Isolation of a subpellicular microtubule protein from Trypanosoma brucei that mediates crosslinking of microtubules

The cell body of Trypanosomatidae is enclosed in densely packed, crosslinked, subpellicular microtubules closely underlying the plasma membrane. We isolated the subpellicular microtubules from bloodstream Trypanosoma brucei parasites by use of a zwitterion detergent. These cold stable structures were solubilized by a high ionic strength salt solution, and the soluble proteins that contained tubulin along with several other proteins were further fractionated by Mono S cation exchange column chromatography. Two distinct peaks were eluted containing one protein each, which had an apparent molecular weight of 52 kDa and 53 kDa. (Mr was determined by SDS-gel electrophoresis). Only the 52 kDa protein showed specific tubulin binding properties, which were demonstrated by exposure of nitrocellulose-bound trypanosome proteins to brain tubulin. When this protein was added to brain tubulin in the presence of taxol and GTP, microtubule bundles were formed with regular crosslinks between the parallel closely packed microtubules. The crosslinks were about 7.2 nm apart (center to center). Under the same conditions, but with the 53 kDA protein or without trypanosome derived proteins, brain tubulin polymerized to single microtubules. It is thus suggested that the unique structural organization of the subpellicular microtubules is dictated by specific parasite proteins and is not an inherent property of the polymerizing tubulin. The in vitro reconstituted microtubule bundles are strikingly similar to the subpellicular microtubule network of the parasite.     

Tubulin tyrosination in Crithidia: modifying enzymes and modification states of tubulin

An enzyme that adds C-terminal tyrosine to tubulin has been identified in Crithidia fasciculata. It tyrosinates Crithidia, but not brain, tubulin and is specific for the alpha chain. Crithidia cells could not be shown to fix tyrosine in the absence of protein synthesis, which is consistent with the pattern of distribution of C-terminal tyrosine in tubulin from different subcellular compartments of this protozoan. Terminal tyrosine was present in about 5% of flagellar alpha chain from cells in stationary phase and 20% from cells from midlog phase; none was detected in tubulin from cytosol or the subpellicular corset. In contrast to mammalian cells, in which a higher state of tyrosinolation characterizes recently assembled or unstable microtubules, terminal tyrosine was present only in the most stable polymer, the flagellar doublet microtubules.     

The association of glycosomal enzymes and microtubules: a physiological phenomenon or an experimental artifact?

Subpellicular microtubules isolated from Trypanosoma brucei parasites were fractionated on a phosphocellulose column, and the trypanosomal p52 microtubule-associated protein was eluted along with two other proteins of 41 and 36 kDa. These proteins were found to be the glycosomal enzymes aldolase (41 kDa) and glyceraldehyde-3-phosphate dehydrogenase (GAPDH, 36 kDa) by enzyme activity, antibody cross-reaction, and N-terminal sequencing. These enzymes were coprecipitated with tubulin in the presence of taxol, and aldolase had the capacity to polymerize tubulin and crosslink microtubules. Immunolocalization of anti-aldolase and anti-GAPDH antibodies did not show an interaction between these enzymes and the subpellicular microtubules. The question whether the copurification of aldolase and the subpellicular microtubules could reflect a physiological phenomenon or may be an experimental artifact is discussed.     

Trypanosoma cruzi: cell type dependent distribution of a tubulin domain in mammalian stages

The distribution of tubulin domains in the mammalian stages of Trypanosoma cruzi was investigated by using monoclonal antibodies elicited against bovine brain tubulin. Western blotting performed on T. brucei trypomastigotes and T. cruzi epimastigotes showed that the monoclonal antibodies 16D3 and 24E3 reacted only with tubulin in these cell types. Indirect immunofluorescence revealed that, whereas 16D3 stained all microtubules, including subpellicular microtubules, the epitope defined by 24E3 was found in only a part of the tubulin pool of amastigotes and intermediate stages infecting murine fibroblasts and of broad trypomastigotes; the staining was limited to the basal bodies and the distal region of the flagellar adhesion zone in these developmental forms. By contrast, slender trypomastigotes did not exhibit any reaction with 24E3. These results are consistent with a transformation of broad trypomastigotes into slender trypomastigotes during which the tubulin domain recognized by 24E3 would undergo modifications leading to its complete masking in slender forms. The morphogenesis of the mammalian stages of T. cruzi would involve modifications of the tubulin molecule.     

