Microtubule arrays in regeneratingMougeotia protoplasts may be oriented by electric fields

Summary Initially non-polar protoplasts of the green algaMougeotia will regenerate to re-establish their original cylindrical cell shape. The orientation of the growth axis of regenerating protoplasts held in agarose was independent of both the direction of incident white light and gravity. Protoplasts elongated parallel to applied DC electric fields of approx. 0.2 Vcm^–1 (1 mV/protoplast) and greater, with an increasing percentage oriented with increasing field strength. At the maximum field strength used (10 mV/cell), 53% of protoplasts were oriented within +- 10° of the 0/180° axis of the field. In untreated controls, the orientation of elongation was random. Protoplast survival was unaffected by field treatment. Some protoplasts (up to 37% in 10 mV/cell fields) formed outgrowths towards the cathode and occasionally towards the anode. Regenerating protoplasts in fields displayed the normal sequence of microtubule reorganization. This means that the positioning of the ordered symmetrical array of microtubules centred on two foci that appears within 3 to 4 h, and the subsequent organization of microtubules by 8 to 12 h into a band that intersects both foci and which is transverse to the axis of elongation (Galway and Hardham 1986), may be controlled by externally applied electric fields. In the region of this microtubule band, the applied field causes the plasma membrane to be stretched parallel to the field (Bryant and Wolfe 1987). We suggest that microtubules may become oriented perpendicular to the direction of field-induced membrane stretching, and that membrane stretching may be one of the orienting mechanisms for membrane-linked microtubules in elongating plant cells.Abbreviations PBS phosphate buffered saline - PMM protoplast maintenance medium - DMM dilute maintenance medium - MES 2(N-morpholino)ethanesulfonic acid - TRIS tris(hydroxymethyl)aminomethane - ANOVA analysis of variance     

Extending the Microtubule/Microfibril Paradigm : Cellulose Synthesis Is Required for Normal Cortical Microtubule Alignment in Elongating Cells

The cortical microtubule array provides spatial information to the cellulose-synthesizing machinery within the plasma membrane of elongating cells. Until now data indicated that information is transferred from organized cortical microtubules to the cellulose-synthesizing complex, which results in the deposition of ordered cellulosic walls. How cortical microtubules become aligned is unclear. The literature indicates that biophysical forces, transmitted by the organized cellulose component of the cell wall, provide a spatial cue to orient cortical microtubules. This hypothesis was tested on tobacco (Nicotiana tabacum L.) protoplasts and suspension-cultured cells treated with the cellulose synthesis inhibitor isoxaben. Isoxaben (0.25–2.5 μm) inhibited the synthesis of cellulose microfibrils (detected by staining with 1 μg mL⁻¹ fluorescent dye and polarized birefringence), the cells failed to elongate, and the cortical microtubules failed to become organized. The affects of isoxaben were reversible, and after its removal microtubules reorganized and cells elongated. Isoxaben did not depolymerize microtubules in vivo or inhibit the polymerization of tubulin in vitro. These data are consistent with the hypothesis that cellulose microfibrils, and hence cell elongation, are involved in providing spatial cues for cortical microtubule organization. These results compel us to extend the microtubule/microfibril paradigm to include the bidirectional flow of information.     

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.     

Responses of Chrysanthemum Cells to Mechanical Stimulation Require Intact Microtubules and Plasma Membrane–Cell Wall Adhesion

Plant cells are highly susceptible and receptive to physical factors, both in nature and under experimental conditions. Exposure to mechanical forces dramatically results in morphological and microstructural alterations in their growth. In the present study, cells from chrysanthemum (Dendranthema morifolium) were subjected to constant pressure from an agarose matrix, which surrounded and immobilized the cells to form a cell-gel block. Cells in the mechanically loaded blocks elongated and divided, with an axis preferentially perpendicular to the direction of principal stress vectors. After a sucrose-induced plasmolysis, application of peptides containing an RGD motif, which interferes with plasma membrane-cell wall adhesion, reduced the oriented growth under stress conditions. Moreover, colchicines, but not cytochalasin B, abolished the effects of mechanical stress on cell morphology. Cellulose staining revealed that mechanical force reinforces the architecture of cell walls and application of mechanical force, and RGD peptides caused aggregative staining on the surface of plasmolyzed protoplasts. These results provide evidence that the oriented cell growth in response to compressive stress requires the maintenance of plasmalemma-cell wall adhesion and intact microtubules. Stress-triggered wall development in individual plant cells was also demonstrated.     

