Tubulin structure probed with antibodies to synthetic peptides. Mapping of three major types of limited proteolysis fragments

We synthesized five peptides homologous to the potentially antigenic positions alpha(214-226), alpha(430-443), alpha(415-443), beta(241-256), and beta(412-431) of the porcine brain tubulin sequences. These peptides were successfully employed to raise tubulin-cross-reactive antibodies. The antibodies are specific of the regions of tubulin spanned by the peptides. They react specifically with the tubulin bands in immunoblots and with microtubules in immunofluorescence assays of cytoskeletons. The peptides of the C-terminal regions have also been employed to localize determinants recognized by two available monoclonal antibodies to tubulin in the positions alpha(415-430) and beta(412-431), respectively. In a first application of the anti-peptide antibodies, we have mapped the fragments of limited proteolysis of purified calf brain tubulin by trypsin, chymotrypsin, papain, thermolysin, subtilisin, and protease V8 from Staphylococcus aureus. Thirty-seven peptides have been identified, of which 32 have been unequivocally aligned into the tubulin sequences on the basis of their antigenic reactivity. There are three major, well-defined zones of preferential cleavage by the proteases: the C-termini and two internal zones in each chain. C-Terminal cleavages of both chains by subtilisin do not remove the antigenic reactivity of the zones alpha(415-430) and beta(412-431). C-Terminal cleavages by protease V8 are preferential of beta-tubulin. All six proteases tested cleave alpha- and/or beta-tubulin at one or both of the internal zones. These zones are located roughly at one-third and two-thirds of the chain length in both subunits. Therefore, a model of the tubulin monomers is proposed which consists of three major, proteolytically defined, compact regions (N-terminal, middle, and C-terminal thirds) and the cleavable zones. This model is discussed with the tubulin structural information presently available.     

Tubulin assembly probed with antibodies to synthetic peptides.

Antibodies to synthetic peptides from the alpha and beta-tubulin sequences were employed to study zones of this protein active in microtubule assembly. In purified calf brain tubulin, six short sequences, selected according to their hydrophilicity and conservation, were found to be accessible to their affinity-purified immunoglobulin G (IgG) antibodies, in a competition radioimmunoassay performed under non-assembly native conditions. This indicated that the six sequences are exposed on the surface of the tubulin alpha beta heterodimer. IgG antibodies to the alpha(430-443) and beta(412-431) sequences perturbed substoichiometrically the assembly of purified tubulin, inducing microtubule bundling and the formation of opened up structures. These positions, which are close to the C termini, were accessible to the anti-peptide antibodies in taxol-induced microtubules, Zn2(+)-induced tubulin sheets, Mg2(+)-induced tubulin rings and in PtK2 cell microtubules. This, together with the comparison of the sizes and gross shapes of the antibody probes and microtubules, suggested that these sequences might be located at the protruding parts of the protofilaments. Antibodies to positions alpha(155-168) did not react with microtubules, while the equivalent zone beta(153-165) was accessible. The alpha(214-226) and beta(241-256) sequences were antigenically occluded in the taxol microtubules, Zn2(+)-induced sheets and Mg2(+)-induced ring arrays, as well as in native microtubules from PtK2 cells, though they became reactive by fixation. This result strongly suggested that these two zones are close to tubulin-tubulin contact sites. A working model is proposed in which the positions alpha(214-226) and beta(241-256) are close to the axial contacts between heterodimers, which lead to protofilament formation, while the positions alpha(241-256) and beta(214-226) are suggested to be related to the alpha-beta binding interface within the heterodimer.     

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.     

