Endosperm Development in Barley: Microtubule Involvement in the Morphogenetic Pathway

An immunofluorescence study of sectioned barley endosperm imaged by confocal laser scanning microscopy provided three-dimensional data on the relationship of microtubules to the cytoplasm, nuclei, and cell walls during development from 4 to 21 days after pollination (DAP). Microtubules play an important role throughout endosperm ontogeny. The syncytium is organized into units of nuclear-cytoplasmic domains by nuclear-based radial microtubule systems that appear to control the pattern of the first anticlinal walls at 5 to 6 DAP. After 7 DAP, phragmoplasts of two origins (interzonal and cytoplasmic) guide wall formation. Large compartments formed by the "free growing" walls in association with cytoplasmic phragmoplasts formed adventitiously at interfaces of opposing microtubule systems are subsequently subdivided by interzonal phragmoplast/cell plates to give rise to the starchy endosperm. During development of the aleurone layer from 8 to 21 DAP, the microtubule cycle is typical of plant histogenesis; cortical microtubules are hooplike, and preprophase bands of microtubules predict the division plane.     

Regulation of secondary cell wall development by cortical microtubules during tracheary element differentiation in Arabidopsis cell suspensions

Cortical microtubules participate in the deposition of patterned secondary walls in tracheary element differentiation. In this study, we established a system to induce the differentiation of tracheary elements using a transgenic Arabidopsis (Arabidopsis thaliana) cell suspension stably expressing a green fluorescent protein-tubulin fusion protein. Approximately 30% of the cells differentiated into tracheary elements 96 h after culture in auxin-free media containing 1 mum brassinolide. With this differentiation system, we have been able to time-sequentially elucidate microtubule arrangement during secondary wall thickening. The development of secondary walls could be followed in living cells by staining with fluorescein-conjugated wheat germ agglutinin, and the three-dimensional structures of the secondary walls could be simultaneously analyzed. A single microtubule bundle first appeared beneath the narrow secondary wall and then developed into two separate bundles locating along both sides of the developing secondary wall. Microtubule inhibitors affected secondary wall thickening, suggesting that the pair of microtubule bundles adjacent to the secondary wall played a crucial role in the regulation of secondary wall development.     

Organisation of microtubules and actin filaments in the cortex of differentiating Selaginella guard cells

Summary Using fluorescent probes and confocal laser scanning microscopy we have examined the organisation of the microtubule and actin components of the cytoskeleton in kidney-shaped guard cells of six species of Selaginella. The stomata of Selaginella exhibit novel cytoskeletal arrangements, and at different developmental stages, display similarities in microtubule organisation to the two major types of stomata: grass (dumbbell-shaped) and non-grass (kidney-shaped). Initially, cortical microtubules and F-actin radiate from the stomatal pore and extend across the external and internal periclinal cell surfaces of the guard cells. As the stomata differentiate, the cytoskeleton reorients only along the internal periclinal walls. Reorganisation is synchronous in guard cells of the same stoma. Microtubules on the inner periclinal walls of the guard cells now emanate from areas of the ventral wall on either side of the pore and form concentric circles around the pore. The rearrangement of F-actin is similar to that of microtubules although F-actin is less well organised. Radial arrays of both microtubules and F-actin are maintained adjacent to the external surfaces. Subsequently, in two of the six species of Selaginella examined, microtubules on both the internal and external walls become oriented longitudinally and exhibit no association with the ventral wall. In the other four species, microtubules adjacent to the internal walls revert to the initial radial alignment. These findings may have implications in the development and evolution of the stomatal complex.Abbreviations GC guard cell - MT microtubule     

