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.     

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     

The Orientation and Localization of Cortical Microtubules in Differentiating Conifer Tracheids during Cell Expansion

Arrays of cortical microtubules (MTs) on radial walls in differentiatingtracheids of Taxus cuspidata were randomly oriented when primarywalls formed. The orientation of MTs changed progressively fromlongitudinal to transverse as cells expanded. During formationof primary walls, MTs in differentiating tracheids disappearedlocally at sites of future intertracheal bordered pits. In furtherdifferentiated tracheids, circular bands of MTs were observedaround the edges of developing bordered pits. (Received July 17, 1996; Accepted November 11, 1996)     

Molecular structural mechanics model for the mechanical properties of microtubules

The aim of this paper was to develop a structural mechanics (SM) model for the microtubules (MTs) in cells. The technique enables one to study the configuration effect on the mechanical properties of MTs and enjoys greatly improved computational efficiency as compared with molecular dynamics simulations. The SM model shows that the Young’s modulus has nearly a constant value around 0.83 GPa, whereas the shear modulus, two orders of magnitude lower, varies considerably with the protofilament number \(N\) and helix-start number \(S\) . The dependence of the bending stiffness and persistence length on the MT length and protofilament number \(N\) is also examined and explained based on the continuum mechanics theories. Specifically, the SM model is found to be in good agreement with available simulation and experiment results, showing its robustness in studying the static deformation of MTs and the potential for characterizing the buckling and vibration of MTs as well as the mechanical behaviour of intermediate and actin filaments.     

The cyclic reorientation of cortical microtubules in epidermal cells of azuki bean epicotyls: the role of actin filaments in the progression of the cycle

The orientation of microtubules (MTs) was examined in epidermal cells of azuki bean (Vigna angularis Ohwi et Ohashi) epicotyls. The orientation of MTs adjacent to the outer tangential wall of the cells, which has a crossed polylamellate structure with lamellae of longitudinal cellulose microfibrils alternating with lamellae of transverse cellulose microfibrils, differed from one cell to another. Treatment with an auxin-free solution caused the accumulation of cells with longitudinal MTs and subsequent treatment with a solution that contained auxin resulted in the accumulation of cells with transverse MTs, showing that sequential treatments with auxin-free and auxin-containing solutions can synchronize the reorientation of MTs. The MTs, once reoriented from longitudinal to transverse, returned to longitudinal and then back to transverse once again, the duration of the cycle being about 6 h. Gibberellic acid, known to increase the percentage of cells with transverse MTs, promoted reorientation of MTs from longitudinal to transverse and inhibited that from transverse to longitudinal. Cytochalasin D, an agent that disrupts actin filaments, speeded up the reorientation from transverse to longitudinal and slowed down that from longitudinal to transverse. It caused an increase in the percentage of cells with MTs in mixed orientation, and the percentage of such cells was highest when the percentage of cells with longitudinal MTs was decreasing and that of cells with transverse MTs was increasing. Received: 27 November 1997 / Accepted: 7 January 1998     

Buckling and postbuckling of radially loaded microtubules by nonlocal shear deformable shell model

This paper presents an investigation on the buckling and postbuckling of microtubules (MTs) subjected to a uniform external radial pressure in thermal environments. The microtubule is modeled as a nonlocal shear deformable cylindrical shell which contains small scale effects. The governing equations are based on higher order shear deformation shell theory with a von Kármán-Donnell-type of kinematic nonlinearity and include the extension-twist and flexural-twist couplings. The thermal effects are also included and the material properties are assumed to be temperature-dependent. A singular perturbation technique is employed to determine the buckling pressure and postbuckling equilibrium paths. The small scale parameter e₀a is estimated by matching the buckling pressure of MTs measured from the experiments with the numerical results obtained from the nonlocal shear deformable shell model. The numerical results show that buckling pressure and postbuckling behavior of MTs are very sensitive to the small scale parameter e₀a. The results reveal that the 13_3 microtubule has a stable postbuckling path, whereas the 13_2 microtubule has an unstable postbuckling behavior due to the presence of skew angles.     

