Structural Analysis of Mutations in the Drosophila β2-Tubulin Isoform Reveals Regions in the β-Tubulin Molecule Required for General and for Tissue-Specific Microtubule Functions

We have determined the lesions in a number of mutant alleles of βTub85D, the gene that encodes the testis-specific β2-tubulin isoform in Drosophila melanogaster. Mutations responsible for different classes of functional phenotypes are distributed throughout the β2-tubulin molecule. There is a telling correlation between the degree of phylogenetic conservation of the altered residues and the number of different microtubule categories disrupted by the lesions. The majority of lesions occur at positions that are evolutionarily highly conserved in all β-tubulins; these lesions disrupt general functions common to multiple classes of microtubules. However, a single allele B2t(6) contains an amino acid substitution within an internal cluster of variable amino acids that has been identified as an isotype-defining domain in vertebrate β-tubulins. Correspondingly, B2t(6) disrupts only a subset of microtubule functions, resulting in misspecification of the morphology of the doublet microtubules of the sperm tail axoneme. We previously demonstrated that β3, a developmentally regulated Drosophila β-tubulin isoform, confers the same restricted morphological phenotype in a dominant way when it is coexpressed in the testis with wild-type β2-tubulin. We show here by complementation analysis that β3 and the B2t(6) product disrupt a common aspect of microtubule assembly. We therefore conclude that the amino acid sequence of the β2-tubulin internal variable region is required for generation of correct axoneme morphology but not for general microtubule functions. As we have previously reported, the β2-tubulin carboxy terminal isotype-defining domain is required for suprastructural organization of the axoneme. We demonstrate here that the β2 variant lacking the carboxy terminus and the B2t(6) variant complement each other for mild-to-moderate meiotic defects but do not complement for proper axonemal morphology. Our results are consistent with the hypothesis drawn from comparisons of vertebrate β-tubulins that the two isotype-defining domains interact in a three-dimensional structure in wild-type β-tubulins. We propose that the integrity of this structure in the Drosophila testis β2-tubulin isoform is required for proper axoneme assembly but not necessarily for general microtubule functions. On the basis of our observations we present a model for regulation of axoneme microtubule morphology as a function of tubulin assembly kinetics.     

Identification of the phosphorylated β-tubulin isotype in differentiated neuroblastoma cells

The tubulin molecule consists of an - and a β-subunit, each of which exists in several isotypic forms. It has been previously shown that one of the isotypes of neuroblastoma β-tubulin is phosphorylated at a serine residue in vivo [(1985) J. Cell Biol. 100, 764–774]. Here we identify the phosphorylated isotype as β₂ (type III). Moreover, the large size of the phosphorylated tryptic peptide and sequence comparisons of vertebrate β-tubulins suggest that one of the two serines in positions 444 and 446 is the phosphorylated residue. Our results raise the possibility that β₂-tubulin differs functionally from the other β-tubulin isotypes.     

Identification of tubulin isoforms in different tissues of Ascaris suum using anti-tubulin monoclonal antibodies.

Three monoclonal antibodies specific to - and β-tubulin were used to examine the expression of tubulin isofoms in the intestine, reproductive tract and body wall muscle of A. suum. The tubulins were found to be different in their isoelectric points, number of isoforms and peptide maps with Western blot analysis of one-dimensional polyacrylamide gel confirming the presence of -, β₁- and β₂- tubulin. Commercial cross-reactive anti- and anti-β MAbs 356 and 357 recognized tubulin from A. suum tissues as well as from pig brain, whereas anti-A. suum β-tubulin specific MAb P3D6 recognized tubulin from the A. suum tissues only. Two-dimensional gel analysis showed different isoform patterns in different A. suum tissues with anti-A. suum β-tubulin MAb P3D6 and cross-reactive β-tubulin MAb 357 recognizing 2–4 β- tubulin isoforms and anti--tubulin MAb 356 recognizing 1–6 -tubulin isoforms. Different peptide maps of tubulin were observed in the three tissues, when subjected to limited proteolysis followed by SDS-PAGE. The data indicate that different tubulins are found in different tissues of adult A. suum.     

