Arrangement of Cellulose Microfibrils in Walls of Elongating Parenchyma Cells

The arrangement of cellulose microfibrils in walls of elongating parenchyma cells of Avena coleoptiles, onion roots, and celery petioles was studied in polarizing and electron microscopes by examining whole cell walls and sections. Walls of these cells consist firstly of regions containing the primary pit fields and composed of microfibrils oriented predominantly transversely. The transverse microfibrils show a progressive disorientation from the inside to the outside of the wall which is consistent with the multinet model of wall growth. Between the pit-field regions and running the length of the cells are ribs composed of longitudinally oriented microfibrils. Two types of rib have been found at all stages of cell elongation. In some regions, the wall appears to consist entirely of longitudinal microfibrils so that the rib forms an integral part of the wall. At the edges of such ribs the microfibrils can be seen to change direction from longitudinal in the rib to transverse in the pit-field region. Often, however, the rib appears to consist of an extra separate layer of longitudinal microfibrils outside a continuous wall of transverse microfibrils. These ribs are quite distinct from secondary wall, which consists of longitudinal microfibrils deposited within the primary wall after elongation has ceased. It is evident that the arrangement of cellulose microfibrils in a primary wall can be complex and is probably an expression of specific cellular differentiation.     

The case for multinet growth in growing walls of plant cells

The basis of multinet gwoth, the multinet growth hypothesis, is examined in view of recent criticisms. It is shown that the strain across a growing wall may be calculated by simple means and the expected reorientations are deduced (a) for a wall in which the microfibrils of the innermost wall lamella always lie helically with the same pitch and (b) in which the microfibrils lie at random. Calculations are presented both for cells increasing in length only and for cells also increasing in breadth. Both the strains and the reorientations are smaller than commonly implied and are too small to be reliably detectable in wall sections. Observations on wall sections cannot therefore be accepted as proof that microfibril reorientation has not occured and it is concluded that the multinet growth hypothesis still stands as applying both to parenchyma and to collenchyma cells. In view of the wide dispersity in the structure of the walls of growing cells, it is recommended that the qualifying multinet should be dropped and replaced by passive reorientation.Abbreviation MGH multinet growth hypothesis     

Transverse viscoelastic extension in nitella: I. Relationship to growth rate

Transverse viscoelastic extensibility was measured directly in isolated walls of Nitella internode cells. Cell walls extended transversely exhibit a yield point which is approximately twice the yield point in the longitudinal direction. Walls from young, growing cells are four to seven times more extensible longitudinally than transversely, while walls from mature, nongrowing cells are only two times more extensible longitudinally. Although longitudinal extensibility decreases drastically with the decrease in the growth rate, lateral extensibility is constant through development. There is a discrepancy between the lateral growth rate and transverse creep, since the lateral growth rate is not constant. However, the degree of wall anisotropy observed is consistent with the view that the transversely oriented cellulose microfibrils act as a “reinforcing filler” in Nitella cell walls.     

Deposition and reorientation of cellulose microfibrils in elongating cells of Petunia stylar tissue

According to Roelofsen and Houwink's (1953, Acta Bot. Neerl. 2, 218–225) multinet growth hypothesis, microfibrils originally deposited transversely in the cell wall become gradually reoriented towards more axial orientations during cell elongation. To establish the extent of reorientation, microfibrils were studied during their deposition and elongation, using stylar parenchyma and transmitting tissue cells of Petunia hybrida L. At the inner surface of very young cells, microfibrils were deposited in alternating Z- and S-helical orientations. The following sequence in deposition, from the exterior to the interior side of the wall, could be inferred: Axial: 150°–180° (Z-helical), 0°–30° (S-helical); oblique: 110°–150° (Z-helical), 30°–70° (S-helical); transverse: 90°–110° (Z-helical), 70°–90° (S-helical). With the increasing pitch, the density of the deposited microfibrils increased as well, giving rise to an alternating helical texture. During elongation, only transversely S- and Z-helically oriented microfibrils were deposited and all microfibrils underwent a certain reorientation as described in the multinet growth hypothesis. The texture resembled that of young cells and the wall maintained its thickness. The extent of passive reorientation was in agreement with the theoretical calculations made by Preston.Dedicated to Professor Dr. A.B. Wardrop, Melbourne, on the occasion of his 70th birthday     