Stabilization of anaphase midzone microtubules is regulated by Rho during cytokinesis in human fibrosarcoma cells

The dynamics of astral and midzone microtubules (MTs) must be separately regulated during cell division, but the mechanism of selective stabilization of midzone MTs is poorly understood. Here we show that, in HT1080 cells, activation of Rho is required to stabilize midzone MTs, and to maintain the midzone structures after anaphase onset or during cytokinesis. Ect2-depleted cells undergoing conventional cytokinesis (cytokinesis A) or contractile ring-independent cytokinesis (cytokinesis B) formed abnormally thin bundles of midzone MTs. C3-loaded mitotic cells with inactivated Rho showed similar but more severe disorganization of midzone MTs. In addition, the bundles of astral MTs were abnormally abundant along the cell periphery in both Ect2-depleted and C3-loaded mitotic cells. Mitotic kinesin-like protein 1 (MKLP1), a component of the spindle midzone required for bundling of MTs, was localized only in the narrower equatorial regions in Ect2-depleted cells, and disappeared from the midzone accompanying the progression of the mitotic phase in C3-loaded cells. Stabilization of MTs by taxol was sufficient to maintain the midzone structures in C3-loaded mitotic cells. These results, when combined with a preceding analysis on another, microtubule-associated Rho GEF (C.J. Bakal, D. Finan, J. LaRose, C.D. Wells, G. Gish, S. Kulkarni, P. DeSepulveda, A. Wilde, R. Rottapel, The Rho GTP exchange factor Lfc promotes spindle assembly in early mitosis, Proc. Natl. Acad. Sci. U. S. A. 102 (2005) 9529–9534), suggest that mammalian cells have two potential steps that require active Rho for the stabilization of midzone MTs during mitosis and cytokinesis.     

Arrangement of Cortical Microtubules in Avena Coleoptiles and Mesocotyls and Pisum Epicotyls

Cortical microtubules (MTs) in coleoptiles and mesocotyls ofAvena sativa and epicotyls of Pisum sativum were examined byimmunofluorescence. In elongating Avena coleoptiles whose elongationis less localized, the orientations of cortical MTs of parenchymaand adaxial epidermal cells, and abaxial epidermal cells aretransverse, and oblique or longitudinal, respectively, and doesnot differ between the upper, middle and lower parts. The transverseMTs in parenchyma and adaxial epidermal cells turns to obliqueor longitudinal ones after elongation stops. The obliquity ofMTs in abaxial epidermal cells also tends to become steeperas elongation comes to a stop. In Avena mesocotyls and Pisumepicotyls whose elongation is localized, the orientation ofcortical MTs of cortical cells in the elongating region is relativelytransverse. The epidermis has intermingling cells of transverseor oblique MTs. In the non-elongating region, MT orientationbecomes steeper both in the cortex and epidermis. The present results indicate that whatever the degree of localizationof the elongation, the obliquity of MTs in these organs is steeperin epidermal than in inner tissue cells and becomes steeperas elongation stops in both tissues. (Received October 26, 1987; Accepted April 19, 1988)     

Epidermal growth factor (EGF) receptor endocytosis is accompanied by reorganization of microtubule system in HeLa cells

Translocation of endosomes along microtubules (MTs) from the cell periphery toward the juxtranuclear region proximal to MTOC is well established. During this translocation the radial MT system is believed to retain its organization. Here we demonstrate that epidermal growth factor receptor (EGFR) endocytosis in HeLa cells is accompanied by dramatic remodeling of the MT system. Synchronized endocytosis was stimulated by warming the cells after EGF prebinding to EGFR on ice. Soon after that MTs were fully reestablished and EGFR was found in EE aligned along peripheral MTs. By the beginning of EE-to-LE sorting, the number of long MTs decreased and MTs appeared like an entangled meshwork of disorientated fragments and were partially depolymerized. Simultaneously, tubulin staining increased in juxtranuclear region, and at the time of LE-Lys interaction, enlarged EGFR-containing endosomes were localized there. Radial MTs were re-established when EGF-EGFR degradation started in lysosomes. In EGF absence, no alterations occurred upon MTs re-establishment. We conclude that MT remodeling is endocytosis-dependent.     

