Spatial and temporal organization of actin during hydration,activation, and germination of pollen inPyrus communis L.: a population study

Summary Dynamics of F-actin organization during activation and germination ofPyrus communis (pear) pollen was examined using rhodaminephalloidin. Prior to activation, the rhodamine-phalloidin labelling pattern appeared as circular profiles in the peripheral cytoplasm of the vegetative cell and as coarse granules around the vegetative nucleus. In activated pollen, parallel arrays of cortical F-actin were aligned circumferentially, along the polar axis in non-apertural areas of the pollen grain, and at 45° to 90° to the polar axis beneath the apertures. Some pollen also showed fluorescent granules or fusiform bodies dispersed throughout the cytoplasm, but as the number of such pollen diminished with prolonged incubation, these are being considered as intermediate patterns. In later stages, the filaments became organized as interapertural bundles traversing the three apertures. However, prior to emergence of the pollen tube, labelling became confined to a single aperture. In germinated pollen grains, actin microfilaments are aligned more or less axially with respect to the axis of the developing pollen tube.The granular labelling pattern seen around the vegetative nucleus prior to pollen activation also became clearly filamentous with pollen activation; this filamentous pattern persisted until germination when it was replaced by cables that aligned longitudinally with respect to the emerging tube axis.The results demonstrate that the organization of actin undergoes considerable changes in the period preceding pollen germination and that microfilament polarization is achieved before pollen germination.     

Fluorescence microscopic localization of actin in pollen tubes: comparison of actin antibody and phalloidin staining

A comparison of actin localization in pollen tubes of Nicotiana has been made using a monoclonal actin antibody and rhodamine-phalloidin (RP). The monoclonal antiactin, based on Western blotting of pollen tube extract, labels a polypeptide at 45 kD that comigrates with muscle actin. A 51-kD unknown protein and three bands less than 45 kD, presumed to be proteolytic fragments of actin, are also observed. Structural observations using this antibody reveal a network of axially oriented strands of microfilaments (MFs). The MFs are distributed throughout the length of the pollen tube except at the very tip, where diffuse staining is usually observed. A similar pattern of MFs is evident after RP staining. When pollen tubes are treated with cytochalasins (CB or CD) cytoplasmic streaming is inhibited, as is tube elongation. Microscopic analysis reveals that the microfilament (MF) pattern is markedly altered; however, the antibody and RP produce different staining patterns. The antibody reveals many MF strands that distribute throughout the tube length and extend into the very tip. In contrast, RP shows mostly a diffuse staining pattern with only a few short clumps of filamentous material. Immunogold labelling of sections of pollen tubes prepared by rapid-freeze fixation and freeze substitution reveals that actin MF bundles are indeed present after cytochalasin treatment. Our results thus question reports in the literature, based on phalloidin staining, asserting that cytochalasin fragments or destroys actin MFs.     

Actin microfilament organization during pollen development ofBrassica napus cv. Topas

Summary The organization of actin microfilaments (MFs) was studied during pollen development ofBrassica napus cv. Topas. Cells were prepared using three techniques and double labelled for fluorescence microscopy with rhodamine-labelled phalloidin for MFs and Hoechst 33258 for DNA. Microfilaments are present at all stages of pollen development with the exception of tricellular pollen just prior to anthesis. Unicellular microspores contain MFs which radiate from the surface of the nuclear envelope into the cytoplasm. During mitosis MFs form a network partially surrounding the mitotic apparatus and extend into the cytoplasm. Both cytoplasmic and phragmoplast-associated MFs are present during cytokinesis. Nuclear associated-, cytoplasmic, and randomly oriented cortical MFs appear in the vegetative cell of the bicellular microspore. Cortical MFs in the vegetative cell organize into parallel MF bundles (MFBs) aligned transverse to the furrows. The MFBs disappear prior to microspore elongation. At anthesis MFs are restricted to the cortical areas subjacent to the furrows of the vegetative cell. The use of cytochalasin D to disrupt MF function resulted in: (1) displacement of the acentric nucleus in the unicellular microspore; (2) displacement of the spindle apparatus in the mitotic cell; (3) symmetrical growth of the bicellular microspore rather than elongation and (4) inhibition of pollen tube germination in the mature pollen grain. This suggests that MFs play an important role in anchoring the nucleus in the unicellular microspore as well as the spindle apparatus during microspore mitosis, in microspore shape determination and in pollen tube germination.Abbreviations MF microfilament - MFB microfilament bundle - rhph rhodamine phalloidin Dedicated to the memory of Professor John G. Torrey     

