Root contraction in hyacinth III. Orientation of cortical microtubules visualized by immunofluorescence microscopy

Summary Cortical microtubules (MTs) were visualized in root cortex cells ofHyacinthus orientalis L. using immunofluorescence techniques. Cellular MT orientation was determined adjacent to radial longitudinal and transverse walls of root tip, uncontracted, contracting, and fully contracted regions. As seen in longitudinal views, MTs formed parallel, apparently helical arrays which were oriented transversely, axially or obliquely depending upon the region. Transverse sectional views showed that MTs adjacent to transverse cell walls formed a variety of patterns which varied with developmental stage and cell location. Microtubules were oriented in crisscross or parallel arrays. The parallel arrays were oriented either parallel, perpendicular or oblique to the radius of the root. There was an apparent temporal progression in MT reorientation from outer cortical to inner cortical cell layers. A resultant progression of reoriented cell growth could account for root contraction. These findings corroborate earlier electron microscopic observations of changing MT orientation accompanying root contraction, and provide cytological evidence to test mathematical and biophysical models of the mechanics of cell expansion.Abbreviations MT microtubule - MF microfibril - MTSB microtubule stabilizing buffer - PBS phosphate buffered saline     

Relationship between microtubule orientation and patterns of cell expansion in developing cortical cells of Lemna minor roots

In actively growing cortical cells in the elongation zone of Lemna minor L. roots, both longitudinal (radial and tangential) and transverse walls expand in both length and width. The longitudinal walls of the three types of cortical cells in the root (i.e. outer, middle and inner) showed the largest expansion in the longitudinal axis. In contrast, the inner cortical cells exhibited the least expansion in width, whereas the middle cortical cells displayed the largest expansion in width. Thus, the profiles of the expansion of longitudinal walls were characteristic for the three types of cortical cells. In this study, both the orientation of cortical microtubule (MT) arrays and their dynamic reorientation, and the density of cortical MTs, were documented and correlated to the patterns of cell wall expansion. Significantly, transverse arrays of cortical MTs were most prominent in the radial walls of the inner cortical cells, and least so in those of the middle cortical cells. Toward the base of roots, beyond the elongation zone, the orientation of cortical MTs shifted continuously from transverse to oblique and then to longitudinal. In this case, the rate of shift in the orientation of cortical MTs along the root axis was appreciably faster in the middle cortical cells than in the other two types of cortical cells. Interestingly, the continuous change in cortical MT orientation was not confirmed in the transverse walls which showed much smaller two-dimensional expansion than the radial walls. Additionally, the presence of fragmented or shortened cortical MTs rapidly increased concomitantly with the decrease of transversely oriented cortical MTs. This relationship was especially prominent in the transverse walls of the inner cortical cells, which displayed the least expansion among the three types of cortical cells investigated. In the root elongation zone, the density of cortical MTs in the inner cortical cells was about three times higher than that in the other two cortical cell types. These results indicate that in the early stage of cell expansion, the orientation of cortical MTs determines a preferential direction of cell expansion and both the shifting orientation and density of cortical MTs affect the magnitude of expansion in width of the cell wall.     

Role of the microtubule cytoskeleton in alternating changes in cellulose-microfibril orientation in the coenocytic green alga,Chaetomorpha moniligera

