Distribution and characteristics of betaII tubulin-enriched microtubules in interphase cells

We have used a polyclonal antibody (Ab196) that specifically recognizes the betaII tubulin isotype to examine the subcellular distribution and properties of microtubules enriched in this isotype. Antibody specificity was tested by a method that involves the analysis of its interaction with individual beta isotypes. Using photoimaging analysis, we observed betaII tubulin-enriched microtubules in the perinuclear region, as well as in the microtubules close to the periphery of interphase cells. The observed sorting of betaII-enriched microtubules together with the reported increased levels of betaII tubulin in taxol-resistant cells (M. Haber et al., 1995, J. Biol. Chem. 270, 31269-31275) prompted us to study the behavior of microtubules enriched in this isotype after different depolymerizing treatments. After cold or nocodazol treatments, betaII-enriched microtubules anchored at the centrosome and at the cell periphery were observed. In addition, cold-resistant microtubules were marked mainly by the specific anti-betaII tubulin antibody but not by anti-acetylated alpha tubulin, suggesting the presence of different stable microtubule subsets enriched in particular tubulin isoforms.     

Differential sorting of beta tubulin isotypes into colchicine-stable microtubules during neuronal and muscle differentiation of embryonal carcinoma cells.

Pluripotent P19 embryonal carcinoma (EC) cells were differentiated along the neuronal and muscle pathways. Comparisons of class I, II, III, and IV beta tubulin isotypes in total and colchicine-stable microtubule (MT) arrays from uncommitted EC, neuronal, and muscle cells were made by immunoblotting and by indirect immunofluorescence microscopy. In undifferentiated EC cells the relative amounts of these four isotypes are the same in both the total and stable MT populations. Subcellular sorting of beta tubulin isotypes was demonstrated in both neuronal and muscle differentiated cells. During neuronal differentiation, class II beta tubulin is preferentially incorporated into the colchicine-stable MTs while class III beta tubulin is preferentially found in the colchicine-labile MTs. The subcellular sorting of class II into stable MTs correlates with the increased staining of MAP 1B, and with the expression of MAP 2C and tau. Although muscle differentiated cells express class II beta tubulin, stable MTs in these cells do not preferentially incorporate this isotype but instead show increased incorporation of class IV beta tubulin. Muscle cells do not show high levels of MAP 1B and do not express MAP 2C or tau. These results are consistent with the hypothesis that a subcellular sorting of tubulin isotypes is the result of a complex interaction between tubulin isotypes and MT-associated proteins.     

MAP2 and tau bind longitudinally along the outer ridges of microtubule protofilaments

MAP2 and tau exhibit microtubule-stabilizing activities that are implicated in the development and maintenance of neuronal axons and dendrites. The proteins share a homologous COOH-terminal domain, composed of three or four microtubule binding repeats separated by inter-repeats (IRs). To investigate how MAP2 and tau stabilize microtubules, we calculated 3D maps of microtubules fully decorated with MAP2c or tau using cryo-EM and helical image analysis. Comparing these maps with an undecorated microtubule map revealed additional densities along protofilament ridges on the microtubule exterior, indicating that MAP2c and tau form an ordered structure when they bind microtubules. Localization of undecagold attached to the second IR of MAP2c showed that IRs also lie along the ridges, not between protofilaments. The densities attributable to the microtubule-associated proteins lie in close proximity to helices 11 and 12 and the COOH terminus of tubulin. Our data further suggest that the evolutionarily maintained differences observed in the repeat domain may be important for the specific targeting of different repeats to either alpha or beta tubulin. These results provide strong evidence suggesting that MAP2c and tau stabilize microtubules by binding along individual protofilaments, possibly by bridging the tubulin interfaces.     

