Microtubule-associated proteins and tubulin interaction by isothermal titration calorimetry.

Microtubules play an important role in a number of vital cell processes such as cell division, intracellular transport, and cell architecture. The highly dynamic structure of microtubules is tightly regulated by a number of stabilizing and destabilizing microtubule-associated proteins (MAPs), such as tau and stathmin. Because of their importance, tubulin-MAPs interactions have been extensively studied using various methods that provide researchers with complementary but sometimes contradictory thermodynamic data. Isothermal titration calorimetry (ITC) is the only direct thermodynamic method that enables a full thermodynamic characterization (stoichiometry, enthalpy, entropy of binding, and association constant) of the interaction after a single titration experiment. This method has been recently applied to study tubulin-MAPs interactions in order to bring new insights into molecular mechanisms of tubulin regulation. In this chapter, we review the technical specificity of this method and then focus on the use of ITC in the investigation of tubulin-MAPs binding. We describe technical issues which could arise during planning and carrying out the ITC experiments, in particular with fragile proteins such as tubulin. Using examples of stathmin and tau, we demonstrate how ITC can be used to gain major insights into tubulin-MAP interaction.

In vitro effect of cryptophycin 52 on microtubule assembly and tubulin: molecular modeling of the mechanism of action of a new antimitotic drug.

Cryptophycin 52 (C52) is a new synthetic compound of the cryptophycin family of antitumor agents that is currently undergoing clinical evaluation for cancer chemotherapy. The cryptophycin class of compounds acts on microtubules. This report details the mechanism by which C52 substoichiometrically inhibits tubulin self-assembly into microtubules. The inhibition data were analyzed through a model described by Perez-Ramirez [Perez-Ramirez, B., Andreu, J. M., Gorbunoff, M. J., and Timasheff, S. N. (1996) Biochemistry 35, 3277-3285]. We thereby determined the values of the apparent binding constant of the tubulin-C52 complex to the end of a growing microtubule (K(i)) and the apparent binding constant of C52 to tubulin (K(b)). The binding of C52 depended on tubulin concentration, and binding induced changes in the sedimentation pattern of tubulin, which indicates that C52 induces the self-association of tubulin and tubulin aggregates other than microtubules. Using analytical ultracentrifugation and electron microscopy, we show that C52 induces tubulin to form ring-shaped oligomers (single rings). We also show that C52 inhibits the formation of double rings from either GTP- or GDP-tubulin. In addition, the advances made by electron crystallography in understanding the structure of the tubulin and the microtubule allowed us to visualize the putative binding site of C52 and to reconstruct C52-induced ring oligomers by molecular modeling.

Three-dimensional structure of the lithostathine protofibril, a protein involved in Alzheimer's disease.

Neurodegenerative diseases are characterized by the presence of filamentous aggregates of proteins. We previously established that lithostathine is a protein overexpressed in the pre-clinical stages of Alzheimer's disease. Furthermore, it is present in the pathognomonic lesions associated with Alzheimer's disease. After self-proteolysis, the N-terminally truncated form of lithostathine leads to the formation of fibrillar aggregates. Here we observed using atomic force microscopy that these aggregates consisted of a network of protofibrils, each of which had a twisted appearance. Electron microscopy and image analysis showed that this twisted protofibril has a quadruple helical structure. Three-dimensional X-ray structural data and the results of biochemical experiments showed that when forming a protofibril, lithostathine was first assembled via lateral hydrophobic interactions into a tetramer. Each tetramer then linked up with another tetramer as the result of longitudinal electrostatic interactions. All these results were used to build a structural model for the lithostathine protofibril called the quadruple-helical filament (QHF-litho). In conclusion, lithostathine strongly resembles the prion protein in its dramatic proteolysis and amyloid proteins in its ability to form fibrils.

Phosphorylation and oligomerization states of native pig brain HSP90 studied by mass spectrometry.