The functions of the microtubule (MT) cytoskeleton in changing the orientation of microfibrils (MFs) in the cell walls of the coenocytic green alga Chaetomorpha moniligera Kjellman were investigated by electron microscopy. The cortical MT cytoskeleton in Chaetomorpha was comprised of longitudinally oriented MTs. Cellulose MFs, however, alternately changed their orientation longitudinally and transversely to form crisscross MF textures. Microtubules were parallel to longitudinally oriented MFs but never to those that were transversely oriented. The average density of MTs during the formation of longitudinally oriented MFs was 216 per 50 m of wall and that of transversely oriented MFs 170/50 m. To determine exactly the MT-density dependency of each MF orientation, changes in MF orientation were examined by changing MT density after treating and removing amiprophos-methyl (APM). Microtubules were reduced in number by a half (100/50 m) after 2 h and by 3/4 (50/50 m) after 3 h of treatment with APM (3 mM). This reduction was caused by the disappearance of alternating MTs. Microtubules retained this density (50/ 50 m) up to 6 h, and then gradually disappeared within 24 h. Microfibril orientation in the innermost cell wall was transverse after treatment with APM for 2 h but was helicoidal after 6 h. Polymerization of MTs occurred in the longitudinal direction following the removal of APM after treatment for 48 h. Microtubule density rose to about 100/50 m and 200/50 m after 6 h and 24 h, respectively. The orientation of MTs changed from helicoidal to transverse and transverse to longitudinal after 6 h and 24 h, respectively. When APM was removed prior to formation of the helicoidal texture, longitudinally oriented MFs appeared within 6 h. There is thus an alternating cycle of formation of longitudinally and transversely oriented MFs within a 12-h period. Formation of transversely oriented MFs as a result of APM treatment started in the middle of a cell as hoops which then extended in the apical and basal directions. Formation of longitudinally oriented MFs as a result of the removal of APM started from the apical end and proceeded toward the base. It follows from these results that: (1) the point of formation of longitudinally oriented MFs differs from that for transversely oriented MFs, (2) MF orientation in each case depends on a separately functioning mechanism, (3) MT density changes rhythmically to trigger a switch for crisscross orientation of MFs.Abbreviations APM amiprophos-methyl - MF microfibril - MT microtubule - TC terminal complex We thank Dr. K. Okuda for making helpful discussion and Miss. T. Matsuki for assistance with replica preparation.     

Dynamic changes in the arrangement of cortical microtubules in conifer tracheids during differentiation.

The arrangement of cortical microtubules (MTs) in differentiating tracheids of Abies sachalinensis Masters was examined by confocal laser scanning microscopy after immunofluorescent staining. The arrays of MTs in the tracheids during formation of the primary wall were not well ordered and the predominant orientation changed from longitudinal to transverse. During formation of the secondary wall, the arrays of MTs were well ordered and their orientation changed progressively from a flat S-helix to a steep Z-helix and then to a flat S-helix as the differentiation of tracheids proceeded. The orientation of cellulose microfibrils (MFs) on the innermost surface of cell walls changed in a similar manner to that of the MTs. These results provide strong evidence for the co-alignment of MTs and MFs during the formation of the semi-helicoidal texture of the cell wall in conifer tracheids.Abbreviations MT cortical microtubule - MF cellulose microfibril - S1, S2 and S3 the outer, middle and inner layers of the secondary wall The authors thank Mr. T. Itoh of the Electron Microscope Laboratory, Faculty of Agriculture, Hokkaido University, for his technical assistance. This work was supported in part by a Grant-in-Aid from the Ministry of Education, Science and Culture, Japan (no. 06404013).     

Is the recovery of microtubule orientation in pea roots dependent on the cell wall?

This study tested several aspects of a model proposed by Williamson (1990, 1991) in which stresses in plant cell walls, detected by stress-receptive portions of inelastic cellulose microfibrils, orient microtubules via interactions with cell wall-linked transmembrane proteins. Young expanding cells of pea root tips have highly ordered transverse arrays of microtubules oriented perpendicular to the direction of cell expansion. The recovery of these ordered MT arrays after depolymerisation with oryzalin was assessed. It was shown that treating roots with disruptors of microfibril synthesis (2,6-dichlorobenzonitrile and calcofluor white) or the disruption of Arg-Gly-Asp (RGD)-mediated wall-membrane links did not affect the orientation of recovering microtubule arrays. Furthermore, cell wall stresses themselves appeared unnecessary for regeneration of transverse arrays. The relevance of these findings to Williamson's hypothesis is discussed.     