γ‐Tubulin complex in Trypanosoma brucei: molecular composition,subunit interdependence and requirement for axonemal central pair protein assembly

γ‐Tubulin complex constitutes a key component of the microtubule‐organizing center and nucleates microtubule assembly. This complex differs in complexity in different organisms: the budding yeast contains the γ‐tubulin small complex (γTuSC) composed of γ‐tubulin, gamma‐tubulin complex protein (GCP)2 and GCP3, whereas animals contain the γ‐tubulin ring complex (γTuRC) composed of γTuSC and three additional proteins, GCP4, GCP5 and GCP6. In Trypanosoma brucei, the composition of the γ‐tubulin complex remains elusive, and it is not known whether it also regulates assembly of the subpellicular microtubules and the spindle microtubules. Here we report that the γ‐tubulin complex in T. brucei is composed of γ‐tubulin and three GCP proteins, GCP2‐GCP4, and is primarily localized in the basal body throughout the cell cycle. Depletion of GCP2 and GCP3, but not GCP4, disrupted the axonemal central pair microtubules, but not the subpellicular microtubules and the spindle microtubules. Furthermore, we showed that the γTuSC is required for assembly of two central pair proteins and that γTuSC subunits are mutually required for stability. Together, these results identified an unusual γ‐tubulin complex in T. brucei, uncovered an essential role of γTuSC in central pair protein assembly, and demonstrated the interdependence of individual γTuSC components for maintaining a stable complex.     

Intrinsically slow dynamic instability of HeLa cell microtubules in vitro

The dynamic behavior of mammalian microtubules has been extensively studied, both in living cells and with microtubules assembled from purified brain tubulin. To understand the intrinsic dynamic behavior of mammalian nonneural microtubules, we purified tubulin from cultured HeLa cells. We find that HeLa cell microtubules exhibit remarkably slow dynamic instability, spending most of their time in an attenuated state. The tempered dynamics contrast sharply with the dynamics of microtubules prepared from purified bovine brain tubulin under similar conditions. In accord with their minimal dynamic instability, assembled HeLa cell microtubules displayed a slow treadmilling rate and a low guanosine-5'-triphosphate hydrolysis rate at steady state. We find that unlike brain tubulin, which consists of a heterogeneous mixture of beta-tubulin isotypes (beta(II), beta(III), and beta(IV) and a low level of beta(I)), HeLa cell tubulin consists of beta(I) tubulin ( approximately 80%) and a minor amount of beta(IV) tubulin ( approximately 20%). The slow dynamic behavior of HeLa cell microtubules in vitro differs strikingly from the dynamic behavior of microtubules in living cultured mammalian cells, supporting the idea that accessory factors create the robust dynamics that occur in cells.     

The in vitro assembly of flagellar outer doublet tubulin

Flagellar outer doublet microtubules were solubilized by use of sonication, and the tubulin was reassembled in vitro into single microtubules containing 14 and 15 protofilaments. The tubulin assembly was dependent on both the KCl and tubulin concentrations, exhibiting a critical concentration of 0.72 mg/ml at optimum solvent conditions. Flagellar tubulin was purified by cycles of temperature-dependent assembly-disassembly and molecular sieve chromatography, and characterized by two-dimensional gel electrophoresis. Although doublet microtubules were not formed in vitro, outer doublet tubulin assembled onto intact A- and B-subfibers of outer doublet microtubules and basal bodies of Chlamydomonas; the rate of assembly from the distal ends of these structures was greater than that from the proximal ends. Microtubule-associated proteins (MAPs) from mammalian brain stimulated outer doublet tubulin assembly, decorating the microtubules with fine filamentous projections.     

The affinity of DNA-microtubule protein complexes and their disruption by tubulin binding drugs.

