Structure and assembly of the cortical microtubule cytoskeleton in the green alga,Boodlea coacta

Summary Examination was made of the structure and assembly of the cortical microtubule (MT) cytoskeleton in the coenocytic green algaBoodlea coacta (Dickie) Murray et De Toni by immunofluorescence microscopy. Cortical MTs inBoodlea protoplasts are arranged randomly but some show a meridional arrangement within 6 h after protoplast formation. At 6–9 h such MTs become highly concentrated and parallel to each other in certain areas. At 12 h the concentration is uniformly high throughout the cell, indicating the completion of high density meridional arrangement of cortical MTs. Cortical MTs exhibiting a high density, meridional arrangement show characteristic disassembly by treatment with 10 M amiprophos-methyl (APM) or cold treatment (0 °C). Disassembly occurs by each MT unit at positions skipping 30–40 m in the transverse direction, and neighboring MTs subsequently disassemble to form MT groups. Each group becomes slender and then disappears completely within the following 24 h. The meridional arrangement of cortical MTs is disrupted by N-ethylmaleimide (NEM) accompanied by a remarkable reduction in density. The remaining MTs form groups at 30–40 m intervals from each other, as also occurs with drug or cold treatment, but disruption and density return to normal levels following removal of NEM. It appears that there are meridionally oriented channels, anchor-rich and anchor-poor, in the plasma membrane. The channels could be distributed alternately and anchors could be deposited in a cross-linking manner with cortical MTs to form a stable cortical MT-cytoskeleton. MTs comprising the cortical MT cytoskeleton could be oriented by meridionally oriented channels of anchors which are distributed following establishment of cell polarity.Abbreviations APM amiprophos-methyl - MT microtubule - MTOC microtubule organizing center - NEM N-ethylrnaleimide     

Microtubule-binding proteins from carrot

Microtubules (MTs) participate in several processes of fundamental importance to growth and development in higher plants, yet little is known about the proteins with which they associate. Information about these molecules is important because they probably play a role in mediating functional and structural differences between various MT arrays. As a first step in gaining insight into this problem, we have isolated, from suspension-cultured cells of carrot (Daucus carota L.), non-tubulin proteins which bind to and affect microtubules (MTs) in vitro. These proteins were isolated using taxol-stabilized neuronal MTs as an affinity substrate. They cause MT bundling at substoichiometric concentrations, support the assembly of tubulin in vitro, and at low concentrations, decorate single MTs in a periodic fashion. The bundled MTs formed in vitro share similarities with those seen in situ in a variety of plant cells, including a center-center spacing of 34 nm, cold stability, resistance to anti-microtubule drugs, and sensitivity to calcium. The bundling activity is specific; other cationic proteins, as well as poly-L-lysine, do not behave in a similar manner. The bundling activity is insensitive to ATP. By assaying bundling activity with dark-field microscopy and employing standard biochemical procedures, a small number of polypeptides involved in the bundling process were identified. Affinity-isolated antibodies to one of these polypeptides (M_r=76000) were found to co-localize with MTs in the cortical array of protoplasts. Our findings are discussed with reference to the importance of these proteins in the cell and to their relationship to microtubule-associated proteins in other eukaryotes.Abbreviations DEAE diethylaminoethyl - MAP(s) microtubule-associated protein(s) - MT(s) microtubule(s) - M_r relative molecular mass - OD optical density - PM 50 mM 1,4-piperazinediethanesulfonic acid (Pipes), pH 6.9, 1 mM magnesium sulphate, 1 mM ethylene glycol-bis(-aminoethyl ether)-N,N,N,N-tetraacetic acid (EGTA) - SDS-PAGE sodium dodecyl sulphate-polyacrylamide gel electrophoresis     

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     

Amiprophos-methyl (APM): A rapid,reversible, anti-microtuble agent for plant cell cultures

Summary In plant cell suspension cultures sensitive to the herbicide amiprophos-methyl (APM), 1 to 3 M APM completely depolymerized both cortical and mitotic microtubule (MT) arrays in 1 hour. In comparison, a 2 hour application of 3 mM colchicine had no effect on MT arrays. Recovery from APM treatment occurred as early as 5 minutes after removal of APM. Short, cortical MTs were visible in 3 hours and complete MT arrays were found within 22 hours after drug removal.Sensitivity to APM-induced MT depolymerization varied according to species but was increased or decreased by varying the mitotic rate in cultures. The results indicated APM sensitivity was related to lowered stability of MT arrays in rapidly cycling cells. APM treatment may help distinguish stabilized cortical MTs in elongating cells and nonstabilized cortical MTs in rapidly dividing cells.Abbreviations MT microtubule - APM amiprophos-methyl - DMSO dimethyl sulfoxide - PBS phosphate buffered saline     

