Confocal laser scanning microscopy of microtubule organizational changes in isolated generative cells of Allemanda neriifolia during mitosis

Summary Organizational changes in the microtubules of isolated generative cells of Allemanda neriifolia during mitosis were examined using anti--tubulin and confocal laser scanning microscopy. Due to an improved resolution and a lack of out-of-focus interference, the images of the mitotic cytoskeleton obtained using the confocal microscope are much clearer than those obtained using the non-confocal fluorescence systems. In the confocal microscope one can see clearly that the spindle-shaped interphase cells contain a cage-like cytoskeleton consisting of numerous longitudinally oriented microtubule bundles and some associated smaller bundles. At prophase, the shape of the cells invariably becomes spherical. The microtubule cytoskeleton inside the cells concomitantly changes into a less organized form — consisting of thick bundles, patches, and dots. This structural form is not very stable, and soon afterwards the cytoskeleton changes into a reticulate network. Then the nuclear envelope breaks down, and the microtubules become randomly dispersed throughout the cell. Afterwards, the microtubules reorganize themselves into a number of half-spindle-like structures, each possessing a microtubule-nucleating center. The locations of these centres mark out the positions of the presumptive spindle poles. Numerous microtubules radiate from these centres toward the opposite pole. At metaphase, the microtubules form a number of bipolar spindles. Each spindle has two half-spindles, and each half-spindle has a sharply focused microtubule centre at the pole region. From the centres, kinetochore and non-kinetochore microtubules radiate toward the opposite half-spindle. At anaphase A, sister chromatids separate, the cells elongate, and the kinetochore microtubules disappear; the non-kinetochore microtubules, however, remain, and a new array of microtubules, in the form of a cage, appears. The peripheral cage bundles and the non-kinetochore bundles coverge into a sharp point at the pole region. Later, at anaphase B the microtubule cytoskeleton undergoes reorganization giving rise to a new array of longitudinally oriented microtubule bundles in the cell centre and a cage-like cytoskeleton in the periphery. At telophase, some of the cells elongate further, but some become spherical. The microtubules in the central region of the elongated cell become partially disrupted due to the formation of a phragmoplast-junction-like structure in the mid-interzone region. The microtubule bundles at the periphery are spirally organized, and they appear not to be disrupted by the phragmoplast-like junction. The microtubules in the spherical telophase cells (unlike those seen in the elongated telophase cells) are arranged differently, and no phragmoplast-junction-like structure forms in the spherical cells. The structural and functional significances of some of these new features of the organization of the microtubule cytoskeleton as revealed by the confocal microscope are discussed.     

Effects of colchicine and amiprophos-methyl on microfibril arrangement and cell shape inAdiantum protonemal cells

Summary 5 mM colchicine and 1 g/ml amiprophos-methyl, known antimicrotubule agents, were applied to fernAdiantum protonemata under red light. Both drugs caused microtubule disruption and subsequent apical swelling of protonemal cells after certain lag periods. While the lag periods for the onset of microtubule disruption after application of the two drugs were different (within 15 minutes in amiprophos-methyl, 1 hour in colchicine), the lag periods of apical swelling after microtubule disruption were nearly the same (approx. 70 minutes). The results suggest that the apical swelling is a consequence of microtubule disruption.In cells examined 1 hour after microtubule disruption by either drug, the microfibril arrangement of the innermost layer of the cell wall was random at the tip, transverse in the subapical region, and roughly longitudinal in the cylindrical region. This pattern of microfibrils was similar to that of untreated cells in which the microtubules show a similar arrangement (Murata and Wada 1989). Surprisingly, even after approx. 4 hours of microtubule disruption, when apical swelling had occurred in most cells, the pattern of microfibril deposition was not altered. The role of microtubules in oriented microfibril deposition and the mechanism of control of cell shape are discussed.Abbreviations APM amiprophos-methyl - DMSO dimethylsulfoxide - MT(s) microtubule(s) - PBS phosphate buffered saline     

