DIATOM MINERALIZATION OF SILICIC ACID. VI. THE EFFECTS OF MICROTUBULE INHIBITORS ON SILICIC ACID METABOLISM IN NAVICULA SAPROPHILA1

The role of microtubules in silicon metabolism leading to valve formation was investigated in the pennate diatom Navicula saprophila Lange-Bertalot & Bonik. By using synchronized cells blocked after mitosis and cytokinesis but prior to cell wall formation, effects due to inhibition of mitosis were eliminated. Cells were treated with three anti-microtubule drugs to assess the role of microtubules. Chemical analogs to two of the drugs provided controls for inhibition not related to microtubule disruption. Although all three anti-microtubule drugs reduced cell separation at high concentrations (1 × 10^?3 M), podophyllotoxin was the only drug which reduced cell separation at concentrations lower than 1 × 10^?5 M. None of the drugs at any concentration tested affected cell viability. There was no differential inhibitory effect between the active and inactive drugs on silicic acid transport, total uptake, incorporation, or pool formation. There was no qualitative difference between silica incorporated in treated and untreated cells. A colchicine binding component was isolated from N. saprophila. The characteristics of colchicine binding suggest this component may be tubulin. Microtubules do not appear to be involved in any of the steps of silicon metabolism leading to valve formation and yet they have profound influence on the symmetry and pattern of the mineralized product, the siliceous valve.     

Microtubules do not control orientation of secondary cell wall microfibril deposition inMicrasterias

Summary The influence of the microtubule disorganizing substances amiprophos-methyl (APM) and colchicine on secondary wall formation inMicrasterias denticulata was investigated by the freezeetch technique. The results reveal that neither microtubule inhibitor changes the pattern of microfibril deposition. The application of APM or colchicine also does not cause any structural alterations of the microfibrils or of the protoplasmic (Pf) and the exoplasmic (Ef) fracture face of the plasma membrane, thus indicating that microtubules are not involved in secondary wall formation inM. denticulata. However, since areas of the plasma membrane which collapsed upon freeze-etching are restricted to the Pf-face of cells treated with microtubule inhibitors, cortical microtubules may function as mechanical support during secondary wall formation. In the cortical cytoplasm filamentous structures are found in close spatial relationship and an almost parallel alignment to rosettes of the plasma membrane.     

THE EFFECTS OF COLCHICINE ON SPERMATOGENESIS IN NITELLA

Treatment of Nitella antheridia with colchicine results in various sperm abnormalities, depending upon duration of exposure and subsequent recovery. Early effects of treatment include disappearance of spindle fibers and a cessation of ordered cell wall formation in dividing cells. Sperm released from antheridia treated for 24 hr and allowed to recover for 4–5 days possess branched flagella. After a recovery period of 6–10 days the sperm appear normal; however, following longer recovery periods, the sperm exhibit variations in size and number of flagella. Branched flagella contain a variety of microtubule patterns ranging from branches containing a single microtubule to flagella with an excess of microtubules. Spermatids which differentiate in the presence of colchicine lack flagella and a microtubular sheath. Nuclear contents undergo condensation stages; however, the nucleus as a whole does not undergo the orderly elongation and coiling characteristic of untreated Nitella spermatids. Long-term colchicine treatment followed by a recovery period produces atypical microtubules and microtubular aggregations in the spermatid. The results indicate that colchicine affects not only polymerization of microtubule subunits but also factors responsible for their ordered spatial relationships in the cell. The presence of microtubules is a prerequisite for normal morphological changes during spermiogenesis.     