Pre- and postmitotic reorientation of microtubule arrays in youngSphagnum leaflets: Transitional stages and initiation sites

Summary The microtubules (MTs) of developingSphagnum leaflets rearrange from the interphase array into the preprophase band without obvious participation of definite initiation sites. At late prophase, additional MTs appear along the nuclear envelope, with the same orientation as in the peripherally situated preprophase band. Spindle formation begins along the nuclear envelope; spindle MTs run perpendicular to preprophase band MTs and converge in several focus points with indistinct polar bodies. After cytokinesis, most spindle and phragmoplast MTs disappear. Interphase MTs reappear at first along the central part of the new cell wall, in a region which was occupied before by the initial phragmoplast; their orientation is perpendicular to the phragmoplast MTs. Also here, distinct MT organizing centers could not be observed. Then the MT spread out over the cell periphery. The observations suggest that diffuse MT organizing zones rather than definite MT organizing centers play a role in the rearrangement of the different MT arrays during the cell cycle.     

Calmodulin and wound healing in the coenocytic green alga Ernodesmis verticillata (Kützing) Børgesen

The involvement of calmodulin (CaM) in wound-induced cytoplasmic contractions in E. verticillata was investigated. Indirect immunofluorescence of CaM in intact cells showed a faint, reticulate pattern of fluorescence in the cortical cytoplasm. Diffuse fluorescence was evident deeper within the cytoplasm. In contracted cells, CaM co-localizes with actin in the cortical cytoplasm in extensive, longitudinal bundles of microfilaments (MFs), and in an actin-containing reticulum. No association of CaM with tubulin was ever observed in the cortical cytoplasm at any stage of wound-healing. When contraction rates in wounded cells are measured, a lag period of 2 min is followed by a rapid, steady rate of movement over the subsequent 10 min. The delay in the initiation of longitudinal contraction corresponds to the time necessary for the assembly of the longitudinal MF bundles. Cytoplasmic motility was inhibited in a dose-dependent manner by CaM antagonists. In these inhibited cells, MF bundles did not assemble, or were poorly formed. In the latter case, CaM was always found associated with MFs. These results indicate a direct spatial and temporal correlation between CaM and actin, and a potential role for CaM in regulating the formation of functional MF bundles during wound-induced cytoplasmic contraction in Ernodesmis.Abbreviations CaM calmodulin - DMSO dimethyl sulfoxide - EGTA ethylene glycol-bis(-aminoethyl ether)-N,N,N,N-tetraacetic acid - MF(s) microfilament(s) - MT(s) microtubule(s) - TFP trifluoperazine - w-5 N-(6-aminohexyl)-1-naphthalenesulfonamide - W-7 N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide We are especially grateful to: Dr. J.A. West (University of California, Berkeley) for the original algal isolates; Dr. L. Van Eldik (Vanderbilt University School of Medicine) and Dr. J.L. Lessard (University of Cincinnati College of Medicine) for graciously providing CaM and actin antibodies, respectively; Dr. S.J. Roux (University of Texas, Austin) for the gift of purified oat CaM; Dr.H. Green (Smith, Kline and French Laboratories, Philadelphia, Penn., USA) for providing the trifluoperazine; and M.E.T. Scioli for assistance with the statistical analyses. Portions of this work were supported by National Science Foundation grant DCB 8402345 and U.S. Department of Agriculture grant 87-CRCR-1-2545 to J.W.L.     

Effects of cycloheximide on preprophase bands and prophase spindles in onion (Allium cepa L.) root tip cells