The role of microtubules and cell-wall deposition in elongation of regenerating protoplasts of Mougeotia

Protoplasts of the filamentous green alga Mougeotia sp. are spherical when isolated and revert to their normal cylindrical cell shape during regeneration of a cell wall. Sections of protoplasts show that cortical microtubules are present at all times but examination of osmotically ruptured protoplasts by negative staining shows that the microtubules are initially free and become progressively cross-bridged to the plasma membrane during the first 3 h of protoplast culture. Cell-wall microfibrils areoobserved within 60 min when protoplasts are returned to growth medium; deposition of microfibrils that is predominantly transverse to the future axis of elongation is detectable after about 6 h of culture. When regenerating protoplasts are treated with either colchicine or isopropyl-N-phenyl carbamate, drugs which interfere with microtubule polymerization, they remain spherical and develop cell walls in which the microfibrils are randomly oriented.     

Effect of colchicine on rat mast cells

In the mast cell, a well-developed array of microtubules is centered around the centrioles. Complete loss of microtubules is observed when mast cells are treated with 10(-5) M colchicine for 4 h at 37 degrees C. The loss of ultrastructurally evident microtubules is associated with a marked change in the shape of mast cells from spheroids to highly irregular, frequently elongated forms with eccentric nuclei. In colchicine-treated cells the association of nucleus, Golgi apparatus, and centrioles is also lost. Mast cells exposed to 10(-5) M colchicine for 4 h at 37 degrees C retain 80% of their capacity to release histamine when stimulated by polymyxin B. Exocytosis is evident in stimulated cells pretreated with colchicine and lacking identifiable microtubules. When the conditions of exposure of mast cells to colchicine are varied with respect to the concentration of colchicine, the length of exposure, and the temperature of exposure, dissociation between deformation of cell shape and inhibition of histamine secretion is observed. These observations indicate that microtubules are not essential for mast cell histamine release and bring into question the assumption that the inhibitory effect of colchicine on mast cell secretion depends on interference with microtubule integrity.     

Microtubules and morphogenesis in ordinary epidermal cells ofVigna sinensis leaves

Summary Undifferentiated ordinary epidermal cells (ECs) ofVigna sinensis leaves possess straight anticlinal walls and cortical microtubules (Mts) scattered along them. At an early stage of EC differentiation cortical Mts adjacent to the above walls form bundles normal to the leaf plane, loosely interconnected through the cortical cytoplasm of the internal periclinal wall. At the upper ends of the Mt bundles, Mts fan out towards the external periclinal wall and form radial arrays. Mt bundles and radial arrays exhibit strict alternate disposition between neighbouring ECs. An identical reticulum of cellulose microfibril (CM) bundles is deposited outside the Mt bundles. Local wall pads rise at the junctions of anticlinal walls with the external periclinal one, where the CM bundles terminate. They display radial CMs fanning towards the external periclinal wall. The CM bundles and radial CM systems prevent local cell bulging, but allow it in the intervening wall areas. In particular, the radial CM systems dictate the pattern of EC waviness by favouring local tangential expansion of external periclinal wall. As a result, ECs obtain an undulate appearance. Constrictions in one EC correspond with protrusions of adjacent ECs. ECs affected by colchicine entirely lose their Mts and do not develop wavy walls, an observation substantiating the role of cortical Mts in EC morphogenesis.Abbreviations CM cellulose microfibril - DTT dithiothreitol - EC epidermal cell - MSB microtubule stabilizing buffer - Mt microtubule - PBS phosphate buffered saline - PMSF phenylmethylsulfonyl fluoride     