Multiple forms of tubulin in the cytoskeletal and flagellar microtubules of polytomella

The alga polytomella contains several organelles composed of microtubules, including four flagella and hundreds of cytoskeletal microtubules. Brown and co-workers have shown (1976. J. Cell Biol. 69:6-125; 1978, Exp. Cell Res. 117: 313-324) that the flagella could be removed and the cytoskeletans dissociated, and that both structures could partially regenerate in the absence of protein synthesis. Because of this, and because both the flagella and the cytoskeletons can be isolated intact, this organism is particularly suitable for studying tubulin heterogeneity and the incorporation of specific tubulins into different microtubule-containing organelles in the same cell. In order to define the different species of tubulin in polytonella cytoplasm, a (35)S- labeled cytoplasmic fraction was subjected to two cycles of assembly and disassembly in the presence of unlabeled brain tubulin. Comparison of the labeled polytomella cytoplasmic tubulin obtained by this procedure with the tubulin of isolated polytomella flagella by two-dimensional gel electrophoresis showed that, whereas the β-tubulin from both cytoplasmic and flagellar tubulin samples comigrated, the two α-tubulins had distinctly different isoelectic points. As a second method of isolating tubulin from the cytoplasm, cells were gently lysed with detergent and intact cytoskeletons obtained. When these cytoskeletons were exposed to cold temperature, the proteins that were released were found to be highly enriched in tubulin; this tubulin, by itself, could be assembled into microtubules in vitro. The predominant α-tubulin of this in vitro- assembled cytoskeletal tubulin corresponded to the major cytoplasmic α-tubulin obtained by coassembly of labeled polytomella cytoplasmic extract with brain tubulin and was quite distinct from the α-tubulin of purified flagella. These results clearly show that two different microtubule-containing organelles from the same cell are composed of distinct tubulins.     

嗜热四膜虫δ微管蛋白基因的克隆、鉴定及细胞定位

微管蛋白(tubulin)在细胞的结构和功能中发挥着重要作用, α微管蛋白和 β微管蛋白是组成微管的主要因子,γ微管蛋白促使α和β微管蛋白二聚体组装为微管结构. 然而, 4种新的微管蛋白δ-,ε-,ζ-, 和η- tubulin在细胞中的功能并不完全清楚. 本研究从嗜热四膜虫大核基因组数据库中鉴定了一种新的编码δ微管蛋白基因（Tetrahymena delta tubulin 1, TDT1, TTHERM_00335970, http://www. ciliate. org）, TDT1基因转录产生1 326 bp和 1 363 bp两种不同的转录本, 1 326 bp的转录本编码441个氨基酸的多肽; 而1 363 bp的转录本含有37 bp未剪切的内含子序列, 从而导致开发读框发生移码突变现象. 实时荧光定量PCR结果表明, TDT1基因在四膜虫细胞营养生长和有性生殖过程中都有表达, 且在有性生殖过程中的表达显著上调. 免疫荧光定位表明, TDT1蛋白不仅定位于四膜虫基体和有性生殖期conjugation junction结构, 而且在四膜虫的大核和小核中也有定位. TDT1基因敲除发现,该基因不能通过表型分配完全被巴龙霉素抗性基因替代, 结果表明, TDT1蛋白在四膜虫细胞中可能具有多种不同的功能, 它的正常表达对四膜虫细胞的生存是必需的.     

Multiple forms of tubulin in Polytomella and Chlamydomonas: evidence for a precursor of flagellar alpha-tubulin

The quadriflagellate alga polytomella agilis contains several α-tubulins with distinct isoelectric points (McKeithan, T.W., and J.L. Rosenbaum, 1981, J. Cell Biol., 91:352-360). While α-3 is the major component in flagella, α-1 predominates in cytoskeletal microtubules. For determination of whether the differences in α- tubulins are due to distinct genes or to posttranslational modification of a common α-tubulin precursor, poly A+ RNA was isolated from deflagellated and control (nonregenerating) cells and translated in vitro. Approximately twice as much α-1 was synthesized using RNA from deflagellated as compared to control cells; however, there was no detectable synthesis in vitro of α-3 in either. These results suggest that α -3 tubulin is formed in vivo by posttranslational modification of a form co- migrating with, and possibly identical to, cytoskeletal α-tubulin. In the related alga chlamydomonas reinhardii deflagellation greatly stimulates synthesis of tubulin and tubulin mRNA. As in polytomella, the principal α-tubulin synthesized both in vivo and in vitro following deflagellation in chlamydomonas is more basic than the major α-tubulin and appears to correspond to α-1 tubulin in polytomella. The conversion of α-1 to α-3 receives additional support from in vivo labeling and pulse-chase experiments. In addition, in both polytomella and chlamydomonas some conversion of α-1 to α-3 appears to occur even when protein synthesis is inhibited.     