Expression of cold-adapted beta-tubulins confer cold-tolerance to human cellular microtubules

Isolated microtubule proteins from the cold-adapted fish, Atlantic cod (Gadus morhua), assemble at temperatures between 8 and 30 degrees C, while avian and mammalian microtubules normally do not assemble at temperatures below 20 degrees C. Tubulin, the main component in microtubules, is expressed as many isotypes. Microtubules with different isotype composition have been shown to have different dynamic properties in vitro. Our hypothesis was that cold-tolerance of microtubules is caused by tubulin isotypes that differ in the primary sequence compared to mammalian tubulins. Here we show that transfection of human HepG2 cells with cod beta-tubulin induced cold-adaptation of the endogenous microtubules. Incorporation of one single tubulin isotype can induce cold-tolerance to cold-intolerant microtubules. Three cod beta-tubulin isotypes were tested and two of these (beta1 and beta2) transferred cold-tolerance to HepG2 microtubules, thus not all cod beta-tubulins were able to confer cold-stability.     

Distinct colchicine binding kinetics of bovine brain tubulin lacking the type III isotype of beta-tubulin

In mammalian brain, beta-tubulin occurs as a mixture of four isotypes designated as types I, II, III, and IV. It has been speculated in recent years that the different tubulin isotypes may confer functional diversity to microtubules. In an effort to investigate whether different tubulin isotypes differ in their functional properties we have studied the colchicine binding kinetics of bovine brain tubulin upon removal of the beta III isotype. We found that the removal of the beta III isotype alters the binding kinetics from biphasic to monophasic with the disappearance of the slow phase. The kinetics become biphasic with the reappearance of the slow phase when the beta III-depleted tubulin was mixed with the beta III fraction eluted from the affinity column with 0.5 M NaCl. The analysis of the kinetic data reveals that the tubulin dimers containing beta III bind colchicine at an on-rate constant of 35 M-1 s-1 while those lacking beta III bind at 182 M-1 s-1. Our results strongly suggest that the beta-subunit plays a very important role in the interaction of tubulin with colchicine.     

Tubulin isotypes and their interaction with microtubule associated proteins

Summary To assay the functional significance of the multiple but closely related - and -tubulin polypeptides (termed isotypes) that are expressed in mammalian cells, we have generated a number of sera that uniquely discriminate among these isotypes. These sera have been used to demonstrate that there is no subcellular sorting of either - or -tubulin isotypes among microtubules of diverse function, either in cells growing in culture or in tissues consisting of cell types that contain specialized kinds of microtubule. In spite of this failure to segregate between functionally distinct kinds of microtubule, the fact that isotype-specific amino acid sequences have been strictly conserved over extensive periods of evolutionary time argues persuasively for a functional role for the different tubulin gene products. One possibility is that they are required for specific interactions with microtubule associated proteins (MAPs), and that tubulin isotypes have coevolved with different cell type-specific MAPs with which they must interact. We have tested this hypothesis by examining the distribution of -tubulin isotypes in mammalian cerebellum in relationship to the known patterns of expression of a number of MAPs, and find that these patterns correlate in the case of M 2 and MAP 3, and M 6 and MAP 1 a. These data, plus emerging data based on a structural analysis of tau, MAP 1 b and MAP 2 obtained via sequence determination of cloned cDNAs, are discussed in terms of the possible functional significance of tubulin isotype/MAP interactionsin vivo.     

Localization of betav tubulin in the cochlea and cultured cells with a novel monoclonal antibody