Changes of the actin filament system in the green algaMicrasterias denticulata induced by different cytoskeleton inhibitors

Summary Two different techniques have been adapted forMicrasterias denticulata to depict the actin cytoskeleton of both untreated and inhibitor-treated developing cells: the quickstaining method, where the cells are fixed in a mixture of glutaraldehyde and formaldehyde followed by staining with phalloidin without embedding, and the methacrylate method, where the cells are also fixed by aldehydes and where the embedding medium is removed prior to incubation with an actin antibody. Both methods produce sufficient preservation and visualization of actin microfilaments (MFs) and confirm earlier observations on the presence of a cortical actin MF network in both the growing and the nongrowing semicell as well as of a basketlike MF arrangement around the migrating nucleus. The results show that a network of actin MFs is essential for the proper development of the young lobes ofM. denticulata. Early developmental stages expanding uniformly at the beginning of growth lack any netlike actin MF arrangement. The actin cytoskeleton in developing cells treated with the actin-targeting agents cytochalasin D and latrunculin B is markedly influenced. Cytochalasin D, which produces the most pronounced effects, causes a breakdown of the network of actin MFs, resulting in bright actin clusters as well as in short and abnormally thick actin fragments particularly in cortical cell regions. In latrunculin B-treated cells remnants of the former actin MF network are still visible, yet most of the actin cytoskeleton appears collapsed and is reduced to short filament pieces. The disturbance of the actin MF system visualized in the present study correlates with the severe morphological and ultrastructural changes occurring in desmid cells as a consequence of both drugs. The dinitroanilin herbicide oryzalin, known to deploymerize cytoplasmic microtubules, causes also an impairment of the actin cytoskeleton inM. denticulata though not sufficient to influence normal cell growth and differentiation.Abbreviations CB cytochalasin B - CD cytochalasin D - DMSO dimethyl sulfoxide - FA formaldehyde - GA glutaraldehyde - LAT-A latrunculin A - LAT-B latrunculin B - MFs microfilaments - MT microtubule Dedicated to Professor Walter Gustav Url on the occasion of his 70th birthday     

Fluorescence visualization of the distribution of microfilaments in gonads and early embryos of the nematode Caenorhabditis elegans

Several intracellular motility events in the Caenorhabditis elegans zygote (pseudocleavage, the asymmetric meeting of the pronuclei, the segregation of germ line-specific granules, and the generation of an asymmetric spindle) appear to depend on microfilaments (MFs). To investigate how MFs participate in these manifestations of zygotic asymmetry, the distribution of MFs in oocytes and early embryos was examined, using both antibodies to actin and the F-actin-specific probe rhodamine-phalloidin. In early-stage zygotes, MFs are found in a uniform cortical meshwork of fine fibers and dots or foci. In later zygotes, concomitant with the intracellular movements that are thought to be MF mediated, MFs also become asymmetrically rearranged; as the zygote undergoes pseudocleavage and as the germ line granules become localized in the posterior half of the cell, the foci of actin become progressively more concentrated in the anterior hemisphere. The foci remain anterior as the spindle becomes asymmetric and the zygote undergoes its first mitosis, at which time fibers align circumferentially around the zygote where the cleavage furrow will form. A model for how the anterior foci of actin may participate in zygotic motility events is discussed. Phalloidin and anti-actin antibodies have also been used to visualize MFs in the somatic tissues of the adult gonad. The myoepithelial cells that surround maturing oocytes are visibly contractile and contain an unusual array of MF bundles; the MFs run roughly longitudinally from the loop of the gonad to the spermatheca. Myosin thick filaments are distributed along the MFs in a periodic manner suggestive of a sarcomere-like configuration. It is proposed that these actin and myosin filaments interact to cause sheath cell contraction and the movement of oocytes through the gonad.     