γ-微管蛋白在猪卵母细胞成熟和活化中的分布

微管蛋白(tubulin)是一蛋白质超家族,其中α-,β-微管蛋白是主要的微管蛋白,而γ-微管蛋白主要在微管组装中起作用. 我们利用蛋白质印迹和激光共聚焦技术研究了γ-微管蛋白在猪卵母细胞成熟、受精和活化中的分布. γ-微管蛋白存在于猪卵母细胞中,并且在减数分裂成熟各个时期的量保持不变. 它聚集在微管上,特别是中期纺锤体的两极和后末期的中板. 体外受精和孤雌活化后,γ-微管蛋白聚集在雌雄原核的周围.另外它也存在于精子的顶体帽和颈部.在早期卵裂中,γ-微管蛋白聚集在胚胎的细胞核周围.实验结果表明,γ-微管蛋白在猪卵母细胞、精子和胚胎的微管组装中起重要的调节作用,在猪受精过程中,精子和卵子都向受精卵贡献中心体物质.     

Molecular Basis for Class V ��-Tubulin Effects on Microtubule Assembly and Paclitaxel Resistance

Vertebrates produce at least seven distinct β-tubulin isotypes that coassemble into all cellular microtubules. The functional differences among these tubulin isoforms are largely unknown, but recent studies indicate that tubulin composition can affect microtubule properties and cellular microtubule-dependent behavior. One of the isotypes whose incorporation causes the largest change in microtubule assembly is β5-tubulin. Overexpression of this isotype can almost completely destroy the microtubule network, yet it appears to be required in smaller amounts for normal mitotic progression. Moderate levels of overexpression can also confer paclitaxel resistance. Experiments using chimeric constructs and site-directed mutagenesis now indicate that the hypervariable C-terminal region of β5 plays no role in these phenotypes. Instead, we demonstrate that two residues found in β5 (Ser-239 and Ser-365) are each sufficient to inhibit microtubule assembly and confer paclitaxel resistance when introduced into β1-tubulin; yet the single mutation of residue Ser-239 in β5 eliminates its ability to confer these phenotypes. Despite the high degree of conservation among β-tubulin isotypes, mutations affecting residue 365 demonstrate that amino acid substitutions can be context sensitive; i.e. an amino acid change in one isotype will not necessarily produce the same phenotype when introduced into a different isotype. Modeling studies indicate that residue Cys-239 of β1-tubulin is close to a highly conserved Cys-354 residue suggesting the possibility that disulfide formation could play a significant role in the stability of microtubules formed with β1- but not with β5-tubulin.Microtubules are needed to organize the Golgi apparatus and endoplasmic reticulum, maintain cell shape, construct ciliary and flagellar axonemes, and ensure the accurate segregation of genetic material prior to cell division. These cytoskeletal structures assemble from α- and β-tubulin heterodimers to form long cylindrical filaments that exist in a state of dynamic equilibrium characterized by stochastic episodes of slow growth and rapid shrinkage (1). Impairment of normal dynamic behavior has serious consequences for cell proliferation and thus makes microtubules an attractive target for drug development (2).Vertebrates express multiple β-tubulin genes that produce highly homologous proteins differing most notably in their C-terminal 15–20 amino acids (3, 4). These variable C-terminal sequences are conserved across vertebrate species and have been used to classify β-tubulin genes into distinct isotypes (5). In mammals, for example, there are seven known isotypes designated by the numbers I, II, III, IVa, IVb, V, and VI. The functional significance of the C-terminal sequences is uncertain, but some studies suggest that they may be involved in binding or modulating the action of microtubule-interacting proteins (6–14). Additional amino acid differences are scattered throughout the primary sequence, but the functional role of these differences, if any, has not been elucidated. Although some β-tubulin isotypes are expressed in a tissue-specific manner (3), evidence indicates that microtubules incorporate all available isotypes, including transfected isotypes that are not normally produced in those cells (5, 15–17). Genetic experiments designed to test potential functional differences among the various β-tubulin isotypes have only demonstrated isotype-specific effects on the assembly of specialized microtubule-containing structures such as flagellar axonemes in Drosophila or 15-protofilament microtubules in Caenorhabditis elegans (18, 19). Thus, the consequences, if any, of producing multiple β-tubulin isoforms in vertebrate organisms remain elusive.Our recent work showed that conditional overexpression of isotypes β1, β2, and β4b has no effect on microtubule assembly or drug sensitivity in transfected Chinese hamster ovary (CHO)² cells (20). Similarly, expression of neuronal-specific β4a produced very minor effects on microtubule assembly but was able to increase sensitivity to paclitaxel, most likely through increased binding of the drug (21). On the other hand, high expression of neuronal-specific β3 reduced microtubule assembly, conferred low level resistance to paclitaxel, and inhibited cell growth (22). The most dramatic effects, however, were seen in cells transfected with β5, a minor but widely expressed isotype (23). Even modest overexpression of this isotype reduced microtubule assembly and conferred paclitaxel resistance, whereas high levels of expression (∼50% of total tubulin) caused fragmentation and a near complete loss of the microtubule cytoskeleton (24). Despite the toxicity associated with β5 overexpression, this isotype was recently shown to be required for normal mitotic progression and cell proliferation (25).Because of its importance for cell division, and the extreme phenotype associated with its overexpression, we sought to identify the structural differences between β5-tubulin and its more “normal” homolog, β1. Although there are 40 amino acid differences between the 2 isotypes, we report that most of the unique properties of β5 can be attributed to the presence of serine in place of cysteine at residue 239. This residue faces the colchicine binding pocket and is very close to a highly conserved Cys-354 residue. We propose that Ser-239 found in β5-tubulin may prevent formation of a disulfide bond that normally stabilizes microtubules.     