Heat stress affects the organization of microtubules and cell division in Nicotiana tabacum cells

To investigate the effects of heat stress on the plant cytoskeleton, the structure of microtubule arrays in N. tabacum suspension cells incubated at 38 or 42°C was analysed. Whilst incubation at 42 °C resulted in the disruption of the majority of cellular microtubules after 30 min, in cells exposed to 38 °C all the microtubule arrays were preserved even after 12 h of incubation, although their organization was altered. The most susceptible were the microtubules of the mitotic spindle and the phragmoplast. Several abnormalities were observed: (i) splitting of the spindle into several parts; (ii) elongation of the spindles; (iii) formation of microtubule asters in mitotic cells, and (iv) elongation of phragmoplast microtubules. Exposure of cells to 38 °C caused a decrease in the mitotic index but an accumulation of telophase cells. The recovery of normal microtubule organization occurred after 12 h. Treatment of the cells subjected to heat stress conditions with an inhibitor of protein synthesis, cycloheximide, did not prevent either the alterations of microtubule organization or accumulation of cells containing phragmoplasts. Therefore, heat shock proteins do not seem to be directly responsible for the microtubule disorganization induced by heat stress.     

Mechanism of inhibition of microtubule polymerization by colchicine: inhibitory potencies of unliganded colchicine and tubulin-colchicine complexes.

The tubulin-colchicine binding reaction appears to involve a number of intermediate steps beginning with rapid formation of a transient preequilibrium complex that is followed by one or more slow steps in which conformational changes in tubulin and colchicine lead to formation of a poorly reversible final-state complex. In the present study, we investigated the relative ability of unliganded colchicine and preformed final-stage tubulin-colchicine complex to incorporate at microtubule ends and to inhibit addition of tubulin at the net assembly ends of bovine brain microtubules in vitro. Addition of 0.1 microM final-stage tubulin-colchicine complex to suspensions of microtubules at polymer-mass steady-state resulted in rapid incorporation of one to two molecules of tubulin-colchicine complex per microtubule net assembly end concomitant with approximately 50-60% inhibition of tubulin addition. Incorporation of colchicine-tubulin complex continued slowly with time, without significant additional change in the rate of tubulin addition. In contrast, addition of unliganded colchicine to microtubule suspensions resulted in incorporation of small numbers of colchicine molecules at microtubule ends and inhibition of tubulin addition only after periods of time that varied from several minutes to approximately 20 min depending upon the concentration of colchicine. Inhibition of tubulin addition beginning with unliganded colchicine increased slowly with time, concomitant with increases in the concentration of final-state tubulin-colchicine complex and the amount of colchicine bound per microtubule end. The results indicate that inhibition of tubulin incorporation at microtubule ends is caused by colchicine-liganded tubulin in the form of a final-state complex.(ABSTRACT TRUNCATED AT 250 WORDS)     

COLONY DEVELOPMENT IN EUDORINA ELEGANS (CHLOROPHYTA,VOLVOCALES)1

A detailed ultrastructure study was made of cell division and colony development in Eudorina elegans Ehrenberg. At the onset of cell division and prior to nuclear division the nucleus moved from the cell center to the cell surface. During nuclear division the nuclear membrane remained intact, except for openings occurring at the nuclear poles. The spindle microtubules appeared to arise from a MTOC-like (microtubule organizing centers) structure, while centrioles were absent from the nuclear poles. Following telophase, daughter nuclei formed which were separated by several distinct bands of endoplasmic reticulum. Cytokinesis occurred with formation of a cleavage furrow, associated with a typical phycoplast band of microtubules. However, cytokinesis was incomplete, resulting in formation of cytoplasmic bridges between the plakeal cells. Upon completion of up to five successive cell divisions, the plakea underwent inversion, which appeared to involve the production of colonial envelope material and rearrangement of cytoplasmic bridges. A new hypothesis concerning inversion is postulated based on these observations.     