HSP90 is one of the most abundant proteins in the cytosol of eukaryotic cells. HSP90 forms transient or stable complexes with several key proteins involved in signal transduction including protooncogenic protein kinases and nuclear receptors, it interacts with cellular structural elements such as actin-microfilament, tubulin-microtubule and intermediate filaments, and also exhibits conventional chaperone functions. This protein exists in two isoforms alpha-HSP90 and beta-HSP90, and it forms dimers which are crucial species for its biological activity. PAGE, ESI-MS and MALDI-MS were used to study HSP90 purified from pig brain. The two protein isoforms were clearly distinguished by ESI-MS, the alpha isoform being approximately six times more abundant than the beta isoform. ESI-MS in combination with lambda phosphatase treatment provided direct evidence of the existence of four phosphorylated forms of native pig brain alpha-HSP90, with the diphosphorylated form being the most abundant. For the beta isoform, the di-phosphorylated was also the most abundant. MALDI mass spectra of HSP90 samples after chemical cross-linking showed a high percentage of alpha-alpha homodimers. In addition, evidence for the existence of higher HSP90 oligomers was obtained.

Caulerpenyne from Caulerpa taxifolia has an antiproliferative activity on tumor cell line SK-N-SH and modifies the microtubule network.

Caulerpenyne, the major secondary metabolite synthesized by the green marine alga Caulerpa taxifolia, is cytotoxic against several cell lines. To identify possible targets of this toxin, we investigated the effect of caulerpenyne on the neuroblastoma SK-N-SH cell line. Caulerpenyne induced an inhibition of SK-N-SH cell proliferation with an IC50 of 10 +/- 2 microM after 2 hr of incubation. We observed no blockage in G2/M phase and an increase in cell death. On immunofluorescence microscopy, caulerpenyne affected the microtubule network in SK-N-SH cell line; we observed a loss of neurites and a compaction of the microtubule network at the cell periphery. In vitro, after 35 min of incubation, caulerpenyne inhibited the polymerization of pig brain purified tubulin or microtubule proteins, with an IC50 of 21 +/- 2 microM and 51 +/- 6 microM respectively. Analysis by electron microscopy indicated that caulerpenyne induced aggregation of tubulin, which may be responsible for inhibition of microtubule polymerization and bundling of residual microtubules.

Biophysical characterization of lithostathine. Evidences for a polymeric structure at physiological pH and a proteolysis mechanism leading to the formation of fibrils.

Lithostathine is a calcium carbonate crystal habit modifier. It is found precipitated under the form of fibrils in chronic calcifying pancreatitis or Alzheimer's disease. In order to gain better insight into the nature and the formation of fibrils, we have expressed and purified recombinant lithostathine. Analytical ultracentrifugation and quasi-elastic light scattering techniques were used to demonstrate that lithostathine remains essentially monomeric at acidic pH while it aggregates at physiological pH. Analysis of these aggregates by electron microscopy showed an apparently unorganized structure of numerous monomers which tend to precipitate forming regular unbranched fibrils. Aggregated forms seem to occur prior to the apparition of fibrils. In addition, we have demonstrated that these fibrils resulted from a proteolysis mechanism due to a specific cleavage of the Arg(11)-Ile(12) peptide bond. It is deduced that the NH(2)-terminal undecapeptide of lithostathine normally impedes fiber formation but not aggregation. A theoretical model explaining the formation of amyloid plaques in neurodegenerative diseases or stones in lithiasis starting from lithostathine is described. Therefore we propose that lithostathine, whose major function is unknown, defines a new class of molecules which is activated by proteolysis and is not involved in cytoskeleton nor intermediate filament functions.

Heat-shock protein 90 (hsp90) binds in vitro to tubulin dimer and inhibits microtubule formation.

Hsp90 interacts with steroid hormone receptors, protein kinases, and cytoskeletal proteins. The mode of action of hsp90 on microtubules and tubulin has not been investigated. Using isolated purified hsp90 and isolated tubulin, we demonstrated in vitro by difference absorption and fluorescence spectroscopy that hsp90 bound to tubulin with an apparent affinity constant of 5 x 10(5) M-1, assuming an apparent stoichiometry of 1 at 25 degrees C. Using microcalorimetry, we found a delta H of -9.8 +/- 0.8 kJ.mol-1. The binding of hsp90 to tubulin was confirmed by a sedimentation assay. Moreover, we showed that hsp90 inhibited tubulin polymerisation.

