Temperature dependent binding of mebendazole to tubulin in benzimidazole-susceptible and -resistant strains of Trichostrongylus colubriformis and Caenorhabditis elegans

The binding of [³H]mebendazole ([³H]MBZ) to tubulin in benzimidazole-susceptible (BZ-S) and benzimidazole-resistant (BZ-R) strains of Trichostrongylus colubriformis and Caenorhabditis elegans was examined in order to investigate the biochemical changes to tubulin that result in BZ resistance in parasitic and free-living nematodes. In both species the extent of [³H]MBZ binding to tubulin was significantly reduced in the BZ-R strain compared with the BZ-S strain. The decrease in [³H]MBZ binding in the BZ-R strain of each species was the result of a significant reduction in the amount of charcoal stable [³H]MBZ-tubulin complexes and was not related to a change in the association constant of the [³H]MBZ-tubulin interaction. [³H]MBZ binding to tubulin was temperature dependent, reaching maximum levels at 37°C in BZ-S T. colubriformis and 10°C in BZ-R T. colubriformis. Both the BZ-S and BZ-R strains of C. elegans displayed maximum [³H]MBZ binding at 4°C. Resistance ratios derived from the amount of [³H]MBZ binding in the BZ-S and BZ-R strains and in vitro development assays demonstrated that the temperature dependence and extent of drug binding was indicative of BZ resistance status and was species specific in the BZ-S isolates. These results indicate that biochemical differences exist in the binding of benzimidazole carbamates to tubulin in nematode species, and suggest that the susceptibility of the parasitic nematodes to the benzimidazole anthelmintics is the result of a unique high affinity and/or high capacity interaction ofbenzimidazole carbamates with tubulin.     

Specific affinity labelling of tubulin with bromocolchicine

Bromocolchicine, synthesized by substituting tho N-acetyl moiety of colchicine with a reactive bromoacetyl group, was found to be an affinity label for tubulin. Binding of [³H]colchicine to tubulin was competitively and irreversibly inhibited by bromocolchicine with a K_i value of 2.3 × 10^?5m. The affinity label could not be displaced by precipitating the protein with trichloroacetic acid and is thus covalently bound. Autoradiographs of brain high-speed supernatant proteins after their electrophoretic separation on sodium dodecyl sulphate/polyacrylamide gels showed that [³H]bromocolchicine reacted with four proteins, of which tubulin was one.Labelling of two of these proteins could be prevented by pretreatment of the brain extracts with α-bromoacetic acid, after which 70% of the covalently bound label was specifically located in the tubulin band. Up to 1.6 mol of affinity label could be bound per mol of tubulin, while under our experimental conditions 1 mol of protein bound irreversibly only 0.2 mol of [³H]colchicine. Autoradiography of sodium dodecyl sulphate/urea-polyacrylamide gels, which separate the subunits of tubulin, showed about 30% [³H] bromocolchicine bound to the α-subunit of tubulin and 70% to tho β-subunit.The irreversible binding site of colchicine was localized to the α-subunit, as labelling of only this subunit was inhibited by colchicine at high affinity label concentrations. At lower concentrations, colchicine inhibited the labelling of both subunits.Bromoacetic acid did not inhibit the reaction of the affinity label with the tubulin subunits, but increased the inhibition of [³H]bromocolchicine binding at lower concentrations of the affinity label in brain extracts preincubated with cold colchicine. This is interpreted to show a conformational change which takes place in the two subunits of tubulin upon binding of colchicine and results in the exposure of some of the binding sites of [³H]bromocolchicine to bromoacetic acid.     

HE TURNOVER RATE OF TUBULIN IN RAT BRAIN

The turnover rate of tubulin in rat brain was determined from the decay in specific radioactivity of the protein after pulse-labeling. When precursors were administered by a parenteral route, the shortest half-life, 9.8 days, was obtained with [¹⁴C]NaHCO₃; the longer half-lives obtained with [U-¹⁴C]glucose or [4,5-³H]leucine suggest significant reutilization of label. Furthermore, with leucine as precursor maximal specific radioactivity of tubulin was not obtained until eight days after administration of label. Labeling and decay kinetics obtained with [4,5-³H]leucine were markedly different when the isotope was administered directly into the lateral ventricle. The difference between the turnover rates of the -α and β subunits of tubulin purified by means of high resolution polyacrylamide gel electrophoresis was not statistically significant. A half-life for tubulin of 6.2 days was measured by continuous intravenous infusion of [U-¹⁴C]tyrosine.     