Summary Effects of cycloheximide (CHM) on preprophase bands (PPBs) of microtubules (MTs) and on prophase spindle MTs in root tip cells of onion (Allium cepa L.) were examined. When root tip cells were treated with 36 M CHM for 0.5–4 h, the population of cells with a PPB did not decrease markedly although the population of mitotic cells and that of prophase cells with a PPB gradually decreased to half of the control root tips. In prophase cells treated with 11 and 36 M CHM for 2 h, the width of the PPB was 1.4 times broader than that in the prophase PPB without CHM. Electron microscopic observation on the cross section of the PPB showed that the number of MTs and the distance between adjacent MTs in prophase PPBs treated with CHM were similar to those in the early developmental stage of PPBs without CHM. The bipolar spindle, that appeared in late prophase was not seen in prophase cells treated with 11 M or higher concentrations of CHM for 2 h. In order to examine differences of perinuclear MT arrangement between CHM treated and non-treated prophase cells, arrangement of perinuclear MTs was examined by confocal laser scanning microscopy. In control cells without CHM, MTs appeared on the nuclear surface with several branched or cross over type MT foci in the cytoplasm when broad PPB formation started. These MT foci were replaced by the aster type MT foci, from which several MTs radiated along the nuclear surface. The aster type MT foci gradually gathered to form a bipolar spindle. MTs connecting the spindle pole region and the PPB were seen in late prophase. In CHM-treated cells (11-360 M for 2 h), branched and cross over type MT foci were prominent, even in prophase cells with well condensed chromosomes. Neither linkages of MTs between the spindle pole region and the PPB nor aster type MT foci were seen. These observations showed that CHM prevents the bundling of MTs in the PPB and also inhibits the formation of aster type MT foci that is essential for bipolar spindle development.     

Dynamics of microtubule reassembly and reorganization in the coenocytic green alga Ernodesmis verticillata (Kützing) Børgesen

The dynamics of microtubule (MT) disassembly and reassembly were studied in the green alga Ernodesmis verticillata, using indirect immunofluorescent localization of tubulin. This alga possesses two distinct MT arrays: highly-ordered, longitudinally-oriented cortical MTs, and shorter perinuclear MTs radiating from nuclear surfaces. Perinuclear MTs are very labile, completely disassembling in the cold (cells on ice) within 5–10 min or in 25 μM amiprophos-methyl (APM) within 15–30 min. Although cortical MTs are generally absent after 3 h in APM, it takes 45–60 min before any cold-induced depolymerization is apparent, and some cortical MTs persist after 6 h of cold treatment. The extent of immunofluorescence of cytoplasmic (depolymerized?) tubulin is inversely proportional to the abundance of cortical MTs. Recovery of MT arrays upon warming or upon removal of APM occurs within 30–60 min for the perinuclear MTs, but the cortical arrays take much longer to regain their normal patterns. The cortical MTs initially reappear in a random distribution with respect to the cell axis, but within 3–4 d of warming (or 24–36 h of removing APM) they are nearly parallel to each other and to the cell's longitudinal axis. Thus, although the timing differs, the actual patterns of depolymerization and recovery are similar, irrespective of whether physical or chemical agents are used. Longer-term treatments in 1 μM APM indicate that despite the rapid disappearance of perinuclear MTs, a loss of the uniform nuclear spacing occurs gradually over 1–6 d. Similar disorganization of nuclei is obtained with long-term treatment with 1 μM taxol, where a gradual loss of perinuclear MTs is accompanied by an increased abundance of mitotic spindles. This implies that perinuclear MTs can disassemble in vivo in the presence of taxol, and that they are not the sole components involved in maintaining nuclear spacing in these coenocytes. The results indicate that both nuclear and cortical sites of MT nucleation may exist in this organism, and that MT reassembly and re-organization are temporally distinct events in cells that have highly-ordered arrays of long MTs.     

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.     

Microtubule formation on the nuclear surface during meiosis inAcetabularia acetabulum

Summary Microtubules (MT) are a feature of all eukaryotic cells. However, they have not been observed in the cytoplasm of the vegetative phase ofAcetabularia acetabulum. Previous investigators have reported that, in the propagative phase, MTs function as anchors in the transport of secondary nuclei to the cap. They also form elaborate arrays around nuclei during cyst formation. The life history ofA. acetabulum is marked by changes in chromatin, the nucleolus, and the perinuclear cytoplasm. In this study light microscopical features of the nucleolus and changes in chromatin, labelled with anti-histon antibodies, were used to define the developmental stages. Anti-tubulin antibodies have been used to trace the origin and development of MTs, MTs are formed on the surface of the primary nucleus. They are organized first into short thick sticks and then later elongate into thinner strands which enclose the nucleus in a dense network. Following these events on the surface of the nucleus, the spindle develops inside the nuclear membrane which remains intact throughout the mitotic division.     

