Ankyrin and synapsin: spectrin-binding proteins associated with brain membranes

Brain membranes contain an actin-binding protein closely related in structure and function to erythrocyte spectrin. The proteins that attach brain spectrin to membranes are not established, but, by analogy with the erythrocyte membrane, may include ankyrin and protein 4.1. In support of this idea, proteins closely related to ankyrin and 4.1 have been purified from brain and have been demonstrated to associate with brain spectrin. Brain ankyrin binds with high affinity to the spectrin beta subunit at the midregion of spectrin tetramers. Brain ankyrin also has binding sites for the cytoplasmic domain of the erythrocyte anion channel (band 3), as well as for tubulin. Ankyrins from brain and erythrocytes have a similar domain structure with protease-resistant domains of Mr = 72,000 that contain spectrin-binding activity, and domains of Mr = 95,000 (brain ankyrin) or 90,000 (erythrocyte ankyrin) that contain binding sites for both tubulin and the anion channel. Brain ankyrin is present at about 100 pmol/mg membrane protein, or about twice the number of copies of spectrum beta chains. Brain ankyrin thus is present in sufficient amounts to attach spectrin to membranes, and it has the potential to attach microtubules to membranes as well as to interconnect microtubules with spectrin-associated actin filaments. Another spectrin-binding protein has been purified from brain membranes, and this protein cross-reacts with erythrocyte 4.1. Brain 4.1 is identical to the membrane protein synapsin, which is one of the brain's major substrates for cAMP-dependent and Ca/calmodulin-dependent protein kinases with equivalent physical properties, immunological cross-reaction, and peptide maps. Synapsin (4.1) is present at about 60 pmol/mg membrane protein, and thus is a logical candidate to regulate certain protein linkages involving spectrin.     

Tubulin exchanges divalent cations at both guanine nucleotide-binding sites

The tubulin heterodimer binds a molecule of GTP at the nonexchangeable nucleotide-binding site (N-site) and either GDP or GTP at the exchangeable nucleotide-binding site (E-site). Mg2+ is known to be tightly linked to the binding of GTP at the E-site (Correia, J. J., Baty, L. T., and Williams, R. C., Jr. (1987) J. Biol. Chem. 262, 17278-17284). Measurements of the exchange of Mn2+ for bound Mg2+ (as monitored by atomic absorption and EPR) demonstrate that tubulin which has GDP at the E-site possesses one high affinity metal-binding site and that tubulin which has GTP at the E-site possesses two such sites. The apparent association constants are 0.7-1.1 x 10(6) M-1 for Mg2+ and approximately 4.1-4.9 x 10(7) M-1 for Mn2+. Divalent cations do bind to GDP at the E-site, but with much lower affinity (2.0-2.3 x 10(3) M-1 for Mg2+ and 3.9-6.6 x 10(3) M-1 for Mn2+). These data suggest that divalent cations are involved in GTP binding to both the N- and E-sites of tubulin. The N-site metal exchanges slowly (kapp = 0.020 min-1), suggesting a mechanism involving protein "breathing" or heterodimer dissociation. The N-site metal exchange rate is independent of the concentration of protein and metal, an observation consistent with the possibility that a dynamic breathing process is the rate-limiting step. The exchange of Mn2+ for Mg2+ has no effect on the secondary structure of tubulin at 4 degrees C or on the ability of tubulin to form microtubules. These results have important consequences for the interpretation of distance measurements within the tubulin dimer using paramagnetic ions. They are also relevant to the detailed mechanism of divalent cation release from microtubules after GTP hydrolysis.     