Real-Time Imaging of Cellulose Reorientation during Cell Wall Expansion in Arabidopsis Roots

Cellulose forms the major load-bearing network of the plant cell wall, which simultaneously protects the cell and directs its growth. Although the process of cellulose synthesis has been observed, little is known about the behavior of cellulose in the wall after synthesis. Using Pontamine Fast Scarlet 4B, a dye that fluoresces preferentially in the presence of cellulose and has excitation and emission wavelengths suitable for confocal microscopy, we imaged the architecture and dynamics of cellulose in the cell walls of expanding root cells. We found that cellulose exists in Arabidopsis (Arabidopsis thaliana) cell walls in large fibrillar bundles that vary in orientation. During anisotropic wall expansion in wild-type plants, we observed that these cellulose bundles rotate in a transverse to longitudinal direction. We also found that cellulose organization is significantly altered in mutants lacking either a cellulose synthase subunit or two xyloglucan xylosyltransferase isoforms. Our results support a model in which cellulose is deposited transversely to accommodate longitudinal cell expansion and reoriented during expansion to generate a cell wall that is fortified against strain from any direction.The walls of growing plant cells must fulfill two simultaneous and seemingly contradictory requirements. First, they must expand to accommodate cell growth, which is anisotropic in many tissues and determines organ morphology. Second, they must maintain their structural integrity, both to constrain the turgor pressure that drives cell growth and to provide structural rigidity to the plant. These requirements are met by constructing primary cell walls that can expand along with growing cells, whereas secondary cell walls are deposited after cell growth has ceased and serve the latter function.One of the major constituents of both types of cell walls is cellulose, which exists as microfibrils composed of parallel β-1,4-linked glucan chains that are held together laterally by hydrogen bonds (Somerville, 2006). Microfibrils are 2 to 5 nm in diameter, can extend to several micrometers in length, and exhibit high tensile strength that allows cell walls to withstand turgor pressures of up to 1 MPa (Franks, 2003). In vascular plants, cellulose is synthesized by a multimeric cellulose synthase (CESA) complex composed of at least three types of glycosyl transferases arranged into a hexameric rosette (Somerville, 2006). After delivery to the plasma membrane, CESA initially moves in alignment with cortical microtubules (Paredez et al., 2006), but its trajectory can be maintained independently of microtubule orientation. For example, in older epidermal cells of the root elongation zone in Arabidopsis (Arabidopsis thaliana), cellulose microfibrils at the inner wall face are oriented transversely despite the fact that microtubules reorient from transverse to longitudinal along the elongation zone (Sugimoto et al., 2000), suggesting that microtubule orientation and cellulose deposition are independent in at least some cases.Depending on species, cell type, and developmental stage, cellulose microfibrils may be surrounded by additional networks of polymers, including hemicelluloses, pectins, lignin, and arabinogalactan proteins (Somerville et al., 2004). Hemicelluloses are composed of β-1,4-linked carbohydrate backbones with side branches and include xyloglucans, mannans, and arabinoxylans. Xyloglucan is thought to interact with the surface of cellulose and form cross-links between adjacent microfibrils (Vissenberg et al., 2005). In some cell types, pectin or lignin may also participate in cross-linking or entrapment of other cell wall polymers. It is unclear how the associations between networks of different cell wall components are relaxed to allow for cell wall expansion during growth.Several models have been proposed for the behavior of cell wall components during wall expansion. The passive reorientation hypothesis (also called the multinet growth hypothesis; Preston, 1982) postulates that in longitudinally expanding cells, cellulose microfibrils are synthesized in a transverse pattern and are then reoriented toward the longitudinal axis due to the strain generated by turgor pressure (Green, 1960). This phenomenon has been observed in the multicellular alga Nitella (Taiz, 1984). In higher plants, there is less direct evidence for passive reorientation, and another hypothesis holds that wall expansion involves active, local, and controlled remodeling of cellulose microfibrils along a diversity of orientations (Baskin, 2005). Such remodeling could be achieved by proteins such as xyloglucan endotransglycosylases (XETs), which break and rejoin xyloglucan chains, and expansins, which loosen cell walls in vitro in a pH-dependent manner (Cosgrove, 2005). Marga et al. measured cellulose microfibril orientation at the innermost layer of the cell wall before and after in vitro extension and did not observe reorientation (Marga et al., 2005). This suggests that processes other than microfibril reorientation might be involved in wall expansion, at least under certain circumstances or in some wall layers. Thus, the degree to which cellulose microfibrils are reoriented after their synthesis during wall expansion has remained unclear.One difficulty in resolving this problem has been the inability to directly image cellulose microfibrils in the growing cell wall. Existing methods to assess cellulose structure and orientation in plant cell walls are limited by the low contrast of cellulose in transmission electron microscopy, the ability to image only the surface of the wall using field emission scanning electron microscopy, and the use of polarized light microscopy in combination with dyes such as Congo red to measure only the bulk orientation of cellulose microfibrils (Baskin et al., 1999; Sugimoto et al., 2000; Verbelen and Kerstens, 2000; MacKinnon et al., 2006). In addition, the sample manipulation required for the former two methods has the potential to introduce artifacts (Marga et al., 2005). Although cellulose microfibril orientation differs at the inner and outer surfaces of the cell wall (Sugimoto et al., 2000) and presumably changes over time, the dynamics of cellulose reorientation during cell wall expansion have not been observed to date.In this study, we tested fluorescent dyes for their potential to allow imaging of cellulose distribution in the walls of Arabidopsis seedlings by confocal microscopy. We used one of these dyes to characterize the distribution of cellulose in wild-type root cells and in mutants with reduced cellulose or xyloglucan. By directly observing the fine structure of cellulose over time in growing wild-type root cells, we concluded that cellulose microfibrils in these cells reorient in a transverse to longitudinal direction as predicted by the passive reorientation hypothesis.     