The cytoskeleton and spatial control of cytokinesis in the plant life cycle

Summary One of the intriguing aspects of development in plants is the precise control of division plane and subsequent placement of walls resulting in the specific architecture of tissues and organs. The placement of walls can be directed by either of two microtubule cycles. The better known microtubule cycle is associated with control of the future division plane in meristematic growth where new cells become part of tissues. The future daughter domains are determined before the nucleus enters prophase and the future site of cytokinesis is marked by a preprophase band (PPB) of cortical microtubules. The spindle axis is then organized in accordance with the PPB and, following chromosome movement, a phragmoplast is initiated in the interzone and expands to join with parental walls at the site previously occupied by the PPB. The alternative microtubule cycle lacks both the hooplike cortical microtubules of interphase and the PPB. Wall placement is determined by a radial microtubule system that defines a domain of cytoplasm either containing a nucleus or destined to contain a nucleus (the nuclear cytoplasmic domain) and controls wall placement at its perimeter. This more flexible system allows for cytoplasmic polarization and migration of nuclei in coenocytes prior to cellularization. The uncoupling of cytokinesis from karyokinesis is a regular feature of the reproductive phase in plants and results in specific, often unusual, patterns of cells which reflect the position of nuclei at the time of cellularization (e.g., the arrangement of spores in a tetrad, cells of the male and female gametophytes of angiosperms, and the distinctive cellularization of endosperm). Thus, both microtubule cycles are required for completion of plant life cycles from bryophytes to angiosperms. In angiosperm seed development, the two methods of determining the boundaries of domains where walls will be deposited are operative side by side. Whereas the PPB cycle drives embryo development, the radial-microtubule-system cycle drives the common nuclear type of endosperm development from the syncytial stage through cellularization. However, a switch to the PPB cycle can occur in endosperm, as it does in barley, when peripheral cells divide to produce a multilayered aleurone. The triggers for the switch between microtubule cycles, which are currently unknown, are key to understanding plant development.Dedicated to Professor Brian E. S. Gunning on the occasion of his 65th birthday     

On the egg investments and fertilization reaction inPomatoceros triqueter L.

Summary After a specific time of glutaraldehyde-acrolein fixation, microtubule walls appear to be composed of single 6.5–7.5 nm diameter osmiophilic subunits. Variations in the duration of glutaraldehyde-acrolein and also glutaraldehyde-osmium fixation reveal a two layered wall containing osmiophilic subunits, 4.0–4.5 nm in diameter, arranged radially, in tandem. The double-layered wall is demonstrated by microdensitometer traces. These observations are discussed in relation to previously proposed models of microtubule substructure.     

The role of microtubular cytoskeleton and callose walls in the cytomixis process in tobacco (Nicotiana tabacum L.) pollen mother cells

We have studied the microtubule cytoskeleton structure and callose walls deposition in the course of meiosis at the cytomictic and normal tobacco (N. tabacum L.) PMCs. It was ascertained that microtubule cytoskeleton did not play an evident part in the process of cytomixis. Increased cytomixis frequency probably is determined by irregular callose walls deposition. The possible reasons of nuclear material passage between tobacco PMCs at the cellular level are discussed.     

Taxol maintains organized microtubule patterns in protoplasts which lead to the resynthesis of organized cell wall microfibrils

Summary We have investigated the effects of microtubule stabilizing conditions upon microtubule patterns in protoplasts and developed a new method for producing protoplasts which have non-random cortical microtubule arrays. Segments of elongating pea epicotyl tissue were treated with the microtubule stabilizing drug taxol for 1 h before enzymatic digestion of the cell walls in the presence of the drug. Anti-tubulin immunofluorescence showed that 40 M taxol preserved regions of ordered microtubules. The microtubules in these regions were arranged in parallel arrays, although the arrays did not always show the transverse orientation seen in the intact tissue. Protoplasts prepared without taxol had microtubules which were random in distribution. Addition of taxol to protoplasts with random microtubule arrangements did not result in organized microtubule arrays. Taxol-treated protoplasts were used to determine whether or not organized microtubule arrays would affect the organization of cell wall microfibrils as new walls were regenerated. We found that protoplasts from taxol-treated tissue which were allowed to regenerate cell walls produced organized arrays of microfibrils whose patterns matched those of the underlying microtubules. Protoplasts from untreated tissue synthesized microfibrils which were disordered. The synthesis of organized microfibrils by protoplasts with ordered microtubules arrays shows that microtubule arrangements in protoplasts influence the arrangement of newly synthesized microfibrils.Abbreviations DIC differential interference contrast - DMSO dimethyl sulfoxide - FITC fluorescein isothiocyanate - IgG immunoglobulin G - PIPES piperazine-N,N-bis[2-ethane-sulfonic acid] - PBS phosphate buffered saline     