Binding of [3H]cytochalasin B and [3H]colchicine to isolated liver plasma membranes

The binding to isolated hepatocyte plasma membranes of radioactively labelled inhibitors of microfilamentous and microtubular protein function ([³H]cytochalasin B and [³H]colchicine, respectively) was studied as one means of assessing the degree of association of these proteins with cell surface membranes. [³H]Cytochalasin B which behaved identically to the unlabelled compound with respect to binding to these membranes was prepared by reduction of cytochalasin A with NaB³H₄. The binding was rapid, readily reversible, proportional to the amount of membrane and relatively insentive to changes of pH or ionic strength. At 10^?6 M [³H]cytochalasin B, glucose or p-chloromercuribenzoate, an inhibitor of glucose transport inhibited binding by about 20%; treatment of membranes with 0.6 M KI which depolymerizes F actin to G actin caused about 60% inhibition of binding. These two types of inhibition were additive indicating two separate classes of binding sites, one associated with sugar transport and one with microfilaments. Filamentous structures with the diameter of microfilaments (50 Å) were seen in electron micrographs of thin sections of the membranes. At concentrations greater than 10^?5 M [³H]cytochalasin B, binding was proportional to drug concentration, characteristic of non-specific adsorption or partitioning. Intracellular membranes of the hepatocyte also bound [³H]cytochalasin B, those of the smooth endoplasmic reticulum to a greater extent than plasma membranes.[³H]Colchicine bound to plasma membranes in proportion to the amount of membrane and at a rate compatible with binding to tubulin. However, other properties of the binding including effects of temperature, drug concentration and antisera against tubulin were different from those of binding to tubulin. Hence, no evidence was obtained for association of microtubular elements with these membranes. Despite this there appeared to be an interdependence between microtubule and microfilament inhibitors: vinblastine sulfate stimulated [³H]cytochalasin B binding and cytochalasin B stimulated ³H colchicine binding. [³H]Colchicine also bound to intracellular membranes, especially smooth microsomes.     

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).     

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.     

The phosphorylation of brain microtubular proteins in situ and in vitro

The phosphorylation of microtubular proteins isolated by reassembly in vitro from slices of guinea-pig cerebral cortex labelled with [32P]orthophosphate was investigated. Under the conditions tested, both and the alpha and beta forms of tubulin contained metabolically-active P which accounted for about one third of the total 32P incorporated into protein; the remaining protein-bound 32P was associated with 3-4 minor high MW components co-purifying with tubulin during two cycles of assembly-disassembly. Microtubular protein prepared in this way contained approx. 0.8 mol of alkalilabile P/mol of tubulin dimer (M.W. 110,000). In vitro studies showed that reassembled microtubular protein preparations catalysed the incorporation of up to 0.55 mol of P/mol of tubulin dimer during incubation with Mg2+ and [gamma 32P]ATP. The reaction was linear during the first 30 min of incubation at 37 degrees C. Cyclic AMP (10 microM, final concentration) caused a transient increase in the initial rates of tubulin phosphorylation. Little label was incorporated into the minor high M.W. components under these conditions. The in vitro phosphorylation of microtubular protein increased in a non-linear manner with respect to protein concentration: this was in contrast to earlier experiments showing linear kinetics when chromatographically isolated tubulin was tested for intrinsic kinase activity. Isolated microtubular protein preparations bound [3H]GTP, [3H]ATP and to a lesser extent, [3H]cyclic AMP, and exhibited Ca(2+)-ATPase activity (up to 60 pmol Pi released min/mg protein at 37 degrees C).     

Direct photoaffinity labeling of tubulin with guanosine 5'-triphosphate

Irradiation of tubulin in the presence of [3H]GTP or [3H]GDP at 254 nm led to the covalent incorporation of nucleotide into the protein. The specific nature of the labeling was shown in the following manner: with tubulin depleted of exchangeable nucleotide, the amount of labeling increased to a plateau value as the [3H]GTP concentration was increased, with saturation being reached at a ratio of approximately 1.5; the same amount of labeling was obtained with GTP/tubulin ratios of 1 and 100; [3H]GMP was not incorporated into the dimer, nor did GMP inhibit the incorporation of [3H]GTP; [3H]ATP was not incorporated; [3H]GTP incorporation did not occur into denatured tubulin or into serum albumin. When [alpha-32P]GTP was used in the irradiation experiments, sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the carboxymethylated protein demonstrated that the incorporated label was associated with the beta subunit. The radiation treatment did cause changes in the tubulin molecule resulting in a decrease in assembly competence and in sulfhydryl groups, but these effects were minimized when a large excess of GTP was present during irradiation. Labeling of tubulin in the assembled state was much less than that observed in the free state.     