Microtubules and epithem-cell morphogenesis in hydathodes of Pilea cadierei

When cell divisions have ceased, the epithem of the hydathodes of Pilea cadierei Gagnep. et Guill. consists of small polyhedral cells exhibiting a meristematic appearance, and completely lacks intercellular spaces. The cortical microtubules in epithem cells exhibit a unique organization: they are not scattered along the whole wall surface but form groups lying at some distance from each other. In sections, from two to eight groups of microtubules can be observed, each lining a wall region averaging between 0.5 and 1.5 m in length. These groups represent sections of microtubule bundles girdling a major part or the whole of the cell periphery. They are connected to one another by anastomoses, forming a microtubular reticulum. The assembly of microtubule bundles is followed by the appearance of distinct local thickenings in the adjacent wall areas. The cellulose microfibrils in the thickenings are deposited in parallel to the underlying microtubules. Gradually, the vacuolating epithem cells undergo swelling, except for the areas bounded by the wall thickenings. Since the latter, and actually their constituent bundles of cellulose microfibrils, cannot extend in length the differential cell growth results in schizogenous formation of intercellular spaces between contiguous cell walls at their thickened regions. The spaces then broaden and merge to become an extensive intercellular space system. As a result of the above processes, the epithem cells become constricted and finally deeply lobed. The observations show that (i) the cortical microtubules are intimately involved in the morphogenesis of the epithem cells and (ii) the initiation and development of the epithem intercellular spaces is a phenomenon directly related to cell morphogenesis and therefore to the cortical microtubule cytoskeleton. The sites of initiation of these spaces are highly predictable.     

MICROTUBULE BIOGENESIS AND CELL SHAPE IN OCHROMONAS : II. The Role of Nucleating Sites in Shape Development

The proposal made in the preceding paper that the species-specific shape of Ochromonas is mediated by cytoplasmic microtubules which are related to two nucleating sites has been experimentally verified. Exposure of cells to colchicine or hydrostatic pressure causes microtubule disassembly and a correlative loss of cell shape in a posterior to anterior direction. Upon removal of colchicine or release of pressure, cell shape regenerates and microtubules reappear, first in association with the kineto-beak site concomitant with regeneration of the anterior asymmetry, and later at the rhizoplast site concomitant with formation of the posterior tail. It is concluded that two separate sets of cytoplasmic tubules function in formation and maintenance of specific portions of the total cell shape. On the basis of the following observations, we further suggest that the beak and rhizoplast sites could exert control over the position and timing of the appearance, the orientation, and the pattern of microtubule distribution in Ochromonas. (a) the two sites are accurately positioned in the cell relative to other cell organelles; (b) in regenerating cells microtubules reform first at these sites and appear to elongate to the cell posterior; (c) microtubules initially reappear in the orientation characteristic of the fully differentiated cell; (d) the two sets of tubules are polymerized at different times, in the same sequence, during reassembly or resynthesis of the microtubular system. Experiments using cycloheximide, after a treatment with colchicine, have demonstrated that Ochromonas cannot reassume its normal shape without new protein synthesis. This suggests that microtubule protein once exposed to colchicine cannot be reassembled into microtubules. Pressure-treated cells, on the other hand, reassemble tubules and regenerate the normal shape in the presence or absence of cycloheximide. The use of these two agents in analyzing nucleating site function and the independent processes of synthesis and assembly of microtubules is discussed.     

Interrelation between the spatial disposition of actin filaments and microtubules during the differentiation of tracheary elements in culturedZinnia cells

