Microtubules and nucleoside diphosphate kinase. Comparison of kinetics of GTP- and CTP-induced assembly.

The kinetics of assembly of MAP2-tubulin microtubule protein were examined as a function of the GTP concentration in order to test the hypothesis that CTP-induced assembly results from the generation of GTP by nucleoside diphosphate kinase. These studies show that (a) there is no assembly below a minimum GTP concentration and that this represents a nucleation requirement, (b) the rate of elongation is inconsistent with a single assembly-species, and (c) the elongation rate increases markedly as the GTP concentration is raised, although GTP is not absolutely required for elongation. These assembly kinetics have been compared with those with increasing CTP concentrations, by using microtubule protein containing a very low nucleoside diphosphate kinase activity of known substrate specificity. Neither nucleation nor the observed rates of elongation can be attributed to the formation of GTP, either (a) in terms of the generation of free GTP and subsequent binding to tubulin or (b) by the direct charging of GDP bound to the tubulin exchangeable site. The results show that nucleoside diphosphate kinase is not required for CTP-induced microtubule assembly, and suggest that CTP directly effects microtubule assembly.     

Direct incorporation of guanosine 5'-diphosphate into microtubules without guanosine 5'-triphosphate hydrolysis

Using highly purified calf brain tubulin bearing [8-14C]guanosine 5'-diphosphate (GDP) in the exchangeable nucleotide site and heat-treated microtubule-associated proteins (both components containing negligible amounts of nucleoside diphosphate kinase and nonspecific phosphatase activities), we have found that a significant proportion of exchangeable-site GDP in microtubules can be incorporated directly during guanosine 5'-triphosphate (GTP) dependent polymerization of tubulin, without an initial exchange of GDP for GTP and subsequent GTP hydrolysis during assembly. The precise amount of GDP incorporated directly into microtubules is highly dependent on specific reaction conditions, being favored by high tubulin concentrations, low GTP and Mg2+ concentrations, and exogenous GDP in the reaction mixture. Minimum effects were observed with changes in reaction pH or temperature, changes in concentration of microtubule-associated proteins, alteration of the sulfonate buffer, or the presence of a calcium chelator in the reaction mixture. Under conditions most favorable for direct GDP incorporation, about one-third of the GDP in microtubules is incorporated directly (without GTP hydrolysis) and two-thirds is incorporated hydrolytically (as a consequence of GTP hydrolysis). Direct incorporation of GDP occurs in a constant proportion throughout elongation, and the amount of direct incorporation probably reflects the rapid equilibration of GDP and GTP at the exchangeable site that occurs before the onset of assembly.     

Evidence for a distinct ligand binding site on tubulin discovered through inhibition by GDP of paclitaxel-induced tubulin assembly in the absence of exogenous GTP

GDP inhibits paclitaxel-induced tubulin assembly without GTP when the tubulin bears GDP in the exchangeable site (E-site). Initially, we thought inhibition was mediated through the E-site, since small amounts of GTP or Mg²⁺, which favors GTP binding to the E-site, reduced inhibition by GDP. We thought trace GTP released from the nonexchangeable site (N-site) by tubulin denaturation was required for polymer nucleation, but microtubule length was unaffected by GDP. Further, enhancing polymer nucleation reduced inhibition by GDP. Other mechanisms involving the E-site were eliminated experimentally. Upon finding that ATP weakly inhibited paclitaxel-induced assembly, we concluded that another ligand binding site was responsible for these inhibitory effects, and we found that GDP was not binding at the taxoid, colchicine, or vinca sites. There may therefore be a lower affinity site on tubulin to which GDP can bind distinct from the E- and N-sites, possibly on α-tubulin, based on molecular modeling studies.     