Regulation of the orientation of cortical microtubules inSpirogyra cells

The orientation of cortical microtubules (MTs) was synchronously regulated inSpirogyra cells. While the reorganized MTs in distilled water for 1.5 hr, after 1 hr treatment with amiprophos-methyl (APM) and complete depolymerization of the MTs, were all transverse, those reorganized in 0.30 M mannitol were all oblique or longitudinal. After the MTs had reorganized in 0.30 M mannitol, these cells were then incubated in distilled water for 6 hr, and the orientation of the MTs, in the cells in which MTs could be observed, all became transverse.     

Effect of Ions on the Orientation of Cortical Microtubules in Spirogyra Cells

Effects of ions on the orientation of cortical micro-lubules(MTs) in Spirogyra cells were studied. After depo-lymerizalionwith amiprophos-methyl (APM), MTs were allowed to reorganizein NaCI solutions of various concentrations. As the concentrationof NaCI increased, the frequency of cells that had oblique MTsincreased. When cells in NaCI solution were transferred intoartificial pond water (APW) and incubated for 6 h, all the MTschanged to become transverse to the longitudinal axis of thecell. KC1 and MgCl₂ also had effects on the orientation of MTs.However, NH₄Cl, CaCl₂;, CoCl₂, and Co(NO₃)₂ did not show anyeffect. These results suggest that Na⁺, K⁺, and Mg²⁺have effectson MT orientation and that NH⁺₄, Ca²⁺, Co²⁺, Cl^–, andNO^–₃ have little effect. When MTs were reorganized ineither NaCl or KCl solutions, all the oblique MTs were organizedinto an S-helix. In contrast, some of the oblique MTs were foundas a Z-helix in the cells incubated in MgCl₂ or mannitol solutions.These results suggest that effects of Na⁺ and K⁺ on the orientationof MTs are not the same as those of Mg²⁺ and mannitol. Theseresults provide the first evidence that ions are involved inthe orientation of MTs in algae. (Received January 27, 1998; Accepted August 10, 1998)     

Aluminum induces changes in the orientation of microtubules and the division plane in root meristem of Zea mays

Aluminum (Al) induces agricultural problems limiting crop productivity in acid soils. Since Al causes morphological changes in roots, and because microtubules (MTs) play important roles in determination of tissue morphology, we investigated whether Al affects the arrangement of MTs in maize root meristem using immunolocalization techniques. When seedling roots were treated with 50 μM Al, the orientations of MTs were dramatically altered in a population of cells located in the protoderm and the two outer layers of cortex: interphase cortical MT arrays lost their normal transverse organization and became random or longitudinal; the preprophase band of MTs, mitotic spindle, and phragmoplast developed at planes 90° rotated compared to their counterparts in controls. These changes in MT orientation resulted in the change of the division plane from transverse to longitudinal, producing daughter cells positioned side by side instead of above and below. The rotation of the otherwise normal MT arrays and the division plane in Al-treated roots indicates that Al interferes with the normal polarity sensing mechanism, which may contribute to the reduced axial growth of the Al-treated roots.     

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)     

Gibberellin A3 and Abscisic Acid Cause the Reorientation of Cortical Microtubules in Epicotyl Cells of the Decapitated Dwarf Pea

To determine whether or not the changes in the orientation ofmicrotubules (MTs) that are induced by GA₃ and ABA result fromchanges in the rate of epicotyl elongation caused by these hormones,we examined the effects of GA₃ and ABA on the orientation ofMTs in epidermal cells of decapitated epicotyls of the dwarfpea (Pisum sativum cv. Little Marvel), in which neither GA₃nor ABA causes changes in the rate of epicotyl elongation. Cuttings taken from GA₃-pretreated seedlings were decapitatedand treated with ABA. ABA eliminated the GA₃-induced predominanceof transverse MTs and treatment with ABA resulted in a predominanceof longitudinal MTs in the decapitated cuttings. However, ABAdid not reduce the rate of epicotyl elongation in these samples.Cuttings taken from ABA-pretreated seedlings were decapitatedand treated with GA₃. GA₃ caused the orientation of MTs to changefrom longitudinal to transverse in the decapitated cuttings.However, GA₃ had no promotive effect on elongation of theseepicotyls. The results indicate that both ABA and GA₃ have the abilityto change the orientation of MTs by mechanisms that do not involvechanges in the rate of cell elongation. (Received August 18, 1992; Accepted January 18, 1993)     