Actin and the elongation of plant cells

Summary We have investigated in parallel the effects of different types of inhibitors on elongation of oat coleoptile cells in IAA and on the integrity of the longitudinally oriented actin-containing microfilaments present in control cells as detected by rhodamine phalloidin (RP) staining. Where growth was 50% inhibited by cytochalasin D (CD), we observed extensive to complete breakdown of the microfilaments (MFs) with the appearance of new RP staining in a few nuclei and markedly along the cross walls. When the CD-treated coleoptiles were held at 4°C the nuclei were uniformly strongly stained and cross wall staining was not seen, suggesting that translocation to the nuclei may be an intermediate step in final disposition of the actin. The divalent ions calcium and magnesium both inhibited growth in a dose dependent way, with calcium giving 50% inhibition at 65 mM and magnesium at 25 mM. KCl was not inhibitory and did not reverse the inhibition by divalent ions even at 250 mM. At 50% inhibition by either ion, the long MFs in many cells were replaced either by short fragmented MFs and small brightly staining granules (calcium) or by short usually twisted MFs and large, less intensely staining masses (magnesium). Iodoacetate at 2mM inhibited growth almost completely and resulted in short, fragmented, twisted or curled MFs in most of the cells. Abscisic acid also caused replacement of some MFs with faintly fluorescent bodies somewhat larger than those in CaCl₂; occasionally granules similar to those in CaCl₂ were also seen. Only mannitol and galactose, which inhibit growth by their osmotic effect, did not cause breakup of the MFs; indeed the MFs in mannitol appeared if anything wider and thicker. The results show that under the influence of three types of growth inhibitors the actin-containing MFs in the cells are broken down to different extents resulting in new structures. The results support the idea that the integrity of the MF bundles is linked, perhaps causally, to the elongation of theAvena cells.Abbreviations IAA indoleacetic acid - ABA abscisic acid - CD cytochalasin D - MF microfilaments - MFB microfilament bundles - RP rhodamine phalloidin     

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.     

Distribution and dynamics of the cytoskeleton in graviresponding protonemata and rhizoids of characean algae: exclusion of microtubules and a convergence of actin filaments in the apex suggest an actin-mediated gravitropism

The organization of the microtubule (MT) and actin microfilament (MF) cytoskeleton of tip-growing rhizoids and protonemata of characean green algae was examined by confocal laser scanning microscopy. This analysis included microinjection of fluorescent tubulin and phallotoxins into living cells, as well as immunofluorescence labeling of fixed material and fluorescent phallotoxin labeling of unfixed material. Although the morphologically very similar positively gravitropic (downward growing) rhizoids and negatively gravitropic (upward growing) protonemata show opposite gravitropic responses, no differences were detected in the extensive three-dimensional distribution of actin MFs and MTs in both cell types. Tubulin microinjection revealed that in contrast to internodal cells, fluorescent tubulin incorporated very slowly into the MT arrays of rhizoids, suggesting that MT dynamics are very different in tip-growing and diffusely expanding cells. Microtubules assembled from multiple sites at the plasma membrane in the basal zone, and a dense subapical array emerged from a diffuse nucleation centre on the basal side of the nuclear envelope. Immunofluorescence confirmed these distribution patterns but revealed more extensive MT arrays. In the basal zone, short branching clusters of MTs form two cortical hemicylinders. Subapical, axially oriented MTs are distributed in equal density throughout the peripheral and inner cytoplasm and are closely associated with subapical organelles. Microtubules, however, are completely absent from the apical zones of rhizoids and protonemata. Actin MFs were found in all zones of rhizoids and protonemata including the apex. Two files of axially oriented bundles of subcortical actin MFs and ring-like actin structures in the streaming endoplasm of rhizoids were detected in the basal zones by microinjection or rhodamine-phalloidin labeling. The subapical zone contains a dense array of mainly axially oriented actin MFs that co-distribute with the subapical MT array. In the apex, actin MFs form thicker bundles that converge into a remarkably distinct actin patch in the apical dome, whose position coincides with the position of the endoplasmic reticulum aggregate in the centre of the Spitzenk?rper. Actin MFs radiate from the actin patch towards the apical membrane. Together with results from previous inhibitor studies (Braun and Sievers, 1994, Eur J Cell Biol 63: 289–298), these results suggest that MTs have a stabilizing function in maintaining the polar cytoplasmic and cytoskeletal organization. The motile processes, however, are mediated by actin. In particular, the actin cytoskeleton appears to be involved in the structural and functional organization of the Spitzenk?rper and thus is responsible for controlling cell shape and growth direction. Despite the similar structural arrangements of the actin cytoskeleton, major differences in the function of actin MFs have been observed in rhizoids and protonemata. Since actin MFs are more directly involved in the gravitropic response of protonemata than of rhizoids, the opposite gravitropism in the two cell types seems to be based mainly on different properties and activities of the actin cytoskeleton. Received: 14 September 1997 / Accepted: 16 October 1997     