The microtubular cytoskeleton in cells of cold-treated roots of maize (Zea mays L.) shows tissue-specific responses

Summary Microtubules (MTs) in cells of various tissues at different distances from the apex of the maize root exhibited different sensitivities to cold (5 °C), as judged by MT reorientation and tendency to depolymerization. Their responses seem to be related to their initial intracellular arrangements. Generally, MTs in cells which were ceasing elongation were the least sensitive during the early stages (6–24 h) of cold treatment, but during the later stages (5–7 d) MTs in most of these cells eventually depolymerized. Pericycle cells showed a unique cold response. Here the MTs were conspicuously cold-labile and quickly depolymerized near the root-tip. However, after 1 d many pericycle cells in more proximal regions had repolymerized their MTs as dense, randomly organized arrays. These persisted for the remainder of the cold treatment. A similar resistance to longterm chilling, by means of MT repolymerization, was found in cells of the root cap, quiescent centre and cells of the distal part of the former meristem. MT repolymerization in the cold may enable the apex to resume growth when more favourable (warmer) conditions return.Abbreviations DAPI 4,6-diamidino-2-phenylindole - DMSO dimethylsulfoxide - EGTA ethylene glycol-bis(-aminoethylether)-N,N,N,N-tetraacetic acid - FITC fluorescein isothiocyanate - IgG immunoglobulin G - MT microtubule - PEG polyethylene glycol - PIPES piperazine-N,N-bis(diethanesulfonic acid)     

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     

Reorganization of cortical microtubules and cellulose deposition during leaf formation in Graptopetalum paraguayense

In the regeneration of a shoot from a leaf of the succulent, Graptopetalum paraguayense E. Walther the first new organs are leaf primordia. The original arrangement of cellulose microfibrils and of microtubules (MTs) in the epidermis of the leaf-forming site is one of parallel, straight lines. In the new primordium both structures still have a congruent arrangement but it is roughly in the form of concentric circles that surround the new cylindrical organ. The regions which undergo the greatest shift in orientation (90°) were studied in detail. Departures from the original cellulose alignment are detected in changes in the polarized-light image. Departures from the original cortical MT arrangement are detected using electron microscopy. The over-all reorganization of the MT pattern is followed by the tally of MT profiles, the various regions being studied in two perpendicular planes of section. This corrects for the difference in efficiency in counting transverse versus longitudinal profiles of MTs. Reorientation takes place sporadically, cell by cell, for both the cellulose microfibrils and the MTs, indicating a coordinated reorientation of the two structures. That MTs and cellulose microfibrils reorient jointly in individual cells was shown by reconstruction of the arrays of cortical MTs in paradermal sections of individual cells whose recent change in the orientation of cellulose deposition had been detected with polarized light. Closeness of the two alignments was also indicated by images where the MT and microfibril alignments co-varied within a single cell. The change-over in alignment of the MTs appears to involve stages where arrays of contrasting orientation co-exist to give a criss-cross image. During this critical reorganization, the frequency of the MTs is high. It falls during subsequent enlargement of the organ. It was found that the rearrangement of the cortical MTs to approximate a series of concentric circles on the residual meristem occurred before the emergence of leaf primordia. Through their apparent influence on microfibril alignments, the changes in MT disposition, described here, have the potential to generate major biophysical changes that accompany organogenesis.Abbreviation MT(s) microtubule(s)     

The distributional changes and role of microtubules in Nod factor-challenged<Emphasis Type="Italic"> Medicago sativa</Emphasis> root hairs

The normal tip-growing pattern exhibited by root hairs of legumes is disrupted when the hair is exposed to Nod factors generated by compatible bacteria capable of inducing nodule formation. Since microtubules (MTs) play an important role in regulating directionality and stability of apical growth in root hairs [T.N. Bibikova et al. (1999) Plant J 17:657–665], we examined the possibility that Nod factors might affect the MT distribution patterns in root hairs of Medicago sativa L. We observed that Nod factor application caused rapid changes in the pattern of MTs starting as early as 3 min after perfusion. Within 3 to 10 min after Nod factor application, first endoplasmic and then cortical MTs depolymerised, initially at the proximal ends of cells. Twenty minutes after exposure to Nod factors, a transverse band of microtubules was seen behind the tip, while almost all other MTs had depolymerised. By 30 min, very few MTs remained in the root hair and yet by 1 h the MT cytoskeleton re-formed. When Nod factors were applied in the presence of 10 M oryzalin or 5 M taxol, the MTs appeared disintegrated while the morphological effects, such as bulging and branching, became enhanced. Compared to the treatments with oryzalin or taxol alone, the combinatory treatments exhibited higher growth rates. Since microtubule reorganization is one of the earliest measurable events following Nod factor application we conclude that microtubules have an important role in the early phases of the signalling cascade. Microtubule involvement could be direct or a consequence of Nod factor-induced changes in ion levels.Electronic Supplementary Material Supplementary material is available in the online version of this article at http://dx.doi.org/10.1007/s00425-003-1097-1Abbreviations BNM buffered nodulation medium - CLSM confocal laser scanning microscopy - MT microtubule     

