Electron microscope demonstration of tubulin in cilia and basal bodies of rat tracheal epithelium by the use of an antitubulin antibody

It has been previously demonstrated that both cytoplasmic microtubules and the microtubules of cilia, flagella, and sperm tail contain tubulin. Although the morphology of cytoplasmic microtubules and that of axonemes differs in cells from which they have been isolated, the tubulin of the two structures shares physical and chemical properties. In some mammalian tissues, such as tracheal epithelium, cilia and basal bodies are difficult to isolate and characterize. The use of an enzyme- labeled immunoglobulin probe would facilitate identification and in situ localization of such proteins. Tubulin prepared from porcine brain by ion-exchange chromatography and from rat brain by the method of cyclic polymerization and depolymerization with subsequent disk gel electrophoresis with SDS were injected intravenously into rabbits. The animals were intermittently bled and the antisera extracted. The specificity of the antisera was proved by indirect immunofluorescence staining of the mitotic spindle, specific blocking of spindle staining by purified tubulin and not by other proteins, staining of 3T3 cytoplasmic microtubules, single line on immunoelectrophoresis, failure of control antisera to show any of these, and precipitation of antibody with all tubulin preparations and not with actin. We have shown by electron microscopy of ciliated cells of the tracheal epithelium stained with antitubulin by the indirect enzyme-labeled antibody method that the basal bodies, outer doublets, and central pair of the cilia contain tubulin. This indicates that tubulin in microtubules of cilia and basal bodies of rat tracheal epithelium is antigenically similar to tubulin extracted from cytoplasmic neurotubules of brains from the same species and from a different mammalian species. No other axonemal structures stained with the antitubulin. Three different preparations of tubulin from pigs and rats were used to immunize rabbits. All elicited similar antisera which gave identical staining patterns. The specificity of the staining was demonstrated by the absence of staining with immune serum absorbed with purified tubulin, the absence of staining with preimmune serum, and the absence of staining if any of the reagents were omitted during the staining reaction.     

Postpolymerization detyrosination of alpha-tubulin: a mechanism for subcellular differentiation of microtubules

Tyrosinated (Tyr) and detyrosinated (Glu) alpha-tubulin, species interconverted by posttranslational modification, are largely segregated in separate populations of microtubules in interphase cultured cells. We sought to understand how distinct Tyr and Glu microtubules are generated in vivo, by examining time-dependent alterations in Tyr and Glu tubulin levels (by immunoblots probed with antibodies specific for each species) and distributions (by immunofluorescence) after microtubule regrowth and stabilization. When microtubules were allowed to regrow after complete depolymerization by microtubule antagonists, Glu microtubules reappeared with a delay of approximately 25 min after the complete array of Tyr microtubules had regrown. In these experiments, Tyr tubulin immunofluorescence first appeared as an aster of distinct microtubules, while Glu tubulin staining first appeared as a grainy pattern that was not altered by detergent extraction, suggesting that Glu microtubules were created by detyrosination of Tyr microtubules. Treatments with taxol, azide, or vinblastine, to stabilize polymeric tubulin, all resulted in time-dependent increases in polymeric Glu tubulin levels, further supporting the hypothesis of postpolymerization detyrosination. Analysis of monomer and polymer fractions during microtubule regrowth and in microtubule stabilization experiments were also consistent with postpolymerization detyrosination; in each case, Glu polymer levels increased in the absence of detectable Glu monomer. The low level of Glu monomer in untreated or nocodazole-treated cells (we estimate that Glu tubulin comprises less than 2% of the monomer pool) also suggested that Glu tubulin entering the monomer pool is efficiently retyrosinated. Taken together these results demonstrate that microtubules are polymerized from Tyr tubulin and are then rapidly converted to Glu microtubules. When Glu microtubules depolymerize, the resulting Glu monomer is retyrosinated. This cycle generates structurally, and perhaps functionally, distinct microtubules.     