Using the gel shift assay system, we have measured the apparent affinity constant for the interaction of two different DNAs with MAP proteins found in both total calf brain microtubules and heat stable brain preparations. Both DNAs studied contained centromere/kinetochore sequences- one was enriched in the calf satellite DNA; the other was a large restriction fragment containing the yeast CEN11 DNA sequence. Complexes formed using both DNAs had similar Kapp values in the range of 2.1 x 10(7) M-1 to 2.0 x 10(8) M-1. CEN11 DNA-MTP complexes had by far the highest Kapp value of 2.0 x 10(8) M-1. The CEN11 DNA sequence is where the yeast kinetochore of chromosome 11 is formed and where the single yeast microtubule is bound in vivo. The CEN11 conserved region II known binding sites-(dA/dT)n runs- for mammalian MAP2 protein, are in good agreement with this higher Kapp value. The effects of the classical tubulin binding drugs colchicine, podophyllotoxin and vinblastine on the DNA-MAP protein complex stability were investigated by determining the drug concentrations where the complexes were destabilized. Only the complexes formed from total microtubule protein (tubulin containing) were destabilized over a wide drug concentration range. Heat stable brain protein complexes (no tubulin) were largely unaffected. Furthermore, it took 10-100 fold higher drug concentrations to disrupt the CEN11 DNA complexes compared to the calf thymus satellite DNA enriched complexes. These data support our previous results suggesting that there is a DNA sequence dependent interaction with MAP proteins that appears to be conserved in evolution (Marx et. al., Biochim. Biophys. Acta. 783, 383-392, 1984; Marx and Denial, Molecular Basis of Cancer 172B, 65-75 1985). In addition, these results imply that the classical tubulin binding drugs may exert their biological effects in cells at least in part by disrupting DNA-Protein complexes of the type we have studied here.     

Epothilone and paclitaxel: unexpected differences in promoting the assembly and stabilization of yeast microtubules

Paclitaxel (Taxol) and the epothilones are antimitotic agents that promote the assembly of mammalian tubulin and stabilization of microtubules. The epothilones competitively inhibit the binding of paclitaxel to mammalian brain tubulin, suggesting that the two types of compounds share a common binding site in tubulin, despite the lack of structural similarities. It is known that paclitaxel does not stabilize microtubules formed in vitro from Saccharomyces cerevisiae tubulin; thus, it would be expected that the epothilones would not affect yeast microtubules. However, we found that epothilone A and B do stimulate the formation of microtubules from purified yeast tubulin. In addition, epothilone B severely dampens the dynamics of yeast microtubules in vitro in a manner similar to the effect of paclitaxel on mammalian microtubules. We used current models describing paclitaxel and epothilone binding to mammalian beta-tubulin to explain why paclitaxel apparently fails to bind to yeast tubulin. We propose that three amino acid substitutions in the N-terminal region and at position 227 in yeast beta-tubulin weaken the interaction of the 3'-benzamido group of paclitaxel with the protein. These results also indicate that mutagenesis of yeast tubulin could help define the sites of interaction with paclitaxel and the epothilones.     

Tubulin tyrosination is a major factor affecting the recruitment of CAP-Gly proteins at microtubule plus ends

Tubulin-tyrosine ligase (TTL), the enzyme that catalyzes the addition of a C-terminal tyrosine residue to alpha-tubulin in the tubulin tyrosination cycle, is involved in tumor progression and has a vital role in neuronal organization. We show that in mammalian fibroblasts, cytoplasmic linker protein (CLIP) 170 and other microtubule plus-end tracking proteins comprising a cytoskeleton-associated protein glycine-rich (CAP-Gly) microtubule binding domain such as CLIP-115 and p150 Glued, localize to the ends of tyrosinated microtubules but not to the ends of detyrosinated microtubules. In vitro, the head domains of CLIP-170 and of p150 Glued bind more efficiently to tyrosinated microtubules than to detyrosinated polymers. In TTL-null fibroblasts, tubulin detyrosination and CAP-Gly protein mislocalization correlate with defects in both spindle positioning during mitosis and cell morphology during interphase. These results indicate that tubulin tyrosination regulates microtubule interactions with CAP-Gly microtubule plus-end tracking proteins and provide explanations for the involvement of TTL in tumor progression and in neuronal organization.     