Tobacco protoplasts differentiate into elongate cells without net microtubule depolymerization

Summary Microtubules (MTs) are important for plant cell morphogenesis because they influence the deposition of cell plate and wall components. It has been observed that tobacco protoplasts contain a disordered MT array in the cortex. Following several days in culture, these protoplasts become elongate cells with an orderly cortical MT array. The transformation of the MT array may occur by net depolymerization of the disordered MTs and repolymerization of MTs into an ordered array, or by movement of the array as an integral unit. To experimentally distinguish between these two possibilities, the drug taxol was used to stabilize MTs. Protoplasts derived from suspension cultured tobacco,Nicotiana tabacum, were grown in a medium containing the two plant hormones -naphthaleneacetic acid and benzyladenine, in the presence or absence of 10M taxol. Changes in cell size and shape were quantified using a video image analysis system. Cell elongation had begun within 48h of protoplast conversion, in both treatments, and continued for 7 days. Immunolocalization of tubulin showed that, in the majority of cells, MTs were disorganized immediately following protoplast conversion. After elongation, the MT arrays were observed to have reoriented to an ordered state. Taxol-treated protoplasts were found to elongate faster and to a greater extent than the non-treated controls. Additionally, the cortical array of taxol-treated protoplasts reorganized more quickly. These data indicate that the net depolymerization of disordered cortical MTs is not necessarily required for the differentiation of a protoplast into an elongate cell.Abbreviations APM amiprophosmethyl - BSA bovine serum albumin - DIC differential interference contrast - DTT dithiothreitol - EGTA ethylenegrycol-bis-(-aminoethyl ether)N,N,N,N-tetra-acetic acid - ELISA enzyme-linked immunosorbent assay - FMS Fukuda, Murashige, and Skoog - MS Murashige and Skoog - MT(s) microtubule(s) - PBS phosphate buffered saline - PIPES piperazine-N,N-bis (2-ethanesulfonic acid, 1.5 sodium) - PM plasma membrane - Tris Tris(hydroxymethyl)amino-methane     

Immunofluorescence microscopy of microtubule arrangement in Closterium acerosum (Schrank) Ehrenberg

The microtubule (MT) arrangement in Closterium acerosum cells was observed by indirect immunofluorescence microscopy both during and following cell division, and during cell expansion without cell division. (During the division period, some cells of this alga divide whereas other cells expand in their middle region without division.) Before septum formation, all cells had a ring-like MT bundle (MT ring) in their middle. Both septum formation and expansion without cell division occurred at the position of this ring. During the periods of division, short, hair-like MTs appeared around the nucleus in some of the cells, in addition to the MT ring. In dividing cells, spindle MTs appeared as the chromosomes were condensed. During the early stages of expansion of the semicells, after cell division, the spindle MTs assumed a radial arrangement, moved, and settled in a position between the daughter chloroplasts. These MTs disappeared about 1.5 h after septum formation. As the new semicells were growing, wall MTs appeared, arranged transversely along the expanding wall. These transverse MTs disappeared gradually 4–5 h after septum formation, and only an MT ring remained near the boundary between the new and old semicells. The MT ring was present until the next cell division or expansion without cell division. During the latter course of development, transverse wall MTs were present only at the band-like expanding region. At the earlier stage of expansion without cell division, the short, hair-like MTs remained around the nucleus, but as time passed, both the hair-like MTs and, somewhat later, the transverse ones disappeared and only the MT rings remained. The remaining MT ring was not always positioned at the boundary between the expanding and the old cell region. The temporal relationships between the changes in MT arrangement, and the orientation and localization of cellulose-microfibril deposition are discussed.Abbreviations DAPI 46-diamino-2-phenylindole - EGTA ethyleneglycol-bis-(-aminoethylether)-N, N, N, N-tetraacetic acid - MT mierotubule - PMSF phenylmethylsulfonyl fruoride     