Colchicine inhibits ionophore-induced formation of leukotriene B4 by human neutrophils: the role of microtubules

Neutrophils which ingest particles (serum-treated zymosan, monosodium urate crystals) or are exposed to calcium ionophore A23187 generate leukotriene B4 (LTB4). Earlier work has shown that cells exposed to colchicine before exposure to monosodium urate crystals produce less LTB4; the formation of 5-HETE is unaffected. To determine whether inhibition by colchicine of LTB4 generation was stimulus-specific and was mediated by microtubule integrity, the effects of colchicine (10 microM, 60 min) on the release of lipoxygenase products from neutrophils exposed to ionophore A23187 (10 microM, 5 min) were examined. In the presence of exogenous arachidonic acid (100 microM, 15 min), colchicine decreased LTB4 to 48% +/- 11.7 of control and 5-HETE to 60.5% +/- 5.7 of control (mean +/- SEM); 15-HETE was also decreased to 61% +/- 10.3 of control. In the absence of exogenous arachidonate, LTB4 was decreased to 22.2% +/- 11.7 of control and 5-HETE to 13% +/- 4.8 of control. Lumicolchicine did not significantly affect formation of 5-HETE or LTB4. However, vinblastine sulfate (20 microM, 60 min), another microtubule-disruptive agent, decreased the formation of both 5-lipoxygenase products. The effects of colchicine and vinblastine were not due to impairment of cell viability because the release of cytoplasmic lactic dehydrogenase was unaffected. Ultrastructural analysis of centriolar microtubules showed that decrements in microtubule numbers of colchicine- and vinblastine-treated cells paralleled decrements in 5-lipoxygenase products. These pharmacologic manipulations suggested that functional microtubules might be required for optimal lipoxygenase activity. Consequently, we prepared neutrophil-derived cytoplasts, devoid of an intact microtubule system. No significant decreases in the 5- or 15-lipoxygenase products were found when cytoplasts were exposed to colchicine in the presence of exogenous arachidonate and A23187. The data show that colchicine inhibits the formation of lipoxygenase products from neutrophils stimulated with A23187, most likely via its effect on microtubules, the integrity of which appears necessary for full expression of 5- and 15-lipoxygenases.     

Arginyl residues involvement in the microtubule assembly

Modification of pig brain tubulin with 2,3-butanedione, an arginine-specific reagent, resulted in a decrease of its microtubule formation capacity, with apparent first-order kinetics. However, microtubules already assembled were not affected by the reagent. The relation between the polymerization inhibition rate constant and the butanedione concentration followed a saturation curve whereas the colchicine binding activity remained unchanged over that concentration range. GTP partially prevented the decrease of tubulin polymerization induced by the butanedione treatment. This protective effect of GTP was increased by glycerol. The butanedione inhibition of tubulin polymerization appears to be related to the modification of no more than three arginyl residues. These data suggest that at least one of the arginyl residues plays an essential role in tubulin polymerization, probably through its interaction with the negatively charged phosphate moiety of the nucleotide.     

Quantitative analysis of microtubule orientation in interdigitated leaf pavement cells

Leaf pavement cells are shaped like a jigsaw puzzle in most dicotyledon species. Molecular genetic studies have identified several genes required for pavement cells morphogenesis and proposed that microtubules play crucial roles in the interdigitation of pavement cells. In this study, we performed quantitative analysis of cortical microtubule orientation in leaf pavement cells in Arabidopsis thaliana. We captured confocal images of cortical microtubules in cotyledon leaf epidermis expressing GFP-tubulinβ and quantitatively evaluated the microtubule orientations relative to the pavement cell growth axis using original image processing techniques. Our results showed that microtubules kept parallel orientations to the growth axis during pavement cell growth. In addition, we showed that immersion treatment of seed cotyledons in solutions containing tubulin polymerization and depolymerization inhibitors decreased pavement cell complexity. Treatment with oryzalin and colchicine inhibited the symmetric division of guard mother cells.     

The small molecule CS1 inhibits mitosis and sister chromatid resolution in HeLa cells

Background

Mitosis, the most dramatic event in the cell cycle, involves the reorganization of virtually all cellular components. Antimitotic agents are useful for dissecting the mechanism of this reorganization. Previously, we found that the small molecule CS1 accumulates cells in G2/M phase [1], but the mechanism of its action remains unknown.