Tubulin, the dimeric structural protein of microtubules, is a heterodimer of alpha and beta subunits; both alpha and beta exist as numerous isotypes encoded by different genes. In vertebrates the sequence differences among the beta(I), beta(II), beta(III), beta(IV) and beta(V) isotypes are highly conserved in evolution, implying that the isotypes may have functional significance. Isotype-specific monoclonal antibodies have been useful in determining the cellular and sub-cellular distributions and possible functions of the beta(I), beta(II), beta(III), and beta(IV) isotypes; however, little is known about the beta(V) isotype. We here report the creation and purification of a monoclonal antibody (SHM.12G11) specific for beta(V). The antibody was designed to be specific for the C-terminal sequence EEEINE, which is unique to rodent and chicken beta(V). The antibody was found to bind specifically to the C-terminal peptide EEEINE, and does not cross-react with the carboxy-termini of either alpha-tubulin or the other beta-tubulin isotypes. However, the antibody also binds to the peptide EEEVNE, but not to the peptide EEEIDG, corresponding respectively to the C-terminal peptides of bovine and human beta(V). Immunofluorescence analysis indicates that beta(V) is found in microtubules of both the interphase network and the mitotic spindle. In gerbils, beta(V) also occurs in the cochlea where it is found largely in the specialized cells that are unique in containing bundled microtubules with 15 protofilaments.     

A ubiquitous beta-tubulin disrupts microtubule assembly and inhibits cell proliferation

Vertebrate tubulin is encoded by a multigene family that produces distinct gene products, or isotypes, of both the alpha- and beta-tubulin subunits. The isotype sequences are conserved across species supporting the hypothesis that different isotypes subserve different functions. To date, however, most studies have demonstrated that tubulin isotypes are freely interchangeable and coassemble into all classes of microtubules. We now report that, in contrast to other isotypes, overexpression of a mouse class V beta-tubulin cDNA in mammalian cells produces a strong, dose-dependent disruption of microtubule organization, increased microtubule fragmentation, and a concomitant reduction in cellular microtubule polymer levels. These changes also disrupt mitotic spindle assembly and block cell proliferation. Consistent with diminished microtubule assembly, there is an increased tolerance for the microtubule stabilizing drug, paclitaxel, which is able to reverse many of the effects of class V beta-tubulin overexpression. Moreover, transfected cells selected in paclitaxel exhibit increased expression of class V beta-tubulin, indicating that this isotype is responsible for the drug resistance. The results show that class V beta-tubulin is functionally distinct from other tubulin isotypes and imparts unique properties on the microtubules into which it incorporates.     

A monoclonal antibody against the type II isotype of beta-tubulin. Preparation of isotypically altered tubulin

Mammalian brain tubulin consists of several isotypes of alpha and beta subunits that separate on polyacrylamide gels into three electrophoretic classes, designated alpha, beta 1, and beta 2. It has not been possible hitherto to resolve the different isotypes in a functional form. To this end, we have now isolated a monoclonal antibody, using as an immunogen a chemically synthesized peptide corresponding to the carboxyl-terminal sequence of the major tubulin isotype (type II) found in the beta 1-tubulin electrophoretic fraction. The antibody binds to beta 1 but not to alpha or beta 2. When pure tubulin from bovine brain is passed through an immunoaffinity column made from the anti-type II antibody, the tubulin that elutes in the unbound fraction is enriched greatly for the beta 2 electrophoretic variant. The tubulin that binds to the column appears to contain only alpha and beta 1, not beta 2. When these tubulin fractions are characterized by immunoblotting using the anti-type II antibody, the antibody binds only to the beta 1 band in the bound fraction, not to the beta 1 band in the unbound fraction. Using polyclonal antibodies generated against the carboxyl-termini of types I, III, and IV, we demonstrate that the beta 1 electrophoretic species is comprised of isotypes I, II, and IV, whereas the beta 2 variant is comprised exclusively of type III beta-tubulin. Further, we calculate that beta-tubulin in purified bovine brain tubulin is comprised of 3% type I, 58% type II, 25% type III, and 13% type IV tubulins.     