Translation of beta-tubulin mRNA in vitro generates multiple molecular forms

We describe the in vitro expression and characterization of the isolated beta-tubulin subunit in rabbit reticulocyte lysates and compare its assembly and chromatographic properties with that of the isolated alpha-subunit and the tubulin heterodimer. The beta-tubulin polypeptides, derived from a single chicken beta-tubulin cDNA, were found in three distinct molecular forms: a multimeric or lysate-associated form, beta I (Mr approximately 180,000); the free beta-subunit beta II (Mr approximately 55,000); and the hybrid heterodimer alpha(rabbit) beta(chick), beta III (Mr approximately 80,000-100,000). The hybrid heterodimers were 100% assembly competent, whereas beta-tubulin in the "associated" beta I and the monomeric beta II forms displayed only approximately 70 +/- 15 and 25 +/- 10% competence, respectively, in coassembly assays with bovine brain tubulin. This reduced functionality was not a consequence of diminished beta-subunit stability or protein denaturation. By comparing the elution positions of the three beta forms, the monomeric alpha-subunit, and tubulin dimer purified from bovine brain, we demonstrate that anion-exchange columns (Mono-Q) interact preferentially with the alpha-subunit and chromatograph tubulin dimer on the basis of alpha-subunit isotype. The rate of exchange of the free beta-subunit into bovine tubulin dimer was followed chromatographically. The exchange was slow at 4 degrees C and rapid at 37 degrees C where it is essentially complete in 40 min in the presence of 2.5 mg/ml bovine microtubule protein. Exogenous GTP, a potent effector of microtubule assembly, binds exchangeably to beta II and enhances the recovery of this form from the Mono-Q column, suggesting that GTP binding may occur at identical sites in the isolated beta-subunit and in the tubulin heterodimer.     

Posttranslational modifications of tubulin in cultured mouse brain neurons and astroglia

Posttranslational modifications of tubulin were analyzed in mouse brain neurons and glia developing in culture. Purified tubulin was resolved by isoelectric focusing. After 3 weeks of culture, neurons were shown to express a high degree of tubulin heterogeneity (8 alpha and 10 beta isoforms), similar to that found in the brain at the same developmental stage. Astroglial tubulin exhibits a less complex pattern consisting of 4 alpha and 4 beta isoforms. After incubation of neuronal and glial cells with 3H-acetate in the presence of cycloheximide, a major posttranslational label was found associated with alpha-tubulin and a minor one with beta-tubulin. The acetate-labeled isotubulins of neurons were resolved by isoelectric focusing into as many as 6 alpha and 7 beta isoforms, while those of astroglia were resolved into only 2 alpha and 2 beta isoforms. The same alpha isoforms were also shown to react with a monoclonal antibody recognizing selectively the acetylated form(s) of alpha-tubulin. Whether acetate-labeling of alpha-tubulin in these cells corresponds to the acetylation of Lys40, as reported for Chlamydomonas reinhardtii, is discussed according to very recent data obtained by protein sequence analysis. Tubulin phosphorylation was analyzed by incubation of cell cultures with 32PO4. No phosphorylation of alpha-tubulin isoforms was detected. A single beta-tubulin isoform (beta'2), expressed only in neurons, was found to be phosphorylated. This isoform is similar to that previously identified in differentiated mouse neuroblastoma cells.     

Posttranslational modification of brain tubulins from the Antarctic fish Notothenia coriiceps: reduced C-terminal glutamylation correlates with efficient microtubule assembly at low temperature

We have shown previously that the tubulins of Antarctic fish assemble into microtubules efficiently at low temperatures (-2 to +2 degrees C) due to adaptations intrinsic to the tubulin subunits. To determine whether changes in posttranslational glutamylation of the fish tubulins may contribute to cold adaptation of microtubule assembly, we have characterized C-terminal peptides from alpha- and beta-tubulin chains from brains of adult specimens of the Antarctic rockcod Notothenia coriiceps by MALDI-TOF mass spectrometry and by Edman degradation amino acid sequencing. Of the four fish beta-tubulin isotypes, nonglutamylated isoforms were more abundant than glutamylated isoforms. In addition, maximal glutamyl side-chain length was shorter than that observed for mammalian brain beta tubulins. For the nine fish alpha-tubulin isotypes, nonglutamylated isoforms were also generally more abundant than glutamylated isoforms. When glutamylated, however, the maximal side-chain lengths of the fish alpha tubulins were generally longer than those of adult rat brain alpha chains. Thus, Antarctic fish adult brain tubulins are glutamylated differently than mammalian brain tubulins, resulting in a more heterogeneous population of alpha isoforms and a reduction in the number of beta isoforms. By contrast, neonatal rat brain tubulin possesses low levels of glutamylation that are similar to that of the adult fish brain tubulins. We suggest that unique residue substitutions in the primary structures of Antarctic fish tubulin isotypes and quantitative changes in isoform glutamylation act synergistically to adapt microtubule assembly to low temperatures.     