EXPERIMENTAL STUDIES OF CYTOPLASMIC ORGANIZATION IN ZONARIA APICAL CELLS

Rapidly growing thalli of Zonaria have been treated with colchicine (10,000, 5,000, and 1,250 μg/ml) and phenobarbital (10,000 and 5,000 μg/ml). Responses of the meristems to drug treatment have been described at the ultrastructural, cellular, and organismic levels. With colchicine treatment microtubule disruption, nuclear envelope abnormalities, nuclear lobing, and increased nuclear sizes were observed. Apical cells ceased dividing but continued to elongate until cessation of treatment when abnormal cytokineses, irregular cell shapes, and cell deaths were observed. The coordinated growth of the meristem margin was disrupted, regions recovering left a zone line on the thalli, and cell deaths resulted in thallus branching. With phenobarbital treatment ER elaboration, inactive-appearing dictyosomes, pyrenoid-like structures, and deeply cup-shaped mitochondria aggregated with ER were observed. Apical cell elongation ceased and the mitotic cycle appeared to be arrested just after cytokinesis. Recovery from 10,000 μg/ml phenobarbital was low, with subapical cells and occasional apical cells starting new thalli. Recovery from 5,000 μg/ml was good, with occasional cell death dividing the meristem and zone lines resulting from the temporary synchrony. Correlations of responses at the ultrastructural, cellular, and organismic levels are discussed.     

Microtubules, colchicine, and lymphocyte blastogenesis.

We have studied the time course of disassembly of microtubules of resting and stimulated mouse lymphocytes caused by the drug colchicine, as well as the effect of this compound on DNA and RNA synthesis of human and mouse lymphocytes. Fine-structure studies with the electron microscope showed a great increase in number of microtubules resulting from stimulation of mouse lymphocytes by the mitogenic lectin Con A. The presence of a network of microtubules was demonstrated in resting lymphocytes by use of the technique of immunofluorescence; this technique was not effective for the study of the microtubules of stimulated lymphocytes in the blast stage. The disappearance of microtubular networks in some cells (approximately 25%) was caused by the protocol of colchicine treatment used in many laboratories (30 min at 10(6) M); a 6- to 8-h treatment was required to cause all cells to lose their microtubules. It is indicated in these findings that there is need for extreme caution in implicating microtubule disruption as the cause of certain colchicine effects, such as that on the Con A-induced inhibition of receptor-ligand migration. The addition of colchicine to stimulated cells at varying times of culture caused marked inhibition of DNA synthesis provided that sufficient time (approximately 20 h for maximum inhibition) elapsed between addition of the drug to the stimulated culture and assay of DNA synthesis. Our data on the time course of inhibition of DNA synthesis by alpha-methyl mannoside (alpha MM) and by colchicine do not exclude the possibility that the latter compound may act partially by affecting the commitment of stimulated lymphocytes to DNA synthesis but they show that it can inhibit well after commitment is complete. The later the time of assay of thymidine incorporation, the more disparate were the curves relating the effects of alpha MM and colchicine to DNA synthesis of human cells. In the case of mouse splenic lymphocytes, there was no resemblance between the time course of the alpha MM and of the colchicine effects. Synthesis of RNA after 12 h of culture of stimulated human lymphocytes was also sensitive to colchicine.     