The two-state process of the heat shock protein 90 thermal denaturation: effect of calcium and magnesium.

Scanning microcalorimetry, native PAG electrophoresis, and circular dichroism were used to characterize thermal denaturation and oligomerization of heat shock protein 90 (hsp90) and the calcium and magnesium effect on these processes. The calorimetric curve of the hsp90 dimer consists of two transitions centered at 53.8 and 63.1 degrees C. Using specific ligand geldanamycin, we have found that N-terminal domains in the hsp90 dimer are melted independently in the lower-temperature peak, while the higher-temperature one comprises unfolding of two non-interacting parts of the middle domains and dimerization region. Unfolding of the N-terminal domain gives start to oligomerization of dimers; oligomers consist of dimers not dissociating upon denaturation. Calcium and magnesium strongly decrease the hsp90 thermostability and thereby cause oligomerization at lower temperature. We suggest that calcium affects the hsp90 oligomerization, known to be important for its chaperone activity, by shifting the unfolding temperature of the hsp90 N-terminal domain close to the heat shock temperature range.

The active GTP- and ground GDP-liganded states of tubulin are distinguished by the binding of chiral isomers of ethyl 5-amino-2-methyl-1,2-dihydro-3-phenylpyrido[3,4-b]pyrazin-7-yl carbamate.

NSC 613862 (S)-(-) and NSC 613863 (R)-(+) are the two chiral isomers of ethyl-5-amino-2-methyl-1,2-dihydro-3-phenylpyrido[3, 4-b]pyrazin-7-yl carbamate. Both compounds bind to tubulin in a region that overlaps the colchicine site. They induce formation of abnormal polymers from purified GTP-Mg-tubulin, the active assembly form of tubulin, in glycerol-free buffer with magnesium [De Ines, C., Leynadier, D., Barasoain, I., Peyrot, V., Garcia, P., Briand, C., Rener, G. A., and Temple, C., Jr. (1994) Cancer Res. 54, 75-84]. In this study, we observed that the S-isomer can promote polymerization of GDP-tubulin, the inactive assembly-incompetent form of tubulin, into nonmicrotubular structures at a critical protein concentration of 1 mg/mL (12 mM MgCl2). Neither the R-isomer nor colchicine have this ability. By electron microscopy, these tubulin polymers showed the same poorly defined filamentous structure when GDP-tubulin or GTP-Mg-tubulin were used. By HPLC measurements, we demonstrated that a dissociated GTP hydrolysis and exchange of nucleotide occurred during the isomer-induced abnormal assembly. Both isomers inhibited the Mg2+-induced tubulin self-association leading to 42 S double ring formation from GTP-Mg-tubulin or GDP-tubulin. Measurement of their binding under nonassociation conditions revealed a 3-fold decrease in the apparent equilibrium binding constant of the R-isomer to GDP-tubulin relative to GTP-Mg-tubulin. For the S-isomer, the decrease in the binding constant was less pronounced. Binding data, analyzed in terms of a system of linked conformational and association equilibria, provide evidence that the active ("straight") rather than the inactive ("curved") conformation of tubulin differentially recognizes these ligands. Whereas binding of colchicine to tubulin is well-known to induce GTP hydrolysis, this is the first case in which the interaction of a ligand with the colchicine site is shown to be sensitive to the presence of GDP or GTP at the distant nucleotide binding site.

Kinetics of association and dissociation of two enantiomers, NSC 613863 (R)-(+) and NSC 613862 (S)-(-) (CI 980), to tubulin.