Brain-specific p25 protein binds to tubulin and microtubules and induces aberrant microtubule assemblies at substoichiometric concentrations

Previously, we have demonstrated the presence of a protein factor [tubulin polymerization perturbing protein (TPPP)] in brain and neuroblastoma cell but not in muscle extract that uniquely influences the microtubule assembly. Here we describe a procedure for isolation of this protein from the cytosolic fraction of bovine brain and present evidence that this protein is a target of both tubulin and microtubules in vitro. The crucial step of the purification is the cationic exchange chromatography; the bound TPPP is eluted at high salt concentrations, indicating the basic character of the protein. By IDA-nanoLC-MS analysis of the peptides extracted from the gel-digested purified TPPP, we show the presence of a single protein in the purified fraction that corresponds to p25, a brain-specific protein the function of which has not been identified. Circular dichroism data have revealed that, on one hand, the alpha-helix content of p25 is very low (4%) with respect to the predicted values (30-43%), and its binding to tubulin induces remarkable alteration in the secondary structure of the protein(s). As shown by turbidimetry, pelleting experiments, and electron microscopy, p25 binds to paclitaxel-stabilized microtubules and bundles them. p25 induces formation of unusual (mainly double-walled) microtubules from tubulin in the absence of paclitaxel. The amount of aberrant tubules formed depends on the p25 concentration, and the process occurs at substoichiometric concentrations. Our in vitro data suggest that p25 could act as a unique MAP in vivo.     

Dynamics of microtubules from erythrocyte marginal bands.

Microtubules can adjust their length by the mechanism of dynamic instability, that is by switching between phases of growth and shrinkage. Thus far this phenomenon has been studied with microtubules that contain several components, that is, a mixture of tubulin isoforms, with or without a mixture of microtubule-associated proteins (MAPs), which can act as regulators of dynamic instability. Here we concentrate on the influence of the tubulin component. We have studied MAP-free microtubules from the marginal band of avian erythrocytes and compared them with mammalian brain microtubules. The erythrocyte system was selected because it represents a naturally stable aggregate of microtubules; second, the tubulin is largely homogeneous, in contrast to brain tubulin. Qualitatively, erythrocyte microtubules show similar features as brain microtubules, but they were found to be much less dynamic. The critical concentration of elongation, and the rates of association and dissociation of tubulin are all lower than with brain microtubules. Catastrophes are rare, rescues frequent, and shrinkage slow. This means that dynamic instability can be controlled by the tubulin isotype, independently of MAPs. Moreover, the extent of dynamic behavior is highly dependent on buffer conditions. In particular, dynamic instability is strongly enhanced in phosphate buffer, both for erythrocyte marginal band and brain microtubules. The lower stability in phosphate buffer argues against the hypothesis that a cap of tubulin.GDP.Pi subunits stabilizes microtubules. The difference in dynamics between tubulin isotypes and between the two ends of microtubules is preserved in the different buffer systems.     

Distribution of acetylated tubulin in cultured cells and tissues from the Atlantic cod (Gadus morhua). Role of acetylation in cold adaptation and drug stability

The Atlantic cod (Gadus morhua) is a poikilothermic animal living at temperatures between 2-15°C. Isolated cod brain tubulin is, in contrast to mammalian brain tubulin, posttranslationally modified by acetylation to a high extent. To investigate the role of acetylation in cold adaptation, microtubules were isolated by a taxol-dependent procedure from different organs of the cod, and cells from different tissues were cultured. All cells from skin and brain were able to grow between 4°C and room temperature. Microtubules in the cultured cells were sometimes severed near the periphery of the cells. Microtubules in brain cells were in general more stable to vinblastine and colchicine, when compared to skin cells. Acetylated microtubules were found only in brain cells, in peripheral nerves on scales and in nerves of the intestinal tract and in microtubules isolated from neuronal tissue. Our results show that acetylated microtubules are found both in the central and peripheral nervous system, but that there is no correlation between acetylation and cold-adaptation.     