The effect of ruthenium red on the assembly and disassembly of microtubules and on rapid axonal transport

The assembly of microtubules was found to decrease in proportion to the amount of added ruthenium red, indicating a high affinity of ruthenium red for the microtubule system. An equimolar amount of ruthenium red per tubulin dimer inhibited the microtubule assembly completely and disassembled existing microtubules. Binding of ruthenium red to tubulin is accompanied by a shift in the absorption maximum from 535 to 538 nm. The binding is very strong, as shown by the finding that ruthenium red could not be displaced from tubulin by gel chromatography on Sephadex, or by the addition of Ca²⁺ or Mg²⁺. The binding of ruthenium red to tubulin did not affect the single colchicine site, nor the Mg²⁺ site(s), as shown by use of Mn²⁺ as an EPR probe. Ruthenium red also interfered with microtubules in an intact cell system, as it inhibited rapid axonal transport in the frog sciatic nerve, measured by the accumulation of [³H]leucine-labelled proteins in front of a ligature.     

Resistance of Rosa microtubule polymerization to colchicine results from a low-affinity interaction of colchicine and tubulin

The inhibition of the polymerization of tubulin from cultured cells of rose (Rosa. sp. cv. Paul's scarlet) by colchicine and the binding of colchicine to tubulin were examined in vitro and compared with data obtained in parallel experiments with bovine brain tubulin. Turbidimetric measurements of taxol-induced polymerization of rose microtubules were found to be sensitive and semiquantitative at low tubulin concentrations, and to conform to some of the characteristics of a nucleation and condensation-polymerization mechanism for assembly of filamentous helical polymers. Colchicine inhibited the rapid phase of polymerization at 24°C with an apparent inhibition constant (K _i) of 1.4·10^-4 M for rose tubulin and an apparent K _i=8.8·10^-7 M for brain tubulin. The binding of [³H]colchicine to rose tubulin to form tubulin-colchicine complex was mildly temperature-dependent and slow, taking 2–3 h to reach equilibrium at 24°C, and was not affected by vinblastine sulfate. The binding of [³H]colchicine to rose tubulin was saturable and Scatchard analysis indicated a single class of low-affinity binding sites having an apparent affinity constant (K) of 9.7·10² M^-1 and an estimated molar binding stoichiometry (r) of 0.47 at 24°C. The values for brain tubulin were K=2.46·10⁶ M^-1 and r=0.45 at 37°C. The binding of [³H]colchicine to rose tubulin was inhibited by excess unlabeled colchicine, but not by podophyllotoxin or tropolone. The data demonstrate divergence of the colchicine-binding sites on plant and animal tubulins and indicate that the relative resistance of plant microtubule polymerization to colchicine results from a low-affinity interaction of colchicine and tubulin.Abbreviations MT microtubule - TC tubulin-colchicine complex     

Glutamine synthetase cascade: enrichment of uridylyltransferase in Escherichia coli carrying hybrid ColE1 plasmids