Root contraction in hyacinth. II. Changes in tubulin levels,microtubule number and orientation associated with differential cell expansion

Root contraction in hyacinth (Hyacinthus orientalis L.) is marked by reoriented cell growth in the cortex of the contractile region. Cellular volume of the inner cortex enlarges fourfold during root contraction. This is associated with large increases in the radial and tangential dimensions and decreases in the longitudinal dimension of the cells. In order to determine the possible role of microtubules (MTs) in these changes we compared tubulin levels and MT numbers and orientation in contracted and non-contracted regions of hyacinth roots. Tubulin content was analysed by a radioimmunoassay; MT numbers and orientation were analyzed by counting profiles in sectioned material using transmission electron microscopy. Contracted tissue was found to have significantly higher levels of tubulin on a per-cell basis than non-contracted tissue, and also increased tubulin levels relative to total protein. The spatial MT frequencies were the same in contracted and non-contracted tissues, indicating a proportional increase in MT numbers in the expanded cells. Although the absolute spatial frequency of MTs was constant, the orientation, as determined by morphometric analysis of MT profiles, was not. While in the longitudinal section plane 42% of the MTs in the non-contracted cells were oblique, in the contracted cells the percentage of MTs presenting oblique profiles increased to 87%. Additionally, a qualitative difference in MTs was observed in contracted cells; electron-opaque material was seen peripherally associated with the MTs of the inner cortex. The changes in tubulin levels and in MT numbers as well as the qualitative differences in the MTs of contracted and non-contracted root regions indicate that, in hyacinth, reoriented cellular enlargement associated with root contraction cannot be explained simply by shifts in the arrangement of preexisting cortical MT arrays, but involves more complex changes in the cytoskeleton.Abbreviations MT(s) microtubule(s) - TEM transmission electron microscopy - RIA radioimmunoassay - M_r apparent molecular mass I=Jernstedt (1984b)     

Organization of cortical microtubules and microfibril deposition in response to blue-light-induced apical swelling in a tip-growing Adiantum protonema cell

The arrangements of cortical microtubules (MTs) in a tip-growing protonemal cell of Adiantum capillus-veneris L. and of cellulose microfibrils (MFs) in its wall were examined during blue-light (BL)-induced apical swelling. In most protonemal cells which had been growing in the longitudinal direction under red light, apical swelling was induced within 2 h of the onset of BL irradiation, and swelling continued for at least 8 h. During the longitudinal growth under red light, the arrangement of MFs around the base of the apical hemisphere (the subapical region) was perpendicular to the cell axis, while a random arrangement of MFs was found at the very tip, and a roughly axial arrangement was observed in the cylindrical region of most cells. This orientation of MFs corresponds to that of the cortical MTs reported previously (Murata et al. 1987, Protoplasma 141, 135–138). In cells irradiated with BL, a random rather than transverse arrangement of both MTs and MFs was found in the subapical region. Time-course studies showed that this reorientation occurred within 1 h after the onset of the BL irradiation, i.e. it preceded the change in growth pattern. These results indicate that the orientation of cortical MTs and of cellulose MFs is involved in the regulation of cell diameter in a tip-growing Adiantum protonemal cell.Abbreviations BL blue light - MF(s) microfibril(s) - MT(s) microtubule(s)     

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     

Changes in microfibril arrangement on the inner surface of the epidermal cell walls in the epicotyl of Vigna angularis ohwi et ohashi during cell growth

Throughout the entire period of cell growth, the microfibrils on the inner surface of the outer tangential walls of the epidermal cells of Vigna angularis epicotyls are running parallel to one another and their orientation differs from cell to cell. Although transverse, oblique and longitudinal microfibrils can be observed irrespective of cell age, the frequency distribution of microfibril orientation changes with age. In young cells, transversely oriented microfibrils predominate. In cells of medium age, which are still undergoing elongation, transverse, oblique and longitudinal microfibrils are present in quite similar frequencies. In old, non-growing cells, longitudinally oriented microfibrils are predominent. A decrease in the relative frequency of transversely oriented microfibrils with cell age was also observed in the radial epidermal walls.     