Microtubules and coated vesicles in guard-cell protoplasts ofAllium cepa L.

Protoplasts were prepared from the guard cells ofA. cepa. Epidermal peels taken from expanding green leaves and largely free of mesophyll were treated with Cellulysin, and protoplasts were harvested after 18 h of digestion. That the protoplasts were derived from guard cells was ascertained from their characteristic vacuolar autofluorescence and from observations showing that all other epidermal cells are killed in the peeling procedure. The protoplasts proved to be a good system with which to view the cell cortex and inner surface of the plasmalemma. The lysis of cells adhering to polylysine-treated, Formvar-coated grids, followed by negative staining in uranyl acetate, showed that many microtubules normally present in ordered arrays in situ remain closely applied to the inner surface of the plasmalemma in protoplasts. In addition, numerous vesiculate elements including coated vesicles and/or pits are present amongst the microtubules. Similar vesicles are evident in thin sections of fixed, embedded guard cells and protoplasts. The significance of these structures in the cell cortex is discussed.     

On the alignment of cellulose microfibrils by cortical microtubules: A review and a model

Summary The hypothesis that microtubules align microfibrils, termed the alignment hypothesis, states that there is a causal link between the orientation of cortical microtubules and the orientation of nascent microfibrils. I have assessed the generality of this hypothesis by reviewing what is known about the relation between microtubules and microfibrils in a wide group of examples: in algae of the family Characeae,Closterium acerosum, Oocystis solitaria, and certain genera of green coenocytes and in land plant tip-growing cells, xylem, diffusely growing cells, and protoplasts. The salient features about microfibril alignment to emerge are as follows. Cellulose microfibrils can be aligned by cortical microtubules, thus supporting the alignment hypothesis. Alignment of microfibrils can occur independently of microtubules, showing that an alternative to the alignment hypothesis must exist. Microfibril organization is often random, suggesting that self-assembly is insufficient. Microfibril organization differs on different faces of the same cell, suggesting that microfibrils are aligned locally, not with respect to the entire cell. Nascent microfibrils appear to associate tightly with the plasma membrane. To account for these observations, I present a model that posits alignment to be mediated through binding the nascent microfibril. The model, termed templated incorporation, postulates that the nascent microfibril is incorporated into the cell wall by binding to a scaffold that is oriented; further, the scaffold is built and oriented around either already incorporated microfibrils or plasma membrane proteins, or both. The role of cortical microtubules is to bind and orient components of the scaffold at the plasma membrane. In this way, spatial information to align the microfibrils may come from either the cell wall or the cell interior, and microfibril alignment with and without microtubules are subsets of a single mechanism.Dedicated to Professor Brian E. S. Gunning on the occasion of his 65th birthday     

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.     

Interaction of purified DNA with plant protoplasts of different cell cycle stage: The concept of a competent phase for plant cell transformation

Summary The polycation mediated attachment of purified tritiated DNA to plant protoplasts has been measured by quantitative microautoradiography. The automated grain counting technique used, also provides information on the cell cycle stage of individual protoplasts, which circumvents the need to synchronize the plant cell population before preparation of protoplasts. With protoplasts from asynchronously dividing suspension cultures of Nicotiana syhestris (NS-1), S-phase protoplasts appear to be inefficient binders of ³H-DNA, as compared with G₁ or G₂ protoplasts. Protoplasts derived from a tumour line of Crepis capillaris (CAPT) exhibit ³H-DNA binding at all cell cycle phases, but Sphase protoplasts appear to be preferential binders. These differences are discussed with reference to cell cycle kinetics, membrane charge variation and the possibility of increasing the efficiency of genetic transformation of higher plant cells in culture.     

The ovaries of Cicadomorpha: distribution of microfilaments and microtubules in terminal filament cells

The ovaries of the investigated homopterans are telotrophicmeroistic and consist of several (7-21 ) ovarioles. Each ovariole is composed of three elements: an anteriorly localized terminal filament, a tropharium, and a posterior vitellarium. The latter comprises several developing ovarian follicles in a linear arrangement. The terminal filaments are relatively solid and composed of two distinct types of cells: the apical cells (ApCs) and the basal cells (BaCs). The BaCs are disc-shaped and oriented perpendicularly to the long axis of the ovariole, whereas the ApCs are strongly elongated and arranged parallel to this axis. The distribution of cytoskeletal elements has been studied with the use of electron microscope and histochemical methods. We show that the ApCs house prominent bundles of highly ordered microfilaments and/or parallel arranged microtubules. In contrast, BaCs contain only individual microtubules that are predominantly located in peripheral regions of the cells. It is suggested that microfilaments and microtubules present in the ApCs are responsible for the mechanical rigidity of the terminal filaments.     