Charge variants of tubulin,tubulin S,membrane-bound and palmitoylated tubulin from brain and pheochromocytoma cells

Isoelectric focusing (IEF) of only approximately 1 microg of rat brain tubulin yields 27-30 distinct charge variants in the pH range of 4.5-5.4 with band separations of 0.01-0.02 pH units as detected by silver staining. Variants can be efficiently transferred from the immobilized gradient strip to polyvinylidene difluoride (PVDF) membranes for reaction with monoclonal antibodies. C-terminal-directed antibodies to alpha- and beta-tubulin yield patterns similar to N-terminal-directed antibodies. Removal of the acidic C-termini with subtilisin to form tubulin S increases the pI values by approximately 1 pH unit, leads to a loss in the isoelectric distinction between the alpha- and beta-tubulin variants seen by N-terminal-directed antibodies, and abolishes reactions with all beta-variants and all but three alpha variants by C-terminal-directed antibodies (TU-04 and TU-14). Many, but not all, of the variants are substrates for autopalmitoylation of rat brain tubulin. The distribution of isoelectric variants differs between cytoplasm and membrane fractions from PC12 pheochromocytoma cells. A potential role for different variants is suggested.     

Helicity of alpha(404-451) and beta(394-445) tubulin C-terminal recombinant peptides

We have investigated the solution conformation of the functionally relevant C-terminal extremes of alpha- and beta-tubulin, employing the model recombinant peptides RL52alpha3 and RL33beta6, which correspond to the amino acid sequences 404-451(end) and 394-445(end) of the main vertebrate isotypes of alpha- and beta-tubulin, respectively, and synthetic peptides with the alpha-tubulin(430-443) and beta-tubulin(412-431) internal sequences. Alpha(404-451) and beta(394-445) are monomeric in neutral aqueous solution (as indicated by sedimentation equilibrium), and have circular dichroism (CD) spectra characteristic of nearly disordered conformation, consistent with low scores in peptide helicity prediction. Limited proteolysis of beta(394-445) with subtilisin, instead of giving extensive degradation, resulted in main cleavages at positions Thr409-Glu410 and Tyr422-Gln423-Gln424, defining the proteolysis resistant segment 410-422, which corresponds to the central part of the predicted beta-tubulin C-terminal helix. Both recombinant peptides inhibited microtubule assembly, probably due to sequestration of the microtubule stabilizing associated proteins. Trifluoroethanol (TFE)-induced markedly helical CD spectra in alpha(404-451) and beta(394-445). A substantial part of the helicity of beta(394-445) was found to be in the CD spectrum of the shorter peptide beta(412-431) with TFE. Two-dimensional 1H-NMR parameters (nonsequential nuclear Overhauser effects (NOE) and conformational C alphaH shifts) in 30% TFE permitted to conclude that about 25% of alpha(404-451) and 40% of beta(394-451) form well-defined helices encompassing residues 418-432 and 408-431, respectively, flanked by disordered N- and C-segments. The side chains of beta(394-451) residues Leu418, Val419, Ser420, Tyr422, Tyr425, and Gln426 are well defined in structure calculations from the NOE distance constraints. The apolar faces of the helix in both alpha and beta chains share a characteristic sequence of conserved residues Ala,Met(+4),Leu(+7),Tyr(+11). The helical segment of alpha(404-451) is the same as that described in the electron crystallographic model structure of alphabeta-tubulin, while in beta(394-451) it extends for nine residues more, supporting the possibility of a functional coil --> helix transition at the C-terminus of beta-tubulin. These peptides may be employed to construct model complexes with microtubule associated protein binding sites.     