Cortical microtubule patterning in roots of Arabidopsis thaliana primary cell wall mutants reveals the bidirectional interplay with cell expansion

Cell elongation requires directional deposition of cellulose microfibrils regulated by transverse cortical microtubules. Microtubules respond differentially to suppression of cell elongation along the developmental zones of Arabidopsis thaliana root apex. Cortical microtubule orientation is particularly affected in the fast elongation zone but not in the meristematic or transition zones of thanatos and pom2–4 cellulose-deficient mutants of Arabidopsis thaliana. Here, we report that a uniform phenotype is established among the primary cell wall mutants, as cortical microtubules of root epidermal cells of rsw1 and prc1 mutants exhibit the same pattern described in thanatos and pom2–4. Whether cortical microtubules assume transverse orientation or not is determined by the demand for cellulose synthesis, according to each root zone''s expansion rate. It is suggested that cessation of cell expansion may provide a biophysical signal resulting in microtubule reorientation.     

FT-IR study of the Chara corallina cell wall under deformation

Fourier-transform infrared (FT-IR) microspectroscopy was used to investigate both the chemical composition of, and the effects of an applied strain on, the structure of the Chara corallina cell wall. The inner layers of the cell wall are known to have a transverse cellulose orientation with a gradient through the thickness to longitudinal orientation in the older layers. In both the native state and following the removal of various biopolymers by a sequential extraction infrared dichroism was used to examine the orientation of different biopolymers in cell-wall samples subjected to longitudinal strain. In the Chara system, cellulose microfibrils were found to be aligned predominantly transverse to the long axis of the cell and became orientated increasingly transversely as longitudinal strain increased. Simultaneously, the pectic polysaccharide matrix underwent molecular orientation parallel to the direction of strain. Following extraction in CDTA, microfibrils were orientated transversely to the strain direction, and again the degree of transverse orientation increased with increasing strain. However, the pectic polysaccharides of the matrix were not detected in the dichroic difference spectra. After a full sequential extraction, the cellulose microfibrils, now with greatly reduced crystallinity, were detected in a longitudinal direction and they became orientated increasingly parallel to the direction of strain as it increased.     