Role of cortical microtubules in the orientation of cellulose microfibril deposition in higher-plant cells

Cortical microtubules (MTs) have been implicated in the morphogenesis of plant cells by regulating the orientation of newly deposited cellulose microfibrils (CMFs). However, the role of MTs in oriented CMF deposition is still unclear. We have investigated the mechanism of CMF deposition with cultured tobacco protoplasts derived from taxol-treated BY-2 cells (taxol protoplasts). The BY-2 protoplasts regenerated patches of beta-l,3-glucan (callose) and fibrils of beta-l,4-glucan (cellulose). Taxol protoplasts possessed the same ordered MT arrays as material cells and regenerated CMFs with patterns almost coincidental with MTs. Electron microscopy revealed that, on the surface of cultured taxol protoplasts, each CMF bundle appeared to be deposited on each cortical MT. These results suggest that MTs may attach directly to the cellulose-synthesizing complexes, by some form of linkage, and regulate the movement of these complexes in higher-plant cells.     

Simulated weightlessness and hyper-g results in opposite effects on the regeneration of the cortical microtubule array in protoplasts from Brassica napus hypocotyls

Enzymatic digestion of the cell wall of Brassica napus hypocotyls gave a heterogeneous suspension of protoplasts with the cortical microtubules (CMTs) randomly organised or CMTs organised in parallel. The effect of variable g- influences has been tested on CMT organisation. In contrast to the 1 g- protoplasts, which reorganised the CMTs into parallel arrays during the 96 h test period, the frequency of randomly-oriented CMTs in the protoplasts exposed to simulated weightlessness (0 g ) on a 2-D clinostat increased significantly during the same period. The opposite effect was obtained when the protoplasts were exposed to hyper -g (7 or 10 g ), where the reorganisation of the CMTs into parallel arrays was accelerated compared to the 1 and 0 g- protoplasts. These results indicate that a unidirectional gravity force is a necessity for the reorganisation of CMTs in protoplasts to parallel arrays and that CMTs act as responding elements that are able to sense different levels of gravity. Besides the inability of the protoplasts to reorganise the CMTs into parallel arrays, the quantity of CMTs in the individual protoplast decreased during 4 days of simulated weightlessness, both compared to the CMTs quantity in the protoplasts immediately after isolation and compared to the 1 g- and hyper -g- protoplasts after 24 and 48 h of g- exposure. The size of the protoplasts was also affected by the g- exposure. Protoplasts exposed to simulated 0 g increased significantly after 24 and 48 h, whereas the 1 g- and 10 g- protoplasts maintained the same size during the 48 h test period.     

Role of cortical microtubules in the orientation of cellulose microfibril deposition in higher-plant cells

Summary Cortical microtubules (MTs) have been implicated in the morphogenesis of plant cells by regulating the orientation of newly deposited cellulose microfibrils (CMFs). However, the role of MTs in oriented CMF deposition is still unclear. We have investigated the mechanism of CMF deposition with cultured tobacco protoplasts derived from taxol-treated BY-2 cells (taxol protoplasts). The BY-2 protoplasts regenerated patches of β-l,3-glucan (callose) and fibrils of β-l,4-glucan (cellulose). Taxol protoplasts possessed the same ordered MT arrays as material cells and regenerated CMFs with patterns almost coincidental with MTs. Electron microscopy revealed that, on the surface of cultured taxol protoplasts, each CMF bundle appeared to be deposited on each cortical MT. These results suggest that MTs may attach directly to the cellulose-synthesizing complexes, by some form of linkage, and regulate the movement of these complexes in higher-plant cells.     