A seasonal cycle of cell wall structure is accompanied by a cyclical rearrangement of cortical microtubules in fusiform cambial cells within taproots of Aesculus hippocastanum (Hippocastanaceae)

Aspects of the structure and ultrastructure of the fusiform cambial cells of the taproot of Aesculus hippocastanum L. (horse chestnut) are described in relation to the seasonal cycle of cambial activity and dormancy. Particular attention is directed at cell walls and the microtubule and microfilament components of the cytoskeleton, using a range of cytochemical and immunolocalization techniques at the optical and electron-microscopical levels. During the dormant phase, cambial cell walls are thick and multi-layered, the cells possess a helical array of cortical microtubules, and microfilament bundles are oriented axially. In the early stages of reactivation, vesicle-like profiles are associated with the cell walls, whereas arrangement of the cytoskeletal elements remains unchanged. In the succeeding active phase, the cell walls are thin, and cortical microtubules form a random array, although microfilament bundles maintain a near-axial orientation. The observations are discussed in relation to the seasonal cycle of wall structure and cortical microtubule rearrangement within the vascular cambium of hardwood trees. It is suggested that the cell-wall thickening at the onset of cambial dormancy, which is associated with the presence of a helical cortical microtubule array, should be considered to be secondary wall thickening, and that selective lysis of this secondary wall layer during cambial reactivation restores the thinner, primary wall found around active cambial cells.     

Strain rate does not affect cortical microtubule orientation in the isolated epidermis of sunflower hypocotyls

A hypothesis exists that external and internal factors affect the orientation of cortical microtubules in as much as these lead to changes in cell elongation rate. Factors that stimulate elongation are proposed to lead to transverse microtubule orientation, whereas factors that inhibit elongation lead to longitudinal orientation. The elongation rate is equal to the rate of longitudinal irreversible strain in cell walls. Incubated epidermis peeled from sunflower hypocotyls does not extend unless it is stretched by loading and the pH of the incubation medium is appropriately low. Thus, peels provide a convenient model to investigate the relationship between longitudinal strain rate and cortical microtubule orientation. In the present study, it was found that peeling affects microtubule orientation. Peels were incubated for several hours in Murashige & Skoog medium (both unbuffered and buffered) to attain a steady state of microtubule orientation before loading. The effects of loading and pH on strain rate and orientation of microtubules under the outer epidermal walls were examined in three portions of peels positioned with respect to the cotyledonary node. Appropriate loading caused longitudinal strain of peels at pH 4.5 but not at pH 6.5. However, no clear effect of strain rate on microtubule orientation in the peels was observed. Independent of applied load and pH of the incubation medium, the microtubule orientation remained unchanged, i.e. orientation was mainly oblique. Our results show that strain rate does not affect cortical microtubule orientation in isolated epidermis of the sunflower hypocotyl model system, although orientation could be changed by white light.     

慈姑根尖细胞微管骨架的免疫荧光观察

分别用考马斯亮蓝染色和间接免疫荧光标记,并运用荧光倒置显微镜和激光共聚焦显微镜,对慈姑根尖固定后酶解获得的去壁细胞和细胞团块以及根尖细胞分裂周期中微管骨架列阵进行详细观察,以探索高等植物微管周期的普遍性。结果表明:慈姑根尖固定后酶解可获得大量结构完整的去壁细胞与细胞团块;考马斯亮蓝染色观察可见,慈姑根尖细胞中丰富的蛋白物质以及处于不同分裂期的细胞核染色体;免疫荧光观察可见,慈姑根尖细胞周期中微管骨架保存较好,主要有周质微管、早前期带微管、纺缍体微管和成膜体微管4种循序变化的排列方式,构成了高等水生植物分裂细胞中典型的微管周期。实验结果证明,高等水生植物与陆生植物微管周期具有相似性,为植物微管周期概念提供了新的实例。     

Xylogenesis in tissue culture II: Microtubules,cell shape and secondary wall patterns

Summary InZinnia suspension cultures, two general categories of tracheary element (TE) secondary wall patterns can be distinguished: bands and webs. Band patterns are found in elongated cells or regions of cells, web patterns in isodiametric cells or regions of cells. Interphase cortical microtubule arrays, organized before overt differentiation occurs, determine both the shape of the cell and whether band or web patterns will be deposited at the time of TE formation. By altering cell shape and consequently also altering the interphase microtubule array, it is possible to control the type of wall pattern which is deposited.These results provide support for the hypothesis which states that the organization of interphase cortical microtubule arrays (i.e., random or parallel), which laterally associate during tracheary element differentiation, determines the pattern in which secondary walls will be deposited.     