Binding of gossypol to purified tubulin and inhibition of its assembly into microtubules

Gossypol is a polyphenolic pigment, which is employed as a male antifertility drug. It inhibits, among other reported effects, the growth of cultured mammalian cells, spermiogenesis, flagellar motility in Trypanosoma and sperm, dynein ATPase and the lactate dehydrogenase X (LDH-X) isozyme. We have characterized the non-covalent binding of gossypol to purified calf brain tubulin in 10 mM phosphate buffer, 0.1 mM GTP pH 7.0 at 25 degrees C. Equilibrium measurements were performed by difference spectroscopy. A peak at 435 nm was produced by the perturbation of gossypol light absorption upon binding to tubulin. The experimental isotherm was fitted by 1.96 +/- 0.06 gossypol binding sites per tubulin molecule, with identical apparent equilibrium binding constants of (7.5 +/- 1.1) X 10(4) M-1. The complex formed could be separated from free gossypol by gel chromatography. Binding of gossypol was independent of the presence of 0.1 mM GTP in the buffer. Gossypol did not affect the binding of ligands to the colchicine site. Gossypol interacted with vinblastine but apparently did not bind to the vinblastine sites of tubulin. Gossypol did not displace anilinonaphthalene sulphonate (ANS) bound to tubulin, but caused a strong (fivefold) quenching of its fluorescence. This indicated that gossypol probably binds in the vicinity of the ANS site of tubulin. Gossypol inhibited in vitro microtubule assembly at the same concentration range employed in the binding studies. An increase in the critical protein concentration required for polymerisation was observed, most simply interpreted by a stoichiometric mechanism. Gossypol did not induce any noticeable distortion of the microtubules observed under the electron microscope. This compound constitutes a new tubulin ligand and an inhibitor of microtubule assembly in vitro.     

Magnesium requirements for guanosine 5'-O-(3-thiotriphosphate) induced assembly of microtubule protein and tubulin

Two conflicting interpretations on the role of guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S) in microtubule protein and tubulin assembly have been previously reported. One study finds that GTP gamma S promotes assembly while another study reports that GTP gamma S is a potent inhibitor of microtubule assembly. We have examined the potential role of Mg2+ to learn if the conflicting interpretations are due to a metal effect. Turbidity, electron microscopy, and nucleotide binding and hydrolysis were used to analyze the effect of the Mg2+ concentration on GTP gamma S-induced assembly of microtubule protein (tubulin + microtubule-associated proteins) in the presence of buffer +/- 30% glycerol and in buffer with GTP added before or after GTP gamma S. GTP gamma S substantially lowers the Mg2+ concentration required to induce cross-linked or clustered rings of tubulin. These cross-linked rings do not assemble well into microtubules, and GTP only partially restores microtubule assembly. However, taxol will promote GTP gamma S-induced cross-linked rings of microtubule protein to assemble into microtubules. The effect of GTP gamma S on microtubule protein assembly in the presence of Zn2+ with and without added Mg2+ suggests that GTP gamma S also effects the formation of Zn2+-induced sheet aggregates. Purified tubulin was used in assembly experiments with Mg2+, Zn2+, and taxol to better understand GTP gamma S interactions with tubulin. The optimal Mg2+ concentration for assembly of tubulin is lower with GTP gamma S than with GTP.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nucleotide binding and phosphorylation in microtubule assembly in vitro.

Two non-hydrolyzable analogs of GTP, guanylyl-β,γ-methylene diphosphonate and guanylyl imidodiphosphate, have been found to induce rapid and efficient microtubule assembly in vitro by binding at the exchangeable site (E-site) on tubulin. Characterization of microtubule polymerization by several criteria, including polymerization kinetics, nucleotide binding to depolymerized and polymerized microtubules, and microtubule stability, reveals strong similarities between microtubule assembly induced by GTP and non-hydrolyzable GTP analogs. Nucleoside triphosphates which bind weakly or not at all to tubulin, such as ATP, UTP and CTP, are shown to induce microtubule assembly by means of a nucleoside diphosphate kinase (NDP-kinase, EC 2.7.4.6.) activity which is not intrinsic to tubulin. The NDP-kinase mediates microtubule polymerization by phosphorylating tubulin-bound GDP in situ at the E-site. Although hydrolysis of exchangeably bound GTP occurs, it is found to be uncoupled from the polymerization reaction. The non-exchangeable nucleotide binding site on tubulin (N-site) is not directly involved in microtubule assembly in vitro. The N-site is shown to contain almost exclusively GTP which is not hydrolyzed during microtubule assembly. A scheme is presented in which GTP acts as an allosteric effector at the E-site during microtubule assembly in vitro.     