Tubulin-G protein interactions involve microtubule polymerization domains

It has been suggested that elements of the cytoskeleton contribute to the signal transduction process and that they do so in association with one or more members of the signal-transducing G protein family. Relatively high-affinity binding between dimeric tubulin and the alpha subunits of Gs and Gi1 has also been reported. Tubulin molecules, which exist in solution as alpha beta dimers, have binding domains for microtubule-associated proteins as well as for other tubulin dimers. This study represents an attempt to ascertain whether the association between G proteins and tubulin occurs at one of these sites. Removal of the binding site for MAP2 and tau from tubulin by subtilisin proteolysis did not influence the association of tubulin with G protein, as demonstrated in overlay studies with [125I]tubulin. A functional consequence of that association, the stable inhibition of synaptic membrane adenylyl cyclase, was also unaffected by subtilisin treatment of tubulin. However, ring structures formed from subtilisin-treated tubulin were incapable of effecting such inhibition. Stable G protein-tubulin complexes were formed, and these were separated from free tubulin by Octyl-Sepharose chromatography. Using this methodology, it was demonstrated that assembled microtubules bound G protein quite weakly compared with tubulin dimers. The alpha subunit of Gi1 and, to a lesser extent, that of Go were demonstrated to inhibit microtubule polymerization. In aggregate, these data suggest that dimeric tubulin binds to the alpha subunits of G protein at the sites where it binds to other tubulin dimers during microtubule polymerization. Interaction with signal-transducing G proteins, thus, might represent a role for tubulin dimers which is independent of microtubule formation.     

A molecular and structural mechanism for G protein-mediated microtubule destabilization

The heterotrimeric, G protein-coupled receptor-associated G protein, Gα(s), binds tubulin with nanomolar affinity and disrupts microtubules in cells and in vitro. Here we determine that the activated form of Gα(s) binds tubulin with a K(D) of 100 nm, stimulates tubulin GTPase, and promotes microtubule dynamic instability. Moreover, the data reveal that the α3-β5 region of Gα(s) is a functionally important motif in the Gα(s)-mediated microtubule destabilization. Indeed, peptides corresponding to that region of Gα(s) mimic Gα(s) protein in activating tubulin GTPase and increase microtubule dynamic instability. We have identified specific mutations in peptides or proteins that interfere with this process. The data allow for a model of the Gα(s)/tubulin interface in which Gα(s) binds to the microtubule plus-end and activates the intrinsic tubulin GTPase. This model illuminates both the role of tubulin as an "effector" (e.g. adenylyl cyclase) for Gα(s) and the role of Gα(s) as a GTPase activator for tubulin. Given the ability of Gα(s) to translocate intracellularly in response to agonist activation, Gα(s) may play a role in hormone- or neurotransmitter-induced regulation of cellular morphology.     

4.1R proteins associate with interphase microtubules in human T cells: a 4.1R constitutive region is involved in tubulin binding

Red blood cell protein 4.1 (4.1R) is an 80-kDa protein that stabilizes the spectrin-actin network and anchors it to the plasma membrane. To contribute to the characterization of functional roles and partners of specific nonerythroid 4.1R isoforms, we analyzed 4.1R in human T cells and found that endogenous 4.1R was distributed to the microtubule network. Transfection experiments of T cell 4.1R cDNAs in conjunction with confocal microscopy analysis revealed the colocalization of exogenous 4.1R isoforms with the tubulin skeleton. Biochemical analyses using Taxol (paclitaxel)-polymerized microtubules from stably transfected T cells confirmed the association of the exogenous 4.1R proteins with microtubules. Consistent with this, endogenous 4.1R immunoreactive proteins were also detected in the microtubule-containing fraction. In vitro binding assays using glutathione S-transferase-4.1R fusion proteins showed that a constitutive domain of the 4.1R molecule, one that is therefore present in all 4.1R isoforms, is responsible for the association with tubulin. A 22-amino acid sequence comprised in this domain and containing heptad repeats of leucine residues was essential for tubulin binding. Furthermore, ectopic expression of 4.1R in COS-7 cells provoked microtubule disorganization. Our results suggest an involvement of 4.1R in interphase microtubule architecture and support the hypothesis that some 4.1R functional activities are cell type-regulated.     

