Effects of griseofulvin on mitosis in PtK1 cells

The concentration dependent effects of griseofulvin (GF) on mitosis in PtK₁ cells were studied using a combination of time lapse cinematography and polarization and electron microscopy. Low concentrations of GF (4×10^–5 M) allowed a substantial number of cells to enter and complete an apparently normal mitosis. At higher concentrations of GF (1×10^–4 M and 2.5×10^–4 M) all cells entering mitosis were arrested. Typical c-mitotic chromosome arrays were observed at 1×10^–4 M GF with microtubules present but no spindle formed. At 2.5×10^–4 M GF chromosomes did not orient toward a common center to form a c-mitotic figure, but instead remained in a loosely clustered grouping at the center of the cell. Electron microscopy showed microtubules to be absent but revealed an irregularly shaped electron dense cloud around the centrioles. Quantitative polarization microscopy of metaphase cells perfused with GF showed rapid loss of spindle birefringence after exposure to the drug. Coinciding with loss of birefringence the spindle shrank rapidly with a pronounced shortening of pole to pole distance.     

NITROUS OXIDE: EFFECTS ON THE MITOTIC APPARATUS AND CHROMOSOME MOVEMENT IN HELA CELLS

When HeLa cells were grown in the presence of nitrous oxide (N₂O) under pressure (80 lb/in²) mitosis was inhibited and the chromosomes displayed a typical colchicine metaphase (c-metaphase) configuration when examined by light microscopy. When the cells were returned to a 37°C incubator, mitosis was resumed and the cells entered G₁ synchronously. Ultrastructural studies of N₂O-blocked cells revealed a bipolar spindle with centriole pairs at each pole. Both chromosomal and interpolar (pole-to-pole) microtubules were also present. Thus, N₂O, unlike most c-mitotic agents, appeared to have little or no effect upon spindle microtubule assembly. However, the failure of chromo somes to become properly aligned onto the metaphase plate indicated an impairment in normal prometaphase movement. The alignment of spindle microtubules was frequently atypical with some chromosomal microtubules extending from kinetochores to the poles, while others extended out at acute angles from the spindle axis. These ultrastructural studies indicated that N₂O blocked cells at a stage in mitosis more advanced than that produced by Colcemid or other c-mitotic agents. Like Colcemid, however, prolonged arrest in mitosis with N₂O led to an increased incidence of multipolar spindles.     

Griseofulvin: Association with tubulin and inhibition of in vitro microtubule assembly

Griseofulvin—shown previously to disrupt the mitotic apparatus $\text{in vivo}$—inhibited the $\text{in vitro}$ microtubule assembly reaction completely at 8 × 10^?4M griseofulvin. In a gel filtration assay, randomly tritiated griseofulvin associated stoichiometrically with purified tubulin, as determined by chromatography on Sephadex G-25. No detectable drug binding was observed when bovine serum albumin was used as a control in an identical column assay. Both gel filtration chromatography and a kinetic analysis of the inhibition of assembly by griseofulvin suggest that the drug interacts directly and stoichimetrically with the tubulin dimer, and that the interaction is both rapid and independent of temperature.     

Kinesin-8 from Fission Yeast: A Heterodimeric, Plus-End–directed Motor that Can Couple Microtubule Depolymerization to Cargo Movement

Fission yeast expresses two kinesin-8s, previously identified and characterized as products of the klp5⁺ and klp6⁺ genes. These polypeptides colocalize throughout the vegetative cell cycle as they bind cytoplasmic microtubules during interphase, spindle microtubules, and/or kinetochores during early mitosis, and the interpolar spindle as it elongates in anaphase B. Here, we describe in vitro properties of these motor proteins and some truncated versions expressed in either bacteria or Sf9 cells. The motor-plus-neck domain of Klp6p formed soluble dimers that cross-linked microtubules and showed both microtubule-activated ATPase and plus-end–directed motor activities. Full-length Klp5p and Klp6p, coexpressed in Sf9 cells, formed soluble heterodimers with the same activities. The latter recombinant protein could also couple microbeads to the ends of shortening microtubules and use energy from tubulin depolymerization to pull a load in the minus end direction. These results, together with the spindle localizations of these proteins in vivo and their requirement for cell viability in the absence of the Dam1/DASH kinetochore complex, support the hypothesis that fission yeast kinesin-8 contributes both to chromosome congression to the metaphase plate and to the coupling of spindle microtubules to kinetochores during anaphase A.     