Assembly of pure tubulin in the absence of free GTP: effect of magnesium, glycerol, ATP, and the nonhydrolyzable GTP analogues

We describe in vitro microtubule assembly that exhibits, in bulk solution, behavior consistent with the GTP cap model of dynamic instability. Microtubules assembled from pure tubulin in the absence of free nucleotides could undergo one cycle of assembly, but could not sustain an assembly plateau. After the initial peak of assembly was reached and bound E-site GTP hydrolyzed to GDP, the microtubules gradually disassembled. We studied buffer conditions that maximized this disassembly while still allowing robust assembly to take place. While both glycerol and glutamate increased the rate of initial assembly and then slowed disassembly, magnesium promoted initial assembly and, surprisingly, enhanced disassembly. After cooling, a second cycle of assembly was unsuccessful unless GTP or the hydrolyzable GTP analogue GMPCPOP was readded. The nonhydrolyzable GTP analogues GMPPNP and GMPPCP could not support the second assembly cycle in the absence of E-site GTP. Analysis using HPLC found no evidence that GMPPNP, GMPPCP, or ATP could bind to free tubulin, and these nucleotides did not compete with GTP for the E-site. We have, however, demonstrated that the nonhydrolyzable GTP analogues and ATP do have an important effect on microtubule assembly. GMPPNP, GMPPCP, and ATP could each enhance the rate of assembly and stabilize the plateau of assembled microtubules against disassembly, while not binding appreciably to free tubulin. We conclude that these nucleotides, as well as GTP itself, enhance assembly by binding to a site on microtubules that is not present on free, unpolymerized tubulin. We estimate the affinity (KD) of the polymeric site for nucleotide triphosphates to be approximately 10(-4)M.     

Nucleoside triphosphate specificity of tubulin

We have determined the binding affinity for binding of the four purine nucleoside triphosphates GTP, ITP, XTP, and ATP to E-site nucleotide- and nucleoside diphosphate kinase-depleted tubulin. The relative binding affinities are 3000 for GTP, 10 for ITP, 2 for XTP, and 1 for ATP. Thus, the 2-exocyclic amino group in GTP is important in determining the nucleotide specificity of tubulin and may interact with a hydrogen bond acceptor group in the protein. The 6-oxo group also makes a contribution to the high affinity for GTP. NMR ROESY experiments indicate that the four nucleotides have different average conformations in solution. ATP and XTP are characterized by a high anti conformation, ITP by a medium anti conformation, and GTP by a low anti conformation. Possibly, the preferred solution conformation contributes to the differences in affinities. When the tubulin E-site is saturated with nucleotide, there appears to be little difference in the ability of the four nucleotides to stimulate assembly. The critical protein concentration is essentially identical in reactions using the four nucleotides. All four of the nucleotides were hydrolyzed during the assembly reaction, and the NDPs were incorporated into the microtubule. We also examined the binding of two gamma-phosphoryl-modified GTP photoaffinity analogues, p(3)-1, 4-azidoanilido-GTP and p(3)-1,3-acetylanilido-GTP. These analogues are inhibitors of the assembly reaction and bind to tubulin with affinities that are 15- and 50-fold lower, respectively, than the affinty for GTP. The affinity of GTP is less sensitive to substitutions at the gamma-phosphoryl position that to changes in the purine ring.     