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     

Orientation of microfibrils and microtubules in developing tension-wood fibres of Japanese ash (Fraxinus mandshurica var. japonica)

The orientation of cellulose microfibrils (MFs) and the arrangement of cortical microtubules (MTs) in the developing tension-wood fibres of Japanese ash (Fraxinus mandshurica Rupr. var. japonica Maxim.) trees were investigated by electron and immunofluorescence microscopy. The MFs were deposited at an angle of about 45° to the longitudinal axis of the fibre in an S-helical orientation at the initiation of secondary wall thickening. The MFs changed their orientation progressively, with clockwise rotation (viewed from the lumen side), from the S-helix until they were oriented approximately parallel to the fibre axis. This configuration can be considered as a semihelicoidal pattern. With arresting of rotation, a thick gelatinous (G-) layer was developed as a result of the repeated deposition of parallel MFs with a consistent texture. Two types of gelatinous fibre were identified on the basis of the orientation of MFs at the later stage of G-layer deposition. Microfibrils of type 1 were oriented parallel to the fibre axis; MFs of type 2 were laid down with counterclockwise rotation. The counterclockwise rotation of MFs was associated with a variation in the angle of MFs with respect to the fibre axis that ranged from 5° to 25° with a Z-helical orientation among the fibres. The MFs showed a high degree of parallelism at all stages of deposition during G-layer formation. No MFs with an S-helical orientation were observed in the G-layer. Based on these results, a model for the orientation and deposition of MFs in the secondary wall of tension-wood fibres with an S₁ + G type of wall organization is proposed. The MT arrays changed progressively, with clockwise rotation (viewed from the lumen side), from an angle of about 35–40° in a Z-helical orientation to an angle of approximately 0° (parallel) to the fibre axis during G-layer formation. The parallelism between MTs and MFs was evident. The density of MTs in the developing tension-wood fibres during formation of the G-layer was about 17–18 per m of wall. It appears that MTs with a high density play a significant role in regulating the orientation of nascent MFs in the secondary walls of wood fibres. It also appears that the high degree of parallelism among MFs is closely related to the parallelism of MTs that are present at a high density.Abbreviations FE-SEM field emission scanning electron microscopy - G gelatinous layer - MF cellulose microfibril - MT cortical microtubule - S₁ outermost layer of the secondary wall - TEM transmission electron microscopy We thank Dr. Y. Akibayashi, Mr. Y. Sano and Mr. T. Itoh of the Faculty of Agriculture, Hokkaido University, for their experimental or technical assistance.     

Microtubules and morphogenesis in stomata of the water fernAzolla: An unusual mode of guard cell and pore development

Summary A mature stomate of the water fernAzolla consists of a single apparently unspecialized annular guard cell (GC) with two nuclei surrounding an elongated pore aligned longitudinally in the leaf. During development, the guard mother cell develops a preprophase band (PPB) of microtubules (MTs) oriented transverse to the leaf axis. This is followed by a cell plate which fuses with the parental walls at the PPB site. Subsequently only the central part of the cell plate is consolidated, while the parts to either side become perforated and tenuous and may disperse completely, forming a single composite GC.Meanwhile, a dense array of MTs appears along both faces of the central part of the new wall, oriented normal to the leaf surface. Further MT arrays radiate out across the periclinal walls from the region of the consolidated cell plate. Putative MT nucleating sites are seen along the cell edges between these anticlinal and periclinal arrays. Polarized light microscopy reveals cellulose deposition parallel to the periclinal MT arrays. At the same time lamellar material is deposited within the new anticlinal wall. As the GC complex elongates, a split appears in these lamellae creating an initially transverse slit which then opens up to become first circular and ultimately an elongated pore aligned in the long axis of the leaf,i.e., at right angles to the wall in which it originated. The radiating pattern of cellulose microfibrils in the periclinal walls contributes to the shaping of the pore. Elongation at the apical and basal ends of the GC is restricted by longitudinal microfibril orientation, while that at the sides is facilitated by transverse alignment.     