The kinetics of binding of R- and S-enantiomers were studied by the fluorescence stopped-flow technique. For the R-enantiomer, the time course of the increase in fluorescence is best fitted by a sum of two exponentials. In pseudo-first-order conditions, the first observed rate constant showed a linear concentration dependence whereas the second showed a hyperbolic one. The dissociation rate constants were determined independently by displacement experiments with 2-methoxy-5-(2,3,4-trimethoxyphenyl)-2,4,6-cycloheptatrien-1-one (MTC). The two exponential phases were assumed to be due to a two-step binding mechanism: an initial binding followed by a conformational change. This is different from colchicine and MTC binding, where the two phases show a hyperbolic concentration dependence and are attributed to the parallel binding to different isoforms of tubulin [Banerjee, A., & Luduena, R. F. (1992) J. Biol. Chem. 267, 13335-13339]. R-isomer binding did not discriminate between the tubulin isoforms. The temperature dependence of all the rate constants were measured, and the entire thermodynamic reaction path was constructed. For the S-isomer, the direct fluorescence stopped-flow study showed that the signals were largely imputable to the fluorescence of the binding at low-affinity sites [Leynadier, D., Peyrot, V., Sarrazin, M., Briand, C., Andreu, J. M., Rener, G. A., & Temple, C., Jr. (1993) Biochemistry 32, 10674-10682]. Therefore, we exploited the competition between R- and S-isomers to determine the binding kinetics of the S-isomer to the R-site. The observed rate constants for competitive binding showed a linear concentration dependence, thus allowing us to calculate the association rate constant of the S-isomer to the R-site. The kinetics of displacement of the S-isomer by MTC allowed the dissociation rate constant for the S-isomer to be determined. The binding of both enantiomers to tubulin in presence of tropolone methyl ether (analog of the colchicine C ring) was decreased, indicating the involvement of the C subsite.

[Sensitivity of the retinal pigment epithelium to spindle poisons]. / Sensibilité du cytosquelette de l'épithélium pigmentaire rétinien aux poisons du fuseau mitotique.

PURPOSE: The function of RPE is well known in PVR. Pharmacological agents have been extensively studied both experimentally and clinically. Few reports have detailed the interactions of antimitotic drugs on the microtubule network. The aim of this study is to visualize by indirect immunofluorescence the effects of colchicine and paclitaxel on the microtubule network of cultured pig RPE cells in interphase. METHODS: Pigs were killed at the slaughter-house, their eyes were enucleated. RPE cells were isolated and cultured. RPE cells were plated onto glass cover-slips at a density of 2,000,000 cells/ml, cultured and treated with the drugs during 4 and 24 hours at 37 degrees C at different concentrations. Immunofluorescence reaction was developped using antitubulin and fluoresceinated anti-mouse antibodies. The cytoskeletons were visualized employing a Zeiss photomicroscope equipped with epiilumination, a 63 x lens and appropriate filters for fluoresceine. RESULTS: The cytoplasmic microtubules of RPE cells were disrupted in a concentration and time-dependant manner by colchicine. Between 10 and 100 nm Veveral degrees of depolymarization of the microtubule network were observed. Paclitaxel between 1 micron and 10 microns was found to induce several degrees of microtubule "bundling" after 4 and 24 hours of incubation. Actin network was modified neither by colchicine and paclitaxel used in the same conditions. CONCLUSIONS: The results show that low doses of antimitotic drugs inhibit the microtubule network formation by depolymerization (colchicine) or stabilize it (paclitaxel). These actions inhibit cell division, which is one of the mechanisms implicated in PVR.

Differential effects of ethyl 5-amino-2-methyl-1,2-dihydro-3-phenylpyrido[3,4-b]pyrazin-7-yl carbamate analogs modified at position C2 on tubulin polymerization, binding, and conformational changes.