The orientation of cell wall microtubules in wheat coleoptile segments subjected to phytohormone treatment

The effect of plant hormones was studied on the growth of excised coleoptile segments of wheat plantlets grown under daylight conditions. In addition to the change in growth, that in the orientation of microtubules and cellulose microfibrils was investigated in parenchyma cells. Following a 6-h treatment gibberellin, and still more kinetin, stímulated the thickening of segments, which became evident also in an altered orientation of microtubules. Whereas in the control the microtubules and wall microfibrils were oriented randomly, following gibberellin treatment they were all parallel and formed an acute angle with the longitudinal cell axis. A still more pronounced difference resulted after kinetin treatment, when microtubules were localized parallel with the longitudinal cell axis. Auxin had the opposite effect: it stimulated the elongation of the segments, which became evident in a transverse orientation of both wall microtubules and microfibrils.     

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     

Microfibril orientation in differentiating and maturing fibre and parenchyma cell walls in culms of bamboo (Phyllostachys viridi-glaucescens (Garr.) Riv. & Riv.)

Results of trials using chemical and enzymatic wall extractants for the removal of matrix materials for in situ observations of newly deposited microfibrils are described. Observations were then made of the orientation of microfibrils on the inner walls of differentiating and maturing fibres and parenchyma cells under the FESEM. Orientation changes were similar in both cell types. During very early primary wall development, deposition of microfibrils was in more or less axial alignment, which was later superseded by microfibrils in transverse orientation (90^o to the long axis). A transverse orientation of microfibrils remained throughout much of primary wall synthesis, until an abrupt shift occurred to a sloped orientation during late primary wall synthesis. Microfibrils of the first secondary wall layer were in axial alignment or steeply sloped. In subsequent secondary wall deposition there was an alternation between a transverse and a sloped or axial alignment in maturing fibres and parenchyma cells.     

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 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.     

The cyclic reorientation of cortical microtubules on walls with a crossed polylamellate structure: effects of plant hormones and an inhibitor of protein kinases on the progression of the cycle

Summary The outer tangential wall (OTW) of epidermal cells of azuki bean epicotyls has a crossed polylamellate structure, in which lamellae of longitudinal cellulose microfibrils alternate with lamellae of transverse cellulose microfibrils. This implies that the cyclic reorientation of cortical microtubules (MTs) from longitudinal to transverse and from transverse to longitudinal occurs on the OTW. Treatment with a solution that contained no auxin caused the accumulation of cells with longitudinal MTs, suggesting that auxin is required for the reorientation of MTs from longitudinal to transverse during the reorientation cycle. Treatment with 6-dimethylaminopurine (DMAP), an inhibitor of protein kinases that promoted the reorientation of MTs from transverse to longitudinal, resulted in the accumulation of cells with longitudinal MTs. Subsequent treatment with auxin caused a marked increase in the percentage of cells with transverse MTs and then a decrease in the percentage, indicating that the reorientation of MTs from longitudinal to transverse and then from transverse to longitudinal occurred during treatment with auxin. The percentage of cells with transverse MTs decreased more slowly in segments that had been pretreated with gibberellin A₃ (GA) than in segments that had been pretreated without GA, suggesting that GA, in cooperation with auxin, caused the suppression of the reorientation of MTs from transverse to longitudinal.Abbreviations BL brassinolide - BSA bovine serum albumin - GA gibberellin A₃ - DMAP 6-dimethylaminopurine - DMSO dimethylsulfoxide - FITC fluorescein isothiocyanate - IAA indoleacetic acid - MT microtubule - OTW outer tangential wall - PBS phosphate-buffered saline Dedicated to Professor Eldon H. Newcomb in recognition of his contributions to cell biology     