Subpellicular and flagellar microtubules of Trypanosoma brucei brucei contain the same alpha-tubulin isoforms

The cytoskeleton of the parasitic hemoflagellate Trypanosoma brucei brucei essentially consists of two microtubule-based structures: a subpellicular layer of singlet microtubules, which are in close contact with the cell membrane, and the flagellar axoneme. In addition, the cells contain a small pool of soluble tubulin. Two-dimensional gel electrophoretic analysis of the tubulins present in these subcellular compartments revealed two distinct electrophoretic isoforms of alpha-tubulin, termed alpha 1 and alpha 3. alpha 1-Tubulin most likely represents the primary translation product, while alpha 3-tubulin is a posttranslationally acetylated derivative of alpha 1-tubulin. In the pool of soluble cytoplasmic tubulin, alpha 1 is the predominant species, while the very stable flagellar microtubules contain almost exclusively the alpha 3-tubulin isoform. The subpellicular microtubules contain both isoforms. Neither of the two alpha-tubulin isoforms is organelle specific, but the alpha 3 isoform is predominantly located in stable microtubules.     

Temperature-dependent reversible assembly of taxol-treated microtubules

Taxol is a plant alkaloid that binds to and strongly stabilizes microtubules. Taxol-treated microtubules resist depolymerization under a variety of conditions that readily disassemble untreated microtubules. We report here that taxol-treated microtubules can be induced to disassemble by a combination of depolymerizating conditions. Reversible cycles of disassembly and reassembly were carried out using taxol-containing microtubules from calf brain and sea urchin eggs by shifting temperature in the presence of millimolar levels of Ca2+. Microtubules depolymerized completely, yielding dimers and ring-shaped oligomers as revealed by negative stain electron microscopy and Bio-Gel A-15m chromatography, and reassembled into well-formed microtubule polymer structures. Microtubule-associated proteins (MAPs), including species previously identified only by taxol-based purification such as MAP 1B and kinesin, were found to copurify with tubulin through reversible assembly cycles. To determine whether taxol remained bound to tubulin subunits, we subjected depolymerized taxol-treated microtubule protein to Sephadex G-25 chromatography, and the fractions were assayed for taxol content by reverse-phase HPLC. Taxol was found to be dissociated from the depolymerized microtubules. Protein treated in this way was found to be competent to reassemble, but now required conditions comparable with those for protein that had never been exposed to taxol. Thus, the binding of taxol to tubulin can be reversed. This has implications for the mechanism of taxol action and for the purification of microtubules from a wide variety of sources for use in self-assembly experiments.     

The Affinity of DNA-Microtubule Protein Complexes and their Disruption by Tubulin Binding Drugs

Abstract

Using the gel shift assay system, we have measured the apparent affinity constant for the interaction of two different DNAs with MAP proteins found in both total calf brain microtubules and heat stable brain preparations. Both DNAs studied contained centromere/kinetochore sequences- one was enriched in the calf satellite DNA; the other was a large restriction fragment containing the yeast CEN11 DNA sequence. Complexes formed using both DNAs had similar K_app values in the range of 2.1×10⁷ M^?1 to 2.0×10⁸ M^?1. CEN11 DNA-MTP complexes had by far the highest K_app value of 2.0×10⁸ M^?1. The CEN11 DNA sequence is where the yeast kinetochore of chromosome 11 is formed and where the single yeast microtubule is bound in vivo. The CEN11 conserved region II known binding sites -(dA/dT)n runs- for mammalian MAP2 protein, are in good agreement with this higher K_app value. The effects of the classical tubulin binding drugs colchicine, podophyllotoxin and vinblastine on the DNA-MAP protein complex stability were investigated by determining the drug concentrations where the complexes were destabilized. Only the complexes formed from total microtubule protein (tubulin containing) were destabilized over a wide drug concentration range. Heat stable brain protein complexes (no tubulin) were largely unaffected. Furthermore, it took 10–100 fold higher drug concentrations to disrupt the CEN 11 DNA complexes compared to the calf thymus satellite DNA enriched complexes. These data support our previous results suggesting that there is a DNA sequence dependent interaction with MAP proteins that appears to be conserved in evolution (Marx et. al., Biochim. Biophys. Acta. 783, 383–392,1984; Marx and Denial, Molecular Basis of Cancer 172B,65-15 1985). In addition, these results imply that the classical tubulin binding drugs may exert their biological effects in cells at least in part by disrupting DNA-Protein complexes of the type we have studied here.     

