Inhibited Tubulin Assembly Research Articles

Interaction of captan with mammalian microtubules

Using turbidometry, electron microscopy and immunofluorescent microscopy experiments we studied the effect of captan, a widely used pesticide on mammalian microtubules and microfilaments. Turbidometry at 350 nm showed a dose-dependent inhibition of tubulin assembly incubated with captan. The pesticide, given at equimolar concentration with tubulin (30 microM), caused the total inhibition of microtubule formation, while at lower concentrations (5-20 microM) the inhibition of tubulin polymerization was less extensive. At the same concentration range (5-30 microM), captan also promoted the disassembly of performed microtubules. The results of the in vitro effects of captan with microtubules were confirmed in parallel by electron microscopic studies. In vivo, captan caused also depolymerization of microtubules in cultured mouse fibroblasts as shown by indirect immunofluorescent staining of tubulin. The extent of microtubules disassembly was concentration- and time-dependent. While incubation of the cells with 10 microM captan for 3 h disturbs totally the microtubular structures, incubation with 5 microM captan needs 12 h for the same effect. Recovery of microtubules was observed, when preincubated cells were extensively washed. No interaction of this drug with equimolar concentration of G- or F-actin could be observed in vitro, as shown by polymerization experiments. In line with this, the fluorescent actin pattern in mouse fibroblasts incubated with 10 mM captan for up to 12 h did not seem to be altered. From these results it is concluded that captan interacts in equimolar concentrations with tubulin affecting the assembly and disassembly of microtubules in vitro and in cultures of mammalian cells.

Effects of 10 known or suspected spindle poisons in the in vitro porcine brain tubulin assembly assay

We tested the 10 known or suspected spindle poisons (colchicine, econazole nitrate, chloral hydrate, hydroquinone, diazepam, thiabendazole, cadmium chloride, thimerosal, pyrimethamine and vinblastine) of the coordinated EEC programme for induction of aneuploidy with the in vitro porcine brain tubulin assembly assay. The influence of the compounds on different parameters [lag-phase, polymerization velocity, endabsorption (steady-state level), reversibility, influence on disassembly at 4 degrees C] was evaluated. Colchicine [IC30 (30% inhibition concentration): 0.002 mM), vinblastine (IC30: 0.002 mM), thimerosal (IC30: 0.03 mM), thiabendazole (IC30: 0.5 mM) and chloral hydrate (IC30: 60 mM) led to an inhibition of tubulin assembly in vitro. No influence on the steady-state level was obtained with econazole nitrate (up to 0.1 mM), diazepam (up to 2.5 mM), cadmium chloride (up to 1 mM), pyrimethamine (up to 1 mM) and hydroquinone (up to 25 mM), the highest dose tested being limited either by precipitation or by reaching the maximal solubility of the compound in the solvent used. Diazepam enhanced the lag-phase and slightly reduced the polymerization velocity dose-dependently; however, all the treated test mixtures reached the same end absorption levels as the control. The influence on the disassembly process was studied at 4 degrees C. Microtubules treated with colchicine, econazole nitrate, diazepam, thiabendazole, cadmium chloride, thimerosal and pyrimethamine reached the same end absorption level after disassembly as the untreated control. Chloral hydrate reduced the disassembly rate but the end absorption of the control was not reached, the 30% reduction concentration being 0.25 mM. Hydroquinone at very high doses (greater than 10 mM) stimulated the disassembly process.(ABSTRACT TRUNCATED AT 250 WORDS)

Rhizoxin resistant mutants with an altered beta-tubulin gene in Aspergillus nidulans.

Rhizoxin and ansamitocin P-3 (a maytansinoid compound), potent inhibitors of mammalian brain tubulin assembly, inhibit growth of a variety of fungi including Aspergillus nidulans. Mutants of A. nidulans, benA10 which is a benomyl resistant beta-tubulin gene mutant and tubA1 which is a benomyl supersensitive alpha-tubulin gene mutant, were both sensitive to rhizoxin and ansamitocin P-3 to the same extent as wild-type strains. We isolated 18 rhizoxin resistant mutants of A. nidulans. All of these mutants were cross-resistant to ansamitocin P-3, but not to benzimidazole antimitotic drugs. These mutants mapped to two loci, rhiA and rhiB, and all of those with high resistance mapped to rhiA. The fact that the protein extracts of rhiA mutants lost rhizoxin binding affinity and that rhiA was closely linked to benA, the major beta-tubulin gene in A. nidulans, indicated that rhiA must be a structural gene for beta-tubulin and that rhiA mutants are a new class of beta-tubulin gene mutants. All of this suggested that, in A. nidulans, these antimitotic drugs bind to beta-tubulin, and that rhizoxin and ansamitocin P-3 share the same binding site but the site does not overlap with the benzimidazole binding site. Protein extracts from a rhiB mutant retained rhizoxin binding affinity, therefore this rhizoxin resistance mechanism should not be a tubulin mediated process.