Growth Arrest by the Antitumor Steroidal Lactone Withaferin A in Human Breast Cancer Cells Is Associated with Down-regulation and Covalent Binding at Cysteine 303 of β-Tubulin

Withaferin A (WA), a C₅,C₆-epoxy steroidal lactone derived from a medicinal plant (Withania somnifera), inhibits growth of human breast cancer cells in vitro and in vivo and prevents mammary cancer development in a transgenic mouse model. However, the mechanisms underlying the anticancer effect of WA are not fully understood. Herein, we report that tubulin is a novel target of WA-mediated growth arrest in human breast cancer cells. The G₂ and mitotic arrest resulting from WA exposure in MCF-7, SUM159, and SK-BR-3 cells was associated with a marked decrease in protein levels of β-tubulin. These effects were not observed with the naturally occurring C₆,C₇-epoxy analogs of WA (withanone and withanolide A). A non-tumorigenic normal mammary epithelial cell line (MCF-10A) was markedly more resistant to mitotic arrest by WA compared with breast cancer cells. Vehicle-treated control cells exhibited a normal bipolar spindle with chromosomes aligned along the metaphase plate. In contrast, WA treatment led to a severe disruption of normal spindle morphology. NMR analyses revealed that the A-ring enone in WA, but not in withanone or withanolide A, was highly reactive with cysteamine and rapidly succumbed to irreversible nucleophilic addition. Mass spectrometry demonstrated direct covalent binding of WA to Cys³⁰³ of β-tubulin in MCF-7 cells. Molecular docking indicated that the WA-binding pocket is located on the surface of β-tubulin and characterized by a hydrophobic floor, a hydrophobic wall, and a charge-balanced hydrophilic entrance. These results provide novel insights into the mechanism of growth arrest by WA in breast cancer cells.     

Effects of Propyzamide on Tobacco Cell Microtubules In Vivo and In Vitro

Treatment with propyzamide at 2 ? 10^-6 M or at higher concentrationsarrested the cell cycleat metaphase in tobacco BY-2 cells. Metaphasecells having disorganized spindle microtubulesand scatteredchromosomes began to appear within several minutes of the additionof propyzamide. Within 30 min, disrupted spindle microtubulesand dispersed chromosomes were seenin all metaphase cells. Propyzamideat 2 ? 10^-6 M or at higher concentrations also disrupted corticalmicrotubules, but disruption of cortical microtubules requiredmore time than disruption of spindle microtubules. The effectof propyzamide on microtubules was found to be readily reversible.The cells arrested at metaphase by 2 ? 10^-6 M propyzamide resumedmitosis within 2 h from the termination of treatment with propyzamide.Spindle microtubules reappeared within 15 min from the terminationof treatment with propyzamide, and the cortical microtubuleswithin 1 h. Tubulin was isolated from tobacco BY-2 cells bycolumn chromatography on ethyl Nphenylcarbamate-Sepharose 4B.On incubation with EGTA, Mg²⁺ and DMSO, the purified tobaccotubulin polymerized into microtubules. Propyzamide at 1 ? 10^-4M completely inhibitedthe polymerization of tobacco tubulin,but did not inhibit polymerization of bovine braintubulin. Tobaccotubulin was adsorbed onto a column of propyzamide-analogue-linkedSepharose 4B and then purified by chromatography on this column. (Received February 15, 1988; Accepted June 29, 1988)     

The sequence of a region of bacteriophage phiX174 DNA coding for parts of genes A and B

The kinetics of microtubule assembly were investigated by monitoring changes in turbidity which result from the scattering of incident light by the polymer. These studies indicated that assembly occurred by a pathway involving a nucleation phase, followed by an elongation phase as evidenced by a lag in the polymerization kinetics, followed by a psuedo-first-order exponential increase in turbidity. Analytical ultracentrifugation of solutions polymerized to equilibrium showed that 6 S tubulin was the only species detectable in equilibrium with microtubules. Investigation of the elongation reaction in mixtures of 6 S tubulin and microtubule fragments demonstrated that: (1) the net rate of assembly was the sum of the rates of polymerization and depolymerization; (2) the rate of polymerization was proportional to the product of the microtubule number concentration and the 6 S tubulin concentration; and (3) the rate of depolymerization was proportional to the number concentration of microtubules. These results demonstrate that microtubule assembly occurs by a condensation polymerization mechanism consisting of distinct nucleation and elongation steps. Microtubules are initiated in a series of protein association reactions in a pathway that has not been fully elucidated. Elongation proceeds by the consecutive association of 6 S tubulin subunits onto the ends of existing microtubules. Similarly, depolymerization occurs by dissociation of 6 S subunits from the ends of microtubules. The rate constants measured for polymerization and depolymerization at 30 °C were 4 × 10⁶m^?1 s^?1 and 7 s^?1, respectively.     