Protein 4.1R, a microtubule-associated protein involved in microtubule aster assembly in mammalian mitotic extract

Non-erythroid protein 4.1R (4.1R) consists of a complex family of isoforms. We have shown that 4.1R isoforms localize at the mitotic spindle/spindle poles and associate in a complex with the mitotic-spindle organization proteins Nuclear Mitotic Apparatus protein (NuMA), dynein, and dynactin. We addressed the mitotic function of 4.1R by investigating its association with microtubules, the main component of the mitotic spindles, and its role in mitotic aster assembly in vitro. 4.1R appears to partially co-localize with microtubules throughout the mitotic stages of the cell cycle. In vitro sedimentation assays showed that 4.1R isoforms directly interact with microtubules. Glutathione S-transferase (GST) pull-down assays using GST-4.1R fusions and mitotic cell extracts further showed that the association of 4.1R with tubulin results from both the membrane-binding domain and C-terminal domain of 4.1R. Moreover, 4.1R, but not actin, is a mitotic microtubule-associated protein; 4.1R associates with microtubules in the microtubule pellet of the mitotic asters assembled in mammalian cell-free mitotic extract. The organization of microtubules into asters depends on 4.1R in that immunodepletion of 4.1R from the extract resulted in randomly dispersed microtubules. Furthermore, adding a 135-kDa recombinant 4.1R reconstituted the mitotic asters. Finally, we demonstrated that a mitotic 4.1R isoform appears to form a complex in vivo with tubulin and NuMA in highly synchronized mitotic HeLa extracts. Our results suggest that a 135-kDa non-erythroid 4.1R is important to cell division, because it participates in the formation of mitotic spindles and spindle poles through its interaction with mitotic microtubules.     

Direct interaction between prion protein and tubulin

Recently published data show that the prion protein in its cellular form (PrP(C)) is a component of multimolecular complexes. In this report, zero-length cross-linking with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) allowed us to identify tubulin as one of the molecules interacting with PrP(C) in complexes observed in porcine brain extracts. We found that porcine brain tubulin added to these extracts can be cross-linked with PrP(C). Moreover, we observed that the 34 kDa species identified previously as full-length diglycosylated prion protein co-purifies with tubulin. Cross-linking of PrP(C) species separated by Cu(2+)-loaded immobilized metal affinity chromatography confirmed that only the full-length protein but not the N-terminally truncated form (C1) binds to tubulin. By means of EDC cross-linking and cosedimentation experiments, we also demonstrated a direct interaction of recombinant human PrP (rPrP) with tubulin. The stoichiometry of cosedimentation implies that rPrP molecules are able to bind both the alpha- and beta-isoforms of tubulin composing microtubule. Furthermore, prion protein exhibits higher affinity for microtubules than for unpolymerized tubulin.     

A porcine brain protein (35 K protein) which bundles microtubules and its identification as glyceraldehyde 3-phosphate dehydrogenase

A protein which binds to both tubulin and tubulin polymer was isolated from porcine brains. This protein has a molecular weight of 35,000 on SDS-polyacrylamide gel electrophoresis (designated as 35 K protein). The 35 K protein was purified through several steps of purification including ammonium sulfate fractionation, Sephadex G-100 gel filtration column chromatography, microtubule protein-agarose gel affinity column chromatography and phosphocellulose column chromatography. The 35 K protein caused pronounced enhancement of the turbidity increase produced by tubulin polymerization in the presence of DMSO, but did not have the ability to initiate polymerization of pure tubulin in the absence of DMSO. It was demonstrated that 35 K protein co-sediments with tubulin polymer in a concentration-dependent manner. Electron microscopic observation revealed the formation of bundles of tubulin polymer. Since the effect of 35 K protein was coupled with tubulin polymerization, 35 K protein did not cause the turbidity increase under conditions where tubulin polymerization was inhibited by Ca2+ or colchicine. The 35 K protein adsorbed on tubulin-Sepharose 4B was eluted by the addition of 2 mM ATP. ATP was shown to inhibit the interaction of 35 K protein with tubulin dimer or polymer. The 35 K protein was finally identified as glyceraldehyde 3-phosphate dehydrogenase from properties such as mobility on SDS-polyacrylamide gel electrophoresis, cleavage pattern on limited proteolysis, ability to bind to tubulin, and so on.     