Common antigenic determinants of the tubulin binding domains of the microtubule-associated proteins MAP-2 and tau.

The structural-functional aspects of the tubulin binding domain on the microtubule-associated protein MAP-2, and its relationship with the tubulin binding domain on tau, were studied using anti-idiotypic antibodies that react specifically with the epitope(s) on MAPs involved in their interaction with tubulin in addition to other tau and MAP-2 specific antibodies. Previous studies showed that MAP-2 and tau share common binding sites on tubulin defined by the peptide sequences alpha (430-441) and beta (422-434) of tubulin subunits. Furthermore, binding experiments revealed the existence of multiple sites for the interaction of the alpha- and beta-tubulin peptides with MAP-2 and tau. Most recent studies showed that the synthetic tau peptide Val187-Gly204 (VRSKIGSTENLKHQPGGG) from the repetitive sequence on tau defines a tubulin binding site on tau. Our present immunological studies using anti-idiotypic antibodies which interact with the synthetic tau peptide and antibodies against the Val187-Gly204 tau peptide indicate that MAP-2 and tau share common antigenic determinants at the level of their respective tubulin binding domains. These antigenic determinants appear to be present in the 35 kDa tubulin binding fragment of MAP-2 and in 18-20 kDa chymotryptic fragments containing the tubulin binding site(s) on MAP-2. These findings, along with structural information on these proteins, provide strong evidence in favor of the hypothesis that tubulin binding domains on MAP-2 and tau share similar structural features.     

Kinetics of colchicine binding to purified beta-tubulin isotypes from bovine brain.

Tubulin, the constituent protein of microtubules, is an alpha beta heterodimer; both alpha and beta exist in several isotypic forms whose functional significance is not precisely known. The antimitotic alkaloid colchicine binds to mammalian brain tubulin in a biphasic manner under pseudo-first-order conditions in the presence of a large excess of colchicine (Garland, D. L. (1978) Biochemistry 17, 4266-4272). We have studied the kinetics of colchicine binding to purified beta-tubulin isotypes and find that each of the purified beta-tubulin isotypes binds colchicine in a monophasic manner. The apparent on-rate constants for the binding of colchicine to alpha beta II-, alpha beta III-, and alpha beta IV-tubulin dimers are respectively 132 +/- 5, 30 +/- 2, and 236 +/- 7 M-1 s-1. When the isotypes are mixed, the kinetics become biphasic. Scatchard analysis revealed that the isotypes differ significantly in their affinity constants (Ka) for binding colchicine. The affinity constants are 0.24 x 10(6), 0.12 x 10(6), and 3.31 x 10(6) M-1, respectively, for alpha beta II-, alpha beta III-, and alpha beta IV-tubulin dimers. Our results are in agreement with the hypothesis that the beta-subunit of tubulin plays a major role in the interaction of colchicine with tubulin. Our binding data raise the possibility that the tubulin isotypes might play important regulatory roles by interacting differently with other non-tubulin proteins in vivo, which in turn, may regulate microtubule-based functions in living cells.     