Tip growth in xylogenic suspension cultures ofZinnia elegans L.: Implications for the relationship between cell shape and secondary-cell-wall pattern in tracheary elements

Summary The relationship between cell expansion, cortical microtubule orientation, and patterned secondary-cell-wall deposition was investigated in xylogenic cell suspension cultures ofZinnia elegans L. The direction of cell expansion in these cultures is pH dependent; cells elongate at pH 5.5–6.0, but expand isodiametrically at pH 6.5–7.0. Contrary to our expectations, indirect immunofluorescence revealed that cortical microtubules are oriented parallel to the long axis in elongating cells. Pulse labeling of the walls of isolated cells with the fluorochrome Tinopal LPW demonstrated that xylogenic Zinnia mesophyll cells elongate by tip growth in culture. These results confirm that cortical microtubules in developing tracheary elements reorient before bundling to form transverse cortical microtubule bands. This rearrangement may allow the secondary cell wall pattern to conform to cell shape, independent of the direction in which the cell was expanding prior to reorientation.Abbreviations CMT cortical microtubules - Mes 2-[N-morpholino]ethanesulfonic acid - TE tracheary element     

Conifer somatic embryogenesis for studies of plant cell biology

Summary Embryogenic cultures have been produced for a wide range of conifers and current methods developed for spruce permit the maturation of high quality embryos that can be desiccated and then germinated to form plantlets. Embryogenic suspensions consisting of immature embryos are an excellent source of regenerable protoplasts. This review considers examples of applications of embryogenic suspension cultures for basic studies in three areas of plant cell biology. a) Immunofluorescence studies of microtubules in mitotic spruce cells reveal focused spindle poles at prophase and anphase, suggesting the presence of microtubule organizing centers (MTOCs). Antibodies known to recognize animal MTOCs do not stain the polar regions but do stain developing kinetochores. b) Embryo-derived protoplasts regenerate directly to somatic embryos. Fluorescence studies of the cytoskeleton in freshly derived protoplasts reveal random cortical microtubules and a fine network of actin filaments. During culture, protoplasts change shape and develop transverse cortical microtubule arrays. Embryonal cells of newly formed embryos possess distinctive arrays of cortical microtubules and networks of fine actin filaments while suspensor cells are characterized by transverse cortical microtubules and longitudinal actin cables. c) Transmission electron microscope studies of endocytosis in spruce protoplasts reveal an endocytotic pathway similar to that described previously for soybean. Uptake results are confirmed using high pressure freeze fixation instead of conventional chemical fixation. Presented in the Session-in-Depth Morphogenesis: Plant Cell and Tissue Differentiation at the 1994 Congress on Cell and Tissue Culture, Research Triangle Park, NC, June 4–7, 1994.     

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     

Cell proliferation,cell shape,and microtubule and cellulose microfibril organization of tobacco BY-2 cells are not altered by exposure to near weightlessness in space

The microtubule cytoskeleton and the cell wall both play key roles in plant cell growth and division, determining the plant’s final stature. At near weightlessness, tubulin polymerizes into microtubules in vitro, but these microtubules do not self-organize in the ordered patterns observed at 1g. Likewise, at near weightlessness cortical microtubules in protoplasts have difficulty organizing into parallel arrays, which are required for proper plant cell elongation. However, intact plants do grow in space and therefore should have a normally functioning microtubule cytoskeleton. Since the main difference between protoplasts and plant cells in a tissue is the presence of a cell wall, we studied single, but walled, tobacco BY-2 suspension-cultured cells during an 8-day space-flight experiment on board of the Soyuz capsule and the International Space Station during the 12S mission (March–April 2006). We show that the cortical microtubule density, ordering and orientation in isolated walled plant cells are unaffected by near weightlessness, as are the orientation of the cellulose microfibrils, cell proliferation, and cell shape. Likely, tissue organization is not essential for the organization of these structures in space. When combined with the fact that many recovering protoplasts have an aberrant cortical microtubule cytoskeleton, the results suggest a role for the cell wall, or its production machinery, in structuring the microtubule cytoskeleton.     