Summary Changes in the spatial relationship between actin filaments and microtubules during the differentiation of tracheary elements (TEs) was investigated by a double staining technique in isolatedZinnia mesophyll cells. Before thickening of the secondary wall began to occur, the actin filaments and microtubules were oriented parallel to the long axis of the cell. Reticulate bundles of microtubules and aggregates of actin filaments emerged beneath the plasma membrane almost simultaneously, immediately before the start of the deposition of the secondary wall. The aggregates of actin filaments were observed exclusively between the microtubule bundles. Subsequently, the aggregates of actin filaments extended preferentially in the direction transverse to the long axis of the cell, and the arrays of bundles of microtubules which were still present between the aggregates of actin filaments became transversely aligned. The deposition of the secondary walls then took place along the transversely aligned bundles of microtubules.Disruption of actin filaments by cytochalasin B produced TEs with longitudinal bands of secondary wall, along which bundles of microtubules were seen, while TEs produced in the absence of cytochalasin B had transverse bands of secondary wall. These results indicate that actin filaments play an important role in the change in the orientation of arrays of microtubules from longitudinal to transverse. Disruption of microtubules by colchicine resulted in dispersal of the regularly arranged aggregates of actin filaments, but did not inhibit the formation of the aggregates itself, suggesting that microtubules are involved in maintaining the arrangement of actin filaments but are not involved in inducing the formation of the regularly arranged aggregates of actin filaments.These findings demonstrate that actin filaments cooperate with microtubules in controlling the site of deposition of the secondary wall in developing TEs.Abbreviations DMSO dimethylsulfoxide - EGTA ethyleneglycolbis(-aminoethyl ether)-N,N,N,N-tetraacetic acid - FITC fluorescein isothiocyanate - MSB microtubule-stabilizing buffer - PBS phosphate buffered saline - PIPES piperazine-N,N-bis(2-ethanesulfonic acid) - TE tracheary element     

Cellulose microfibril orientation and cell shaping in developing guard cells of Allium: The role of microtubules and ion accumulation

Summary The role of microtubules and ions in cell shaping was investigated in differentiating guard cells of Allium using light and electron microscopy and cytochemistry. Microtubules appear soon after cytokinesis in a discrete zone close to the plasmalemma adjacent to the common wall between guard cells. The microtubules fan out from this zone, which corresponds to the future pore site, towards the other sides of the cell. Soon new cellulose microfibrils are deposited on the wall adjacent to the microtubules and oriented parallel to them. As the wall thickens, the shape of the cell shifts from cylindrical to kidney-like. Studies with polarized light show that guard cells gradually assume a birefringence pattern during development characteristic of wall microfibrils radiating away from the pore site. Retardation increases from 10 Å when cells just begin to take shape, to 80–100 Å at maturity. Both microfibril and microtubule orientation remain constant during development. Observations on aberrant cells including those produced under the influence of drugs such as colchicine, which leads to loss of microtubules, abnormal wall thickenings and disruption of wall birefringence, further support the role of microtubules in cell shaping through their function in the localization of wall deposition and the orientation of cellulose microfibrils in the new wall layer. Potassium first appears in guard mother cells before division and rapidly accumulates afterwards during cell shaping, as judged by the cobaltinitrite reaction. Some chloride and perhaps organic acid anions also accumulate. Thus, these ions, which are known to play a role in the function of mature guard cells, also seem to be important in the early growth and shaping of these cells.Abbreviations IPC isopropyl-N-phenylcarbamate - CB cytochalasin B - GMC guard mother cell - MTOC microtubule organizing center     

Microtubule organization,mesophyll cell morphogenesis,and intercellular space formation inAdiantum capillus veneris leaflets

Summary Mesophyll cells (MCs) ofAdiantum capillus veneris are elongated and highly asymmetric, bearing several lateral branches and forming a meshwork resembling aerenchyma. Young MCs are polyhedral and display oppositely arranged walls and transverse cortical microtubules (Mts). Their morphogenesis is accomplished in three stages. At first they become cylindrical. Intercellular space (IS) canals, containing PAS-positive material, open through their junctions and expand laterally. During the second stage the cortical Mts form a reticulum of bundles, externally of which an identical reticulum of wall thickenings, containing bundles of parallel cellulose microfibrils, emerges. MCs do not grow in girth in the regions of wall thickenings, where constrictions form and new ISs open. Thus, MCs obtain a multi-lobed form. At the third morphogenetic stage MCs display a multi-axial growth. During this process, additional Mt rings are assembled at the base of cell lobes accompanied by similarly organized wall thickenings-cellulose microfibrils. Consequently, cell lobes elongate to form lateral branches, where MCs attach one another, while the IS labyrinth broadens considerably. Colchicine treatment, destroying Mts, inhibits MC morphogenesis and the concomitant IS expansion, but does not affect IS canal formation. These observations show that: (a) MC morphogenesis inA. capillus veneris is an impressive phenomenon accurately controlled by highly organized cortical Mt systems. (b) The disposition of Mt bundles between neighbouring MCs is highly coordinated, (c) The perinuclear cytoplasm does not appear to be involved in cortical Mt formation. Cortical sites seem to participate in Mt bundling, (d) Although extensive IS canals open before Mt bundling, the Mtdependent MC morphogenesis contributes in IS formation.Abbreviations EM electron microscopy - ER endoplasmic reticulum - IS intercellular space - MC mesophyll cell - MSB microtubule stabilizing buffer - Mt microtubule - PBS phosphate buffered saline     