Binding of dolastatin 10 to tubulin at a distinct site for peptide antimitotic agents near the exchangeable nucleotide and vinca alkaloid sites

Dolastatin 10, a potent antimitotic peptide from a marine animal, strongly inhibits microtubule assembly, tubulin-dependent GTP hydrolysis, and the binding of vinca alkaloids to tubulin. In studies of the binding of [3H]vincristine to the protein, with vinblastine as a control for competitive inhibition (Ki, 6.6 microM), we found that the macrolide antimitotic agents maytansine and rhizoxin were also competitive inhibitors (Ki values, 3.1 and 12 microM). Dolastatin 10 and an unrelated peptide antimitotic, phomopsin A, were more potent but noncompetitive inhibitors (Ki values, 1.4 and 2.8 microM). Since maytansine and, to a much lesser extent, vinblastine interfere with nucleotide exchange on tubulin, all drugs were examined for effects on nucleotide interactions at the exchangeable GTP site. Rhizoxin had effects intermediate between those of vinblastine and maytansine. Both peptides inhibited binding of radiolabeled GTP to tubulin even more strongly than did maytansine, but no drug displaced nucleotide from tubulin. The drugs were evaluated for stabilizing effects on the colchicine binding activity of tubulin. The peptides prevented loss of this activity, and vinblastine provided partial protection, while rhizoxin and maytansine did not stabilize tubulin. A tripeptide segment of dolastatin 10 also effectively inhibits tubulin polymerization and GTP hydrolysis. The tripeptide did not significantly inhibit either vincristine binding or nucleotide exchange, nor did it stabilize colchicine binding. These findings are rationalized in terms of a model with two distinct drug binding sites in close physical proximity to each other and to the exchangeable GTP site on beta-tubulin.     

Tubulin Dimers Oligomerize before Their Incorporation into Microtubules

In the presence of GTP, purified dimers of α- and β-tubulin will interact longitudinally and laterally to self-assemble into microtubules (MTs). This property provides a powerful in vitro experimental system to describe MT dynamic behavior at the micrometer scale and to study effects and functioning of a large variety of microtubule associated proteins (MAPs). Despite the plethora of such data produced, the molecular mechanisms of MT assembly remain disputed. Electron microscopy (EM) studies suggested that tubulin dimers interact longitudinally to form short oligomers which form a tube by lateral interaction and which contribute to MT elongation. This idea is however challenged: Based on estimated association constants it was proposed that single dimers represent the major fraction of free tubulin. This view was recently supported by measurements suggesting that MTs elongate by addition of single tubulin dimers. To solve this discrepancy, we performed a direct measurement of the longitudinal interaction energy for tubulin dimers. We quantified the size distribution of tubulin oligomers using EM and fluorescence correlation spectroscopy (FCS). From the distribution we derived the longitudinal interaction energy in the presence of GDP and the non-hydrolysable GTP analog GMPCPP. Our data suggest that MT elongation and nucleation involves interactions of short tubulin oligomers rather than dimers. Our approach provides a solid experimental framework to better understand the role of MAPs in MT nucleation and growth.     

Insight into the GTPase activity of tubulin from complexes with stathmin-like domains

Microtubules are dynamically unstable tubulin polymers that interconvert stochastically between growing and shrinking states, a property central to their cellular functions. Following its incorporation in microtubules, tubulin hydrolyzes one GTP molecule. Microtubule dynamic instability depends on GTP hydrolysis so that this activity is crucial to the regulation of microtubule assembly. Tubulin also has a much lower GTPase activity in solution. We have used ternary complexes made of two tubulin molecules and one stathmin-like domain to investigate the mechanism of the tubulin GTPase activity in solution. We show that whereas stathmin-like domains and colchicine enhance this activity, it is inhibited by vinblastine and by the N-terminal part of stathmin-like domains. Taken together with the structures of the tubulin-colchicine-stathmin-like domain-vinblastine complex and of microtubules, our results lead to the conclusions that the tubulin-colchicine GTPase activity in solution is caused by tubulin-tubulin associations and that the residues involved in catalysis comprise the beta tubulin GTP binding site and alpha tubulin residues that participate in intermolecular interactions in protofilaments. This site resembles the one that has been proposed to give rise to GTP hydrolysis in microtubules. The widely different hydrolysis rates in these two sites result at least in part from the curved and straight tubulin assemblies in solution and in microtubules, respectively.     