Colchicine-binding properties of the total cytoplasmic pool of tubulin from rat liver were evaluated in tubulin-stabilizing (TS) supernates. Microtubules were separated from free tubulin using a microtubule-stabilizing solution (MTS) and ultracentrifugation. [³H]Colchicine-binding properties of microtubule-derived tubulin were investigated in supernates prepared after resuspension of MTS pellets in TS. In TS buffer at 37 °C the colchicine-binding activity of the total cytoplasmic pool of tubulin decayed with $\text{T}\text{1}\text{2}$ of 3.39 h. Resuspended pellet tubulin decayed much more rapidly under the same conditions with a $\text{T}\text{1}\text{2}$ of 0.72 h. This rapid time decay of microtubule-derived tubulin was found to be at least partially attributable to prior microtubule-stabilizing solution exposure. Since tartrate has been reported to increase the rate of colchicine binding to tubulin, sodium tartrate (150 mm) was added to our colchicine-binding system. This addition increased the detectable [³H]colchicine binding by 10% in the total cytoplasmic preparation and by 85% in the resuspended pellet preparation. Addition of tartrate (150 mm) also resulted in a 105% increase in the $\text{T}\text{1}\text{2}$ for total cytoplasmic tubulin and a 412% increase for microtubule derived tubulin. Total cytoplasmic supernates of liver bound [³H]colchicine linearly over a wide range of tissue concentrations. However, resuspended microtubule-stabilizing solution pellet supernates in tubulin-stabilizing solution showed some increase in colchicine binding per tissue weight in the more dilute samples. Our data which demonstrate differences in colchicine-binding properties for total cytoplasmic and microtubule-derived pools of tubulin suggest that present assays for hepatic tubulin polymerization which assume identical binding properties should be interpreted with caution.     

PURIFICATION OF RAT BRAIN CHOLINE ACETYLTRANSFERASE AND AN ESTIMATION OF ITS HALF-LIFE

—Acetyl-CoA:choline-O-acetyltransferase (ChAc, EC 2.3.1.6) was purified from rat cerebral cortex and its half-life determined. The molecular weight of the enzyme under non-denaturing conditions was estimated by gel filtration to be in the range of 60,000–65,000. On SDS acrylamide gels, the purified enzyme migrated as a single band with a molecular weight estimated as 62,000. The turnover rate of ChAc in the mature rat was determined by the double label method, employing l -[1-¹⁴C]leucine and l -[4,5-³H]leucine. Its half-life under steady-state conditions was estimated to be 5.2 days. As a control, tubulin was isolated from the same preparation and its half-life measured. Under these conditions tubulin exhibited a half-life of 3.8 days.     

Stoichiometry for guanine nucleotide binding to tubulin under polymerizing and nonpolymerizing conditions

The maximal stoichiometry for [³H]GTP binding to depolymerized tubulin with saturating amounts of added [³H]GTP is 0.4 mol/110,000 g protein. In contrast, 1 mol of radioactive nucleotide is incorporated into microtubules as a result of polymerization with [³H]GTP. The different stoichiometries result from a difference in the nucleotide binding properties of ring protein under polymerizing and nonpolymerizing conditions: ring protein at 0 °C is devoid of binding activity but binds added radioactive guanine nucleotide during microtubule assembly. The radioactive nucleotide which is incorporated into rings during microtubule assembly is not displaced by excess GDP, although it is at a site which is distinct from the N site.     

Tubulin-like protein from Aspergillus nidulans

[³⁵S] labeled extracts of the fungus $\text{Aspergillus nidulans}$ were copolymerized with purified porcine brain tubulin. The [³⁵S] $\text{A. nidulans}$ protein which copurified with porcine microtubules was found to be similar to [³H] chick tubulin when the two were coelectrophoresed on several polyacrylamide gel electrophoresis systems. These results strongly suggest the presence in $\text{A. nidulans}$ of a tubulin-like protein.     

Tubulin synthesis during ciliogenesis in the mouse oviduct.

We reported earlier that tubulin levels increase in the developing mouse oviduct during that period after birth when ciliogenesis is at a maximum (Staprans, I., and Dirksen, E. R. (1974) J. Cell Biol., 62, 164). To determine the degree to which de novo synthesis and tubulin pools contribute to this increase, [³H]leucine-incorporation experiments were performed in vivo and in culture. Soluble, particulate and axonemal fractions, obtained from homogenized oviducts of 3-, 5-, 8- and 12-day-old suckling mice, were electrophoresed on sodium dodecyl sulfate gels and the specific activity of the tubulin band determined. The present work shows that more than 90% of the tubulin in 3-day-old and 75% in 5-day-old mouse oviducts is synthesized de novo. From both the in vivo and in culture experiments we conclude that although tubulin pools are present in mouse oviduct, they are continuously being replenished by newly synthesized protein as there is a rapid outflow from the soluble and particulate to the axonemal fraction into structures such as basal bodies and cilia. This burst of de novo tubulin synthesis corresponds to evidence from electron microscopic autoradiography, where label is present to a greater extent over centriole precursors and basal bodies than over other cell organelles. [³H]leucine incorporation into tubulin was inhibited by cycloheximide, demonstrating that we are dealing with synthesis, while colchicine below 10^?3, M concentration had no effect on tubulin assembly into axonemes.     