Microtubule changes during the development of generative cells in Hippeastrum vittatum pollen

Summary The three-dimensional organization of microtubules in generative cells during their development in pollen grains of Hippeastrum vittatum and the dynamic changes that occur were studied by collecting large quantities of fixed and isolated generative cells for immunofluorescence microscopy. The framework configuration and the arrangement pattern of the microtubule organization was investigated. The microtubule framework changed in shape from being spherical at an early stage to being long spindle-shaped at maturity: various transitional forms were observed: ellipsoidal, pear-shaped and short spindle-shaped. The microtubule arrangement making up this framework changed correspondingly from the original network, which was random in distribution, to axially oriented long bundles via an intermediate pattern composed of a mixture of networks with long bundles. However, cells with the same framework configuration might be heterogeneous in microtubule arrangements.     

Mechanisms of cellular adhesion : II. The interplay between adhesion, the cytoskeleton and morphology in substrate-attached cells

cAMP/theophylline exaggerates cell shape—whether the fibroblastic morphology of controls or the epithelioid shape of colchicine-treated cells. The ultrastructural basis is that cAMP/theophylline increases the number and linearity of microtubules and microfilament bundles, although where also treated with colchicine, the cells adopt a well-spread shape maintained by microfilament bundles alone. Since interference reflection microscopy shows that colchicine promotes the marked alignment of focal contacts (which terminate microfilament bundles) it is concluded that microtubules encourage angular cell form and modify the pattern of adhesions by influencing the directionality of microfilament bundle formation although they are inessential for the maintenance of the spread form or adhesion per se.     

Spreading of porcine kidney epithelial cells under normal conditions and under the effect of inhibitors of energy metabolism. II. Behavior of cellular organelles

In the present work the behavior of mitochondria and lysosomes during cell spreading has been investigated in normal conditions and under ATP-synthesis inhibitors: sodium aside and N,N-dicyclohexylcarbodiimide (DCCD). In the control culture, microtubules run along the stable edge and perpendicular to the leading edge in most of spreading cells. As a whole, microtubules form a dense network in these cells. However, the radial cells contain bundles of microtubules, radiating from the perinuclear area or form circular arrays around the nucleus. The microtubule network is more dense under inhibitory treatment, than in control conditions. In the control culture the spherical cells display numerous small mitochondria (staining with Rhodamine 123). In the process of cell spreading some elongated mitochondria appear, most of them being localized in the perinuclear area. The mitochondria of cells with radial microtubule organization are directed towards the cell periphery, while in cells with circular bundles of microtubules the mitochondria are localized chaotically. Under DCCD treatment the mitochondria retain the staining for 2-3 h. In the spreading cells, round mitochondria may be distributed all over the cytoplasm. In the presence of sodium aside the mitochondria are not stained. However, by means of phase contrast microscopy some disoriented thread-shaped structures are observed, obviously corresponding to mitochondria. In the control conditions, lysosomes (stained with Acridine orange) in spreading cells are dispersed chaotically, all over the cytoplasm, or are localized in the perinuclear area. In the presence of sodium aside lysosomes are observed only in the perinuclear area. Under DCCD treatment lysosomes do not accumulate the dye. Thus, the cytoskeleton modification and changes in the properties of membrane organelles, induced by ATP-synthesis inhibitors, do not prevent attachment, spreading or cell polarization.     