Tubulin subunit sorting: Analysis of the mechanisms involved in the segregation of unique tubulin isotypes within microtubule copolymers

Summary Vertebrate cells contain biochemical and genetic isotypes of tubulin which are expressed in unique combinations in different tissues and cell types. To determine if mixtures of tubulin isotypes assemblein vitro to form different classes of microtubules, we analyzed the composition of microtubule copolymers assembled from mixtures of chicken brain and erythrocyte tubulin. During microtubule elongation brain tubulin assembled onto the ends of microtubules faster than erythrocyte tubulin, resulting in copolymers with continually changing ratios of isotypes along their lengths. Unlike examples of microtubule assembly where the rate of polymerization depends on the association rate constant (k⁺) and the subunit concentration, the rate and extent of sorting in copolymers appear to depend on the dissociation rate constant (k^–), which governs the rate at which subunits are released from tubulin oligomers and microtubules and thereby made available for reassembly into copolymers. The type of microtubule seed used to initiate elongation was also found to influence the composition of copolymers, indicating that polymerization favors association of subunits of the same isotype.     

Mechanism of action of the antimitotic drug 2,4-dichlorobenzyl thiocyanate: alkylation of sulfhydryl group(s) of ß-tubulin

The compound 2,4-dichlorobenzyl thiocyanate (DCBT) was previously shown to cause mitotic arrest, disruption of intracellular microtubules, and inhibition of tubulin polymerization, with resistance to the drug conferred by a mutation in a ß-tubulin gene (Abraham, I., Dion, R.L., Duanmu, C., Gottesman, M.M. and Hamel, E. (1986) Proc. Natl. Acad. Sci. USA 83, 6839–6843). We have now examined its mechanism of action in further detail and conclude that DCBT acts as a sulfhydryl alkylating reagent. A mixed disulfide forms between the 2,4-dichlorobenzyl mercaptan moiety of DCBT and protein sulfhydryl groups with release of cyanate anion to the medium. Gel filtration and dialysis of complexes of tubulin formed with either [nitrile-¹⁴C]DCBT, [³⁵S]DCBT or [benzyl-³H]DCBT demonstrated persistent association of³⁵S and³H with denatured tubulin, but no binding of¹⁴C to the protein even under native conditions. With equimolar tubulin and DCBT, ß-tubulin is the predominant alkylated species. At high drug concentrations, superstoichiometric amounts of DCBT react with tubulin, and both subunits are alkylated almost equally. When extracts of drug-treated L1210 murine leukemia cells were examined by polyacrylamide gel electroporesis, we found that multiple proteins were alkylated by DCBT, but the most prominent radiolabeled band was that corresponding to ß-tubulin. Dithiothreitol partially reverses inhibition of tubulin polymerization by DCBT and removes almost all the 2,4-dichlorobenzyl mercaptan moiety covalently bound to tubulin. Mitotic arrest occurs with DCBT because tubulin is the cellular protein most sensitive to the agent, probably because of its high cysteine content (20/mol).     

High-Affinity Accumulation of a Maytansinoid in Cells via Weak Tubulin Interaction

The microtubule-targeting maytansinoids accumulate in cells and induce mitotic arrest at 250- to 1000-fold lower concentrations than those required for their association with tubulin or microtubules. To identify the mechanisms of this intracellular accumulation and exceptional cytotoxicity of maytansinoids we studied interaction of a highly cytotoxic maytansinoid, S-methyl DM1 and several other maytansinoids with cells. S-methyl DM1 accumulated inside the cells with a markedly higher apparent affinity than to tubulin or microtubules. The apparent affinities of maytansinoids correlated with their cytotoxicities. The number of intracellular binding sites for S-methyl DM1 in MCF7 cells was comparable to the number of tubulin molecules per cell (~ 4–6 × 10⁷ copies). Efflux of ³ [H]-S-methyl DM1 from cells was enhanced in the presence of an excess of non-labeled S-methyl DM1, indicating that re-binding of ³ [H]-S-methyl DM1 to intracellular binding sites contributed to its intracellular retention. Liposomes loaded with non-polymerized tubulin recapitulated the apparent high-affinity association of S-methyl DM1 to cells. We propose a model for the intracellular accumulation of maytansinoids in which molecules of the compounds diffuse into a cell and associate with tubulin. Affinities of maytansinoids for individual tubulin molecules are weak, but the high intracellular concentration of tubulin favors, after dissociation of a compound-tubulin complex, their re-binding to a tubulin molecule, or to a tip of a microtubule in the same cell, over their efflux. As a result, a significant fraction of microtubule tips is occupied with a maytansinoid when added to cells at sub-nanomolar concentrations, inducing mitotic arrest and cell death.     