Interrelationships of tubulin-GDP and tubulin-GTP in microtubule assembly

We previously reported that direct incorporation of GDP (i.e., without an initial hydrolysis of GTP) into microtubules occurs throughout an assembly cycle in a constant proportion. The exact proportion varied with reaction conditions, becoming greater under all conditions in which tubulin-GDP increased relative to tubulin-GTP (low Mg2+ and GTP concentrations, high tubulin concentrations, and in the presence of exogenous GDP). These findings led us to explore further interrelationships of tubulin-GDP and tubulin-GTP in microtubule assembly. We have now determined the minimum amount of tubulin-GTP required for the initiation of microtubule assembly and the relative efficiency with which tubulin-GDP participates in microtubule elongation. When GTP, GDP, and tubulin concentrations were varied at a constant Mg2+ concentration (0.2 mM), initiation of assembly required that 35% of the nucleotide-bearing tubulin be in the form of tubulin-GTP, and incorporation of tubulin-GDP into microtubules during elongation was only 60% as efficient as would be predicted on the basis of its proportional concentration in the reaction mixtures. Very different results were obtained when the Mg2+ concentration was varied. Even though Mg2+ enhances the binding of GTP to tubulin (the equilibrium constant for the exchange of GTP for GDP was 0.2 in the absence of exogenous Mg2+, 3 with 0.2 mM Mg2+, 5 with 0.5 mM Mg2+, and 11 with 2 and 4 mM Mg2+), as Mg2+ was increased the proportion of tubulin-GTP required for the initiation of microtubule assembly rose greatly, and the direct incorporation of tubulin-GDP into microtubules during elongation became progressively more efficient. In the absence of exogenous Mg2+, only 20% tubulin-GTP was required for initiation, and tubulin-GDP was directly incorporated into microtubules half as efficiently as would be predicted on the basis of its concentration in the reaction mixture. At the highest Mg2+ concentration examined (4 mM), 80% tubulin-GTP was required for initiation of assembly, and tubulin-GDP was incorporated into microtubules as efficiently as tubulin-GTP.     

Direct incorporation of microtubule oligomers at high GTP concentrations

Chick brain microtubule protein consists primarily of a mixture of MAP2:tubulin oligomers and dimeric tubulin. The assembly of this protein is described by a single pseudofirst-order reaction at 20 microM GTP, but by the summation of two pseudofirst-order reactions at 1 mM GTP. The protein contains two GTP-binding species, corresponding to the tubulin dimers and the oligomers, and conditions which alter the dimer: oligomer equilibrium, affect the kinetics of microtubule assembly. The results indicate that the oligomers are only direct assembly intermediates at high GTP concentrations.     

Some features of the vinblastine-induced assembly of porcine tubulin.

Porcine tubulin precipitated by 10^?3, m vinblastine (VLB) contains approximately 0.50 molecule of VLB bound per 110,000-molecular-weight tubulin dimer. The amount of precipitate, followed by turbidity, is a linear function of the initial tubulin concentration. The rate of precipitation is roughly first order in protein concentration. Vindoline and velbanamine halves of VLB are ineffective separately or together in producing the tubular aggregates observed for VLB precipitates by electron microscopy. At 10^?3, m concentrations no turbidity is observed nor is there any competition with VLB-induced turbidity. Removal of GTP from tubulin by dialysis or incubation of tubulin in the absence of added GTP blocks VLB-induced assembly. Readdition of GTP at room temperature or above restores sensitivity to VLB precipitation. The β,γ methylene analog of GTP cannot substitute for GTP in this process. About 0.7 mol of added GTP is found bound per mole of tubulin dimer. During the course of VLB-induced assembly, roughly half of this GTP is displaced. These results show interesting similarities and differences in the VLB-induced assembly of tubulin and the normal in vitro assembly of microtubules. Further comparisons between both assembly processes should be useful.     