Interaction of the novel agent amphethinile with tubulin.

The novel agent amphethinile is shown to inhibit tubulin assembly in vitro. This agent is capable of displacing colchicine but not vinblastine from tubulin and causes a stimulation in GTPase activity in vitro. The affinity constant for the association of this drug with tubulin has been determined (Ka = 1.3 x 10(6) M-1). It is concluded that amphethinile belongs to the class of agents which share a common binding site with colchicine on the tubulin molecule.

The binding of Isocolchicine to Tubulin: Mechanisms of Ligand Association with Tubulin

Abstract Isocolchicine is a structurally related isomer of colchicine altered in the methoxytropone C ring. In spite of virtual structural homology of colchicine and isocolchicine, isocolchicine is commonly believed to be inactive in binding to tubulin and inhibiting microtubule assembly. We have found that isocolchicine does indeed bind to the colchicine site on tubulin, as demonstrated by its ability to competitively inhibit [3H]colchicine binding to tubulin with a KI approximately 400 microM. Isocolchicine inhibits tubulin assembly into microtubules with an I50 of about 1 mM, but the affinity of isocolchicine for the colchicine receptor site, 5.5 +/- 0.9 x 10(3) M-1 at 23 degrees C, is much less (approximately 500-fold) than that of colchicine. Unlike colchicine, isocolchicine binds rapidly, and the absorption and fluorescence properties of the complex are only modestly altered compared to free ligand. It is proposed that the binding of isocolchicine to tubulin may be rationalized either in terms of conformational states of colchicinoids when liganded to tubulin or by the structural requirements for C-10 substituents for high affinity binding to the colchicine receptor.

Reversible inhibition of mammalian tubulin assembly in vitro and effects in Saccharomyces cerevisiae D61.M by mitomycin C

Gaulden reported a novel and unexpected mitomycin C (MMC) effect, namely a pronounced retardation of very late prophase and loss of chromosome orientation in neuroblasts of the grasshopper Chortophaga viridifasciate. Because this effect may be due to interactions of MMC with non-DNA targets, MMC was tested for its interaction with porcine brain tubulin assembly in vitro and for the induction of chromosomal malsegregation in the diploid yeast Saccharomyces cerevisiae strain D61.M. A reversible dose-dependent inhibition of tubulin assembly was observed. Since no biological activation system was present in the incubation mixture this inhibition seems to result from an interaction of unactivated MMC with the assembly process. The possible chemical activation of MMC by reduction with 1,4-dithioerythritol (DTE) was investigated by omission of this compound during isolation and polymerization of tubulin. The absence of DTE resulted in a strong reduction of the net tubulin assembly. Also under these conditions MMC led to a dose-dependent inhibition of the assembly, indicating that the effect of MMC on tubulin assembly is independent of a reductive chemical modification. In S. cerevisiae D61.M, MMC did not induce chromosome loss, but induced other genetic events (possibly mutations, deletions or mitotic recombination) as was detected by an increase of the total number and of the frequency of cycloheximide-resistant colonies. This effect could be observed with and without the addition of rat liver S9 as an exogenous activation system.

Dynamics of a fluorescent calmodulin analog in the mammalian mitotic spindle at metaphase.