Rapid rate of tubulin dissociation from microtubules in the mitotic spindle in vivo measured by blocking polymerization with colchicine

At metaphase, the amount of tubulin assembled into spindle microtubules is relatively constant; the rate of tubulin association equals the rate of dissociation. To measure the intrinsic rate of dissociation, we microinjected high concentrations of colchicine, or its derivative colcemid, into sea urchin embryos at metaphase to bind the free tubulin, thereby rapidly blocking polymerization. The rate of microtubule disassembly was measured from a calibrated video signal by the change in birefringent retardation (BR). After an initial delay after injection of colchicine or colcemid at final intracellular concentrations of 0.1-3.0 mM, BR decreased rapidly and simultaneously throughout the central spindle and aster. Measured BR in the central half-spindle decreased exponentially to 10% of its initial value within a characteristic period of approximately 20 s; the rate constant, k = 0.11 +/- 0.023 s-1, and the corresponding half-time, t 1/2, of BR decay was approximately 6.5 +/- 1.1 s in this concentration range. Below 0.1 mM colchicine or colcemid, the rate at which BR decreased was concentration dependent. Electron micrographs showed that the rapid decrease in BR corresponded to the disappearance of nonkinetochore microtubules; kinetochore fiber microtubules were differentially stable. As a control, lumicolchicine, which does not bind to tubulin with high affinity, was shown to have no effect on spindle BR at intracellular concentrations of 0.5 mM. If colchicine and colcemid block only polymerization, then the initial rate of tubulin dissociation from nonkinetochore spindle microtubules is in the range of 180-992 dimers per second. This range of rates is based on k = 11% of the initial polymer per second and an estimate from electron micrographs that the average length of a half-spindle microtubule is 1- 5.5 micron. Much slower rates of tubulin association are predicted from the characteristics of end-dependent microtubule assembly measured previously in vitro when the association rate constant is corrected for the lower rate of tubulin diffusion in the embryo cytoplasm. Various possibilities for this discrepancy are discussed.     

Chromosomes selectively detach at one pole and quickly move towards the opposite pole when kinetochore microtubules are depolymerized in <Emphasis Type="Italic">Mesostoma ehrenbergii</Emphasis> spermatocytes

In a typical cell division, chromosomes align at the metaphase plate before anaphase commences. This is not the case in Mesostoma spermatocytes. Throughout prometaphase, the three bivalents persistently oscillate towards and away from either pole, at average speeds of 5–6 μm/min, without ever aligning at a metaphase plate. In our experiments, nocodazole (NOC) was added to prometaphase spermatocytes to depolymerize the microtubules. Traditional theories state that microtubules are the producers of force in the spindle, either by tubulin depolymerizing at the kinetochore (PacMan) or at the pole (Flux). Accordingly, if microtubules are quickly depolymerized, the chromosomes should arrest at the metaphase plate and not move. However, in 57/59 cells, at least one chromosome moved to a pole after NOC treatment, and in 52 of these cells, all three bivalents moved to the same pole. Thus, the movements are not random to one pole or other. After treatment with NOC, chromosome movement followed a consistent pattern. Bivalents stretched out towards both poles, paused, detached at one pole, and then the detached kinetochores quickly moved towards the other pole, reaching initial speeds up to more than 200 μm/min, much greater than anything previously recorded in this cell. As the NOC concentration increased, the average speeds increased and the microtubules disappeared faster. As the kinetochores approached the pole, they slowed down and eventually stopped. Similar results were obtained with colcemid treatment. Confocal immunofluorescence microscopy confirms that microtubules are not associated with moving chromosomes. Thus, these rapid chromosome movements may be due to non-microtubule spindle components such as actin-myosin or the spindle matrix.     