Modulation of phosducin-like protein 3 (PhLP3) levels promotes cytoskeletal remodelling in a MAPK and RhoA-dependent manner

Background

Phosducin-like protein 3 (PhLP3) forms a ternary complex with the ATP-dependent molecular chaperone CCT and its folding client tubulin. In vitro studies suggest PhLP3 plays an inhibitory role in β-tubulin folding while conversely in vivo genetic studies suggest PhLP3 is required for the correct folding of β-tubulin. We have a particular interest in the cytoskeleton, its chaperones and their role in determining cellular phenotypes associated with high level recombinant protein expression from mammalian cell expression systems.

Methodology/Principal Findings

As studies into PhLP3 function have been largely carried out in non mammalian systems, we examined the effect of human PhLP3 over-expression and siRNA silencing using a single murine siRNA on both tubulin and actin systems in mammalian Chinese hamster ovary (CHO) cell lines. We show that over-expression of PhLP3 promotes an imbalance of α and β tubulin subunits, microtubule disassembly and cell death. In contrast, β-actin levels are not obviously perturbed. On-the-other-hand, RNA silencing of PhLP3 increases RhoA-dependent actin filament formation and focal adhesion formation and promotes a dramatic elongated fibroblast-like change in morphology. This was accompanied by an increase in phosphorylated MAPK which has been associated with promoting focal adhesion assembly and maturation. Transient overexpression of PhLP3 in knockdown experiments rescues cells from the morphological change observed during PhLP3 silencing but mitosis is perturbed, probably reflecting a tipping back of the balance of PhLP3 levels towards the overexpression state.

Conclusions

Our results support the hypothesis that PhLP3 is important for the maintenance of β-tubulin levels in mammalian cells but also that its modulation can promote actin-based cytoskeletal remodelling by a mechanism linked with MAPK phosphorylation and RhoA-dependent changes. PhLP3 levels in mammalian cells are thus finely poised and represents a novel target for engineering industrially relevant cell lines to evolve lines more suited to suspension or adherent cell growth.     

1,5-Disubstituted 1,2,3-triazoles as cis-restricted analogues of combretastatin A-4: Synthesis, molecular modeling and evaluation as cytotoxic agents and inhibitors of tubulin

A series of cis-restricted 1,5-disubstituted 1,2,3-triazole analogues of combretastatin A-4 (1) have been prepared. The triazole 12f, 2-methoxy-5-(1-(3,4,5-trimethoxyphenyl)-1H-1,2,3-triazol-5-yl)aniline, displayed potent cytotoxic activity against several cancer cell lines with IC₅₀ values in the nanomolar range. The ability of triazoles to inhibit tubulin polymerization has been evaluated, and 12f inhibited tubulin polymerization with IC₅₀ = 4.8 μM. Molecular modeling experiments involving 12f and the colchicine binding site of ,β-tubulin showed that the triazole moiety interacts with β-tubulin via hydrogen bonding with several amino acids.     