NSC 613863 (R)-(+) and NSC 613862 (S)-(-) (CI980) are two chiral isomers of ethyl 5-amino 2-methyl-1,2-dihydro-3-phenylpyrido[3,4-b]pyrazin-7-yl carbamate which have potent antitubulin activity. The S-isomer is a more potent antimitotic compound than the R-isomer, and the two isomers differ markedly in binding to tubulin [Leynadier, D., Peyrot, V., Sarrazin, M., Briand, C., Andreu, J. M., Rener, G. A., & Temple, C., Jr. (1993) Biochemistry 32, 10675-10682]. To understand the origin of such differences, we studied the interactions of three R- and S-isomer structural analogs which differ in C2 (the chiral carbon), i.e., C179, NSC 337238, and NSC 330770. C179 is a methylated dehydrogenated achiral compound. It bound to tubulin with an apparent affinity Ka of (2.29 +/- 0.17) x 10(4) M-1, inhibited tubulin polymerization in vitro at a half-inhibitory concentration (IC50) of 100 microM, and presented no GTPase activity. The substitution of -CH3 by -H leads to the NSC 337238 compound. It bound to tubulin with a higher affinity [Ka = (2.62 +/- 0.35) x 10(5) M-1] and inhibited tubulin polymerization at a lower concentration (IC50 = 14 microM). It presented no GTPase activity and induced the formation of abnormal polymers at a protein critical concentration (Cr) of 2 mg mL-1. NSC 330770, a demethylated hydrogenated molecule, interacted strongly with tubulin [Ka = (3.30 +/- 0.56) x 10(6) M-1].(ABSTRACT TRUNCATED AT 250 WORDS)

Molecular interaction of tubulin with 1-deaza-7,8-dihydropteridines: a comparative study of enantiomers NSC 613862 (S) and NSC 613863 (R) by Raman and Fourier transform infrared spectroscopy.

Pre-resonance Raman spectroscopy has been applied to compare the vibrational modes of the R and S chiral isomers of 1-deaza-7,8-dihydropteridine when they are bound to tubulin. The main Raman bands are due to the chromophore and are coupled with the pi-pi electronic transition of C = C and C = N vibrational stretching. On binding to tubulin, the Raman spectra of both isomers are modified. However, the modifications induced are different for each isomer. The Raman bands due to C = C stretching from the phenyl ring are more strongly modified for the bound R isomer than for the S isomer. This leads us to suggest that R and S isomers differ in terms of their orientation in front of the binding locus of tubulin. In fact, with respect to the orientation of the bulky methyl group, the chromophore of the R isomer is more likely to be positioned against the external surface of either tubulin or GTPase proteins, while that of the S isomer is likely to be positioned away from the surface. The conformational changes induced in tubulin by R and S isomers have also been studied by Fourier transform infrared spectroscopy and by the analysis of amide I and II absorption bands. Both enantiomers induce similar minor changes to the tubulin secondary structure, corresponding to a decrease in the disordered alpha-helical content and accompanied by an increase in the undefined conformation content.

Solution structure of Taxotere-induced microtubules to 3-nm resolution. The change in protofilament number is linked to the binding of the taxol side chain.

The synchrotron x-ray solution scattering profiles of microtubules assembled from purified GDP- or GTP-tubulin with the antitumor drug docetaxel (Taxotere) are consistent with identical non-globular alpha and beta-tubulin monomers ordered within the known surface lattice of microtubules, with a center to center lateral spacing of 5.7 +/- 0.1 nm. The higher angle part of the scattering profile, and therefore the substructure of the microtubule wall is identical in Taxotere- and Taxol-induced microtubules, to the resolution of the measurements. However, Taxotere-induced microtubules have a mean diameter of 24.2 +/- 0.4 nm, which is 1.12 +/- 0.01 times larger than that of paclitaxel (Taxol) induced microtubules. The population of Taxotere microtubules has on average 13.4 protofilaments, which is similar to control microtubules assembled with glycerol but is in marked contrast with Taxol-induced microtubules, which have on average 12 protofilaments under identical solution conditions. Model populations of Taxotere and Taxol microtubules with the distributions of protofilament numbers determined by electron microscopy reproduce the positions and approximate intensities of the experimental x-ray scattering data. Comparison of the structures and activities of both taxoids strongly suggests that the change of the more frequent lateral bond angle between tubulin molecules from 152.3 degrees (13-protofilament microtubules) to 150 degrees (12-protofilament microtubules) is linked to the binding of the side chain of Taxol. Optimal microtubule formation is obtained with unitary Taxotere to tubulin heterodimer ratio; however, ligand molecules in excess over tubulin dimers cause a loss of cylindrical scattering features, consistent with microtubule opening. The results are compatible with the observed biochemical and thermodynamic properties of this ligand-induced microtubule assembly system and also with the simple working hypothesis that taxoids would bind between adjacent microtubule protofilaments.