Tubulin dynamics during the cytoplasmic cohesiveness cycle in artificially activated sea urchin eggs

Sedimentation studies and [³H]colchicine-binding assays have demonstrated a relationship between the cytoplasmic cohesiveness cycles and the changes in tubulin organization in Paracentrotus lividus eggs activated by 2.5 mM procaine. The same amount of tubulin (20–25 % of the total egg tubulin) is involved in these cyclic process and appears to undergo polymerization and depolymerization cycles. Electron microscopy studies reveal that the microtubules formed during these cytoplasmic cohesiveness cycles are under a particulate form which is sedimentable at low speed. Activation experiments carried out in the presence of cytochalasin B (CB) show that the increase in the cytoplasmic cohesiveness is highly reduced while tubulin polymerization and depolymerization cycles and pronuclear centration are not affected. Although tubulin or actin polymerization can be independently triggered in procaine-activated eggs, the increase in cytoplasmic cohesiveness requires the polymerization of both proteins. However, the cytoplasmic cohesiveness cycles appear to be regulated by tubulin polymerization and depolymerization cycles.     

Head-to-tail polymerization of microtubules in vitro

The kinetics of microtubule polymerization to steady-state and the ability of tubulin subunits to exchange with polymer at steady-state were examined to determine the applicability of the head-to-tail polymerization mechanism (Wegner, 1976) to microtubule assembly in vitro. Under conditions where self-nucleation was a rare event, tubulin was induced to polymerize by the addition of short microtubule fragments, and the kinetics of elongation were analyzed as a pseudofirst-order reaction. At steady-state, a trace amount of [³H]tubulin, prepared by labeling in vivo of chick brain protein, was added to polymerized microtubules and the kinetics of label uptake into polymer were monitored by a rapid centrifugal assay. The isotope exchange kinetics were analyzed according to a theoretical model previously applied to actin polymerization (Wegner, 1976) and extended for the case of microtubule polymerization. The rate of head-to-tail polymerization, expressed as the steady-state subunit flux, was 27·6 ± 7·6 per second at 37 °C. The head-to-tail parameter s, a measure of the efficiency of subunit flux, was 0·26 ± 0·07, indicating that four association and four dissociation events resulted in the flux of one subunit through the polymer at steady-state.The role of GTP in this mechanism of microtubule polymerization was examined by replacement of the nucleotide occupying the exchangeable binding site of tubulin with the non-hydrolyzable GTP analog guanosine 5′-(β,γ-methylene)triphosphate. It was found that the rate of steady-state flux was reduced by two orders of magnitude compared to tubulin polymerized with GTP. The head-to-tail parameter approached its limiting value of zero, indicating greatly reduced efficiency of subunit flux through the polymer in the presence of this analog.In summary, this study demonstrates that microtubules exhibit significant headto-tail polymerization in the presence of GTP and, in keeping with theoretical considerations, provides evidence that nucleotide hydrolysis is required for subunit flux through the polymer.     

Radioiodination of brain tubulin with Bolton-Hunter reagent

Radio-iodination of tubulin can be achieved by Bolton-Hunter reagent both in the absence and presence of microtubule associated proteins. Specific radioactivities as high as 400 C_i/mmole tubulin dimer can be obtained, i.e. an average of 0.2 molecule of reagent is bound per molecule of tubulin. About 80 % of the [¹²⁵I]- labelled tubulin keeps its ability to assemble in microtubules and polymerizes with the same critical concentration as the native tubulin, which makes the method adequate for preparing tracer tubulin useful for in vivo and in vitro studies. Both α and β subunits are labelled, 60 % of the radiolabel being bound to the β subunit.     

Basal body duplication in Paramecium requires γ-tubulin

First discovered in the fungus Aspergillus nidulans[1], γ-tubulin is a ubiquitous component of microtubule organizing centres [2]. In centrosomes, γ-tubulin has been immunolocalized at the pericentriolar material, suggesting a role in cytoplasmic microtubule nucleation [3], as well as within the centriole core itself [4]. Although its function in the nucleation of the mitotic spindle and of cytoplasmic interphasic microtubules has been demonstrated in vitro[5], [6] and in vivo[7], [8], [9], the hypothesis that γ-tubulin could intervene in centriole assembly has never been experimentally addressed because the mitotic arrest caused by the inactivation of γ-tubulin in vivo precludes any further phenotypic analysis of putative centriole defects. The issue can be addressed in the ciliate Paramecium, which is characterized by numerous basal bodies that are similar to centrioles but the biogenesis of which is not tightly coupled to the nuclear division cycle. We demonstrate that the inactivation of the Paramecium γ-tubulin genes leads to inhibition of basal body duplication.     