Dehydration and embedding temperatures affect the antigenic specificity of tubulin and immunolabeling by the protein A-colloidal gold technique

Qualitative and quantitative tests were performed to determine whether the temperature at which dehydration and embedding occur affects the antigenic specificity of tubulin and the protein A-gold (pAg) immunolabeling technique. The analysis indicates that low temperature (-35 degrees C) treatment increased the specificity and density of pAg labeled anti-tubulin antibodies to Leishmania tropica subpellicular microtubules as compared to samples prepared at 0 degrees C or 20 degrees C.     

Antimitotic antifungal compound benomyl inhibits brain microtubule polymerization and dynamics and cancer cell proliferation at mitosis, by binding to a novel site in tubulin

The antifungal agent benomyl [methyl-1-(butylcarbamoyl)-2-benzimidazolecarbamate] is used throughout the world against a wide range of agricultural fungal diseases. In this paper, we investigated the interaction of benomyl with mammalian brain tubulin and microtubules. Using the hydrophobic fluorescent probe 1-anilinonaphthalene-8-sulfonic acid, benomyl was found to bind to brain tubulin with a dissociation constant of 11.9 +/- 1.2 microM. Further, benomyl bound to at a novel site, distinct from the well-characterized colchicine and vinblastine binding sites. Benomyl altered the far-UV circular dichroism spectrum of tubulin and reduced the accessibility of its cysteine residues to modification by 5,5'-dithiobis-2-nitrobenzoic acid, indicating that benomyl binding to tubulin induces a conformational change in the tubulin. Benomyl inhibited the polymerization of brain tubulin into microtubules, with 50% inhibition occurring at a concentration of 70-75 microM. Furthermore, it strongly suppressed the dynamic instability behavior of individual brain microtubules in vitro as determined by video microscopy. It reduced the growing and shortening rates of the microtubules but did not alter the catastrophe or rescue frequencies. The unexpected potency of benomyl against mammalian microtubule polymerization and dynamics prompted us to investigate the effects of benomyl on HeLa cell proliferation and mitosis. Benomyl inhibited proliferation of the cells with an IC(50) of 5 microM, and it blocked mitotic spindle function by perturbing microtubule and chromosome organization. The greater than expected actions of benomyl on mammalian microtubules and mitosis together with its relatively low toxicity suggest that it might be useful as an adjuvant in cancer chemotherapy.     

A carbamate herbicide causes microtubule and microfilament disruption and nuclear fragmentation in fibroblasts

Microtubule associated proteins (MAPs) are high molecular weight proteins that associate with microtubules during polymerization. This report describes a high molecular weight protein fraction with a molecular weight of approx. 290 000 from cultured mammalian fibroblasts that associates with polymerized rat brain tubulin. This protein(s), which is referred to as f-MAP, is enriched approx. 25-fold in a twice polymerized microtubules when compared with the original cell extract. Polymerization of rat brain extract in the presence of in vivo ³²P-labeled fibroblast extract reveals the presence of a ³²P-labeled protein in the polymerized pellet with the same electrophoretic mobility as f-MAP. The present study suggests that fibroblasts in culture contain a high molecular weight phosphoprotein with properties and a molecular weight very similar to the MAPs described in mammalian brain.     

Tau protein function in living cells

Tau protein from mammalian brain promotes microtubule polymerization in vitro and is induced during nerve cell differentiation. However, the effects of tau or any other microtubule-associated protein on tubulin assembly within cells are presently unknown. We have tested tau protein activity in vivo by microinjection into a cell type that has no endogenous tau protein. Immunofluorescence shows that tau protein microinjected into fibroblast cells associates specifically with microtubules. The injected tau protein increases tubulin polymerization and stabilizes microtubules against depolymerization. This increased polymerization does not, however, cause major changes in cell morphology or microtubule arrangement. Thus, tau protein acts in vivo primarily to induce tubulin assembly and stabilize microtubules, activities that may be necessary, but not sufficient, for neuronal morphogenesis.