Identifying the site of microtubule polymerization during regrowth of UV-sheared kinetochore fibres using antibodies against acetylated alpha-tubulin

Areas of reduced birefringence (ARBs) produced on chromosomal fibres of crane-fly spermatocyte spindles by ultraviolet microbeam irradiation move poleward. The ARB is due to the depolymerization of the microtubules in that area, and its poleward motion is due in part to the lengthening of that part of the kinetochore fibre which is left attached to the kinetochore after shearing the microtubules. We tested whether the lengthening of this fibre is due to the polymerization of microtubules at the growing edge of the ARB by staining growing fibres in irradiated spindles with antibodies to tubulin and to acetylated tubulin. We have previously argued that newly-polymerized kinetochore microtubules are not acetylated, whereas older kinetochore microtubules are (Wilson & Forer, 1989). Therefore we expected to see an absence of staining with antibodies to acetylated tubulin at the edge of the ARB if microtubules were polymerizing there. There is no absence of staining, however, which suggests that growth of the sheared microtubules does not occur at the ARB edge. Other possibilities are discussed.     

Assembly and turnover of detyrosinated tubulin in vivo

Detyrosinated (Glu) tubulin was prepared from porcine brain and microinjected into human fibroblasts and Chinese hamster ovary (CHO) cells. Glu tubulin assembled onto the ends of preexisting microtubules and directly from the centrosome within minutes of its microinjection. Incorporation into the cytoskeleton continued until almost all of the microtubules were copolymers of Glu and tyrosinated (Tyr) tubulin. However, further incubation resulted in the progressive and ultimately complete loss of Glu-staining microtubules. Glu tubulin injected into nocodazole-treated cells was converted to Tyr tubulin by a putative tubulin/tyrosine ligase activity. The observed decrease in staining with the Glu antibody over time was used to analyze microtubule turnover in microinjected cells. The mode of Glu disappearance was analyzed quantitatively by tabulating the number of Glu-Tyr copolymers and Tyr-only microtubules at fixed times after injection. The proportion of Glu-Tyr copolymers decreased progressively over time and no segmentally labeled microtubules were observed, indicating that microtubules turn over rapidly and individually. Our results are consistent with a closely regulated tyrosination-detyrosination cycle in living cells and suggest that microtubule turnover is mediated by dynamic instability.     

Localization of acetylated alpha-tubulin in Tritrichomonas foetus and Trichomonas vaginalis

We used monoclonal antibodies specific for acetylated and nonacetylated alpha-tubulin to detect and to localize microtubules containing acetylated alpha-tubulin (stable microtubules) in the pathogenic protozoa Tritrichomonas foetus and Trichomonas vaginalis. SDS-PAGE analysis showed that tubulin is a major protein of both parasites, being enriched in cytoskeletal preparations of whole cells extracted with Triton X-100. The monoclonal antibodies, which recognize all isoforms of alpha-tubulin (B-5-1-2) and only acetylated alpha-tubulin (6-11B-1), bind to the tubulin of T. foetus and T. vaginalis as seen by immunoblotting. Tubulin-containing structures were localized using immunofluorescence microscopy and transmission electron microscopy of the whole cytoskeleton previously incubated in the presence of the anti-tubulin antibodies and a second antibody-gold complex, and then processed using the negative staining or replica techniques. The results obtained indicate that, in addition to the flagellar microtubules, those which form the peltar-axostyle system represent stable microtubules containing acetylated alpha-tubulin.     

Localization of tubulin in the mitotic apparatus of mammalian cells by immunofluorescence and immunoelectron microscopy

Antitubulin antibody was used as an immunofluorescent and immunoelectron microscopic probe to localize tubulin in components of the mitotic apparatus of rat kangaroo (strain PtK₁) cells in vitro. In addition to the detection of tubulin in the spindle microtubules and centrioles, other structures were found to display specific staining including kinetochores, amorphous pericentriolar material and small virus-like particles associated with the centrioles. The kinetochores consisted of a densely stained outer layer about 400 Å thick which is separated from an inner layer of the same dimension by a lightly staining middle layer. Microtubules were primarily associated with the outermost plate of the kinetochore but tubulin was uniformly distributed in both outer and inner plates. Colcemid treatment prevented the assembly of spindle microtubules and resulted in specific alterations of the kinetochore but failed to diminish the staining of the kinetochores. These observations suggest that tubulin molecules may comprise an important structural component of the kinetochore.     