The 93-kDa glycine receptor-associated protein binds to tubulin.

A peripheral membrane protein with a relative molecular mass of 93,000 Da is associated with cytoplasmic domains of the inhibitory glycine receptor of mammalian spinal cord. Here, evidence is given that this 93-kDa protein binds to polymerized tubulin. First, tubulin cofractionated with the 93-kDa protein upon affinity purification of the glycine receptor. Second, tubulin bound to the isolated 93-kDa protein in an overlay procedure. Third, in assays containing the purified glycine receptor, the 93-kDa protein as well as the glycine receptor alpha and beta subunits coassembled with tubulin and microtubules. The interaction of the 93-kDa protein with tubulin displayed high affinity (KD approximately 2.5 nM) and significant cooperativity (Hill coefficient approximately 2.1) and approached a stoichiometry of approximately 1:4 under saturating conditions. These data suggest that the 93-kDa protein anchors the glycine receptor at postsynaptic sites via binding to subsynaptic tubulin.     

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.     

Tubulin Binds to the Cytoplasmic Loop of TRESK Background K+ Channel In Vitro

The cytoplasmic loop between the second and third transmembrane segments is pivotal in the regulation of TRESK (TWIK-related spinal cord K⁺ channel, K2P18.1, KCNK18). Calcineurin binds to this region and activates the channel by dephosphorylation in response to the calcium signal. Phosphorylation-dependent anchorage of 14-3-3 adaptor protein also modulates TRESK at this location. In the present study, we identified molecular interacting partners of the intracellular loop. By an affinity chromatography approach using the cytoplasmic loop as bait, we have verified the specific association of calcineurin and 14-3-3 to the channel. In addition to these known interacting proteins, we observed substantial binding of tubulin to the intracellular loop. Successive truncation of the polypeptide and pull-down experiments from mouse brain cytosol narrowed down the region sufficient for the binding of tubulin to a 16 amino acid sequence: LVLGRLSYSIISNLDE. The first six residues of this sequence are similar to the previously reported tubulin-binding region of P2X2 purinergic receptor. The tubulin-binding site of TRESK is located close to the protein kinase A (PKA)-dependent 14-3-3-docking motif of the channel. We provide experimental evidence suggesting that 14-3-3 competes with tubulin for the binding to the cytoplasmic loop of TRESK. It is intriguing that the 16 amino acid tubulin-binding sequence includes the serines, which were previously shown to be phosphorylated by microtubule-affinity regulating kinases (MARK kinases) and contribute to channel inhibition. Although tubulin binds to TRESK in vitro, it remains to be established whether the two proteins also interact in the living cell.     

Tau induces ring and microtubule formation from alphabeta-tubulin dimers under nonassembly conditions

Tau is a neuronal microtubule-associated protein that plays a central role in many cellular processes, both physiological and pathological, such as axons stabilization and Alzheimer's disease. Despite extensive studies, very little is known about the detailed molecular basis of tau binding to microtubules. We used the four-repeat recombinant htau40 and tubulin dimers to show for the first time that tau is able to induce both microtubule and ring formation from 6S alphabeta tubulin in phosphate buffer without added magnesium (nonassembly conditions). The amount of microtubules or rings formed was protein concentration-, temperature-, and nucleotide-dependent. By means of biophysical approaches, we showed that tau binds to tubulin without global-folding change, detectable by circular dichroism. We also demonstrated that the tau-tubulin interaction follows a ligand-mediated elongation process, with two tau-binding site per tubulin dimer. Moreover, using a tubulin recombinant alpha-tubulin C-terminal fragment (404-451) and a beta-tubulin C-terminal fragment (394-445), we demonstrated the involvement of both of these tubulin regions in tau binding. From this model system, we gain new insight into the mechanisms by which tau binds to tubulin and induces microtubule formation.     