Stathmin and Interfacial Microtubule Inhibitors Recognize a Naturally Curved Conformation of Tubulin Dimers

Tubulin is able to switch between a straight microtubule-like structure and a curved structure in complex with the stathmin-like domain of the RB3 protein (T₂RB3). GTP hydrolysis following microtubule assembly induces protofilament curvature and disassembly. The conformation of the labile tubulin heterodimers is unknown. One important question is whether free GDP-tubulin dimers are straightened by GTP binding or if GTP-tubulin is also curved and switches into a straight conformation upon assembly. We have obtained insight into the bending flexibility of tubulin by analyzing the interplay of tubulin-stathmin association with the binding of several small molecule inhibitors to the colchicine domain at the tubulin intradimer interface, combining structural and biochemical approaches. The crystal structures of T₂RB3 complexes with the chiral R and S isomers of ethyl-5-amino-2-methyl-1,2-dihydro-3-phenylpyrido[3,4-b]pyrazin-7-yl-carbamate, show that their binding site overlaps with colchicine ring A and that both complexes have the same curvature as unliganded T₂RB3. The binding of these ligands is incompatible with a straight tubulin structure in microtubules. Analytical ultracentrifugation and binding measurements show that tubulin-stathmin associations (T₂RB3, T₂Stath) and binding of ligands (R, S, TN-16, or the colchicine analogue MTC) are thermodynamically independent from one another, irrespective of tubulin being bound to GTP or GDP. The fact that the interfacial ligands bind equally well to tubulin dimers or stathmin complexes supports a bent conformation of the free tubulin dimers. It is tempting to speculate that stathmin evolved to recognize curved structures in unassembled and disassembling tubulin, thus regulating microtubule assembly.     

Guanine nucleotide-dependent assembly of FtsZ into filaments.

FtsZ is an essential cell division protein that is localized to the leading edge of the bacterial septum in a cytokinetic ring. It contains the tubulin signature motif and is a GTP binding protein with a GTPase activity. Further comparison of FtsZ with eukaryotic tubulins revealed some additional sequence similarities, perhaps indicating a similar GTP binding site. Examination of FtsZ incubated in vitro by electron microscopy revealed a guanine nucleotide-dependent assembly into protein filaments, supporting the hypothesis that the FtsZ ring is formed through self-assembly. FtsZ3, which is unable to bind GTP, does not polymerize, whereas FtsZ2, which binds GTP but is deficient in GTP hydrolysis, is capable of polymerization.     

Thermodynamics of the Op18/stathmin-tubulin interaction

Op18/stathmin (stathmin) is an intrinsically disordered protein involved in the regulation of the microtubule filament system. One function of stathmin is to sequester tubulin dimers into assembly incompetent complexes, and recent studies revealed two tubulin binding sites per stathmin molecule. Using high sensitivity isothermal titration calorimetry, we document that at 10 degrees C and under the conditions of 80 mM PIPES, pH 6.8, 1 mM EGTA, 1 mM MgCl2, 1 mM GTP these two binding sites are of equal affinity with an equilibrium binding constant of K0 = 6.0 x 10(6) m(-1). The obtained large negative molar heat capacity change of deltaCp0 = -860 cal mol(-1) K(-1) (referring to tubulin) for the tubulin-stathmin binding equilibrium suggests that the hydrophobic effect is the major driving force of the binding reaction. Replacing GTP by GDP on beta-tubulin had no significant effect on the thermodynamic parameters of the tubulin-stathmin binding equilibrium. The proposed pH-sensitive dual function of stathmin was further evaluated by circular dichroism spectroscopy and nuclear magnetic resonance. At low temperatures, stathmin was found to be extensively helical but devoid of any stable tertiary structure. However, in complex with two tubulin subunits stathmin adopts a stable conformation. Both the stability and conformation of the individual proteins and complexes were not significantly affected by small changes in pH. A 4-fold decrease in affinity of stathmin for tubulin was revealed at pH 7.5 compared with pH 6.8. This decrease could be attributed to a weaker binding of the C terminus of stathmin. These findings do not support the view that stathmin works as a pH-sensitive protein.     