八肋游仆虫微管蛋白基因家族的鉴定及进化分析

为了系统分析八肋游仆虫(Euplotes octocarinatus)微管蛋白基因家族,从八肋游仆虫大核基因组中共鉴定得到20个微管蛋白基因,基于同源比对及系统进化分析,将其归入α、β、γ、δ、ε及η六个微管蛋白亚家族;多序列比对及Western blot结果显示八肋游仆虫η微管蛋白基因在翻译过程中需发生一次+1位编程性核糖体移码,其移码位点为AAA-TAA;所有自由生纤毛虫都含有多个α和β微管蛋白基因亚型,可能用于组成不同的微管结构。研究为后续深入探讨八肋游仆虫微管蛋白的生物学功能及微管多样性奠定了基础。     

Identification of a gene for beta-tubulin in Aspergillus nidulans.

The tubulins of Aspergillus nidulans have been characterized in wild-type and ben A, B and C benomyl-resistant strains by two-dimensional gel electrophoresis, co-polymerization with porcine brain tubulin and peptide mapping. Four α-tubulins and at least four β-tubulins were resolved by two-dimensional gel electrophoresis of wild-type proteins. Eighteen of 26 benA mutants studied had electrophoretically abnormal β-tubulins. In these strains, one or more of the β-tubulins had either an altered isoelectric point or an altered electrophoretic mobility in the SDS gel dimension, or was diminished in amount. The a-tubulins were normal. Two-dimensional gels of protein extracts of a ben A/wild-type diploid strain demonstrated co-expression of the wild-type β-tubulins with the variant ben A tubulin. This experiment rules out post-translational modification as the source of the β-tubulin abnormalities in the benA mutants. We therefore conclude that benA must be a structural gene for β-tubulin. Due to the variety of abnormalities affecting β-tubulins in ben A mutants, and the absence of abnormalities affecting α-tubulins in any of the benomyl-resistant mutants, we also believe that the benomyl binding site must be located on the β-subunit of the tubulin dimer. The benA mutants of A. nidulans promise to be useful not only for characterizing the biochemical determinants of the benomyl binding site of tubulin but also for understanding the relationship between tubulin structure and function.     

On and Around Microtubules: An Overview

Microtubules are hollow tubes some 25 nm in diameter participating in the eukaryotic cytoskeleton. They are built from αβ-tubulin heterodimers that associate to form protofilaments running lengthwise along the microtubule wall with the β-tubulin subunit facing the microtubule plus end conferring a structural polarity. The α- and β-tubulins are highly conserved. A third member of the tubulin family, γ-tubulin, plays a role in microtubule nucleation and assembly. Other members of the tubulin family appear to be involved in microtubule nucleation. Microtubule assembly is accompanied by hydrolysis of GTP associated with β-tubulin so that microtubules consist principally of ‘GDP-tubulin’ stabilized at the plus end by a short ‘cap’. An important property of microtubules is dynamic instability characterized by growth randomly interrupted by pauses and shrinkage. Many proteins interact with microtubules within the cell and are involved in essential functions such as microtubule growth, stabilization, destabilization, and interactions with chromosomes during cell division. The motor proteins kinesin and dynein use microtubules as pathways for transport and are also involved in cell division. Crystallography and electron microscopy are providing a structural basis for understanding the interactions of microtubules with antimitotic drugs, with motor proteins and with plus end tracking proteins.     

Evolution of the multi-tubulin hypothesis

Microtubules are organized into diverse cellular structures in multicellular organisms. How is such diversity generated? Although highly conserved overall, variable regions within α- and β-tubulins show divergence from other α- and β-tubulins in the same species, but show conservation among different species. Such conservation raises the question of whether diversity in tubulin structure mediates diversity in microtubule organization. Recent studies probing the function of β-tubulin isotypes in axonemes of insects⁽¹⁾ suggest that tubulin structure, through interactions with extrinsic proteins, can direct the architecture and supramolecular organization of microtubules.     

Tubulin Isotypes in Rye Roots Are Altered during Cold Acclimation

The cold stability of cortical microtubules in root-tip cells of winter rye (Secale cereale L. cv Puma) is altered by growth temperature (GP Kerr, JV Carter [1990] Plant Physiol 93:77-82). One hypothesis for the basis of this alteration is that different tubulin isotypes are present at different growth temperatures, and that the cold stability of microtubules is affected by these isotypic differences. We have explored the first part of this hypothesis by comparing protein extracts from roots of seedlings grown for 2 days at 22°C (nonacclimated) or for an additional 2 or 4 days at 4°C (cold-acclimated). Immunoblots of two-dimensional polyacrylamide gels were probed with monoclonal antibodies to α- and β-tubulin. At least six α- and seven β-tubulins were present in the extracts from both the nonacclimated and cold-acclimated roots. Changes in electrophoretic mobility and isotype number of both α- and β-tubulin were observed after only 2 days at 4°C. Further changes in tubulin were observed after 4 days at 4°C. Changes in α-tubulin were more pronounced than those in β-tubulin.     