Mitotic regulation of protein 4.1R involves phosphorylation by cdc2 kinase

The nonerythrocyte isoform of the cytoskeletal protein 4.1R (4.1R) is associated with morphologically dynamic structures during cell division and has been implicated in mitotic spindle function. In this study, we define important 4.1R isoforms expressed in interphase and mitotic cells by RT-PCR and mini-cDNA library construction. Moreover, we show that 4.1R is phosphorylated by p34cdc2 kinase on residues Thr60 and Ser679 in a mitosis-specific manner. Phosphorylated 4.1R135 isoform(s) associate with tubulin and Nuclear Mitotic Apparatus protein (NuMA) in intact HeLa cells in vivo as well as with the microtubule-associated proteins in mitotic asters assembled in vitro. Recombinant 4.1R135 is readily phosphorylated in mitotic extracts and reconstitutes mitotic aster assemblies in 4.1R-immunodepleted extracts in vitro. Furthermore, phosphorylation of these residues appears to be essential for the targeting of 4.1R to the spindle poles and for mitotic microtubule aster assembly in vitro. Phosphorylation of 4.1R also enhances its association with NuMA and tubulin. Finally, we used siRNA inhibition to deplete 4.1R from HeLa cells and provide the first direct genetic evidence that 4.1R is required to efficiently focus mitotic spindle poles. Thus, we suggest that 4.1R is a member of the suite of direct cdc2 substrates that are required for the establishment of a bipolar spindle.     

Fluorescence energy transfer measurement of distances between ligand binding sites of tubulin and its implication for protein-protein interaction.

9-(Dicyanovinyl) julolidine (DCVJ) is a fluorescent probe, which binds to a unique site on the tubulin dimer and exhibits different properties that are dependent upon its oligomeric state (Kung & Reed, 1989). DCVJ binds to tubulin, the tubulin-colchicine complex, and the tubulin-ruthenium red complex equally well, but binds tighter to the ANS-tubulin complex than to tubulin alone. The energy transfer studies indicate a small amount of energy transfer with colchicine, but a significant energy transfer with ANS. It was shown previously that ruthenium red binds near the C-terminal tail region of the alpha-subunit. Ruthenium red causes major quenching of fluorescence of the tubulin-DCVJ complex, suggesting proximity of binding sites. The derived distances are consistent with DCVJ binding near the alpha beta interface, but on the opposite face of the colchicine binding site. Location of the binding site correlates with the observed effect of a different polymerized state of tubulin on the DCVJ spectroscopic properties. The effect of dimer-dimer association on DCVJ binding, at high protein concentrations (Kung & Reed, 1989), suggests that such an association may occur through lateral contacts of the elongated tubulin dimer, at least in a significant fraction of the cases. Transmission of ANS-induced conformational change to the DCVJ binding site, which is near important dimer-dimer contact sites, makes it possible that such conformational changes may be responsible for polymerization inhibition by anilino-naphthalene sulfonates.     

Glyceraldehyde-3-phosphate dehydrogenase is a microtubule binding protein in a human colon tumor cell line

A protein which binds to tubulin polymer was isolated from a human colonic tumor cell line. This protein has a molecular mass of 35 kDa, as determined by polyacrylamide slab gel electrophoresis. The protein was purified by affinity chromatography on taxol-stabilized microtubules, and it did not cross-react with anti-MAP2 or anti-tau antibodies. This protein was identified as glyceraldehyde-3-phosphate dehydrogenase by its enzyme activity and immunoblotting experiments. The purified protein caused a pronounced enhancement in the turbidity increase produced by in vitro tubulin polymerization, and electron microscopic observations revealed the presence of bundles of microtubules.     

Colchicine binding to an oligomer of tubulin

An oligomeric form of tubulin present in microtubule protein prepared from mammalian brain, the 36S double ring containing tau protein, is reported to bind colchicine. Colchicine binds to each individual 6S tubulin subunit in the 36S ring without apparent effect on quarternary structure. The colchicine-oligomer complex forms by colchicine binding directly to the tubulin ring; alternatively, complexes formed by colchicine with 6S tubulin subunits associate in the presence of tau protein to form the colchicine-oligomer complex.     