Distribution of microtubules and microfilaments in thyroid follicular epithelial cells of normal,TSH-treated,aged, and hypophysectomized rats

Summary We investigated the distribution of microtubules and microfilaments in rat thyroid follicular epithelial cells by applying an immunofluorescence technique with monoclonal antibodies against tubulin and by staining sections with rhodamine-phalloidin. In normal thyroid cells, microtubules run longitudinally from the apical region to the basal region intersecting with each other. In addition, intense labelling with tubulin antibodies was observed in the apical part of the cell. The ultrastructural examinations showed that microtubules often run along the apical plasma membrane. Dot-like labelling with anti-tubulin antibodies was often observed in the perinuclear space, but no microtubules were recognized in the nucleus. Microfilaments bound to rhodamine-phalloidin were distributed mainly beneath the apical plasma membrane, and the portion along the basolateral membrane was scarcely positive. The apical pole of the follicle cell was also decorated by anti-microtubule-associated protein-2 (MAP-2). After TSH stimulation, the intensity of immunocytochemical staining against tubulin was remarkably increased in the cytoplasm. Simultaneously, at the apical region, the staining intensity of rhodamine-phalloidin was increased. Microtubules and microfilaments appeared in the pseudopods after TSH injection. In hypophysectomized or aged rats, thyroid follicular epithelial cells decreased in height, and both immunofluorescent labelling against tubulin and rhodamine-phalloidin labelling were markedly decreased. These results indicate that the distribution and polymerization of microtubules and microfilaments in thyroid follicular epithelial cells vary with the functional stage.     

Ultrastructural colocalization of tyrosinated and detyrosinated alpha-tubulin in interphase and mitotic cells

Immunofluorescence with specific peptide antibodies has previously established that tyrosinated (Tyr) and detyrosinated (Glu) tubulin, the two species generated by posttranslational modification of the COOH-terminus of alpha-tubulin, are present in distinct, but overlapping, subsets of microtubules in cultured cells (Gundersen, G. G., M. H. Kalnoski, and J. C. Bulinski, 1984, Cell, 38:779-789). Similar results were observed by light microscopic immunogold staining in the two cell types used in this study, CV1 and PtK2 cells: most microtubules were stained with the Tyr antibody, whereas only a few were stained with the Glu antibody. We have examined immunogold-stained preparations by electron microscopy to extend these results. In general, electron microscopic localization confirmed results obtained at the light microscopic level: the majority of the microtubules in CV1 and PtK2 cells were nearly continuously labeled with the Tyr antibody, whereas only a few were heavily labeled with the Glu antibody. However, in contrast to the light microscopic staining, we found that all microtubules of interphase and mitotic CV1 and PtK2 cells contained detectable Tyr and Glu immunoreactivity at the electron microscopic level. No specific localization of either species was observed in microtubules near particular organelles (e.g., mitochondria or intermediate filaments). Quantification of the relative levels of Glu and Tyr immunoreactivity in individual interphase and metaphase microtubules showed that all classes of spindle microtubules (i.e., kinetochore, polar, and astral) contained nearly the same level of Glu immunoreactivity; this level of Glu immunoreactivity was lower than that found in all interphase microtubules. Most interphase microtubules had low levels of Glu immunoreactivity, whereas a few had relatively high levels; the latter corresponded to morphologically sinuous microtubules. Quantification of the relative levels of Tyr and Glu immunoreactivity in segments along individual microtubules suggested that the level of Tyr (or Glu) tubulin in a given microtubule was uniform along its length. Understanding how microtubules with different levels of Tyr and Glu tubulin arise will be important for understanding the role of tyrosination/detyrosination in microtubule function. Additionally, the coexistence of microtubules with different levels of the two species may have important implications for microtubule dynamics in vivo.     

Interaction of captan with mammalian microtubules

Using turbidometry, electron microscopy and immunofluorescent microscopy experiments we studied the effect of captan, a widely used pesticide on mammalian microtubules and microfilaments. Turbidometry at 350 nm showed a dose-dependent inhibition of tubulin assembly incubated with captan. The pesticide, given at equimolar concentration with tubulin (30 microM), caused the total inhibition of microtubule formation, while at lower concentrations (5-20 microM) the inhibition of tubulin polymerization was less extensive. At the same concentration range (5-30 microM), captan also promoted the disassembly of performed microtubules. The results of the in vitro effects of captan with microtubules were confirmed in parallel by electron microscopic studies. In vivo, captan caused also depolymerization of microtubules in cultured mouse fibroblasts as shown by indirect immunofluorescent staining of tubulin. The extent of microtubules disassembly was concentration- and time-dependent. While incubation of the cells with 10 microM captan for 3 h disturbs totally the microtubular structures, incubation with 5 microM captan needs 12 h for the same effect. Recovery of microtubules was observed, when preincubated cells were extensively washed. No interaction of this drug with equimolar concentration of G- or F-actin could be observed in vitro, as shown by polymerization experiments. In line with this, the fluorescent actin pattern in mouse fibroblasts incubated with 10 mM captan for up to 12 h did not seem to be altered. From these results it is concluded that captan interacts in equimolar concentrations with tubulin affecting the assembly and disassembly of microtubules in vitro and in cultures of mammalian cells.     