We have compared the exchange kinetics of fluorescein-labeled calmodulin and tubulin in the spindles of living mitotic cells at metaphase. Cultured mammalian cells in early stages of mitosis were microinjected with labeled calmodulin or tubulin and returned to an incubator to allow equilibration of the fluorescent protein with the endogenous protein pools. Calmodulin becomes concentrated in the mitotic spindle, and treatments with inhibitors of tubulin assembly show that this concentration is dependent on the presence of microtubules. The steady-state exchange rates of both tubulin and calmodulin were measured by an analysis of fluorescence redistribution after photobleaching (FRAP), using cells pre-equilibrated to either 26 +/- 2 degrees C or 36 +/- 2 degrees C. A pulse of laser light focused to a 5-microns diameter column was used to destroy the fluorescence at one pole of a metaphase mitotic spindle. Ratios of fluorescence intensity from the two half-spindles and from the two polar regions were calculated for each image in a post-bleach time series to determine the rates and extents of FRAP. For tubulin, we confirm earlier observations concerning the temperature dependence of the extent of FRAP, but our data do not show a significant temperature dependence for the rate of FRAP. We hypothesize that the reduced extent of tubulin FRAP at the lower temperatures is a result of microtubules that are stable to depolymerization at 26 degrees C and are thus less likely to exchange subunits. Calmodulin's FRAP, however, does not exhibit any of the temperature dependence observed with fluorescent tubulin. At 26 +/- 2 degrees C calmodulin exchanges rapidly with the relatively stable population of microtubules, suggesting that calmodulin is bound, either directly or indirectly, to microtubule walls.

Multi‐13 C‐labelled inhibitors of tubulin assembly: 5‐substituted methyl N‐(1H‐benzimidazol‐2‐YL)carbamates

AbstractEight methyl N‐(1H‐benzimidazol‐2‐yl) carbamates with various 5‐substituents were synthesized, each 13C‐enriched at carbon 2, and the carbonyl and methoxy carbons. Five were prepared by cyclization involving the appropriate 4‐substituted 1,2‐diaminobenzene (C6H5CO‐, CH3CH2CH2O‐, CH3CH2S‐, C6H5S‐ and CH3CH2CH2‐), and methyl‐13C N‐[imino(methylthio) methyl‐13C]carbamate‐13C or methyl N, N'‐bis(methoxy‐13C‐carbonyl‐13C)carbamimidothionate‐ 13C. The latter were prepared from commercially available 13C‐enriched (91‐92 atom %) carbon tetrachloride, methanol, and thiourea. The remaining three (5‐substituents: C6H5CH(OH)‐, C6H5SO‐ and CH3CH2CH2SO‐) were prepared by side‐chain reduction or oxidation. The 1H‐ and 13C‐NMR, and the methane CI mass spectral data of the products and intermediates are presented.

In vitro inhibition of tubulin assembly by a ribonucleoprotein complex associated with the free ribosome fraction isolated from Xenopus laevis oocytes: effect at the level of microtubule-associated proteins

The 100 000 × g supernatant prepared from defolliculated Xenopus laevis oocytes inhibits, in a dose-dependent manner, the in vitro polymerization of rat brain neurotubulin. The oocyte inhibitory factor is thermolabile, totally inactivated by RNAse and partially by trypsin. A preliminary purification of the inhibitor showed that it is associated with the free oocyte ribosomes (80 S). The saturable binding of microtubule-associated proteins, essentially MAP 2, to this 80 S ribonucleoprotein fraction is responsible for the inhibition of the in vitro tubulin assembly

Inhibition of tubulin assembly by antileprosy drug dapsone

The effect of dapsone on assembly-disassembly process of bovine brain tubulin was examined. The drug was found to readily bind tubulin dimer and that in its presence colchicine binding to tubulin was enhanced. Although dapsone associated with tubulin at a site other than the colchicine binding site, distinct inhibition of microtubule assembly was detected.

Inhibition of tubulin assembly by ethylacetylacrylate, a sulfhydryl reagent and potential analog of cytochalasin A

Ethyl acetylacrylate reacts rapidly with 2-mercaptoethanol and the sulfhydryl groups of tubulin. The structure of ethyl acetylacrylate resembles that of the reactive portion of cytochalasin A and potentially can serve as an analog of this antibiotic.

CAMP inhibits the in vitro assembly of microtubules

A new method for assaying microtubule assembly is described. The method utilizes the colchicine binding property of tubulin. This technique was used to study the effect of cyclic AMP on tubulin assembly using 100,000 g supernatant and cycle-purified tubulin prepared from porcine brain. Cyclic AMP, in the presence of NaF, inhibited tubulin assembly from 100,000 g supernatant but had no effect on cycle-purified tubulin.

Effect of antimitotic drugs on tubulin GTPase activity and self-assembly.