Microtubules do not control orientation of secondary cell wall microfibril deposition inMicrasterias

Summary The influence of the microtubule disorganizing substances amiprophos-methyl (APM) and colchicine on secondary wall formation inMicrasterias denticulata was investigated by the freezeetch technique. The results reveal that neither microtubule inhibitor changes the pattern of microfibril deposition. The application of APM or colchicine also does not cause any structural alterations of the microfibrils or of the protoplasmic (Pf) and the exoplasmic (Ef) fracture face of the plasma membrane, thus indicating that microtubules are not involved in secondary wall formation inM. denticulata. However, since areas of the plasma membrane which collapsed upon freeze-etching are restricted to the Pf-face of cells treated with microtubule inhibitors, cortical microtubules may function as mechanical support during secondary wall formation. In the cortical cytoplasm filamentous structures are found in close spatial relationship and an almost parallel alignment to rosettes of the plasma membrane.     

New techniques enable comparative analysis of microtubule orientation, wall texture, and growth rate in intact roots of Arabidopsis

This article explores root epidermal cell elongation and its dependence on two structural elements of cells, cortical microtubules and cellulose microfibrils. The recent identification of Arabidopsis morphology mutants with putative cell wall or cytoskeletal defects demands a procedure for examining and comparing wall architecture and microtubule organization patterns in this species. We developed methods to examine cellulose microfibrils by field emission scanning electron microscopy and microtubules by immunofluorescence in essentially intact roots. We were able to compare cellulose microfibril and microtubule alignment patterns at equivalent stages of cell expansion. Field emission scanning electron microscopy revealed that Arabidopsis root epidermal cells have typical dicot primary cell wall structure with prominent transverse cellulose microfibrils embedded in pectic substances. Our analysis showed that microtubules and microfibrils have similar orientation only during the initial phase of elongation growth. Microtubule patterns deviate from a predominantly transverse orientation while cells are still expanding, whereas cellulose microfibrils remain transverse until well after expansion finishes. We also observed microtubule-microfibril alignment discord before cells enter their elongation phase. This study and the new technology it presents provide a starting point for further investigations on the physical properties of cell walls and their mechanisms of assembly.     

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.     

Pressure Induced Reorientation of Cortical Microtubules in Epidermal Cells of Lolium rigidum Leaves

In order to assess the effect on microtubule arrays of slowlypressurising cells over 50 s from 0.1 MPa (atmospheric pressure)to 55 MPa, microtubules in epidermal cells of Lolium rigidumleaves were visualised by immunofluorescent staining and fluorescencemicroscopy. In both control and pressure-treated leaves cellshape, measured as the ratio of cell length and width, can becorrelated to the arrangement of cortical microtubules. Microtubulearrays change from random to organised in cells whose lengthis greater than their width. In untreated leaves, elongatedcells have microtubules aligned predominantly transversely.In pressure-treated leaves, elongated cells have microtubulesaligned predominantly longitudinally. Thus, pressure treatmentresults in the rapid reorientation of organised cortical microtubulesfrom a transverse to a longitudinal orientation. (Received June 21, 1993; Accepted July 15, 1993)     

Cortical microtubules optimize cell-wall crystallinity to drive unidirectional growth in Arabidopsis