Inhibition of microtubules and cell cycle arrest by a new 1-deaza-7,8-dihydropteridine antitumor drug, CI 980, and by its chiral isomer, NSC 613863.

CI 980 (NSC 613862; [S-(-)]) and NSC 613863 [R-(+)] are the two chiral isomers of ethyl 5-amino 1,2-dihydro-2-methyl-3-phenylpyrido[3,4-b]pyrazin-7-ylcar bamate (NSC 370147), which is a mitotic inhibitor with in vivo and in vitro activity against murine multidrug-resistant sublines. We have characterized the inhibition of in vitro microtubule assembly by the S (CI 980) and R (NSC 613863) enantiomers, their actions on the cytoplasmic microtubule network of epithelial-like PtK2 cells, and on the cell cycle of different human and murine leukemias and PtK2 cells. Assembly of purified tubulin, or tubulin plus microtubule-associated proteins, into microtubules was substoichiometrically inhibited by both compounds, which also induced a slow depolymerization of preassembled microtubules. Half inhibitory concentrations were 0.4-0.7 microM and 1.6-2.1 microM for the S and R isomers, respectively. Excess of both drugs induced polymerization of liganded tubulin into abnormal polymers similar to colchicine. The cytoplasmic microtubules of PtK2 cells were disrupted by both compounds in a concentration- and time-dependent manner, which was observed by indirect immunofluorescence microscopy and quantified by an enzyme-linked immunoassay of cytoskeletal tubulin. Half inhibitory concentrations were 6 nM S isomer, 100 nM R isomer, and 1 microM colchicine. Twenty nM S isomer or 500-700 nM R isomer gave nearly maximal effect. At these concentrations, half maximal microtubule depolymerization took place after 2 h of treatment. After drug removal, slow microtubule assembly and nearly complete reorganization of the cytoplasmic microtubules of PtK2 cells were observed (24 h). One nM S enantiomer or 25 nM R enantiomer induced mitotic arrest in 8 h in U937, HL60, and EL4 leukemias. PtK2 cells also stopped in mitosis after a 24-h incubation with 50 nM R isomer or 5 nM S isomer. The inhibition of cell division was irreversible in the leukemic cells, while PtK2 cells partially resumed growth. Although the interactions of CI 980 with microtubules in vitro are not very different from other drugs, it is a most potent cellular microtubule and mitotic inhibitor.

Tubulin binding of two 1-deaza-7,8-dihydropteridines with different biological properties: enantiomers NSC 613862 (S)-(-) and NSC 613863 (R)-(+).

Several fluorescence properties of two enantiomers, NSC 613862 (S)-(-) and NSC 613863 (R)-(+), have been compared. Even though the two isomers showed the same fluorescence behavior in solution in different solvents, drastic differences were observed after binding to purified calf brain tubulin. Binding measurements for the two compounds were performed both by fluorescence spectroscopy and by column gel permeation, a direct method of measurement. For both isomers, the binding was characterized by the presence of one high-affinity binding site with an apparent association constant of (3.2 +/- 0.5) x 10(6) M-1 and (4.1 +/- 0.9) x 10(6) M-1 for the R- and S-isomer, respectively, and by several low-affinity sites. Both isomers were also shown to induce GTPase activity in tubulin. The high-affinity binding site seems to be the same for the two isomers. Moreover, fluorescence competition experiments suggest at least a partial overlap of the colchicine and podophyllotoxin site. To explain the differences in fluorescence behavior after binding to tubulin, we hypothesize that the R-isomer is positioned differently in its binding locus as compared with the S-isomer.