Cell marking in Arabidopsis thaliana and its application to patch–clamp studies

Ion transport processes at the plasma membrane of plant cells are frequently studied by applying membrane-patch voltage-clamp (patch–clamp) electrophysiological techniques to isolated protoplasts. As plants are composed of many tissues and cell types, and each tissue and cell type may be specialized to a particular function and possess a unique complement of transport proteins, it is important to certify the anatomical origin of the protoplasts used for patch–clamp studies. This paper describes a general molecular genetic approach to marking specific cell types for subsequent patch–clamp studies and presents a specific example: a comparison of the K⁺ currents in protoplasts from cortical and stelar cells of Arabidopsis roots. Transgenic Arabidopsis were generated in which the expression of green fluorescent protein (GFP) from Aequoria victoria was driven by the CaMV 35S promoter (line mGFP3). In roots of the transgenic mGFP3 line, visible fluorescence was restricted to the stele. Protoplasts were generated from roots of the mGFP3 line and K⁺ currents in non-fluorescent (cortical/epidermal) and fluorescent (stelar) protoplasts were assayed using patch–clamp techniques. It was found that both the frequency of observing inward rectifying K⁺ channel (IRC) activity and the relative occurrence of IRC compared to outward rectifying K⁺ channels were significantly lower in protoplasts from cortical/epidermal cells compared to cells of the stele. The presence of GFP did not affect the occurrence or biophysical properties of K⁺ channels. It is concluded that the generation of transgenic Arabidopsis expressing GFP in a cell-specific fashion is a convenient and reliable way to mark protoplasts derived from contrasting cell types for subsequent patch–clamp studies.     

应力诱导的菊花原生质体定向性伸长响应

从单细胞水平探索了应力条件对植物细胞伸长这一生长发育过程中的基本和重要现象的影响。从菊花叶片中分离原生质体并将其包埋于琼脂糖凝胶块中,通过自主研发的微应力加载装置对该细胞-凝胶混合物施加机械挤压,加载后的凝胶块培养并切片后进行细胞形态分析,采用基于有限元方法的ABAQUS软件计算细胞周围的应力场,发现受到应力刺激的原生质体在培养过程中倾向于以垂直于凝胶块中主应力张量的方向伸长,应力强度与这种细胞响应遵照某种非线性的剂量依赖关系,且该响应会受到外源性含RGD序列的多肽的抑制。说明植物单细胞具有响应外部力学信号的能力;植物细胞质膜上可能存在与动物细胞系统中类似的RGD特异结合受体,它在应力条件下的细胞伸长响应中可能参与了力学信号的介导。     

A plasmolytic cycle: The fate of cytoskeletal elements

Summary In most plant cells, transfer to hypertonic solutions causes osmotic loss of water from the vacuole and detachment of the living protoplast from the cell wall (plasmolysis). This process is reversible and after removal of the plasmolytic solution, protoplasts can re-expand to their original size (deplasmolysis). We have investigated this phenomenon with special reference to cytoskeletal elements in onion inner epidermal cells. The main processes of plasmolysis seem to be membrane dependent because destabilization of cytoskeletal elements had only minor effects on plasmolysis speed and form. In most cells, the array of cortical microtubules is similar to that found in nonplasmolyzed states except that longitudinal patterns seen in some control cells were never observed in plasmolyzed protoplasts of onion inner epidermis. As soon as deplasmolysis starts, cortical microtubules become disrupted and only slowly regenerate to form an oblique array, similar to most nontreated cells. Actin microfilaments responded rapidly to the plasmolysis-induced deformation of the protoplast and adapted to its new form without marked changes in organization and structure. Both actin microfilaments and microtubules can be present in Hechtian strands, which, in plasmolyzed cells, connect the cell wall to the protoplast. Anticytoskeletal drugs did not affect the formation of Hechtian strands.Abbreviations DIC differential interference contrast - DiOC₆(3) 3,3-dihexyloxacarbocyanine iodide Dedicated to Professor Walter Gustav Url on the occasion of his 70th birthday     

The origin and organization of cortical microtubules during the transition between M and G1 phases of the cell cycle as observed in highly synchronized cells of tobacco BY-2

The organization of microtubules (MTs) during the transition from the M phase to the G₁ phase of the cell cycle was followed in highly synchronized suspension-cultured cells ofNicotiana tabacum L. (tobacco BY-2) by sequential treatment of cells with aphidicolin and propyzamide. Short MTs were first formed in the perinuclear regions at the expense of phragmoplasts, but when these short MTs elongated to reach the cell cortex, they grew parallel to the long axis and towards the distal end of the cells. As soon as, or shortly before the tips of elongated MTs reached the distal end, transverse cortical MTs were formed in the region proximal to the division plane. Thereafter, almost all cells retained cortical MTs which were transversely orientated to the long axis of cells and could be observed in the G₁ phase. Thus, in the organization of cortical MTs, there are two steps that have been overlooked thus far. This novel observation provides a new scheme for the organization of cortical MTs, which could unify two contrasting hypotheses, i.e. organization in the perinuclear regions versus that in the cell cortex. These observations are discussed in relation to the microtubule-organizing center of plant cells.