Microtubule rearrangements accompanying dedifferentiation in mesophyll cultures ofZinnia elegans L.

Summary To determine the orientation of cortical microtubule arrays in mesophyll cells ofZinnia, a new technique designed to increase the rate of fixation of excised leaf tissue and subsequent permeabilization of mesophyll cell walls was developed. This procedure resulted in immunolabeling of high percentages of mesophyll cells, making it possible to quantify cells with different types of cortical microtubule arrays. When developing palisade mesophyll cells were fixed in situ, most of the cells had cortical microtubules organized in parallel arrays oriented transverse to the long axis. Delay in the transfer of leaf tissue to fixative resulted in increased numbers of cells with random cortical microtubule orientations, indicating that arrays may become reoriented rapidly during leaf excision and cell isolation procedures. The role of wound-induced microtubule reorientation in mesophyll dedifferentiation and tracheary element development is discussed.Abbreviations BSA bovine serum albumin - CMT cortical microtubule - TE tracheary element - TBS tris-buffered saline     

Assembly and three-dimensional image reconstruction of tubulin hoops

The three-dimensional structure of tubulin hoops has been determined by image reconstruction. The surface lattice of hoops is similar to that of microtubules, but in addition hoops possess a superstructure of protofilament triplets. The protofilaments differ mainly in their apparent volumes and lateral spacings. The volumes depend strongly on the orientation on the carbon support, while the spacings do not. The differences of appearance do not reflect changes of intrinsic subunit structure. They are explained by differential staining related to the orientation and packing of protofilament. Microtubule-associated proteins do not contribute to the average subunit structure. All apparent protofilament structures differ from that expected from X-ray patterns of microtubules in terms of subunit tilt and distribution of contrast. It is concluded that the negatively stained structure is a reliable representation of the arrangement of protein subunits, but not of their shape. Tubulin hoops occur in conditions of microtubule assembly near the critical concentration in a stabilizing buffer. Their formation depends on microtubule-associated proteins and on the initial presence of tubulin oligomers, which may associate into short protofilament triplets. If their elongation is rapid compared to lateral aggregation, they form closed hoops. The growth phase is followed by a redistribution phase, during which hoops disappear in favour of microtubules. This behaviour is explained by kinetic overshoot assembly. Each triplet resembles an incomplete microtubule wall so that the junction between two triplets may be compared to a junction between microtubule walls. Such junctions are formed by a closely spaced pair of protofilaments. They are analogous to junctions between microtubules and incomplete microtubule walls, and they have the same clockwise curvature when viewed at the growing end.     

The outer plate in vertebrate kinetochores is a flexible network with multiple microtubule interactions

Intricate interactions between kinetochores and microtubules are essential for the proper distribution of chromosomes during mitosis. A crucial long-standing question is how vertebrate kinetochores generate chromosome motion while maintaining attachments to the dynamic plus ends of the multiple kinetochore MTs (kMTs) in a kinetochore fibre. Here, we demonstrate that individual kMTs in PtK(1) cells are attached to the kinetochore outer plate by several fibres that either embed the microtubule plus-end tips in a radial mesh, or extend out from the outer plate to bind microtubule walls. The extended fibres also interact with the walls of nearby microtubules that are not part of the kinetochore fibre. These structural data, in combination with other recent reports, support a network model of kMT attachment wherein the fibrous network in the unbound outer plate, including the Hec1-Ndc80 complex, dissociates and rearranges to form kMT attachments.     