Cloning, purification, and polymerization of Capsicum annuum recombinant alpha and beta tubulin

Alpha and beta tubulin genes were cloned from the Capsicum annuum leaves using rapid amplification of cDNA ends (RACE)-PCR. Nucleotide sequence analysis revealed that 1,353 bp Capsicum annuum alpha/beta-tubulin (CAnm alpha/beta-TUB) encodes a protein of 450 amino acids (aa) each. The recombinant alpha/beta tubulin was overexpressed mainly as an inclusion body in Escherichia coli BL21 (DE3), upon induction with 0.2 mM isopropyl-beta-D-thiogalactopyranoside (IPTG), and its content was as high as 50% of the total protein content. Effective fusion protein purification and refolding are described. The average yields of alpha and beta tubulin were 2.0 and 1.3 mg/l of culture respectively. The apparent molecular weight of each tubulin was estimated to be 55 kDa by SDS-polyacrylamide gel electrophoresis (PAGE). The tubulin monomers were found to be assembly competent using a standard dimerization assay, and also retained antigenicity with anti-His/T7 antibodies. The purified tubulins were polymerized to microtubule-like structures in the presence of 2 mM guanosine 5'-triphosphate (GTP).     

Carboxy-terminal regions on the surface of tubulin and microtubules. Epitope locations of YOL1/34, DM1A and DM1B

Tryptic and cyanogen bromide peptides of pig brain alpha- and beta-tubulin reacting with monoclonal antibodies YOL1/34, DM1A and DM1B have been isolated and identified. They all correspond to parts of the C-terminal regions of either alpha- or beta-tubulin, and those peptides reacting with a given antibody have overlapping sequences. In the case of YOL1/34, its relatively high reactivity with small peptides suggests that many of the determinants for this antibody are within the overlapping region of these peptides comprising only nine amino acids in positions alpha 414 to 422. The smallest common region of peptides reacting with the other alpha-tubulin antibody DM1A corresponds to positions alpha 426 to 450, whereby amino acids within the positions 426 and 430 appear to be particularly important for reactivity. Since the last C-terminal residues of alpha-tubulin are also accessible to antibodies and enzymes, it seems that an extensive part (35 to 40 residues) of this very acidic C-terminal domain is exposed on the surface of native tubulin dimers. In microtubules, however, the amino-terminal end of this region appears to be less accessible, as YOL1/34 reacts poorly, if at all, with intact microtubules. All of the peptides reacting with beta-tubulin monoclonal antibody DM1B were derived from the acidic C-terminal domain and they overlapped in positions beta 416 to 430. This indicates that beta-tubulin is also positioned with at least part of its acidic C-terminal domain on the surface of microtubules, since DM1B reacts with unfixed microtubules after microinjection.     

Brain and erythrocyte microtubules from chicken contain different beta-tubulin polypeptides

beta-Tubulin subunits isolated from chicken brain tissue and erythrocytes are distinguishable as unique biochemical species by electrophoretic and peptide mapping procedures. 1) The subunits of beta-tubulin exhibit major differences in electrophoretic mobility on sodium dodecyl sulfate-polyacrylamide gels that vary according to the pH and ionic strength of the gel. 2) The isoelectric points of urea-denatured beta subunits from brain tissue and erythrocytes are pH 5.1 and 5.4, respectively, whereas those of both alpha subunits are approximately pH 5.2.3) Two-dimensional peptide maps prepared with alpha-chymotrypsin or V8 protease show that alpha-tubulin peptides are indistinguishable, whereas beta-tubulin peptides are very different. Only one-third of the 15 major tyrosine-containing beta-tubulin peptides prepared with alpha-chymotrypsin are common to both beta-tubulin species. The data indicate that the beta-tubulin subunits of brain tissue and erythrocytes are biochemically distinct and may be different gene products. The presence of tubulin variants in brain tissue and erythrocytes may indicate special requirements for microtubule assembly and function in different cell types.     

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.     

Reversible polyglutamylation of alpha- and beta-tubulin and microtubule dynamics in mouse brain neurons.