Axis elongation can occur with net longitudinal orientation of wall microfibrils

During the initial phases of elongation of pea internodes, oat and rice coleoptiles, oat mesocotyls, soybean hypocotyls and dandelion peduncles, net transverse orientation of cellulose wall microfibrils (Mfs) was found in the outer epidermal wall. This paper demonstrates that in all these axes, with the exception of rice coleoptile, net longitudinal orientation of microfibrils occurs in the outer epidermal wall in portions of the axes that were still elongating at the time of sampling. The timing of the transition to net longitudinal orientation and whether the transition proceeded acropetally or basipetally varied with the type of axis under study. The variability of the relationship between extension and the transition from net transverse to net longitudinal orientation suggests that factors other than extension are important in determining the transition. Layers of longitudinal wall microfibrils may be added to the extending epidermal wall to bolster its tensile strength commensurate with its function during and after extension. Attention is drawn to the parallels between the concept of tissue tension in growing axes and the concept that the epidermis functions as a stressed skin in the support of mature plant parts in primary growth.     

Differential Responsiveness of Cortical Microtubule Orientation to Suppression of Cell Expansion among the Developmental Zones of Arabidopsis thaliana Root Apex

Τhe bidirectional relationship between cortical microtubule orientation and cell wall structure has been extensively studied in elongating cells. Nevertheless, the possible interplay between microtubules and cell wall elements in meristematic cells still remains elusive. Herein, the impact of cellulose synthesis inhibition and suppressed cell elongation on cortical microtubule orientation was assessed throughout the developmental zones of Arabidopsis thaliana root apex by whole-mount tubulin immunolabeling and confocal microscopy. Apart from the wild-type, thanatos and pom2-4 mutants of Cellulose SynthaseA3 and Cellulose Synthase Interacting1, respectively, were studied. Pharmacological and mechanical approaches inhibiting cell expansion were also applied. Cortical microtubules of untreated wild-type roots were predominantly transverse in the meristematic, transition and elongation root zones. Cellulose-deficient mutants, chemical inhibition of cell expansion, or growth in soil resulted in microtubule reorientation in the elongation zone, wherein cell length was significantly decreased. Combinatorial genetic and chemical suppression of cell expansion extended microtubule reorientation to the transition zone. According to the results, transverse cortical microtubule orientation is established in the meristematic root zone, persisting upon inhibition of cell expansion. Microtubule reorientation in the elongation zone could be attributed to conditional suppression of cell elongation. The differential responsiveness of microtubule orientation to genetic and environmental cues is most likely associated with distinct biophysical traits of the cells among each developmental root zone.     

Microfibrillar Structure, Cortical Microtubule Arrangement and the Effect of Amiprophos-methyl on Microfibril Orientation in the Thallus Cells of the Filamentous Green Alga, Chamaedoris orientalis

Microfibrillar structure, cortical microtubule orientation andthe effect of amiprophos-methyl (APM) on the arrangement ofthe most recently deposited cellulose microfibrils were investigatedin the marine filamentous green alga, Chamaedoris orientalis.The thallus cells of Chamaedoris showed typical tip growth.The orientation of microfibrils in the thick cell wall showedorderly change in longitudinal, transverse and oblique directionsin a polar dependent manner. Microtubules run parallel to thelongitudinally arranged microfibrils in the innermost layerof the wall but they are never parallel to either transverseor obliquely arranged microfibrils. The ordered change in microfibrilorientation is altered by the disruption of the microtubuleswith APM. The walls, deposited in the absence of the microtubules,showed typical helicoidal pattern. However, the original crossedpolylamellate pattern was restored by the removal of APM. Thissuggests that cortical microtubules in this alga do not controlthe direction of microfibril orientation but control the orderedchange of microfibril orientation. Amiprophos-methyl, Chamaedoris orientalis, coenocytic green alga, cortical microtubule, microfibrillar structure, tip growth     