Application of trifluralin to embryogenic microspore cultures to generate doubled haploid plants in Brassica napus

Microspore or anther culture has been used to produce desirable meiotic recombinants in numerous species. However, the utilization of these recombinants relies on inefficient genome doubling procedures to obtain fertile doubled haploid plants. This study presents a simple and rapid procedure to generate fertile doubled haploids in Brassica napus cv. Topas using trifluralin (α,α,α-trifluoro-2,6-dinitro-N,N-dipropyl- p -toluidine), a plant specific microtubule inhibitor. The effects of trifluralin on microtubule depolymerization and chromosome doubling in embryogenic microspore cultures of B. napus were examined and compared with those of colchicine. Indirect immunofluorescence labeling of isolated microspores indicated that microtubules were depolymerized within 30 min of trifluralin treatment and after 3–8 h of colchicine treatment. The direct application of these microtubule inhibitors to microspore cultures resulted in the recovery of fertile doubled haploid plants. Continuous culture in the presence of colchicine, was more effective than 18-h treatments for fertile plant production but resulted in abnormal embryo formation and recalcitrant plant regeneration. The application of 1 or 10 μ M trifluralin during the first 18 h of microspore culture was found to be the superior method for doubled haploid production. The embryos generated after trifluralin treatment developed normally, germinated readily and of the plants produced, close to 60% were fertile. The use of trifluralin to double chromosomes very early in microspore cultures is a simple process requiring minimal manipulation and should be very useful for genetic studies and breeding programs of B. napus and possibly other species.     

Microtubules become more dynamic but not shorter during preprophase band formation: a possible "search-and-capture" mechanism for microtubule translocation

The dynamic behavior of the microtubule cytoskeleton plays a crucial role in cellular organization, but the physical mechanisms underlying microtubule (re)organization in plant cells are poorly understood. We investigated microtubule dynamics in tobacco BY-2 suspension cells during interphase and during the formation of the preprophase band (PPB), the cytoskeletal structure that defines the site of cytokinesis. Here we show that after 2 h of microtubule accumulation in the PPB and concurrent disappearance elsewhere in the cortex, the PPB is completed and starts to breakdown exponentially already 20 min before the onset of prometaphase. During formation of the PPB, the dynamic instability, i.e., the stochastic alternating between growing and shrinking phases, of the cortical microtubules outside the PPB increases significantly, but the microtubules do not become shorter. Based on this, as well as on the cross-linking of microtubules in the PPB and the lack of evidence for motor involvement, we propose a "search-and-capture" mechanism for PPB formation, in which the regulation of dynamic instability causes the cortical microtubules to become more dynamic and possibly longer, while the microtubule cross-linking activity of the developing PPB preferentially stabilizes these "searching" microtubules. Thus, microtubules gradually disappear from the cortex outside the PPB and aggregate to the forming PPB.     

The dynamics of microtubule repolymerization in a cell: rapid growth from the centrosome and slow recovery of free microtubules

According to the current view, the microtubule system in animal cells consists of two components: microtubules attached to the centrosome (these microtubules stretch radially towards the cell margin), and free microtubules randomly distributed in the cytoplasm without visible association with any microtubule-organizing centers. The ratio of the two sets of microtubules in the whole microtubule array is under discussion. Addressing this question, we have analysed the recovery of microtubules in cultured Vero nucleated cells and cytoplasts, with and without centrosomes in these. Cells were fixed at different time points, and individual microtubules were traced on serial optical sections. During a slow recovery after cold treatment (4 degrees C, for 4 h; recovery at 30 degrees C) polymerization of microtubules started mainly from the centrosome. At early stages of recovery the share of free microtubules made about 10% of all microtubules, and their total length increased slower than the lenght of centrosome-attached microtubules. During a rapid recovery after nocodazole treatment (10 microg/ml, 2 h; recovery in drug-free medium at 37 degrees C), the share of free microtubules was about 35%, but their total length increased slower than the length of centrosome-attached microtubules. In 6-8 min (rapid recovery) or 12-16 min (slow recovery), tips of centrosomal microtubules reached the cell margin, and their increased density made it impossible to recognize individual microtubules. However, under the same conditions in cytoplasts without centrosomes the normal number of microtubules recovered only in 60 min, which enabled us to suppose that the complete recovery of microtubule system in the whole cells may be also rather long. When the first centrosomal microtubules reached the cell margin, the optical density of microtubules started to decrease from the centrosome region towards the cell margin, according to the exponential curve. Later on, the optical density in the centrosome region and near the cell margin remained at the same level, but microtubule density increased in the middle part of the cell, and in 45-60 min the plot of the optical density vs the distance from the centrosome became linear, as in control cells. Since no significant curling of microtubules occurs near the cell margin, the density of microtubules in the endoplasm may increase due only to polymerization of free microtubules. We suppose that in cultured cells the microtubule network recovery proceeds in two stages. At the initial stage, a rapid growth of centrosomal microtubules takes place in addition to the turnover of free microtubules with unstable minus ends. At the second stage, when microtubule growth from the centrosome becomes limited by the cell margin, a gradual extension of free microtubules occurs in the internal cytoplasm.     