The relationship between microtubule dynamics and polyglutamylation of tubulin was investigated in young differentiating mouse brain neurons. Selective posttranslational labeling with [3H]glutamate and immunoblotting with a specific monoclonal antibody (GT335) enabled us to analyze polyglutamylation of both alpha and beta subunits. Nocodazole markedly inhibited incorporation of [3H]glutamate into alpha- and beta-tubulin, whereas taxol had no effect for alpha-tubulin and a stimulating effect for beta-tubulin. These results strongly suggest that microtubule polymers are the preferred substrate for polyglutamylation. Chase experiments revealed the existence of a reversal reaction that, in the case of alpha-tubulin, was not affected by microtubule drugs, suggesting that deglutamylation of this subunit can occur on both polymers and soluble tubulin. Evidence was obtained that deglutamylation of alpha-tubulin operates following two distinct rates depending on the length of the polyglutamyl chain, the distal units (4th-6th) being removed rapidly whereas the proximal ones (1st-3rd) appearing much more resistant to deglutamylation. Partition of glutamylated alpha-tubulin isoforms was also correlated with the length of the polyglutamyl chain. Forms bearing four to six units were recovered specifically in the polymeric fraction, whereas those bearing one to three units were distributed evenly between polymeric and soluble fractions. It thus appears that the slow rate component of the deglutamylation reaction offers to neurons the possibility to maintain a basal level of glutamylated alpha-tubulin in the soluble pool independently of microtubule dynamics. Finally, some differences observed in the glutamylation of alpha- and beta-tubulin suggest that distinct enzymes are involved.     

The role of microtubules in platelet secretory release

The role of microtubules in platelet aggregation and secretion has been analyzed using platelets permeabilized with digitonin and monoclonal antibodies to alpha (DM1A) and beta (DM1B) subunits of tubulin. Permeabilized platelets were able to undergo aggregation and secretory release. However, threshold doses of agonists capable of eliciting a second wave of aggregation and the platelet release reaction were higher than in control platelets exposed to dimethyl sulfoxide, the solvent for digitonin. Both antibodies to alpha and beta tubulin caused a further increase in the threshold concentration of agonists and inhibited the secretory release of permeabilized platelets, but were ineffective using intact platelets. Neither monoclonal antibody inhibited polymerization or depolymerization of platelet tubulin in vitro. Antibodies to platelet actin and myosin also exhibited an inhibitory activity on platelet aggregation albeit less severe than that observed with the antibodies to alpha and beta tubulin. There was evidence of an interaction between DM1A and DM1B and the antibodies to actin and myosin. The interaction of platelet tubulin and myosin was investigated by two different methods. (1) Coprecipitation of the proteins at low ionic strength at which tubulin by itself did not precipitate and (2) affinity chromatography on columns of immobilized myosin. Tubulin freed of its associated proteins (MAPs) by phosphocellulose chromatography bound to myosin in a molar ratio which approached 2. Platelet actin competed with tubulin for 1 binding site on the myosin molecule. MAPs also reduced the binding stoichiometry of tubulin/myosin. Treatment of microtubule protein with p-chloromercuribenzoate or colchicine did not influence its binding to myosin. DM1A and DM1B inhibited the interaction of tubulin and myosin. This effect could also be demonstrated by reaction of electrophoretic transblots of extracted platelet tubulin with the respective proteins. We interpret these results as evidence for an interference of the two monoclonal antibodies to the tubulin subunits (DM1A and DM1B) with the translocation of microtubule protein from its submembranous site to a more central one during the activation process.     

Identification of betaIII- and betaIV-tubulin isotypes in cold-adapted microtubules from Atlantic cod (Gadus morhua): antibody mapping and cDNA sequencing