Autopalmitoylation of tubulin

Pure rat brain tubulin is readily palmitoylated in vitro using [3H]palmitoyl CoA but no added enzymes. A maximum of approximately six palmitic acids are added per dimer in 2-3 h at 36-37 degrees C under native conditions. Both alpha and beta tubulin are labeled, and 63-73% of the label was hydroxylamine-labile, presumed thioesters. Labeling increases with increasing pH and temperature, and with low concentrations of guanidine HCl or KCl (but not with urea) to a maximum of approximately 13 palmitates/dimer. High SDS and guanidine HCl concentrations are inhibitory. At no time could all 20 cysteine residues of the dimer be palmitoylated. Polymerization to microtubules, or use of tubulin S, markedly decreases the accessibility of the palmitoylation sites. Palmitoylation increases the electrophoretic mobility of a portion of alpha tubulin toward the beta band. Palmitoylated tubulin binds a colchicine analogue normally, but during three warm/cold polymerization/depolymerization cycles there is a progressive loss of palmitoylated tubulin, indicating decreased polymerization competence. We postulate that local electrostatic factors are major regulators of reactivity of tubulin cysteine residues toward palmitoyl CoA, and that the negative charges surrounding a number of the cysteines are sensitive to negative charges on palmitoyl CoA.     

Taxol binds to polymerized tubulin in vitro

Taxol, a natural plant product that enhances the rate and extent of microtubule assembly in vitro and stabilizes microtubules in vitro and in cells, was labeled with tritium by catalytic exchange with (3)H(2)O. The binding of [(3)H]taxol to microtubule protein was studied by a sedimentation assay. Microtubules assembled in the presence of [(3)H]taxol bind drug specifically with an apparent binding constant, K(app), of 8.7 x 19(-7) M and binding saturates with a calculated maximal binding ration, B(max), of 0.6 mol taxol bound/mol tubulin dimer. [(3)H]Taxol also binds and assembles phosphocellulose-purified tubulin, and we suggest that taxol stabilizes interactions between dimers that lead to microtubule polymer formation. With both microtubule protein and phosphocellulose- purified tubulin, binding saturation occurs at approximate stoichiometry with the tubulin dimmer concentration. Under assembly conditions, podophyllotoxin and vinblastine inhibit the binding of [(3)H]taxol to microtubule protein in a complex manner which we believe reflects a competition between these drugs, not for a single binding site, but for different forms (dimer and polymer) of tubulin. Steady-state microtubules assembled with GTP or with 5’-guanylyl-α,β-methylene diphosphonate (GPCPP), a GTP analog reported to inhibit microtubule treadmilling (I.V. Sandoval and K. Weber. 1980. J. Biol. Chem. 255:6966-6974), bind [(3)H]taxol with approximately the same stoichiometry as microtubules assembled in the presence of [(3)H]taxol. Such data indicate that a taxol binding site exists on the intact microtubule. Unlabeled taxol competitively displaces [(3)H]taxol from microtubules, while podophyllotoxin, vinblastine, and CaCl(2) do not. Podophyllotoxin and vinblastine, however, reduce the mass of sedimented taxol-stabilized microtubules, but the specific activity of bound [(3)H]taxol in the pellet remains constant. We conclude that taxol binds specifically and reversibly to a polymerized form of tubulin with a stoichiometry approaching unity.     

Metabolism of [3H]gibberellin A4 in somatic suspension cell cultures of carrot

The native gibberellin A₄ (GA₄), in radioactive form ([1,2-³H]GA₄, 1.06 Ci/mmol), was fed to carrot somatic cell cultures (suspension and immobilized cell systems) and its metabolism over a 48 hr period was investigated. It was found that the [³H]GA₄ was metabolized to at least two GAs, [³H]GA₁ and [³H]GA₈, six GA glucosyl conjugates, [³H]GA₁-0(3)-glucoside, [³H]GA₁-0(13)-glucoside, [³H]GA₁-glucosyl ester, [³H]GA₄-glucoside, [³H]GA₄-glucosyl ester, a [³H]GA₈ glucosyl conjugate(s) and a previously unknown [³H]GA₁ glucosyl conjugate ([³H]GA₁-0(3,13)-diglucoside-like compound). The GA₁-diglucoside-like compound was found only in extracts of cells and was present in significant amounts (33 % of total extractable radioactivity). All other metabolites were present in both cells and medium. For extracts of the medium, no differences between the suspension and immobilized cultures existed in types of [³H]GA₄ metabolites although quantitative differences were apparent.     