Enhancement of tubulin assembly as monitored by a rapid filtration assay

The early kinetics of microtubule formation from lamb brain tubulin isolated by affinity chromatography can be followed by a newly developed filter assay. The rapid collection of microtubules on glass fiber filters permits the calculation of the moles of tubulin polymerized. The filter assay gives both a rate and extent of polymerization that are identical to those obtained by turbidity or sedimentation analysis, respectively. The microtubules trapped by the filter are readily depolymerized by cold (t12= 3 min) and slowly by colchicine (t1/2= 32min). Tubulin purified by affinity chromatography requires a high protein concentration (>4 mg/ml) for polymerization. Although 5m glycerol allows polymerization to occur at tubulin concentrations below 2 mg/ml, the maximum amount of microtubule formation is observed at low tubulin concentration when microtubule-associated proteins are present. These proteins are not retained by the affinity resin; however, they can be eluted from diethylaminoethyl-Sephadex by solutions containing 0.3m KCl. Microtubule-associated proteins enhance both the rate of polymerization and the total amount of tubulin polymerized as assessed by the filter assay, suggesting that they are involved in both initiation and elongation of microtubules.     

Giardia lamblia: evaluation of the in vitro effects of nocodazole and colchicine on trophozoites

Giardia lamblia is the most commonly detected parasite in the intestinal tract of humans and other mammals causing giardiasis. Giardia presents several cytoskeletal structures with microtubules as major components such as the ventral adhesive disk, eight flagella axonemes, the median body and funis. Many drugs have already been tested as antigiardial agents, such as albendazole and mebendazole, which act by specifically inhibiting tubulin polymerization and hence microtubule assembly. In the present work, we used the microtubule inhibitors nocodazole and colchicine in order to investigate their direct and indirect effects on Giardia ultrastructure and attachment to the glass surface, respectively. Axenically grown G. lamblia trophozoites were treated with nocodazole or colchicine for different time intervals and analyzed by light and electron microscopy. It was observed that trophozoites became completely misshapen, detached from the glass surface and failed to complete cell division. The main alterations observed included disc fragmentation, presence of large vacuoles, and appearance of electrondense deposits made of tubulin. The cytokinesis was blocked, but not the karyokinesis, and membrane blebs were observed. These findings show that Giardia behavior and cytoskeleton are clearly affected by the commonly used microtubule targetting agents colchicine and nozodazole.     

Distribution and content of microtubules in relation to the transport of lipid. An ultrastructural quantitative study of the absorptive cell of the small intestine