Isolated microtubule proteins from the Atlantic cod (Gadus morhua) assemble at temperatures between 8 and 30 degrees C. The cold-adaptation is an intrinsic property of the tubulin molecules, but the reason for it is unknown. To increase our knowledge of tubulin diversity and its role in cold-adaptation we have further characterized cod tubulins using alpha- and beta-tubulin site-directed antibodies and antibodies towards posttranslationally modified tubulin. In addition, one cod brain beta-tubulin isotype has been sequenced. In mammals there are five beta-tubulins (betaI, betaII, betaIII, betaIVa and betaIVb) expressed in brain. A cod betaIII-tubulin was identified by its electrophoretic mobility after reduction and carboxymethylation. The betaIII-like tubulin accounted for more than 30% of total brain beta-tubulins, the highest yield yet observed in any animal. This tubulin corresponds most probably with an additional band, designated beta(x), which was found between alpha- and beta-tubulins on SDS-polyacrylamide gels. It was found to be phosphorylated and neurospecific, and constituted about 30% of total cod beta-tubulin isoforms. The sequenced cod tubulin was identified as a betaIV-tubulin, and a betaIV-isotype was stained by a C-terminal specific antibody. The amount of staining indicates that this isotype, as in mammals, only accounts for a minor part of the total brain beta-tubulin. Based on the estimated amounts of betaIII- and betaIV-tubulins in cod brain, our results indicate that cod has at least one additional beta-tubulin isotype and that beta-tubulin diversity evolved early during fish evolution. The sequenced cod betaIV-tubulin had four unique amino acid substitutions when compared to beta-tubulin sequences from other animals, while one substitution was in common with Antarctic rockcod beta-tubulin. Residues 221, Thr to Ser, and 283, Ala to Ser, correspond in the bovine tubulin dimer structure to loops that most probably interact with other tubulin molecules within the microtubule, and might contribute to cold-adaptation of microtubules.     

A discrete repeated sequence defines a tubulin binding domain on microtubule-associated protein tau

The protein domain responsible for the interaction of tau with tubulin has been identified. Biophysical studies indicated that the synthetic peptide Val187-Gly204 (VRSKIG-STENLKHQPGGG) from the repetitive sequence on tau binds to two sites on the tubulin heterodimer and to one site on each of the microtubule-associated protein-interacting C-terminal tubulin peptides alpha(430-441) and beta(422-434). The binding data showed a relatively stronger interaction of Val187-Gly204 with beta(422-434) as compared to that with alpha(430-441). The interaction of this tau peptide with either alpha or beta tubulin peptides appears to be associated with conformational changes in both the tau and the tubulin peptides. The beta tubulin peptide also appears to induce a structural change of tau fragment Val218-Gly235. Interestingly, tau peptides Val187-Gly204 and Val218-Gly235 induced tubulin self-assembly in a cold-reversible fashion, and incorporated into the assembled polymers. The specificity of the interaction of the tau peptide was supported by the competition of tau protein for the interaction with the tubulin polymer. In addition, the tau peptide appears to contain the principal antigenic determinant(s) recognized by anti-idiotypic antibodies that react with the tubulin binding domains on microtubule-associated proteins. The present findings together with the demonstration of the presence of multiple sites for the binding of the alpha(430-441) and beta(422-434) tubulin fragments to tau, and the existence of repetitive sequences on tau, strongly support the hypothesis that the region of tau defined by the repetitive sequences is involved in its interaction with tubulin.     

Structure of tubulin C-terminal domain obtained by subtilisin treatment. The major alpha and beta tubulin isotypes from pig brain are glutamylated.

Limited subtilisin digestion of the tubulin alpha, beta heterodimer has been used in this work to reduce the total number of tubulin isotypes from 20 for native to 9 for subtilisin-cleaved tubulin. This indicates that the major part of tubulin heterogeneity is located at the C-terminus of the molecule. The C-terminal peptides of both alpha and beta subunits of tubulin were purified by anion-exchange HPLC. Combined use of Edman degradation chemistry and mass spectrometry on the isolated peptides shows that subtilisin cleavage occurs at position Asp-438 and His-406 of alpha and Gln-433 and His-396 of beta tubulin chains. Quantitative analysis of our data show that cleavage at positions His-406 (alpha) and His-396 (beta) occurs with a low efficiency and indicates that the major isotypes of pig brain tubulin are modified by sequential attachment of 1 to 5 glutamic acid residues at positions Glu-445 or -435 of alpha and beta tubulin, respectively.