Root contraction in hyacinth IV. Orientation of cellulose microfibrils in radial longitudinal and transverse cell walls

Summary Cellulose microfibrils (MFs) were visualized on the inner surface of root cortex cell walls ofHyacinthus orientalis L. using a replica technique. Microfibril orientation was determined in radial longitudinal and transverse cell walls of the root tip, uncontracted, contracting, and fully contracted regions of the root. In longitudinal walls, the innermost MFs were ordered and parallel to one another and were oriented transversely, axially or obliquely, depending upon the developmental stage of the region. In transverse walls MFs in a single layer formed crisscross or ordered parallel arrays, depending upon the region. Parallel arrays were oriented either parallel, perpendicular, or oblique to the radius of the root. Inner walls of certain cells in the contracting region had MFs which appeared interrupted over their lengths. In general, these findings parallel earlier immunofluorescence and electron microscopic observations of changing cortical microtubule (MT) orientation accompanying root contraction. The major exception to MT-MF congruence occurred in cells of the actively contracting region. In middle and outer cell layers, MFs appeared short and partially obscured, while MTs in these cells occurred in conspicuous laterally aggregated strands parallel to one another over the length of the cells or were absent. This alteration in MF-MT parallelism may be related to the reorientation in cell growth occurring in the contractile zone or to the collapse of specific cells during the process of root contraction.Abbreviations MF microfibril - MT microtubule     

Microtubule and actin filament organization during stomatal morphogenesis in the fernAsplenium nidus

Summary The newly-formed guard cell mother cells (GMCs) ofAsplenium nidus are small, lens-shaped and are formed by one or two asymmetrical divisions. Their growth axis is parallel to the plane of their future division, a process during which the internal periclinal wall (IPW) is detached from the partner wall of the underlying cell(s). This oriented GMC expansion occurs transversely to a microfibril bundle, which is deposited externally to a U-like microtubule (Mt) bundle and a co-localized actin filament (Af) bundle. They line the IPW and the major part of the anticlinal walls. The deposition of the microfibril bundle is followed by the slight constriction of the internal part of the GMCs and the broadening of the substomatal cavity. The IPW forms a distinct bulging distal to the neighbouring leaf margin, as well as a less defined proximal one. During the IPW bulging, the Mts and Afs under the external periclinal wall (EPW) attain a radial organization. This is followed by thinning of the central EPW region, which becomes impregnated with a callose-like glucan. The rest of the EPW becomes unequally thickened. The disintegration of the U-like Mt bundle is succeeded by the organization of radial Mt and Af arrays under the IPW. The radial Mt systems, controlling the alignment of the newly-deposited microfibrils, allow the GMC to assume a round paradermal profile. The GMCs form a preprophase Mt band (PPB) perpendicular to the interphase U-like Mt bundle. The anticlinal PPB portions appear first and those lining the periclinal walls later. The cytoplasm adjacent to the latter walls retain the radial Mt systems during early preprophase, simultaneously with the anticlinal PPB portions. The observations suggest that the GMCs of the fernA. nidus obtain a unique form, as a result of a particular polarity established in the cortical cytoplasm of the periclinal walls, in which Mts and Afs appear involved. This polarity persists in cell division and is inherited to guard cells (GCs). It provides primary morphogenetic information not only to GMCs but also to GCs.Abbreviations Af actin filament - EPW external periclinal wall - GC guard cell - GMC guard cell mother cell - IPW internal periclinal wall - Mt microtubule - MTOC microtubule organizing centre - PPB preprophase microtubule band     

Cortical microtubule arrays in the Arabidopsis seedling

Advances in live-cell imaging technology have provided an unprecedented look at the dynamic behaviors of the plant microtubule cytoskeleton. Recent studies revisit the classic question of how plants create cell shape through the patterned construction of the cell wall. Visualization of the cellulose synthase complex traveling in the plasma membrane has brought a watershed of new information about cellulose deposition. Observation of the cellulose synthase complex tracking precisely over the underlying cortical microtubules has provided clear evidence that the microtubule array pattern serves as a spatial template for cellulose microfibril extrusion. Understanding how the microtubules are organized into specific array patterns remains a challenge, though new ideas are arising from genetic and cell biological studies. Long-term time-lapse observations of the microtubule arrays in light-grown hypocotyl cells have revealed a striking process of microtubule patterning possibly linked to the creation of polylamellate cell walls.     