Effect of tubulin self-association on GTP hydrolysis and nucleotide exchange reactions

We investigated how the self-association of isolated tubulin dimers affects the rate of GTP hydrolysis and the equilibrium of nucleotide exchange. Both reactions are relevant for microtubule (MT) dynamics. We used HPLC to determine the concentrations of GDP and GTP and thereby the GTPase activity of SEC-eluted tubulin dimers in assembly buffer solution, free of glycerol and tubulin aggregates. When GTP hydrolysis was negligible, the nucleotide exchange mechanism was studied by determining the concentrations of tubulin-free and tubulin-bound GTP and GDP. We observed no GTP hydrolysis below the critical conditions for MT assembly (either below the critical tubulin concentration and/or at low temperature), despite the assembly of tubulin 1D curved oligomers and single-rings, showing that their assembly did not involve GTP hydrolysis. Under conditions enabling spontaneous slow MT assembly, a slow pseudo-first-order GTP hydrolysis kinetics was detected, limited by the rate of MT assembly. Cryo-TEM images showed that GTP-tubulin 1D oligomers were curved also at 36 °C. Nucleotide exchange depended on the total tubulin concentration and the molar ratio between tubulin-free GDP and GTP. We used a thermodynamic model of isodesmic tubulin self-association, terminated by the formation of tubulin single-rings to determine the molar fractions of dimers with exposed and buried nucleotide exchangeable sites (E-sites). Our analysis shows that the GDP to GTP exchange reaction equilibrium constant was an order-of-magnitude larger for tubulin dimers with exposed E-sites than for assembled dimers with buried E-sites. This conclusion may have implications on the dynamics at the tip of the MT plus end.     

4',6-Diamidino-2-phenylindole, a fluorescent probe for tubulin and microtubules

A new fluorophor for tubulin which has permitted the monitoring of microtubule assembly in vitro is reported. DAPI (4',6-diamidino-2-phenylindole), a fluorophor already known as a DNA intercalator, was shown to bind specifically to a unique tubulin site as a dimer (KD(app) = 43 +/- 5 microM at 37 degrees C) or to tubulin associated in microtubules (KD(app) = 6 +/- 2 microM at 37 degrees C) with the same maximum enhancement in fluorescence. When tubulin polymerization was induced with GTP, the change in DAPI affinity for tubulin resulted in an enhancement of DAPI binding and, consequently, of fluorescence intensity. DAPI, whose binding site is different from that of colchicine, vinblastine, or taxol, did not interfere greatly with microtubule polymerization. It induced a slight diminution of the critical concentration for tubulin assembly due to a decrease in the depolymerizing rate constant. Moreover, DAPI did not interfere with GTP hydrolysis correlated with tubulin polymerization, but it decreased the GTPase activity at the steady state of tubulin assembly. Even at substoichiometric levels DAPI can be used to follow the kinetics of microtubule assembly.     

Guanosine 5'-O-(3-thiotriphosphate), a potent nucleotide inhibitor of microtubule assembly

Guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S) and the two diastereoisomers of guanosine 5'-O-(2-thiotriphosphate) (GTP beta S) were prepared enzymatically, and their interactions with tubulin and microtubule-associated proteins (MAPs) in 0.1 M 2-(N-morpholino)ethanesulfonate, 0.5 mM MgCl2 were examined. GTP gamma S did not support microtubule assembly but instead inhibited the reaction. This analog was 1.5-2 times more potent than GDP in inhibiting both tubulin polymerization and GTP hydrolysis under conditions in which these reactions were dependent on MAPs. In contrast to the analog's inhibitory effects on polymerization and hydrolysis, however, radiolabeled GTP gamma S was only feebly bound by purified tubulin at 0 degrees C relative to the binding of GDP and GTP. There was a marked increase in the amount of GTP gamma S bound when the reaction temperature was raised to 37 degrees C or when MAPs were included in the reaction mixture. Only when both MAPs were present and the higher reaction temperature was used did the binding of GTP gamma S exceed that of GDP. Since substitution of sulfur for oxygen in a molecule should decrease its hydrophilic properties, these findings suggest that the exchangeable nucleotide binding site of tubulin becomes more hydrophobic at higher temperatures and in the presence of MAPs. The two isomers of GTP beta S were able to support MAP-dependent polymerization, although a 50-100-fold higher concentration of the analogs as compared to GTP was required. Neither isomer of GTP beta S had a significant inhibitory effect on GTP hydrolysis dependent on tubulin + MAPs.