Microtubule assembly of isotypically purified tubulin and its mixtures

Numerous isotypes of the structural protein tubulin have now been characterized in various organisms and their expression offers a plausible explanation for observed differences affecting microtubule function in vivo. While this is an attractive hypothesis, there are only a handful of studies demonstrating a direct influence of tubulin isotype composition on the dynamic properties of microtubules. Here, we present the results of experimental assays on the assembly of microtubules from bovine brain tubulin using purified isotypes at various controlled relative concentrations. A novel data analysis is developed using recursive maps which are shown to be related to the master equation formalism. We have found striking similarities between the three isotypes of bovine tubulin studied in regard to their dynamic instability properties, except for subtle differences in their catastrophe frequencies. When mixtures of tubulin isotypes are analyzed, their nonlinear concentration dependence is modeled and interpreted in terms of lower affinities of tubulin dimers belonging to the same isotype than those that represent different isotypes indicating hitherto unsuspected influences of tubulin dimers on each other within a microtubule. Finally, we investigate the fluctuations in microtubule assembly and disassembly rates and conclude that the inherent rate variability may signify differences in the guanosine-5′-triphosphate composition of the growing and shortening microtubule tips. It is the main objective of this article to develop a quantitative model of tubulin polymerization for individual isotypes and their mixtures. The possible biological significance of the observed differences is addressed.     

Patterns of tubulin isotype synthesis and usage during mitotic spindle morphogenesis in Physarum

Tubulin synthesis in the naturally synchronous plasmodium of Physarum polycephalum is a markedly periodic event restricted to the late G2 period of the cell cycle. Mitosis in the plasmodium is intranuclear, and there are no cytoplasmic microtubules at any stage of the cell cycle. We have combined a biochemical investigation of the synthesis of the plasmodial tubulin isotypes and their participation in the mitotic spindle with a microscopic study (immunofluorescence) of the development of spindle microtubules throughout the cell cycle. We have shown that all four tubulin isotypes identified in the plasmodium (alpha 1, alpha 2, beta 1 and beta 2) are present in the mitotic spindle. The stoichiometry of isotype usage in the mitotic spindle generally reflects the overall abundance of isotypes in the plasmodium as a whole: beta 2 greater than alpha 1 greater than alpha 2 greater than beta 1. We have also shown that tubulins synthesized in the G2 period of one cell cycle can be incorporated into the spindles of the immediately ensuing mitosis and have sufficient biological longevity to allow participation in the mitotic divisions of future cell cycles. Thus, the phenomenon of periodic tubulin synthesis does not reflect a restricted use of tubulin to the cell cycle in which it was synthesized. The major polymerization of tubulin in the nucleus occurred less than 30 min before metaphase. A novel tubulin-containing structure was, however, present in the nucleus approximately 60 min before metaphase. Polymerized tubulin is rapidly removed from the nucleus following nucleokinesis.     

Brain and egg tubulins from antarctic fishes are functionally and structurally distinct.

The multitubulin hypothesis proposes that chemically distinct tubulins may possess different polymerization properties or may form functionally different microtubules. To test this hypothesis, we have examined the functional properties and the structures of singlet-specific nonneural and neural tubulins from Antarctic fishes. Tubulins were purified from eggs of Notothenia coriiceps neglecta, and from brain tissues of N. coriiceps neglecta or N. gibberifrons, by DEAE ion-exchange chromatography and cycles of microtubule assembly/disassembly. At temperatures between 0 and 20 degrees C, each of these tubulins polymerized efficiently in vitro to yield microtubules of normal morphology. Critical concentrations for polymerization of egg tubulin ranged from 0.057 mg/ml at 3 degrees C to 0.002 mg/ml at 18 degrees C, whereas those for brain tubulin at like temperatures were 4-10-fold larger. Polymerization of both tubulins was entropically driven, but the apparent standard enthalpy and entropy changes for microtubule elongation by egg tubulin (delta Happ0 = +33.9 kcal/mol, delta Sapp0 = +151 entropy units) were significantly greater than values observed for brain tubulin (delta Happ0 = +26.5 kcal/mol, delta Sapp0 = +121 entropy units). Egg tubulin was composed of approximately six alpha and two beta chains and lacked the beta III isotype, whereas brain tubulin was more complex (greater than or equal to 10 of each chain type). Furthermore, egg alpha tubulins were more basic, and their carboxyl termini more resistant to cleavage by subtilisin, than were the alpha chains of brain. We conclude that brain and egg tubulins from the Antarctic fishes are functionally distinct in vitro, due either to qualitative or quantitative differences in isotypic composition, to differential posttranslational modification of shared isotypes, or to both.     