To determine whether microtubules are linked to intracellular transport in absorptive cells of the proximal intestine, quantitative ultrastructural studies were carried out in which microtubule distribution and content were determined in cells from fasting and fed animals. Rats were given a 1-h meal of standard chow, and tissue was taken from the mid-jejunum before, 1/2 h, and 6 h after the meal. The microtubule content of apical, Golgi, and basal regions of cells was quantitated by point-counting stereology. The results show) that microtubules are localized in intracellular regions of enterocytes (apical and Golgi areas) previously shown to be associated with lipid transport, and that the microtubule content within apical and Golgi regions is significantly (P less than 0.01) reduced during transport of foodstuffs. To determine the effect of inhibition of microtubule assembly on transport, colchicine or vinblastine sulfate was administered to postabsorptive rats, and the lipid and microtubule content of enterocytes determined 1 and 3 h later. After treatment with these agents, lipid was found to accumulate in apical regions of the cells; this event was associated with a significant reduction in microtubule content. In conclusion, the regional distribution of microtubules in enterocytes, the decrease in assembled microtubules after a fat-containing meal, and the accumulation of lipid after the administration of antimicrotubule agents suggest that microtubules are related to lipid transport in enterocytes.     

Reversible inhibition of microtubules and cell growth by the bicyclic colchicine analogue MTC

2-methoxy-5-(2,3,4-trimethoxyphenyl) 2,4,6-cycloheptatrien-1-one (MTC) is a synthetic colchicine analogue, lacking the B ring of the alkaloid (Fitzgerald: Biochem. Pharmacol. 25:1381-1387, 1976). MTC has been shown to bind reversibly to the colchicine binding site of tubulin and to inhibit microtubule assembly in vitro (Andreu et al: Biochemistry 23:1742-1752, 1984; Bane et al: J. Biol. Chem. 259:7391-7398, 1984). Its action on different cultured cell lines (PtK2, Pk15, and SV-3T3) has now been studied. 0.2 X 10(-6) M MTC stopped Pk15 and SV-3T3 cell growth, inducing an accumulation of mitoses in a few hours. Removal of MTC from the culture medium rapidly restored normal mitotic index and growth rates. Partial depolymerization of the cytoplasmic microtubules of PtK2 cells was observed at concentrations ranging from 2 to 5 X 10(-7) M. Maximal microtubule network depolymerization was obtained after 4 h of treatment with 2 to 5 X 10(-6) M MTC or at a higher MTC concentration (2 X 10(-5) M) for less than 2 h. Removal of 2 X 10(-5) M MTC (the highest MTC concentration used) from the culture medium resulted in almost complete microtubule polymerization after 10 min of drug recovery and a normal microtubule network in 20-30 min. MTC constitutes an antimitotic drug directed to the colchicine site. It is water-soluble, shows a fast and reversible action, and may therefore be employed as a convenient tool to study cellular microtubule-dependent functions.     

Ultrastructural effects of the herbicide chlorpropham (CIPC) in root tip cells of wheat

The present ultrastructural investigation on the effects of 50 M chlorpropham (previously called CIPC) on growing roots of wheat (Triticum aestivum (L.) Thell cv. Vergina) was undertaken to clarify the mechanism of a carbamate herbicide action in plant cells, since the wide range of responses of plant cells to carbamate herbicides is based mainly on immunofluorescence studies. Cells of control roots contained abundant microtubules both in interphase and mitotic arrays. In chlorpropham-treated roots, however, no microtubules could be detected at all, neither in dividing nor in differentiating cells. Cycling cells became binucleate, polyploid or contained incomplete cell walls, the result of inhibition of cytokinesis. In long-term drug treatments (24 h or more) the affected cells entered a new cycle, which, however, did not progress beyond mid-metaphase. The nuclei of binucleate cells initiated prophase synchronously. Small vacuoles and Golgi vesicles were trapped within the nucleoplasm of the multilobed nuclei. In roots recovering from 8 h chlorpropham treatment, cells continued to exhibit polyploid nuclei, intranuclear vacuoles and incomplete walls. Microtubules reappeared but they were sparse and lacked a definite orientation. Preprophase cells did not form normal preprophase bands of microtubules, while mitotic cells occasionally contained microtubules bound to chromosomes and converged to minipoles. It is concluded that chlorpropham disorganized directly microtubules in addition to irreversibly affecting microtubule organizing centres, which failed to further support microtubule arrays.