The shape of plants depends on cellulose, a biopolymer that self-assembles into crystalline, inextensible microfibrils (CMFs) upon synthesis at the plasma membrane by multi-enzyme cellulose synthase complexes (CSCs). CSCs are displaced in directions predicted by underlying parallel arrays of cortical microtubules, but CMFs remain transverse in cells that have lost the ability to expand unidirectionally as a result of disrupted microtubules. These conflicting findings suggest that microtubules are important for some physico-chemical property of cellulose that maintains wall integrity. Using X-ray diffraction, we demonstrate that abundant microtubules enable a decrease in the degree of wall crystallinity during rapid growth at high temperatures. Reduced microtubule polymer mass in the mor1-1 mutant at high temperatures is associated with failure of crystallinity to decrease and a loss of unidirectional expansion. Promotion of microtubule bundling by over-expressing the RIC1 microtubule-associated protein reduced the degree of crystallinity. Using live-cell imaging, we detected an increase in the proportion of CSCs that track in microtubule-free domains in mor1-1, and an increase in the CSC velocity. These results suggest that microtubule domains affect glucan chain crystallization during unidirectional cell expansion. Microtubule disruption had no obvious effect on the orientation of CMFs in dark-grown hypocotyl cells. CMFs at the outer face of the hypocotyl epidermal cells had highly variable orientation, in contrast to the transverse CMFs on the radial and inner periclinal walls. This suggests that the outer epidermal mechanical properties are relatively isotropic, and that axial expansion is largely dependent on the inner tissue layers.     

Microtubule organization in the differentiating transfer cells of the placenta inLilium spp.

Summary Placental cells in the ovarian transmitting tissue ofLilium spp. are organized as transfer cells with inbuddings facing the ovarian locule. A detailed analysis of microtubule (MT) organization during development of these polarized cells is reported here. Formation of wall projections occurs at the apical part of the cell starting on the day of anthesis, and a fully mature secretion zone is found four days after anthesis. MTs are organized into distinct cortical and central arrays. The cortical array undergoes a unique transition at anthesis. MTs in the basal half of the cell remain in longitudinal bundles while in the apical half of the cell their longitudinal orientation is replaced by a transverse alignment. One day after anthesis, these transverse bundles become a meshwork of short, randomly organized MTs, while MTs in the basal half of the cell retain their longitudinal alignment. The realignment of MTs in the apical half of the cell coincides with the deposition of the secondary cell wall. The central array is composed of short, randomly arranged strands of MTs in the cytoplasm between the nucleus and the apical and basal periclinal walls of the cell. This array first appears as solitary strands in the apical part of the cell one day before anthesis. The central array extends during development and is eventually seen in the basal half of the cell. We propose that MTs in the cortical region near the apical wall act as templates for the deposition of cellulose microfibrils in the secondary cell wall. MTs in the central array in these transfer cells may be involved in the trafficking of vesicles and/or positioning of organelles near the secretion zone.Abbreviations MT microtubule - daa day after anthesis - dba day before anthesis     

Microtubule reorganization,cell wall synthesis and establishment of the axis of elongation in regenerating protoplasts of the algaMougeotia

Summary Microtubule reorganization and cell wall deposition have been monitored during the first 30 hours of regeneration of protoplasts of the filamentous green algaMougeotia, using immunofluorescence microscopy to detect microtubules, and the cell-wall stain Tinopal LPW to detect the orientation of cell wall microfibrils. In the cylindrical cells of the alga, cortical microtubules lie in an ordered array, transverse to the long axis of the cells. In newly formed protoplasts, cortical microtubules exhibit some localized order, but within 1 hour microtubules become disordered. However, within 3 to 4 hours, microtubules are reorganized into a highly ordered, symmetrical array centered on two cortical foci. Cell wall synthesis is first detected during early microtubule reorganization. Oriented cell wall microfibrils, co-aligned with the microtubule array, appear subsequent to microtubule reorganization but before cell elongation begins. Most cells elongate in the period between 20 to 30 hours. Elongation is preceded by the aggregation of microtubules into a band intersecting both foci, and transverse to the incipient axis of elongation. The foci subsequently disappear, the microtubule band widens, and microfibrils are deposited in a band which is co-aligned with the band of microtubules. It is proposed that this band of microfibrils restricts lateral expansion of the cells and promotes elongation. Throughout the entire regeneration process inMougeotia, changes in microtubule organization precede and are paralleled by changes in cell wall organization. Protoplast regeneration inMougeotia is therefore a highly ordered process in which the orientation of the rapidly reorganized array of cortical microtubules establishes the future axis of elongation.