During Drosophila spermatogenesis beta 1, beta 2 and beta 3 tubulin isotypes are cell-type specifically expressed but have the potential to coassemble into the axoneme of transgenic flies

alpha and beta Tubulins exist in a number of different isotypes with distinct expression patterns during development. We have shown by immunofluorescent staining that beta 1, beta 2 and beta 3 tubulins are distributed very specifically in the testes of Drosophila. beta 3 Tubulin is present exclusively in cytoplasmic microtubules of cells somatic in origin, while the beta 1 isotype is localized in the somatic cells and in early germ cells of both the microtubules of the cytoskeleton as well as in the mitotic spindle. In contrast, beta 2 tubulin is present in all microtubular arrays (cytoskeleton, meiotic spindles, axoneme) of germ cells from meiotic prophase onward, though not detectable in somatic cells. Thus, a switch of beta tubulin isotypes from beta 1 to beta 2 occurs during male germ cell differentiation. This switch is also observed in the distantly related species Drosophila hydei. By fusing beta 1 or beta 3 amino acid coding regions to the control region of the beta 2 tubulin gene and performing germ line transformation experiments, we have examined the copolymerization properties of the different tubulin isotypes. Neither beta 1 nor beta 3 are detectable in the axoneme in the wild-type situation. Analysis of transgenic flies carrying beta 2-beta 1 fusion genes or beta 2-beta 3 fusion genes revealed that both beta 1 and beta 3 tubulin isotypes have the potential to co-incorporate with beta 2 tubulin into microtubules of the sperm axoneme. Male flies homozygous for the fusion genes (beta 2-beta 1 or beta 2-beta 3) remain fertile, despite the mixture of beta tubulin isotypes in the axoneme.     

Differences in surface morphology of microtubules reconstituted from pure brain tubulin using two different microtubule-associated proteins: the high molecular weight MAP 2 proteins and tau proteins.

Microtubules were reconstituted from homogeneous brain tubulin and homogeneous preparations of two different microtubule associated proteins, the high molecular weight MAP 2 proteins or the tau proteins. The resulting microtubules were characterized by three electron microscopical procedures: Thin sectional analysis of embeded material, negative staining analysis using a STEM microscope and high resolution metal-shadowing analysis. By all three procedures MAP 2 microtubules have a much rougher surface morphology than tau microtubules, in agreement with the much higher molecular weight of the MAP 2 proteins. Tau microtubules, however, do not show the very smooth surface of microtubules assembled from pure tubulin in the absence of any microtubule associated proteins. In the case of MAP 2 microtubules thin sectional analysis as well as metal shadowing reveals that the globular protrusions seen in negative staining analysis appear as linear side arms which may extend by as much as 30 nm on both sides from the microtubular wall proper, giving rise to an overall structure with a diameter close to 100 nm. The possible implication of such structures for in vivo situations is briefly discussed as is the possibility that the "halo-effect" around microtubules seen in vivo may be due to a structural organization similar to that of MAP 2 tubules in vitro.     

Over-expression of betaI tubulin in MDCK cells and incorporation of exogenous betaI tubulin into microtubules interferes with adhesion and spreading.