Fine structure of the Golgi complex during mitosis of cartilaginous cells in vitro

Chondrocytes were isolated enzymatically from guinea-pig epiphyses and grown in vitro. The fate of the Golgi complex during mitosis in relation to changes in the cytoplasmic microtubules was then studied by transmission electron microscopy. Interphase cells were observed to be polarized, with the Golgi complex occupying a well-defined juxtanuclear area of the cell's cytoplasmic pole. During prophase the cytoplasmic microtubules were largely lost, the nucleus moved to the center of the cell and the Golgi complex dissolved into single dictyosomes spread diffusely throughout the cytoplasm. The distribution of other organelles also changed to a more random pattern. In telophase, i.e. after the completion of nuclear division, the mitotic spindle decomposed and cytoplasmic microtubules reappeared. Furthermore, the organization of the Golgi complex and other organelles returned to that characteristic of interphase cells. Previous studies on cells treated with colchicine have indicated that the polarized distribution of cell organelles is dependent on the presence of intact cytoplasmic micro-tubules. It is suggested that the disappearance of such tubules observed here to be coupled with the disorganization of cell interphase structure fulfills the double function of providing free tubulin units from which to build the mitotic spindle and ensuring an approximately equal distribution of dictyosomes and other organelles to the daughter cells during cytokinesis.     

In vitro assembly of microtubule proteins from myxamoebae of Physarum polycephalum

Microtubule protein of >95% purity has been isolated by self-assembly from concentrated cell extracts of myxamoebae of Physarum polycephalum. Ninety-eight percent of the amoebal microtubule protein was tubulin. Both a and β subunits of amoebal tubulin were different from neurotubulin α and β subunits, but very similar to those of Tetrahymena ciliary tubulin. The non-tubulin components, which co-purified with tubulin through three assembly cycles, were essential to microtubule formation and contained several polypeptides including some of apparent molecular weights 49000, 57000 and 59000. Purified amoebal microtubule protein formed microtubules on warming in the absence of glycerol which were cold- and Ca²⁺-labile. In vitro, microtubule assembly was inhibited by vinblastine, benzimidazole derivatives and griseofulvin, but not by 10^?4 M colchicine. Amoebal tubulin had a much lower affinity than neurotubulin for colchicine.     

Polymerization of tubulin in the presence of colchicine or podophyllotoxin. Formation of a ribbon structure induced by guanylyl-5'-methylene diphosphonate

GTP-dependent in vitro polymerization of rat brain microtubular protein is inhibited to 50% by substoichiometric concentrations of the antimitotic drugs colchicine (0.12 mol/mol of tubulin) and podophyllotoxin (0.14 mol/mol of tubulin). Substitution of pp(CH₂)pG² for GTP, however, results in an extensive microtubular protein polymerization at such concentrations. In the presence of pp(CH₂)pG, suprastoichiometric concentrations of podophyllotoxin (19 mol/mol of tubulin) are required to inhibit the polymerization process by 50%. Colchicine is very ineffective since 3 × 10⁵ moles/mole of tubulin are required to give a 50% inhibition. Electron microscopical analysis shows that the polymers formed by microtubular protein in the presence of suprastoichiometric concentrations of drugs are not the normal short microtubules typical of pp(CH₂)pG-driven polymerization, but are ribbons with three or four protofilaments. The colchicine content of the harvested ribbons has been measured directly and found to be approximately 0.8 moles colchicine/mole of tubulin. Treatment of microtubular protein with substoichiometric concentrations of drugs results in an increase in the number of protofilaments forming the ribbons. Many of the ribbons can close into morphologically normal microtubules when microtubular protein is treated with only 0.05 moles of either colchicine or podophyllotoxin per mole of tubulin.     

HURP wraps microtubule ends with an additional tubulin sheet that has a novel conformation of tubulin

HURP is a newly discovered microtubule-associated protein (MAP) required for correct spindle formation both in vitro and in vivo. HURP protein is highly charged with few predicted secondary and tertiary folding domains. Here we explore the effect of HURP on pure tubulin, and describe its ability to induce a new conformation of tubulin sheets that wrap around the ends of intact microtubules, thereby forming two concentric tubes. The inner tube is a normal microtubule, while the outer one is a sheet composed of tubulin protofilaments that wind around the inner tube with a 42.5° inclination. We used cryo-electron microscopy and unidirectional surface shadowing to elucidate the structure and conformation of HURP-induced tubulin sheets and their interaction with the inner microtubule. These studies clarified that HURP-induced sheets are composed of anti-parallel protofilaments exhibiting P2 symmetry. HURP is a unique MAP that not only stabilizes and bundles microtubules, but also polymerizes free tubulin into a new configuration.