Complete disintegration of the microtubular cytoskeleton precedes its auxin-mediated reconstruction in postmitotic maize root cells

The inhibitory action of 0.1 microM auxin (IAA) on maize root growth was closely associated with a rapid and complete disintegration of the microtubular (MT) cytoskeleton, as visualized by indirect immunofluorescence of tubulin, throughout the growth region. After 30 min of this treatment, only fluorescent spots were present in root cells, accumulating either around nuclei or along cell walls. Six h later, in addition to some background fluorescence, dense but partially oriented oblique or longitudinal arrays of cortical MTs (CMTs) were found in most growing cells of the root apex. After 24 h of treatment, maize roots had adapted to the auxin, as inferred from the slowly recovering elongation rate and from the reassembly of a dense and well-ordered MT cytoskeleton which showed only slight deviations from that of the control root cells. Taxol pretreatment (100 microM, 24 h) prevented not only the rapid auxin-mediated disintegration of the MT cytoskeleton but also a reorientation of the CMT arrays, from transversal to longitudinal. The only tissue to show MTs in their cells throughout the auxin treatment was the epidermis. Significant resistance of transverse CMT arrays in these cells towards auxin was confirmed using a higher auxin concentration (100 microM, 24 h). The latter auxin dose also revealed inter-tissue-specific responses to auxin: outer cortical cell files reoriented their CMTs from the transversal to longitudinal orientation, whereas inner cortical cell files lost their MTs. This high auxin-mediated response, associated with the swelling of root apices, was abolished with the pretreatment of maize root with taxol.     

Microtubule organization during development of stomatal complexes inLolium rigidum

Summary Microtubule (MT) arrays in stomatal complexes ofLolium have been studied using cryosectioning and immunofluorescence microscopy. This in situ analysis reveals that the arrangement of MTs in pairs of guard cells (GCs) or subsidiary cells (SCs) within a complex is very similar, indicating that MT deployment is closely coordinated during development. In premitotic guard mother cells (GMCs), MTs of the transverse interphase MT band (IMB) are reorganized into a longitudinal array via a transitory array in which the MTs appear to radiate from the cell edges towards the centre of the walls. Following the longitudinal division of GMCs, cortical MTs are reinstated in the GCs at the edge of the periclinal and ventral walls. The MTs become organized into arrays which radiate across the periclinal walls, initially from along the length of the ventral wall and later only from the pore site. As the GCs elongate, the organization of MTs and the patterns of wall expansion differ on the internal and external periclinal walls. A final reorientation of MTs from transverse to longitudinal is associated with the elongation and constriction of GCs to produce mature complexes. During cytokinesis in the subsidiary mother cells (SMCs), MTs appear around the reforming nucleus in the daughter epidermal cells but appear in the cortex of the SC once division is complete. Our results are thus consistent with the idea that interphase MTs are nucleated in the cell cortex in all cells of the stomatal complex but not in adjacent epidermal cells.Abbreviations GMC guard mother cell - GC guard cell - IMB interphase microtubule band - MT microtubule - PPB preprophase band - SMC subsidiary mother cell - SC subsidiary cell     

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

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

Development of the preprophase band from random cytoplasmic microtubules in guard mother cells of Allium cepa L.

The organization of microtubule (MT) arrays in the guard mother cells (GMCs) of A. cepa was examined, focussing on the stage at which a longitudinal preprophase band (PPB) is established perpendicular to all other division planes in the epidermis. In the majority of young GMCs, including those seen just after asymmetric division, MTs are distributed randomly throughout the cortex and inner regions of the cytoplasm. Few MTs are associated with the nuclear surface. As the GMCs continue to develop, MTs cluster around the nucleus and a PPB appears as a wide longitudinal band. Microtubules also become prominent between the nucleus and the periclinal and transverse walls, while they decrease in number along the radial longitudinal walls. The PPB progressively narrows by early prophase, and a transversely oriented spindle gradually ensheaths the nucleus. These observations indicate that the initial, broad PPB is organized by a rearrangement of the random cytoplasmic array of MTs. Additional reorganization is responsible for MTs linking the nucleus and the cortex in the future plane of the cell plate, and for narrowing of the PPB.Abbreviations GMC guard mother cell - MT microtubule - PPB preprophase band     

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 patterning in apical epidermal cells ofVinca minor preceding leaf emergence