Role of plasma membrane proteins and cell wall in meridional arrangement of cortical microtubules inBoodlea coacta

Summary The effects of 2,6-dichlorobenzonitrile (DCB, an agent which inhibits cellulose synthesis) and cycloheximide (CHI, a known inhibitor of protein synthesis) on the construction and stability of the cortical microtubule (MT) cytoskeleton in two kinds of protoplasts (smaller protoplasts and larger ones) prepared fromBoodlea coacta (Dickie) Murray et De Toni were examined by immunofluorescence microscopy. In smaller protoplasts which develop from released protoplasmic masses in culture media, parental cortical MTs assume a convoluted configuration, but new cortical MTs appear following disassembly of convoluted MTs. New cortical MTs initially have a random arrangement but later, a rough meridional arrangement following development of cell polarity and finally, a high density meridional arrangement. In larger protoplasts which are formed within cell wall cylinders of thalli cut at 500 m length, longitudinally oriented parental cortical MTs are preserved. Each exhibits a curving configuration just after protoplast formation, but a straight configuration after 3 h of culture. In smaller protoplasts, cortical MT orientation changes from random to rough meridional orientation but never to a high density meridional orientation following treatment with 10 M CHI, and MT density decreases after 12 h. However, rough meridional and high density meridional arrangements of MTs ceased to be formed and MT density decreased following treatment with 10 M DCB. In larger protoplasts, high density meridional arrangements of MTs were noted not to be affected by treatment with CHI; instead, they continued to remain oriented meridionally, but the length and density were decreased after treatment with DCB for 3–4 h. After 10 h, the MTs became fragmented and orientation was random. From these findings it is summarized that: (1) There are no putative anchors in the plasma membrane of nascent smaller protoplasts, but the meridional orientation of cortical MTs requires anchors which may be distributed in the plasma membrane following the establishment of cell polarity. (2) Plasma membranes in larger protoplasts contain parental anchors oriented meridionally. Anchors stabilize cortical MTs via their close relation to cell walls (especially to cellulose). Anchors are detached from the plasma membrane when cellulose is not formed. (3) Cellulose regeneration may be indispensable to the formation and stabilization of the MT cytoskeleton inBoodlea.Abbreviations CHI cycloheximide - DCB 2,6-dichlorobenzonitrile - DMSO dimethylsulfoxide - MT microtubule     

Microtubule orientation in globular leaflet cells of <Emphasis Type="Italic">Chara inflata</Emphasis>

Chara inflata has globular leaflet cells and cylindrical internodal cells. The morphology of the leaflet cells is different from that of other Characeae. The orientation of cortical microtubules (MTs) in young leaflet and internodal cells of this species was analyzed by immunofluorescence microscopy. MTs with random orientation were observed in leaflet cells, while those relatively transverse to the cell axis were observed in cylindrical internodal cells. In cylindrical leaflet cells in Chara corallina, transverse MTs were observed. These results imply that C. inflata is a morphological mutant lacking a mechanism for orienting cortical MTs transverse in leaflet cells.     

Nonlocal shear deformable shell model for postbuckling of axially compressed microtubules embedded in an elastic medium

Buckling and postbuckling analysis is presented for axially compressed microtubules (MTs) embedded in an elastic matrix of cytoplasm. The microtubule is modeled as a nonlocal shear deformable cylindrical shell which contains small scale effects. The surrounding elastic medium is modeled as a Pasternak foundation. The governing equations are based on higher order shear deformation shell theory with a von Kármán-Donnell-type of kinematic nonlinearity and include the extension-twist and flexural-twist couplings. The thermal effects are also included and the material properties are assumed to be temperature-dependent. The small scale parameter e ₀ a is estimated by matching the buckling load from their vibrational behavior of MTs with the numerical results obtained from the nonlocal shear deformable shell model. The numerical results show that buckling load and postbuckling behavior of MTs are very sensitive to the small scale parameter e ₀ a. The results reveal that the MTs under axial compressive loading condition have an unstable postbuckling path, and the lateral constraint has a significant effect on the postbuckling response of a microtubule when the foundation stiffness is sufficiently large.     