- and β-tubulin mRNAs of Trypanosoma cruzi originate from a single multicistronic transcript

The cluster of alternated - and β-tubulin genes in the genome of Trypanosoma cruzi was shown to be transcribed into a single RNA molecule which upon processing gives rise to the mature - and β-tubulin mRNAs. This conclusion was based on: (i) nuclear RNA species with the same molecular mass hybridize to both - and β-tubulin cDNA probes; (ii) S₁ nuclease assay of the clustered tubulin genes has shown protected DNA fragments of the same size and of greater molecular mass than that corresponding to the mRNAs, hybridizable to both - and β-tubulin cDNA probes; (iii) β-tubulin hybrid selected RNA is still able to hybridize to -tubulin probe.     

Centrosomes Isolated from Spisula solidissima Oocytes Contain Rings and an Unusual Stoichiometric Ratio of α/β Tubulin

Centrosome-dependent microtubule nucleation involves the interaction of tubulin subunits with pericentriolar material. To study the biochemical and structural basis of centrosome-dependent microtubule nucleation, centrosomes capable of organizing microtubules into astral arrays were isolated from parthenogenetically activated Spisula solidissima oocytes. Intermediate voltage electron microscopy tomography revealed that each centrosome was composed of a single centriole surrounded by pericentriolar material that was studded with ring-shaped structures ~25 nm in diameter and <25 nm in length. A number of proteins copurified with centrosomes including: (a) proteins that contained M-phase–specific phosphoepitopes (MPM-2), (b) α-, β-, and γ-tubulins, (c) actin, and (d) three low molecular weight proteins of <20 kD. γ-Tubulin was not an MPM-2 phosphoprotein and was the most abundant form of tubulin in centrosomes. Relatively little α- or β-tubulin copurified with centrosomes, and the ratio of α- to β-tubulin in centrosomes was not 1:1 as expected, but rather 1:4.6, suggesting that centrosomes contain β-tubulin that is not dimerized with α-tubulin.     

Tubulin and actin protein patterns in Scots pine (Pinus sylvestris) roots and developing ectomycorrhiza with Suillus bovinus

The role of tubulin and actin in the development of Scots pine ( Pinus sylvestris ) roots and in the formation of the ectomycorrhiza with the basidiomycete Suillus bovinus was studied by immunoblotting of 2D-gels with anti-tubulin and anti-actin antibodies. In the short roots the α-tubulin pattern was different from that in the other root types due to the more acidic pI of the two α-tubulins. During the formation of the ectomycorrhiza, two new α-tubulins were detected in the acidic α-tubulin cluster. No such variation occurred in the plant β-tubulin patterns. The fungal tubulins dominated in the ectomycorrhiza, but no changes in tubulin polypeptide patterns from those in the S. bovinus mycelium were observed. Contrary to the tubulins, plant actin dominated in the mycorrhiza. The specific α-tubulin patterns of uninfected and infected short roots indicate that α-tubulin is involved in the morphogenesis of Pinus sylvestris short roots. The high level of plant actin at early stage of the mycorrhiza formation suggests a significant role of this protein in the interaction between plant cells and fungal hyphae.     

Occurrence of two β-tubulin isoforms with different polymerizing abilities in L5178Y cells

Mouse lymphoma L5178Y cells express at least two isoforms of β-tubulin, designated Mβ_I, and Mβ_II, as revealed by isoelectrofocusing, whereas two independently isolated normal T-cell clones, 3D10 and K23, express only Mβ_I. Mβ_II-tubulin is more acidic (pI, 5.10) than Mβ_I-tubulin (pI, 5.15). L5178Y cells were disrupted under the microtubule-stabilizing conditions, followed by centrifugation to separate fractions containing polymerized and unpolymerized tubulin. We found that a proportion of Mβ_II to total β-tubulins is larger in the fraction containing unpolymerized tubulin than in that containing polymerized tubulin. In addition, when tubulin was purified from extracts of L5178Y cells by repeated cycles of polymerization-depolymerization, the Mβ_II-tubulin isoform was gradually lost during the successive purification steps. The low recovery of Mβ_II-tubulin was observed, irrespective of the presence or absence of MAPs, and even in the presence of an excess amount of essentially polymerizable porcine brain tubulin. These results indicate that Mβ_II-tubulin is less able to polymerize than is Mβ_I-tubulin, both in vivo and in vitro.