Metabolism of [3H] Gibberellin A5 in Cell Suspension Cultures of Pharbitis nil

Gibberellin A₅ (GA₅), a native GA of immature seeds of Pharbitis nil, was fed to Pharbitis nil cell suspension cultures as [C-l, ³H] GA₅ (3.1 Ci/mmol), and its metabolism over a 48 hr period was investigated. Radioactivity in free GA metabolites was 13.1%, with 79.9% in GA glucosyl conjugate-like metabolites. Only 7.0% of the radioactivity remained as [³H] GA₅. Tentative identifications were based on comparison with retention times of authentic free GAs and/or glucosyl conjugates after sequential chromatography on Si gel partition column → gradient-eluted C18 HPLC-radiocounting (RC) → isocratic-eluted C18 HPLC-RC, and showed that [³H] GA₅ was converted to [³H] GA₁ (2%), [³H] GA₃ (4%), [³H] GA₆ (2%), [³H] GA₂₂ (1%) and their glucosyl conjugates, and also to [³H] GA₈ glucoside, and [³H] GA₅ glucosyl conjugates. The major conjugate-like substances were [³H] GA₁ and [³H] GA₃ glucosyl esters, at 15% and 34%, respectively, of the total extractable radioactivity.     

Rapid and Reversible High-Affinity Binding of the Dinitroaniline Herbicide Oryzalin to Tubulin from Zea mays L

Oryzalin, a dinitroaniline herbicide, was previously reported to bind to plant tubulin with a moderate strengthe interaction (dissociation constant [Kd] = 8.4 [mu]M) that appeared inconsistent with the nanomolar concentrations of drug that cause the loss of microtubules, inhibit mitosis, and produce herbicidal effects in plants (L.C. Morejohn, T.E. Bureau, J. Mole-Bajer, A.S. Bajer, D.E. Fosket [1987] Planta 172: 252-264). To characterize further the mechanism of action of oryzalin, both kinetic and quasi-equilibrium ligand-binding methods were used to examine the interaction of [14C]-oryzalin with tubulin from cultured cells of maize (Zea mays L. cv Black Mexican Sweet). Oryzalin binds to maize tubulin dimer via a rapid and pH-dependent interaction to form a tubulin-oryzalin complex. Both the tubulin-oryzalin binding strength and stoichiometry are underestimated substantially when measured by kinetic binding methods, because the tubulin-oryzalin complex dissociates rapidly into unliganded tubulin and free oryzalin. Also, an uncharacterized factor(s) that is co-isolated with maize tubulin was found to noncompetitively inhibit oryzalin binding to the dimer. Quasi-equilibrium binding measurements of the tubulin-oryzalin complex using purified maize dimer afforded a Kd of 95 nM (pH 6.9; 23[deg]C) and an estimated maximum molar binding stoichiometry of 0.5. No binding of oryzalin to pure bovine brain tubulin was detected by equilibrium dialysis, and oryzalin has no discernible effect on microtubules in mouse 3T3 fibroblasts, indicating an absence of the oryzalin-binding site on mammalian tubulin. Oryzalin binds to pure taxol-stabilized maize microtubules in a polymer mass- and number-dependent manner, although polymerized tubulin has a much lower oryzalin-binding capacity than unpolymerized tubulin. Much more oryzalin is incorporated into polyment during taxol-induced assembly of pure maize tubulin, and half-maximal inhibition of the rapid phase of taxol-induced polymerization of 5 [mu]M tubulin is obtained with 700 [mu]M oryzalin. The data are consistent with a molecular mechanism whereby oryzalin binds rapidly, reversibly, and with high affinity to the plant tubulin dimer to form a tubulin-oryzalin complex that, at concentrations substoichiometric to tubulin, copolymerizes with unliganded tubulin and slows further assembly. Because half-maximal inhibition of maize callus growth is produced by 37 nM oryzalin, the herbicidal effects of oryzalin appear to result from a substoichiometric poisoning of microtubules.