Mechanism of binding of the new antimitotic drug MDL 27048 to the colchicine site of tubulin: equilibrium studies.

MDL 27048 [trans-1-(2,5-dimethoxyphenyl)-3-[4-(dimethylamino)phenyl]-2- methyl-2-propen-1-one] fluoresces when bound to tubulin but not in solution. This effect has been investigated and found to be mimicked by viscous solvents. Therefore, MDL 27048 appears to be a fluorescent compound whose intramolecular rotational relaxation varies as a function of microenvironment viscosity. The binding parameters of MDL 27048 to tubulin have been firmly established by fluorescence of the ligand, quenching of the protein fluorescence, and gel equilibrium chromatography. The apparent binding equilibrium constant was (2.75 +/- 0.45) x 10(6)M-1, and the binding site number was 0.81 +/- 0.12 (10 mM sodium phosphate-0.1 mM GTP, pH 7.0, at 25 degrees C). The binding is exothermic. The binding of MDL 27048 overlaps the colchicine and podophyllotoxin binding sites. Binding of MDL 27048 to the colchicine site was also measured by competition with MTC [2-methoxy-5-(2,3,4-trimethoxyphenyl)-2,4,6-cycloheptatrien-1-one] , a well-characterized reversibly binding probe of the colchicine site [Andreu et al. (1984) Biochemistry 23, 1742-1752; Bane et al., (1984) J. Biol. Chem. 259, 7391-7398]. In contrast with close analogues of colchicine, MDL 27048 and podophyllotoxin neither affected the far-ultraviolet circular dichroism spectrum of tubulin, within experimental error, nor induced tubulin GTPase activity. Like podophyllotoxin, an excess of MDL 27048 over tubulin induced no abnormal cooperative polymerization of tubulin, which is characteristic of colchicine binding.(ABSTRACT TRUNCATED AT 250 WORDS)

Fluorescence stopped-flow study of the interaction of tubulin with the antimitotic drug MDL 27048.

The kinetics of the binding of MDL 27048 to tubulin have been studied by fluorescence stopped flow. The binding is accompanied by a fluorescence increase. The time course can be described by a sum of two exponentials, assumed to be due to the presence of two major tubulin isoforms. The observed rate constants depend in a nonlinear way on the concentration of MDL in pseudo-first-order conditions. This concentration dependence can be described by the presence of a fast equilibrium of low affinity, followed by an isomerization of the initial complex. The dissociation kinetics have been studied by displacement experiments, in which MTC was used as a competitive ligand. The reaction enthalpy change for the first binding equilibrium and the activation energies for the forward and reverse steps of the isomerization were determined from the temperature dependence. This was possible for the two tubulin isotype populations. The kinetics of the binding of MDL to tubulin are slowed down in the presence of 3',4',5'-trimethoxyacetophenone, a fast binding analog of the colchicine A-ring, but are not influenced by the binding of tropolone methyl ether, indicating that the binding site of MDL has the A-subsite in common with colchicine, but not the C-subsite.

Qualitative study of the interaction mechanism of estrogenic drugs with tubulin.

Synthetic estrogenic drugs (E-diethylstilbestrol, erythro-hexestrol and E,E-dienestrol) inhibit tubulin assembly and erythro-hexestrol and E,E-dienestrol lead to the formation of twisted ribbon structures. For the inhibitory effect on tubulin assembly, estrogenic drugs seem to interact directly with tubulin 6S on site(s) analogous to the colchicine-site, but independent of the GTP- and vinblastine-sites. This binding does not involve tubulin tryptophanyl residues or sulfhydryl groups. The influence of temperature, calcium and magnesium on the formation of twisted ribbon structures induced by the binding of estrogenic drugs to microtubular protein and tubulin has also been studied. This formation is strongly magnesium-dependent whereas preformed twisted ribbon structures are calcium- and chilling-insensitive.