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)     

Processes induced by tau expression in Sf9 cells have an axon-like microtubule organization

We have indirectly analyzed the role of tau in generating the highly organized microtubule (MT) array of the axon. Axons contain MT arrays of uniform polarity orientation, plus ends distal to the cell body (Heidemann, S. R., J. M. Landers, and M. A. Hamborg. 1981. J. Cell Biol. 91:661-673). Surprisingly, these MTs do not radiate from a single discrete nucleating structure in the cell body (Sharp, G. A., K. Weber, and M. Osborn. 1982. Eur. J. Cell Biol. 29: 97-103), but rather stop and start at multiple sites along the length of the axon (Bray, D., and M. B. Bunge. 1981. J. Neurocytol. 10:589-605). When Sf9 ovarian cells are induced to express high levels of tau protein, they develop cellular processes which are similar in appearance to axons and which contain dense arrays of MTs (Knops, J., K. S. Kosik, G. Lee, J. D. Pardee, L. Cohen-Gould, and L. McConlogue. 1991. J. Cell Biol. 114:725-734). We have analyzed the organization of MTs within these arrays, and determined it to be similar, but not identical, to the organization of MTs within the axon. The caliber, MT number, and MT density vary significantly from process to process, but on average are manyfold higher in the tau-induced processes than typically found in axons. Greater than 89% of the MTs in the processes are oriented with their plus ends distal to the cell body, and this proportion is even higher in the processes that are most similar to axons with regard to caliber, MT number, and MT density. Similar to the situation in the axon, MTs are discontinuous along the length of the tau-induced processes, and do not emanate from any observable nucleating structure in the cell body. We have also identified bundles of MTs throughout the cell bodies of the Sf9 cells induced to express tau. Similar to the MT arrays in the processes, these MT bundles are not visibly associated with any other cytological structures that might regulate their polarity orientation. Nevertheless, these bundles consist of MTs most (greater than 82%) of which have the same polarity orientation. Collectively, these results suggest that tau may play a fundamental role in generating MT organization in the axon. In particular, a key property of tau may be to bundle MTs preferentially with the same polarity orientation.     

Regulation of the spatial order of cortical microtubules in developing guard cells ofAllium

The organization of microtubules (MTs) in the cortex of cells at interphase is an important element in morphogenesis. Mechanisms controlling the initiation of MTs and their spatial ordering, however, are largely unknown. Our recent study concerning the generation of a radial array of MTs in stomatal guard cells inAllium showed that the MTs initiate in a cortical MT-organizing zone adjacent to the ventral wall separating the two young guard cells (Marc, Mineyuki and Palevitz, 1989, Planta179, 516, 530). In an attempt to detect MT-ordering mechanisms separate from the sites of MT initiation, we now employ various drugs to manipulate the geometry and integrity of the ventral wall and thereby also the associated MT-organizing zone. In the presence of cytochalasin D the ventral wall is tilted away from its normal mid-longitudinal anticlinal alignment, while treatments with the herbicide chloroisopropyl-N-phenylcarbamate (CIPC) induce the formation of a branched ventral wall. Nonetheless, in either case the MTs still form a radial array, although this is asymmetric as it is centered in accordance with the misaligned or branched ventral wall. Since the MTs maintain their original course undisturbed as they extend beyond the abnormal ventral wall, there is no evidence for the presence of an inherent MT-ordering mechanism at locations remote from MT-initiation sites. Following treatments with caffeine, which abolishes the formation of the ventral wall, the MTs revert to a transversely oriented cylindrical array as in normal epidermal cells. Thus the presence of the ventral wall, and presumably also the associated MT-organizing zone, is essential for the establishment of the radial array. The MT-organizing zone is therefore involved not only in the initiation of MTs, but also in determining their spatial order throughout the cell cortex. We thank Drs. Richard J. Cyr and Yoshi Mineyuki for providing valueable suggestions during the course of this work, and Ms. Elizabeth Bruce printing some of the figures. This research was supported by Funds from the National Science Foundation grants DCB-8703292 to B.A.P. and DCB-8803286 to B.A.P. and J.M.