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     

A planar microtubule-organizing zone in guard cells of Allium: experimental depolymerization and reassembly of microtubules

The generation of the unique radial array of microtubules (MTs) in stomatal guard cells raises questions about the location and activities of relevant MT-organizing centers. By using tubulin immunofluorescence microscopy, we studied the pattern of depolymerization and reassembly of MTs in guard cells of Allium cepa L. Chilling at 0°C reduces the MTs to small remnants that surround the nuclear surface of cells in the early postcytokinetic stage, or form a dense layer along the central portion of the ventral wall in older guard cells. A rapid reassembly on rewarming restores either MTs extending from the nuclear surface randomly throughout the cytoplasm in very young cells, or an array of MTs radiating from the dense layer at the ventral wall later in development. A similar pattern of depolymerization and reassembly is achieved by incubation with 100 M colchicine followed by a brief irradiation with ultraviolet (UV) light. Incubation with 200 M colchicine leads to a complete depolymerization that leaves only a uniform, diffuse cytoplasmic fluorescence. Nonetheless, UV irradiation of developing guard cells induces the regeneration of a dense layer of MTs at the ventral wall. The layer is again positioned centrally along the wall, even if the nucleus has been displaced by centrifugation in the presence of cytochalasin D. Neither the regenerated layer nor the perinuclear MTs seen earlier are related to the staining pattern of serum 5051, which reportedly binds to centrosomal material in animal and plant cells. The results support the view that, soon after cytokinesis, a planar MT-organizing zone is established in the cortex along the central portion of the ventral wall, which then generates the radial MT array.Abbreviations GC guard cell - MT microtubule - MTOC microtubule-organizing center - UV ultraviolet To whom correspondence should be addressed.     

Reorganization of the cortical cytoskeleton in tip-growing fern protonemal cells during phytochrome-mediated phototropism and blue light-induced apical swelling

Summary Circular arrays of cortical microtubules (MTs) and microfilaments (MFs) are found in the subapical region of tip-growing protonemal cells of the fernAdiantum capillus-veneris. Reorganization of the two cytoskeletal structures during phytochrome-mediated phototropism and blue light-induced apical swelling was investigated by double-staining of MTs and MFs with rhodaminephalloidin and an indirect immunofluorescence method with tubulinspecific antibody. Before any growth responses were detectable, the MF and MT structures were reorganized according to similar patterns in both photoresponses, that is, oblique orientation and transient disappearance of the structures occurred during the phototropic response, and the disappearance of the structures occurred during apical swelling. The reorganization of MF structures clearly preceded that of the MT structures in the phototropic response. In the case of apical swelling, both types of circular array disappeared with an almost identical time course.These results provide evidence for the significant role of the circular organization of MFs as well as of MTs, in the light-induced growth responses of tip-growing fern protonemal cells. Possible roles of the circular array of MFs in the regulation of tip growth are discussed.Abbreviations DMSO dimethylsulfoxide - PIPES piperazine-N,N-bis(2-ethane-sulfonic acid) - EGTA ethyleneglycol-bis-(-aminoethylether)-N,N,N,N-tetraacetic acid - PMSF phenylmethylsulfonyl fluoride - MF microfilament - MT microtubule - Rh-Phal rhodaminelabeled phalloidin     

Microtubule organization in cultured soybean and black spruce cells: Interphase —mitosis transition and spindle morphology

Summary Microtubule (MT) distribution during the cell cycle, especially spindle organization, has been investigated using immunofluorescence light microscopy in cultured cells of two higher plant species, soybean (angiosperm) and black spruce (gymnosperm). In soybean, the prophase and metaphase spindles were different in morphology and structure. The prophase spindle covering the nucleus was barrel-shaped and MTs extended between poles. The metaphase spindle consisted mainly of short MT bundles on either side of the chromosome mass. During prometaphase, the polarity and shape of the prophase spindle disappeared, suggesting that the metaphase spindle is newly formed in prometaphase and not derived from the prophase spindle. A striking feature of MT organization in black spruce was sharply defined poles during prometaphase and anaphase. They were located close to the cell edge, suggesting that a structure in the cytoplasm or associated with the plasma membrane is responsible for their formation. In black spruce the metaphase spindle was long with pointed poles and MT fir tree structures. In contrast, the metaphase spindle of soybean was short with very broad poles and lacked MT fir trees. These results suggest that MT fir tree structure may not be necessary for a functional spindle.