Importance of actin cytoskeleton behaviour during preservation of carrot cell suspensions in liquid nitrogen

Summary Conventional methods for preservation of suspended, highly vacuolated, plant cells in liquid nitrogen (LN) usually involve equilibration in molar concentrations of cryoprotective additives, followed by slow cooling to an intermediate subzero temperature (–40 °C), before quenching in LN. Cryomicroscopy was used to monitor the reversible protoplasmic shrinkage of cryoprotected carrot cells, caused by freeze-induced dehydration. Behaviour of actin filaments was analyzed by fluorescence microscopy after labelling with rhodarnine-conjugated phalloidin, in relation to the type of pretreatment and to survival and regrowth ability after preservation at — 196 °C. Loading with dimethylsulphoxide (Me₂SO, 5%) resulted in high survival rates (70%) and regrowth. After thawing, the actin filament (MF) abundance was reduced, but the structure and distribution of the remaining MFs seemed undisturbed. Higher Me₂SO concentrations caused further reduction of MFs, which appeared fragmented after thawing. MFs were maintained by pretreatment with 0.5 M sorbitol alone but carrot cells did not survive at — 196 °C. The same pretreatment, followed by incubation with cytochalasin D (10 M), which greatly reduced MFs, enabled plasmolyzed carrot cells to survive preservation in liquid nitrogen. Thus, after both Me₂SO and sorbitol plus cytochalasin D pretreatments, partial disruption of actin filaments seemed to accompany (Me₂SO) or promote (sorbitol plus cytochalasin D) freezing tolerance at extremely low temperatures.Abbreviations CD cytochalasin D - FDA fluorescein diacetate - LN liquid nitrogen - MF actin filament - Me₂SO dimethylsulphoxide     

Reorganization of the cortical cytoskeleton in tip-growing fern protonemal cells during phytochrome-mediated phototropism and blue light-induced apical swelling

Summary Circular arrays of cortical microtubules (MTs) and microfilaments (MFs) are found in the subapical region of tip-growing protonemal cells of the fernAdiantum capillus-veneris. Reorganization of the two cytoskeletal structures during phytochrome-mediated phototropism and blue light-induced apical swelling was investigated by double-staining of MTs and MFs with rhodaminephalloidin and an indirect immunofluorescence method with tubulinspecific antibody. Before any growth responses were detectable, the MF and MT structures were reorganized according to similar patterns in both photoresponses, that is, oblique orientation and transient disappearance of the structures occurred during the phototropic response, and the disappearance of the structures occurred during apical swelling. The reorganization of MF structures clearly preceded that of the MT structures in the phototropic response. In the case of apical swelling, both types of circular array disappeared with an almost identical time course.These results provide evidence for the significant role of the circular organization of MFs as well as of MTs, in the light-induced growth responses of tip-growing fern protonemal cells. Possible roles of the circular array of MFs in the regulation of tip growth are discussed.Abbreviations DMSO dimethylsulfoxide - PIPES piperazine-N,N-bis(2-ethane-sulfonic acid) - EGTA ethyleneglycol-bis-(-aminoethylether)-N,N,N,N-tetraacetic acid - PMSF phenylmethylsulfonyl fluoride - MF microfilament - MT microtubule - Rh-Phal rhodaminelabeled phalloidin     

Actin microfilaments do not form a dense meshwork inLilium longiflorum pollen tube tips