Cellulose microfibril alignment recovers from DCB-induced disruption despite microtubule disorganization

Cellulose microfibril deposition patterns define the direction of plant cell expansion. To better understand how microfibril alignment is controlled, we examined microfibril orientation during cortical microtubule disruption using the temperature-sensitive mutant of Arabidopsis thaliana, mor1-1. In a previous study, it was shown that at restrictive temperature for mor1-1, cortical microtubules lose transverse orientation and cells lose growth anisotropy without any change in the parallel arrangement of cellulose microfibrils. In this study, we investigated whether a pre-existing template of well-ordered microfibrils or the presence of well-organized cortical microtubules was essential for the cell to resume deposition of parallel microfibrils. We first transiently disrupted the parallel order of microfibrils in mor1-1 using a brief treatment with the cellulose synthesis inhibitor 2,6-dichlorobenzonitrile (DCB). We then analysed the alignment of recently deposited cellulose microfibrils (by field emission scanning electron microscopy) as cellulose synthesis recovered and microtubules remained disrupted at the mor1-1 mutant's non-permissive culture temperature. Despite the disordered cortical microtubules and an initially randomized wall texture, new cellulose microfibrils were deposited with parallel, transverse orientation. These results show that transverse cellulose microfibril deposition requires neither accurately transverse cortical microtubules nor a pre-existing template of well-ordered microfibrils. We also demonstrated that DCB treatments reduced the ability of cortical microtubules to form transverse arrays, supporting a role for cellulose microfibrils in influencing cortical microtubule organization.     

Orientation of Microtubules during Regeneration of Cell Wall in Selected Giant Marine Algae

The microtubules in highly synchronized aplanospores of twogiant marine algae, Boergesenia forbesii and Valonia ventricosa,were examined by immunofluorescence microscopy throughout theregeneration of the cell wall. Microtubule orientation was alwaysrandom up to 20 h after wounding, although the orientation ofcellulose microfibrils changed from random to parallel withinthat time period. When the rhizoid cells were in the stage ofelongation at 7 to 10 days after wounding, highly ordered microtubuleswere always observed along the longitudinal cell axis exceptat the very tip of the cells where random ones were found. Incontrast, the microfibrils in the innermost lamellae of newlysynthesized cell walls showed three different orientations,that is, transverse, longitudinal and oblique to the longitudinalcell axis. These observations suggest that microtubules maycontrol cell shape, but not the orientation of microfibrils.The mechanism of cell wall construction in these algae is discussedin relation to the self-assembly mechanism thought to operatein the construction of helicoidal cell walls. ³ Present address: Polymer Research Laboratory, Mitsui ToatsuChemicals, Inc., Yokohama, Kanagawa 244, Japan. (Received November 18, 1987; Accepted April 11, 1988)     

Effects of ethylene on the orientation of microtubules and cellulose microfibrils of pea epicotyl cells with polylamellate cell walls

Summary Following a 5 hours ethylene treatment, cortical cells of Pea (Pisum sativum L. var Alaska) epicotyl third internode showed a change in the orientation of both microtubules near the plasma membrane and recently deposited cellulose microfibrils. Control cortical cells had mostly transverse microtubules. The ratio of the average frequency of transverse to longitudinal microtubules was 6.0. After 5 hours of ethylene treatment, cortical cells had mostly longitudinal microtubules, with the ratio of transverse to longitudinal microtubules equal to 0.1. Epidermal cells were more variable than cortical cells with regard to the frequency of longitudinal and transverse microtubules. Observation of cortical cell walls in conventionally stained thin sections revealed that recent deposition of microfibrils had been primarily transverse in almost all of the control cortical cells sampled. In contrast, more than half of the ethylene-treated cortical cells had recent deposition oriented primarily longitudinally. This change in microtubule and microfibril orientation may be early enough to constitute the primary effect of ethylene leading to radial cell expansion.Research supported by NSF grant PCM 78-03244, A1, 2 to PBG and by a Research Corporation grant to WRE.