Phragmoplasts in the Absence of Nuclear Division

All land plants (embryophytes) use a phragmoplast for cytokinesis. Phragmoplasts are distinctive cytoskeletal structures that are instrumental in the deposition of new walls in both vegetative and reproductive phases of the life cycle. In meristems, the phragmoplast is initiated among remaining non-kinetochore spindle fibers between sister nuclei and expands to join parental walls at the site previously marked by the preprophase band of microtubules (PPB). The microtubule cycle and cell cycle are closely coordinated: the hoop-like cortical microtubules of interphase are replaced by the PPB just prior to prophase, the PPB disappears as the spindle forms, and the phragmoplast mediates cell plate deposition after nuclear division. In the reproductive phase, however, cortical microtubules and PPBs are absent and cytokinesis may be uncoupled from the cell cycle resulting in multinucleate cells (syncytia). Minisyncytia of 4 nuclei occur in microsporocytes and several (typically 8) nuclei occur in the developing megagametophyte. Macrosyncytia with thousands of nuclei may occur in the nuclear type endosperm. Cellularization of syncytia involves formation of adventitious phragmoplasts at boundaries of nuclear-cytoplasmic domains (NCDs) defined by radial microtubule systems (RMSs) emanating from non-sister nuclei. Once initiated in the region of microtubule overlap at interfaces of opposing RMSs, the adventitious phragmoplasts appear structurally identical to interzonal phragmoplasts. Phragmoplasts are constructed of multiple opposing arrays similar to what have been termed microtubule converging centers. The individual phragmoplast units are distinctive fusiform bundles of anti-parallel microtubules bisected by a dark mid-zone where vesicles accumulate and fuse into a cell plate.     

Microtubule organization and morphogenesis of stomata in caffeine-affected seedlings ofZea mays

Summary Treatment ofZea mays seedlings with a 5 mM caffeine solution inhibits cytokinesis in guard cell mother cells (GMCs), producing unicellular, binucleate aberrant stomata (a-stomata). Ventral wall (VW) strips of limited length, which usually meet the wall portions of GMCs adjoining the cortical zone of the preprophase microtubule band (PMB), are laid down in many a-stomata.In a-stomata with or without VW-strips, the periclinal walls are lined by numerous microtubules (Mts) converging on their mid-region, where local wall thickenings are deposited. When the VW-strips reach the mid-region of the periclinal walls, thickenings lined by numerous Mts rise at their free margins. In certain a-stomata an anticlinal wall column, surrounded by a dense Mt bundle, grows centripetally from either or both of the periclinal wall thickenings. In wall thickenings, the cellulose microfibrils are co-aligned with the adjacent Mts. Pore formation is initiated in all a-stomata. Deposition of an electron dense intra-wall material followed by lysis precedes pore opening. This process is closely related to the a-stornata morphogenesis. These observations show that the primary morphogenetic phenomenon in a-stomata is the establishment of an intense and stable polarity in the cytoplasm abutting on the mid-region of the periclinal walls and/or the adjacent plasmalemma area. Prime morphogenetic factor(s), including microtubule organizing centres (MTOCs), seem to function in these sites. Morphogenesis in a-stomata is a Mt-dependent process that is carried out as in normal stomata but in the absence of a VW.Abbreviations a-stomata unicellular binucleate aberrant stomata - CIPC chlorisopropyl-N-phenyl carbamate - GC guard cell - GMC guard cell mother cell - Mt microtubule - MTOC microtubule organizing centre - PMB preprophase microtubule band - VW ventral wall     

Wave propagation in protein microtubules modeled as orthotropic elastic shells including transverse shear deformations

Wave propagation along the microtubules is one of the issues of major concern in various microtubule cellular functions. In this study, the general wave propagation behavior in protein microtubules is investigated based on a first-order shear deformation shell theory for orthotropic materials, with particular emphasis on the role of strongly anisotropic elastic properties of microtubules. According to experimental observation, the first-order shear deformation theory is used for the modeling of microtubule walls. A general displacement representation is introduced and a type of coupled polynomial eigenvalue problem is developed. Numerical examples describe the effects of shear deformation and rotary inertia on wave velocities in orthotropic microtubules. Finally, the influences of the microtubule shear modulus, axial external force, effective thickness and material temperature dependency on wave velocities along the microtubule protofilaments, helical pathway and radial directions are elucidated. Most results presented in the present investigation have been absent from the literature for the wave propagation in microtubules.