, while an inner callose positive cell wall forms de novo. As the lenticular generative cell begins its migration into the pollen cytoplasm, the generative cell becomes polarized both externally and internally, displaying a characteristic shape and patterns of organelle distribution oriented with respect to the vegetative nucleus and independent of pollen aperture location. Separation of the generative cell from the pollen wall begins at the end opposite the vegetative nucleus and results in an elongating protuberance at the opposite end of the generative cell; this becomes associated with a preformed groove located on the surface of the vegetative nucleus. The generative cell subsequently separates from the intine near the vegetative nucleus and moves progressively toward the opposite end of the cell; during this separation, the edge of the wall facing the intine becomes callose-positive and remains so until separating from the intine. The generative cell becomes a free cell within the pollen, which is in physical association with the vegetative nucleus. Generative cell organization and organelle content become increasingly polarized during maturation, with microtubules evident both in the elongating protuberance of the generative cell and in association with organelles. The generative nucleus migrates away from the vegetative nucleus and toward the plastid-rich end of the generative cell, whereas mitochondria are more generally distributed within the cell. Generative cell polarization is made permanent during mitotic division and cytokinesis, i.e., two sperm cells differing in morphology are formed: the larger cell associated with the vegetative nucleus (S_vn) contains a majority of the mitochondria, and the smaller, unassociated sperm cell (S_ua) receives the plastids.     

Chloroplast proliferation based on their distribution and arrangement inAdiantum protonemata growing under red light

Chloroplast proliferation was investigated inAdiantum protonemata growing under continuous red light. Cell division is absent when cells are grown under red light. The chloroplast number increases as the cell length increases, therefore the chloroplasts divide in the absence of cell division. Chloroplasts in the basal part of the filamentous protonemal cell migrate gradually toward the cell apex, but there is no large net migration from the tip to the base or vice versa, indicating that chloroplast division takes place in the apical part of the protonemata. Chloroplast number in the apical 100 μm was maintained at about 200 during cell growth at least over eight days. The chloroplasts were either dumbbell- or ellipsoid-shaped. Dumbbell-shaped chloroplasts are abundant everywhere in a protonema, ranging from 30 to 50% of the total chloroplasts. The dumbbell-shaped chloroplasts attached to or very close to the plasma membrane seem to be the ones that are dividing but the dumbbell-shaped ones in the other regions do not divide. These data support the hypothesis that a signal from the plasma membrane induces the dumbbell-shaped chloroplasts to divide.     

Division,growth, and branch formation in protonema of the mossPhyscomitrium turbinatum: Studies of sequential cytological changes in living cells

Summary Elongating caulonemal tip cells ofPhyscomitrium turbinatum were cultivated on mediumcoated cover slips and periodically observed with Nomarski differential interference contrast optics. Tip cells exhibit apical growth and an average growth rate of 27.5 m/h. During cell elongation the nucleus migrates forward in the tip cell, but this movement slowly decreases so that there is a gradual increase in the distance between the nucleus and cell tip. Minimum length cells contain small vacuoles adjacent to the basal wall which coalesce during subsequent cell elongation to form a solitary large basal vacuole.An increase in chloroplasts during cell elongation is due to the presence of a population of proliferating chloroplasts located between the cell tip and the nucleus resulting in a gradient in chloroplast number and shape. The zone of chloroplast proliferation shifts progressively forward during cell elongation from a peri-nuclear position to a region closer to the cell tip. During division of the apical cell a perpendicular metaphase plate is formed. Reorientation movements of the phragmoplast-cell plate during telophase, and early stages of the following interphase produce a 35–40° cross wall. This rotation of the spindle axis positions the daughter nuclei temporarily adjacent to the lateral walls on opposite sides of the cell with the sub-apical nucleus on the side nearest the light source. It subsequently migrates across the cell to become situated on the wall farthest from the light source. Sub-apical cells form branches at the distal (= apical) end of the cell on the lateral wall closest to the light source. Branch development is accompanied by changes in chloroplast shape, number, and position.     

Nuclear behavior during branch formation in a centrifugedAdiantum protonema and the nuclear polarity

A new branch was induced on the side wall of fern protonema by cell centrifugation and subsequent polarized red light irradiation after the induction of cell division under white light. Nuclear behavior during the branch formation was analyzed. Immediately after cell division, the two daughter nuclei moved away from the division site in both red and dark conditions. Under continuous irradiation with polarized red light, cell swelling occurred as an early step of branching near the cell dividing wall, even though the nucleus was localized far from the branching site at the beginning of the swelling. After a new branch started to grow, the nucleus returned to the branching site and moved into the new branch from its basipetal end. When a protonema incubated in the dark was centrifuged again acropetally or basipetally just before the irradiation of polarized red light, the rate of apical growth or branch formation was increased, respectively. Moreover, growth of a branched protonema was altered from its former apex or from the branch again by dislocating the nucleus acropetally or basipetally by centrifugation, respectively. These facts suggest that the nucleus has no polarity physiologically, i.e. head and tail, namely either end of the spindle-shaped nucleus can be the nuclear front in a tip-growing protonema.     

SECRETION AND DEPLOYMENT OF BRISTLES IN MALLOMONAS SPLENDENS (SYNUROPHYCEAE)1

Mallomonas splendens (G. S. West) Playfair has a cell covering of siliceous scales and bristles. Interphase cells bear four anterior and four posterior bristles that each articulate, at their flexed basal ends via a complex of labile fibers (the fibrillar complex), on a specialized body scale (a base-plate scale). Body scales, base-plate scales and bristles are formed independently of each other and at different times in silica deposition vesicles (SDVs) that are associated with one of the two chloroplasts. The fine structure of scale and bristle morphogenesis in M. splendens agrees with that previously described for Synura and Mallomonas. Four new posterior bristles are formed at late interphase with their basal ends towards the cell posterior. The fibrillar complex is formed in situ on the bristle in the SDV. Mature bristles are secreted one by one onto the surface of the protoplast, beneath the layer of body scales, where the basal ends of the bristles adhere to the plasma membrane via the fibrillar complex. The extrusion of posterior bristles and their deployment onto the cell surface was monitored with video. A fine cellular protuberance accompanies the bristles as they are extruded from beneath the scale layer with their basal ends leading. When distant from the cell, the basal ends of the bristles appear attached to the protuberance, possibly by way of their fibrillar complexes. Once bristles are fully extruded, and their tips free in the surrounding environment, the bristle bases are drawn back to the posterior apex of the cell, apparently by the now shortening protuberance. Thus a 180° reorientation of the posterior bristles has been effected outside the cell. Thin-sections of cells that are extruding bristles show a threadlike, cytoplasmic extension of the cell posterior which may be analogous to the protuberance seen in live cells. Four new posterior base-plate scales are secreted after the bristles have reoriented. Scanning electron microscopy indicates that the fibrillar complex is involved in positioning the bristles onto their respective base-plate scales. Anterior bristles are formed in new daughter cells in the same orientation as the posterior bristles; thus they are extruded tip first and no reorientation is required.     

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

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