Little is known about the presence and distribution of tubulin isotypes in MDCK cells although essential epithelial functions in these monolayers are regulated by dynamic changes in the microtubule architecture. Using specific antibodies, we show here that the betaI, betaII, and betaIV isotypes are differentially distributed in the microtubules of these cells. Microtubules in subconfluent cells radiating from the perinuclear region contain betaI and betaII tubulins, while those extending to the cell edges are enriched in betaII. Confluent cells contain similar proportions of betaI and betaII along the entire microtubule length. betaIV is the less abundant isotype and shows a similar distribution to betaII. The effect of modifying tubulin isotype ratios in the microtubules that could affect their dynamics and function was analyzed by stably expressing in MDCK cells betaI tubulin from CHO cells. Three recombinant clones expressing different levels of the exogenous betaI tubulin were selected and subcloned. Clone 17-2 showed the highest expression of CHO beta1 tubulin. Total betaI tubulin levels (MDCK+CHO) in the clones were approximately 1.8 to 1.1-fold higher than in mock-transfected cells only expressing MDCK beta1 tubulin. In all the cells, betaII tubulin levels remained unchanged. The cells expressing CHO beta1 tubulin showed defective attachment, spreading, and delayed formation of adhesion sites at short times after plating, whereas mock-transfected cells attached and spread normally. Analysis of cytoskeletal fractions from clone 17-2 showed a MDCK betaI/CHO betaI ratio of 1.89 at 2 h that gradually decreased to 1.0 by 24 h. The ratio of the two isotypes in the soluble fraction remained unchanged, although with higher values than those found for the polymerized betaI tubulin. By 24 h, the transfected cells had regained normal spreading and formed a confluent monolayer. Our results show that excess levels of total betaI tubulin, resulting from the expression of the exogenous beta1 isotype, and incorporation of it into microtubules affect their stability and some cellular functions. As the levels return to normal, the cells recover their normal phenotype. Regulation of betaI tubulin levels implies the release of the MDCK betaI isotype from the microtubules into the soluble fraction where it would be degraded.     

Effect of estramustine phosphate on the assembly of trypsin-treated microtubules and microtubules reconstituted from purified tubulin with either tau, MAP2, or the tubulin-binding fragment of MAP2

Estramustine phosphate, an estradiol nitrogen-mustard derivative is a microtubule-associated protein (MAP)-binding microtubule inhibitor, used in the therapy of prostatic carcinoma. It was found to inhibit assembly and to induce disassembly of microtubules reconstituted from phosphocellulose-purified tubulin with either tau, microtubule-associated protein 2, or chymotrypsin-digested microtubule-associated protein 2. Estramustine phosphate also inhibited assembly of trypsin-treated microtubules, completely depleted of high-molecular-weight microtubule-associated proteins, but with their microtubule-binding fragment present. In all cases estramustine phosphate induced disassembly to about 50%, at a concentration of approximately 100 microM, at similar protein concentrations. However, estramustine phosphate did not affect dimethyl sulfoxide-induced assembly of phosphocellulose-purified tubulin. Estramustine phosphate is a reversible inhibitor, as the nonionic detergent Triton X-100 was found to counteract the inhibition in a concentration-dependent manner. The reversibility was nondisruptive, as Triton X-100 itself did not affect microtubule assembly, microtubule protein composition, or morphology. This new reversible MAPs-dependent inhibitor estramustine phosphate affects the tubulin assembly, induced by tau, as well as by the small tubulin-binding part of MAP2 with the same concentration dependency. This indicates that tau and the tubulin-binding part of MAP2, in addition to their assembly promoting functions also have binding site(s) for estramustine phosphate in common.     