Microtubule inhibitors can be classified into two categories: 1) those which inhibit the polymerization-dependent GTPase activity of phosphocellulose-purified tubulin, but induce a significant polymerization-independent GTPase activity (e.g. colchicine, griseofulvine, daunorubicine); 2) those which inhibit the GTPase activity associated with tubulin polymerization and that induced by inhibitors of the first class (e.g. the vincaalkaloids and podophyllotoxin). The colchicine-stimulated GTPase activity of tubulin appears to be due to the tubulin.colchicine complex. This suggests that colchicine inhibits tubulin assembly by binding to a tubulin-tubulin interaction site required for the polymerization-dependent GTPase activity and induces by itself a tubulin conformational change that leads to polymerization-independent GTPase activity. Stoichiometry of inhibition by vinblastine of the colchicine-stimulated GTPase activity is 1:2. On the other hand, the inhibition by vinblastine of the tubulin self-assembly and of the polymerization-dependent GTPase activity is strongly substoichiometric at the beginning of the polymerization reaction, 1 vinblastine molecule inhibiting the ability of 10 tubulin dimers to polymerize and to hydrolyze the GTP. However, at the polymerization plateau, the inhibition effect by vinblastine appears to be lower, suggesting a selective action of vinblastine on the early stages of the polymerization reaction.

Inhibition of tubulin assembly by RNA and other polyanions: evidence for a required protein.

Nonneural cell extracts contain a heat-stable, nondialyzable activity that will inhibit the spontaneous assembly in vitro of partially purified brain tubulin. The sensitivity of this inhibitory activity to ribonucleases but not to a variety of other hydrolytic enzymes indicates that the inhibitor is an RNA. This conclusion is supported by the observation that purified RNAs from sea urchins, chinese hamster ovary cells, and brain all inhibit spontaneous microtubule assembly in vitro. The synthetic polynucleotides [poly(A), (C), (G), and (U)] are also inhibitory. This inhibition, however, appears to be nonspecific since the RNA base composition is unimportant and a variety of other nonnucleic acid polyanions also function as inhibitors. The treatment of assembly competent tubulin preparations with an insoluble RNA in the form of poly(A) covalently linked to agarose beads produces a "stripped" tubulin which will not assemble microtubules unless a heat-stable, trypsin-sensitive fraction eluted with increased ionic strength is mixed with the "stripped" tubulin. Similar results can be obtained with other cation exchangers, including phosphocellulose and carboxymethylcellulose. The heat-stable protein sequestered by poly(A)-agarose appears to be identical to the "tau" factor recently described by Kirschner and coworkers. Reconstitution experiments indicate that there is a stoichiometric requirement for these factors. These results suggest that spontaneous assembly of microtubules in nonneural cell extracts is blocked because the endogenous factors are complexed with RNA. This idea is supported by the observation that the ratio of tubulin to RNA is low in cultured cell extracts but very high in neural tissue extracts.

Microtubule assembly and function in Chlamydomonas: inhibition of growth and flagellar regeneration by antitubulins and other drugs and isolation of resistant mutants.

The distribution of microtubules in Chlamydomonas reinhardtii suggests that they are involved in mitosis, cell and nuclear cleavage, and generation of flagella. Vinblastine, colchicine, and podophyllotoxin bind to the protein building block of microtubules (tubulin) and prevent normal assembly. Mutants resistant to these "antitubulin" drugs are candidates to have alterations in tubulin primary structure. We report the ability to inhibit growth, and flagellar regeneration after amputation, of: vinblastine, several colchicine derivatives, two water-soluble derivatives of podophyllotoxin (succinylpodophyllotoxin and epipodophyllotoxin thiuronium bromide), and other substances which may interfere with flagellar assembly or motility (isopropyl N-phenyl carbamate, 2-methoxy-5-nitrotropone, chloral hydrate, caffeine, and nickel acetate). The ability of each drug to inhibit binding of labeled colchicine or podophyllotoxin to mammalian brain tubulin was also determined. The results suggest that only in the cases of colchicine, colcemide, and epipodophyllotoxin thiruonium bromide was the toxicity to Chlamydomonas mediated by inhibition of tubulin assembly. The requirement for high concentrations of colchicine may be due to permeability barriers, since colchicine toxicity was potentiated by deoxycholate. Mutants resistant to antitubulins were isolated after treatment with methyl methanesulfonate. The results with vinblastine were equivocal. Of three mutants resistant to inhibition of growth and flagellar regeneration by colchicine, one was also cross-resistant to epipodophyllotoxin thiuronium bromide.