Summary Controversy over whether the apical region of a growing pollen tube contains a dense array of actin microfilaments (MFs) was the impetus for the present study. Microinjection of small amounts of fluorescently labeled phalloidin allowed the observation of MF bundles inLilium longiflorum pollen tubes that were growing and functioning normally. The results show that while the pollen tube contains numerous MF bundles arranged axially, the apical region is essentially devoid of them. The MF bundles could be seen shifting and changing in distribution as the cells grew, but they always remained out of the apical regions. Perturbation of normal growth and function by caffeine causes a change in the MF distribution, which returns to normal upon removal of caffeine from the growth medium. The lack of MFs in the apex is confirmed by careful immunogold electron microscopic analysis of thin sections of rapidly frozen and freeze-substituted pollen tubes, in which very fine MF bundles could be seen somewhat closer to the tip than is discernible with fluorescence microscopy. Still, these are very few in number and are basically absent from the very tip. Thus a reassessment of current assumptions about the distribution of actin in the pollen tube apical region is required.Abbreviations MF microfilaments - FITC fluorescein isothiocyanate - RF-FS rapidly frozen and freeze-substituted - EM electron microscopy Dedicated to Professor Eldon H. Newcomb in recognition of his contributions to cell biology     

Actin organization and regulation during pollen tube growth

Pollen is the male gametophyte of seed plants and its tube growth is essential for successful fertilization. Mounting evidence has demonstrated that actin organization and regulation plays a central role in the process of its germination and polarized growth. The native structures and dynamics of actin are subtly modulated by many factors among which numerous actin binding proteins (ABPs) are the most direct and significant regulators. Upstream signals such as Ca²⁺, PIP₂ (phosphatidylinositol-4,5-bis-phosphate) and GTPases can also indirectly act on actin organization through several ABPs. Under such elaborate regulation, actin structures show dynamically continuous modulation to adapt to the in vivo biologic functions to mediate secretory vesicle transportation and fusion, which lead to normal growth of the pollen tube. Many encouraging progress has been made in the connection between actin regulation and pollen tube growth in recent years. In this review, we summarize different factors that affect actin organization in pollen tube growth and highlight relative research progress.     

The role of microfilaments in the organization and orientation of microtubules during the cell cycle transition from M phase to G1 phase in tobacco BY-2 cells

Summary During cell cycle transition from M to G₁ phase, micro-tubules (MTs), organized on the perinuclear region, reached the cell cortex. Microfilaments (MFs) were not involved in this process, however, MFs accumulated to form a ring-like structure in the division plane and from there they elongated toward the distal end in the cell cortex. Subsequently, when MTs elongated along the long axis of the cells, towards the distal end, the MTs ran into and then associated with the predeveloped MFs in the cell cortex, suggesting the involvement of MFs in organizing the parallel oriented MTs in the cell cortex. When cortical MTs were formed in the direction transverse to the long axis of cells, the two structures were again closely associated. Therefore, with regards to the determination of the direction of organizing MTs, predeveloped MFs may have guided the orientation of MTs at the initial stage. Disorganization of MFs in this period, by cytochalasins, prevented the organization of cortical MTs, and resulted in the appearance of abnormal MT configurations. We thus demonstrate the involvement of MFs in determining the orientation and organization of cortical MTs, and discuss the possible role of MFs during this process.Abbreviations CB cytochalasin B - CD cytochalasin D - CLSM confocal laser scanning microscopy - DAPI 4,6-diamidino-2-phenylindole - EF-1 elongation factor 1 - MF microfilament - MT microtubule     

The initiation and organization of microtubules in germinating pear (Pyrus communis L.) pollen

To study microtubule organization in germinating pear (Pyrus communis L., cv., Bartlett) pollen, we removed the pollen wall by freeze-fracturing before treating the resultant pollen protoplasts by conventional immunofluorescence procedures. Results reveal that axial bundles of microtubules are present in the generative cell of both inactivated and activated pollen grains. Microtubules are not present in the vegetative cells of inactivated pollen, but they are present in the vegetative cells of activated pollen grains. Microtubule nucleation occurs in the vegetative cell cortex. Subsequently, the microtubules grow as branching arrays through most of the vegetative cell cortex except at the apertures where they form localized converging or criss-cross patterns. Eventually, in a germinated pollen grain, the microtubules form network-like arrays through most of the pollen grain and a collar of short arrays at the base of the pollen tube. It is suggested that the role of vegetative cell microtubules in pollen germination is indirect through their mediation of the conformational changes in actin organization that are essential for pollen germination.     