Distribution and Characteristics of βII Tubulin-Enriched Microtubules in Interphase Cells

We have used a polyclonal antibody (Ab196) that specifically recognizes the βII tubulin isotype to examine the subcellular distribution and properties of microtubules enriched in this isotype. Antibody specificity was tested by a method that involves the analysis of its interaction with individual β isotypes. Using photoimaging analysis, we observed βII tubulin-enriched microtubules in the perinuclear region, as well as in the microtubules close to the periphery of interphase cells. The observed sorting of βII-enriched microtubules together with the reported increased levels of βII tubulin in taxol-resistant cells (M. Haberet al.,1995,J. Biol. Chem.270, 31269–31275) prompted us to study the behavior of microtubules enriched in this isotype after different depolymerizing treatments. After cold or nocodazol treatments, βII-enriched microtubules anchored at the centrosome and at the cell periphery were observed. In addition, cold-resistant microtubules were marked mainly by the specific anti-βII tubulin antibody but not by anti-acetylated α tubulin, suggesting the presence of different stable microtubule subsets enriched in particular tubulin isoforms.     

Preparation of a monoclonal antibody specific for the class IV isotype of beta-tubulin. Purification and assembly of alpha beta II, alpha beta III, and alpha beta IV tubulin dimers from bovine brain.

Tubulin, the 100-kDa subunit protein of microtubules, is a heterodimer of two 50-kDa subunits, alpha and beta. Both alpha and beta subunits exist as numerous isotypic forms. There are four isotypes of beta-tubulin in bovine brain tubulin preparations; their designations and relative abundances in these preparations are as follows: beta I, 3%; beta II, 58%; beta III, 25%; and beta IV, 13%. We have previously reported the preparation of monoclonal antibodies specific for beta II and beta III (Banerjee, A., Roach, M. C., Wall, K. A., Lopata, M. A., Cleveland, D. W., and Luduena, R. F. (1988) J. Biol. Chem. 263, 3029-3034; Banerjee, A., Roach, M. C., Trcka, P., and Luduena, R. F. (1990) J. Biol. Chem. 265, 1794-1799). We here report the preparation of a monoclonal antibody specific for beta IV. By using this antibody together with those specific for beta II and beta III, we have prepared isotypically pure tubulin dimers with the composition alpha beta II, alpha beta III, and alpha beta IV. We have found that, in the presence of microtubule-associated proteins, all three dimers assemble into microtubules considerably faster and to a greater extent than does unfractionated tubulin. More assembly was noted with alpha beta II and alpha beta III than with alpha beta IV. When assembly is measured in the presence of taxol (10 microM), little difference is seen among the isotypically purified dimers or between them and unfractionated tubulin. These results indicate that the assembly properties of a tubulin preparation are influenced by its isotypic composition and raise the possibility that the structural differences among tubulin isotypes may have functional significance.     

Biphasic kinetics of the colchicine-tubulin interaction: role of amino acids surrounding the A ring of bound colchicine molecule

Isotypes of vertebrate tubulin have variable amino acid sequences, which are clustered at their C-terminal ends. Isotypes bind colchicine at different on-rates and affinity constants. The kinetics of colchicine binding to purified (unfractionated) brain tubulin have been reported to be biphasic under pseudo-first-order conditions. Experiments with individual isotypes established that the presence of beta(III) in the purified tubulin is responsible for the biphasic kinetics. Because the isotypes mainly differ at the C termini, the colchicine-binding kinetics of unfractionated tubulin and the beta(III) isotype, cleaved at the C termini, have been tested under pseudo-first-order conditions. Removal of the C termini made no difference to the nature of the kinetics. Sequence alignment of different beta isotypes of tubulin showed that besides the C-terminal region, there are differences in the main body as well. To establish whether these differences lie at the colchicine-binding site or not, homology modeling of all beta-tubulin isotypes was done. We found that the isotypes differed from each other in the amino acids located near the A ring of colchicine at the colchicine-binding site on beta tubulin. While the beta(III) isotype has two hydrophilic residues (serine(242) and threonine(317)), both beta(II) and beta(IV) have two hydrophobic residues (leucine(242) and alanine(317)). beta(II) has isoleucine at position 318, while beta(III) and beta(IV) have valine at that position. Thus, these alterations in the nature of the amino acids surrounding the colchicine site could be responsible for the different colchicine-binding kinetics of the different isotypes of tubulin.