Tau – an inhibitor of deacetylase HDAC6 function

Analysis of brain microtubule protein from patients with Alzheimer's disease showed decreased alpha tubulin levels along with increased acetylation of the alpha tubulin subunit, mainly in those microtubules from neurons containing neurofibrillary tau pathology. To determine the relationship of tau protein and increased tubulin acetylation, we studied the effect of tau on the acetylation-deacetylation of tubulin. Our results indicate that tau binds to the tubulin-deacetylase, histone deacetylase 6 (HDAC6), decreasing its activity with a consequent increase in tubulin acetylation. As expected, increased acetylation was also found in tubulin from wild-type mice compared with tubulin from mice lacking tau because of the tau-mediated inhibition of the deacetylase. In addition, we found that an excess of tau protein, as a HDAC6 inhibitor, prevents induction of autophagy by inhibiting proteasome function.     

Isolation of a tubulin-like protein from Phaseolus

Colchicine binds to a protein fraction isolated from Phaseolus aureus. A protein with characteristics similar to calf brain tubulin, in terms of its MW, elution properties from DEAE cellulose, precipitation by Ca²⁺ ions and Chlorpromazine was detected in whole cell supernatants. This protein consisted of two monomeric subunits with MWs of 56000 and 53000. This protein, tentatively identified as tubulin, was compared by cyanogen bromide peptide mapping with calf brain tubulin.     

The carboxy-terminus of protein 4.1r resembles Beta-tubulin

The protein 4.1R is an isoform of a larger family of 4.1 proteins. It is known as a component of the plasma membrane skeleton, but it is also found at the centrosomes in interphase and mitosis. To investigate the properties of the carboxy terminal region of protein 4.1R, we raised antibodies against a peptide representing the last 14 amino acids of 4.1R. These antibodies crossreact with an epitope in beta-tubulin and stain the microtubule network by immunofluorescence. Furthermore, sequence comparison of the carboxy terminal 4.1R peptide sequence with tubulin reveals homology with a region at the end of helix 5 in beta-tubulin, but not alpha-tubulin. A potential function of the 4.1R carboxy terminus in regulating the formation of microtubule networks is discussed.     

Aging of tubulin at neutral pH: the destabilizing effect of vinca alkaloids.

The effect of the vinca alkaloid drugs, vincristine, vinblastine, catharanthine, and vindoline, on the aging process of tubulin has been examined. It was found that addition of vincristine or vinblastine accelerated by a factor of 3-3.5 the transformation of tubulin from the 5.8 S alpha-beta-tubulin dimer to paucidisperse polymers, with an average sedimentation coefficient of 9 S, previously observed in the absence of drugs (V. Prakash and S. N. Timasheff, 1982, J. Mol. Biol. 160, 499-515). This transformation of tubulin from 5.8 S to "9 S" followed pseudo-first-order kinetics whether the starting protein was predominantly dimeric (i.e., at low drug concentration) or self-associated into the reversible linear polymers induced by the vinca alkaloid drugs at high drug concentration (G. C. Na and S. N. Timasheff, 1980, Biochemistry 19, 1355-1365; V. Prakash and S. N. Timasheff, 1985, Biochemistry 24, 5004-5010). Identical kinetics were found in a fluorescence examination of the loss by tubulin of its ability to bind colchicine specifically, indicating that the rate determining step is a protein conformational change that induces a major change in the far uv circular dichroism spectrum of tubulin. The found lack of an effect of dithiothreitol on the aging and aggregation processes is consistent with the irreversible aggregation being due to the intermolecular coalescence of nonpolar patches on the protein. The observations that vincristine binds to aged tubulin and that the aging of tubulin is accompanied by quenching of the tryptophan fluorescence similar to that which occurs on the binding of the vinca drugs has led to the proposal that the vinca alkaloids stabilize the aged conformation of the protein by interacting with nonpolar regions that may be related to the aggregation sites.