Confocal Microscopic Observations of Microfilaments in germinating Pollen of Hedychium coronarium

Changes in the microfilament (actin)organization in the germinating pollen of Hedychium coronarium Koenig were followed after TRITC-phalloidin staining without fixation. Changes in the pattern of organization of the microfilaments were visualized using eonfocal microscopy. In the hydrated pollen a reticulate network of microfilament can be observed. Before the pollen tube protrudes out from the germination pore numerous microfilaments begin to converge towards the aperture. After 10–30 mins of germination,pollen tube appears. In the pollen tube a new network of microfilament forms near the tip region. Between the pollen and the pollen tube tip region there are numerous linearly arranged microfilaments. About 1 hour after germination,the pollen tube has reached a length of about 300μm Inside the pollen, tube there are numerous longitudinally oriented microfilaments. The microfilament network in the pollen tube tip region does not change much. About 2 hours after germination,the pollen tube reaches about 1000μm in length. At this stage,the pattern of distribution of microfilament in the pollen tube is very similar to that seen at the earlier stages of development ,whereas the pattern is somewhat different in the pollen. Microfilaments in the central region of the pollen grain disappear but still a parietal network in the peripheral region. About 5 hours after germination,the microfilaments in the pollen tube become abnormally variable and produce branches. Some even change into spicules, sheets and thick bundles.     

Actin and pollen tube growth

Summary Actin microfilaments (MFs) are essential for the growth of the pollen tube. Although it is well known that MFs, together with myosin, deliver the vesicles required for cell elongation, it is becoming evident that the polymerization of new actin MFs, in a process that is independent of actomyosin-dependent vesicle translocation, is also necessary for cell elongation. Herein we review the recent literature that focuses on this subject, including brief discussions of the actin-binding proteins in pollen, and their possible role in regulating actin MF activity. We promote the view that polymerization of new actin MFs polarizes the cytoplasm at the apex of the tube. This process is regulated in part by the apical calcium gradient and by different actin-binding proteins. For example, profilin binds actin monomers and gives the cell control over the initiation of polymerization. A more recently discovered actin-binding protein, villin, stimulates the formation of unipolar bundles of MFs. Villin may also respond to the apical calcium gradient, fragmenting MFs, and thus locally facilitating actin remodeling. While much remains to be discovered, it is nevertheless apparent that actin MFs play a fundamental role in controlling apical cell growth in pollen tubes.Dedicated to Professor Brian E. S. Gunning on the occasion of his 65th birthday     

Possible involvement of membrane fluidity in helicoidal microfibrillar orientation in the coenocytic green alga,Boergesenia forbesii

Summary Microfibrillar textures and orientation of cellulose microfibrils (MFs) in the coenocytic green alga,Boergesenia forbesii, were investigated by fluorescence and electron microscopy. Newly formed aplanosporic spherical cells inBoergesenia start to form cellulose MFs on their surfaces after 2 h of culture at 25°C. Microfibrillar orientation becomes random, fountain-shaped, and helicoidal after 2, 4, and 5 h, respectively. The fountain orientation of MFs is usually apparent prior to helicoidal MF orientation and thus may be considered to initiate helicoid formation. Microfibrils continue to take on the helicoidal arrangement during the growth ofBoergesenia thallus. The helicoidal orientation of MFs occurs through gradual counterclockwise change in MF deposition by terminal complexes (TCs) viewed from inside the cell. On the dorsal side of curving TC impressions in helicoidal texture formation on a freeze-fractured plasma membrane, the aggregation of intramembranous particles (IMPs) occurs. Membrane flow may thus possibly affect the regulation of helicoidal orientation inBoergesenia. Following treatment with 3 M amiprophos-methyl (APM) or 1 mM colchicine, cortical microtubules (MTs) completely disappear within 24 h but helicoidal textures formation is not affected. With 15 M cytochalasin B or 30 M phalloidin, however, the helicoidal orientation of MFs becomes random. Treatment with CaCl₂ (10 mM) causes the helicoidal MF orientation of cells to become random, but co-treatment with N-(6-aminohexyl)-5-chloro-1-naphthalene sulfonamide (W-7) (100 mM) prevents this effect, though W-7 has no effect on the helicoidal MF formation. It thus follows that MF orientation inBoergesenia possibly involves actin whose action may be regulated by calmodulin.Abbreviations APM amiprophos-methyl - DMSO dimethylsulfoxide - IMP intramembranous particle - MF microfibril - MT microtubule - TC terminal complex; W-7 N-(6-aminohexyl)-5-chloro-1-naphthalene sulfonamide     