Summary Serial thin sectioning for electron microscopy was carried out on the cortical cytoplasm of surface cells of the apical dome ofVinca minor. The cellulose reinforcement pattern in the outer epidermal walls forming this surface is known to correlate well with the decussate phyllotaxis pattern. The purpose of this study was to determine the location of microtubules immediately under these epidermal walls as a first step toward finding out how the cellulose pattern arises. First, correspondence between the patterns of microtubules and cellulose was checked. Second, the role of potential orienting cues for the alignment of microtubule arrays in specific cells was evaluated.Microtubule arrays which were well or moderately ordered (70% of the total interphase cells) generally had alignment parallel to the adjacent leaf base, as has been seen for cellulose. The aligned features or cues potentially correlating with a given array were: (1) orientation and length of the previous anticlinal cross-wall, (2) alignment of microtubules in adjacent cells, and (3) direction of inferred stretch, parallel to the nearby leaf bases. All three features were found to agree with the microtubule alignment in 17 of 34 cells with ordered arrays. At least two features agreed in 33 of the 34 cases. All 34 cells with ordered arrays had at least one feature parallel to the array. Random association between microtubule orientation and these features would lead to such correlations less than 0.01% of the time. Thirty percent of the interphase cells showed no obvious order. Most of these cells were located in the central linear corridor region of the apex. The unordered cells were more likely than the ordered cells to have more than one orientation specified by the potential cues; i.e., no single orientation parallel to all of the cues existed. This indicates that uniformity of the orientation cues may be as important as their direction.     

Microtubule organization in root cortical cells ofHyacinthus orientalis

Summary Overall cellular arrangement of cortical microtubules (MTs) is studied by reconstruction of MT images on serial thin sections. The mature root cortex ofHyacinthus orientalis L. cv. Delft blue is composed of elongate, highly vacuolate nondividing parenchyma cells. In longitudinal sections in these cells, MTs generally form parallel arrays at oblique angles to longitudinal cell axes. These MTs extend towards the transverse face of the cell where they appear in localized parallel arrays as well as in crisscross patterns. Repeated observations of oblique parallel arrays of MTs along the length of the cell and the continuity of MT bundles in serial sections suggest that MTs form a single helix in the cell. MTs in neighboring cells appear in sections either as parallel or as herringbone patterns, suggesting that the MT helices in these cells may spiral in the same or the opposite directions.Abbreviations MT Microtubule - MF microfibil - EM electron microscopy     

Interaction of auxin, light, and mechanical stress in orienting microtubules in relation to tropic curvature in the epidermis of maize coleoptiles

Summary Changes in the orientation of cortical microtubules (longitudinal vs. transverse with respect to the long cell axis) at the outer epidermal wall of maize coleoptile segments were induced by auxin, red or blue light, and mechanical stresses (cell extension or compression produced by bending). Immunofluorescent techniques were used for the quantitative determination of frequency distributions of microtubule orientation. Detailed kinetic studies showed that microtubule reorientations are temporally correlated with the simultaneously measured changes in growth rate elicited by auxin, red light, or blue light. Growth inhibition induced by depletion of endogenous auxin produces a longitudinal microtubule pattern that can be changed into a transverse pattern in a dose-dependent manner by applying exogenous auxin. A mid-point pattern with equal frequencies of longitudinal and transverse microtubules was adjusted at 2 mol/1 auxin. Bending stress applied under these conditions adjusts permanent, maximally longitudinal and transverse microtubule orientations at the compressed and extended segment sides, respectively, quantitatively mimicking the responses to differential flank growth during phototropic and gravitropic curvature. During tropic curvature the changes in microtubule pattern reflect the distribution of growth rather than the distribution of auxin. The microtubule pattern responds to auxin-dependent growth changes and mechanical stress in a synergistic manner, confirming the functional equivalence of these factors in affecting microtubule orientation. Similar results were obtained when segment growth was altered by blue or red light instead of auxin in the presence or absence of mechanical stress. It is concluded from these results that growth changes, elicited by auxin, light, etc., and mechanical stress affect microtubule orientation through a common signal perception and transduction chain.Abbreviations IAA indole-3-acetic acid (auxin) - MT cortical microtubule