A cytoskeletal basis for wood formation in angiosperm trees: the involvement of microfilaments

The cortical microfilament (MF) component of the cytoskeleton within axial elements of the secondary vascular system of the angiosperm tree, Aesculus hippocastanum L. (horse-chestnut) was studied using transmission electron microscopy of ultrathin sections and indirect immunofluorescence microscopy of actin in thick sections. As seen by electron microscopy, MF bundles have a net axial orientation within fusiform cambial cells and their secondary vascular derivatives (i.e. in the axial xylem and phloem parenchyma, xylem fibres, vessel and sieve elements, and companion cells). Immunofluorescence studies, however, reveal that this axial orientation can be more accurately described as a helix of extremely high pitch; it is a persistent feature of all axial secondary vascular elements during their development. Helical MF arrays are the only arrangement seen in secondary phloem cells. However, in addition to helices, other MF arrays are seen in secondary xylem cells. For example, fibres possess ellipses of MFs associated with simple-pit formation, and vessel elements possess circular arrays of MFs that associate with the developing inter-vessel bordered pits, ray–vessel contact pits, and with the perforation plate. Linear MF arrays are seen co-oriented with the developing tertiary wall-thickenings in vessel elements. The possible roles of MFs during the cytodifferentiation of secondary vascular cells is discussed, and compared with that of microtubules. Received: 7 June 1999 / Accepted: 23 December 1999     

Ultrastructure of the cytoskeleton in freeze-substituted pollen tubes ofNicotiana alata

Summary The ultrastructure of the cytoskeleton inNicotiana alata pollen tubes grownin vitro has been examined after rapid freeze fixation and freeze substitution (RF-FS). Whereas cytoplasmic microtubules (MTs) and especially microfilaments (MFs) are infrequently observed after conventional chemical fixation, they occur in all samples prepared by RF-FS. Cortical MTs are oriented parallel to the long axis of the pollen tube and usually appear evenly spaced around the circumference of the cell. They are always observed with other components in a structural complex that includes the following: 1. a system of MFs, in which individual elements are aligned along the sides of the MTs and crossbridged to them; 2. a system of cooriented tubular endoplasmic reticulum (ER) lying beneath the MTs, and 3. the plasma membrane (PM) to which the MTs appear to be extensively linked. The cortical cytoskeleton is thus structurally complex, and contains elements such as MFs and ER that must be considered together with the MTs in any attempt to elucidate cytoskeletal function. MTs are also observed within the vegetative cytoplasm either singly or in small groups. Observations reveal that some of these may be closely associated with the envelope of the vegetative nucleus. MTs of the generative cell, in contrast to those of the vegetative cytoplasm, occur tightly clustered in bundles and show extensive cross-bridging. These bundles, especially in the distal tail of the generative cell, are markedly undulated. MFs are observed commonly in the cytoplasm of the vegetative cell. They occur in bundles oriented predominantly parallel to the pollen tube axis. Although proof is not provided, we suggest that they are composed of actin and are responsible for generating the vigorous cytoplasmic streaming characteristic of living pollen tubes.Abbreviations EGTA ethylene glycol bis-(-aminoethyl ether), N,N,N,N-tetraacetic acid - ER endoplasmic reticulum - MF microfilament - MT microtubule - PEG polyethylene glycol - PM plasma membrane - RF-FS rapid freeze fixation-freeze substitution     

Intracellular motility,the actin cytoskeleton and germinability in the pollen of wheat (Triticum aestivum L.)

Summary The tricellular pollen of wheat germinates rapidly on a receptive stigma without the often protracted activation period characteristic of bicellular pollens. This is associated with a high level of hydration in the mature pollen and the absence of a dormancy period. Intracellular movement of organelles continues throughout development; in the mature pollen along pathways related both to the aperture site and the distribution of the amyloplasts in the vegetative cell. The movement pathways reflect the organisation of the actin cytoskeleton, elements of which are already focused upon the germination site at the time of dispersal, a disposition only achieved during rehydration and activation in bicellular pollens. Dehydration after dispersal rapidly arrests movement, disrupts the actin cytoskeleton and leads to loss of germinability. These effects are irreversible, again in contrast to the situation found in bicellular pollens such as those of the Liliaceae, species of which have been shown to be capable of withstanding several cycles of hydration and dehydration while still retaining some capacity for germination.