Synapsin-1 is found in a microtubule-associated complex of proteins isolated from bovine brain

We have prepared microtubules from brain tissue by stabilizing the cellular microtubules in 6.7 M glycerol buffer, instead of the usual procedure which extracts the solubilized protein and then reassembles microtubules in vitro at some later time. There are substantial differences in the microtubule associated proteins obtained by the two methods, and brain spectrin is a major component of the stabilized microtubules. We have now modified the buffer used for the isolation of stabilized microtubules to minimize their tendency to aggregate. When the stabilized microtubules were further purified by sucrose density gradient centrifugation, we were able to distinguish previously unidentified polypeptides at 49, 74 (doublet), and 100 kilodaltons (doublet). These bands maintained staining intensity in the same proportion to tubulin as in the original homogenate, whereas background proteins were diminished in staining intensity. We now report the identification of the 74-kilodalton doublet polypeptides as synapsin-1 by peptide mapping. Synapsin-1 is a protein known to bind to brain spectrin and also to microtubules, and may thus serve as a linker between these cytoskeletal components.     

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.     

Spatial distribution of posttranslationally modified tubulins in polarized cells of developing Artemia

In many differentiated cells, posttranslationally modified tubulins exhibit restricted subcellular distribution, leading to the proposal that they are required for the production and maintenance of polarity. To study this possibility, we used immunological approaches to examine tubulin isoforms in developing Artemia larvae and to determine their location in several types of cells within the organism. The amount of tubulin in relation to total protein remained relatively constant during early larval development while detyrosinated tubulin increased, an event correlated with the differentiation of larval gut muscle cells. Except for epidermal cells of the developing thorax, each type of cell within the Artemia larvae exhibited characteristic staining patterns which were very similar for each antitubulin antibody. Within epidermal cells, microtubules containing acetylated tubulin appeared patchy or punctate in their distribution, an image not seen with the other antibodies. In most polarized cells, staining for tubulin and actin colocalized in discrete areas, demonstrating enrichment of both proteins within the same cellular compartment and suggesting functional interactions. Mitotic figures were stained with qualitatively equal intensity by all of the antitubulin antibodies, but asters were not observed. Midbodies were intensely stained with phalloidin as well as the antibodies to tubulin. It was clear that microtubules exhibited a preferential localization in cells of Artemia but in no case was a tubulin isoform found exclusively in one area of a cell. The results support the contention that microtubules influence the organization of polarized cell structure and function but they do not permit the conclusion that this capability is dependent on the localization of posttranslationally modified tubulins to restricted subcellular positions.     

Vaults bind directly to microtubules via their caps and not their barrels

Vaults are large (13 Mda) ribonucleoprotein particles that are especially abundant in multidrug resistant cancer cells and have been implicated in nucleocytoplasmic drug transport. To understand how these large barrel-shaped complexes are transported through the cytosol, we examined the association of vaults with microtubules both in vitro and in vivo. Within cells, a subpopulation of vaults clearly associates with microtubules, and these vaults remain associated with tubulin dimers/oligomers when microtubules are disassembled by nocodazole treatment. In vitro, a microtubule-pull down assay using highly purified rat vaults and reassembled microtubules reveals that vaults exhibit concentration-dependent binding to microtubules that does not require the carboxyl terminal end of tubulin. Remarkably, negative staining for electron microscopy reveals that vault binding to microtubules is mediated by the vault caps; more than 82% of bound vaults attach to the microtubule lattice with their long axes perpendicular to the long axis of the microtubule. Five to six vault particles were bound per micron of microtubule, with no crosslinking of microtubules observed, suggesting that only one end of the vault can bind microtubules. Taken together, the data support the model of vaults as barrel-shaped containers that transiently interact with microtubules.     

Characterization of the cytoskeleton of isolated chick osteoclasts: effect of calcitonin

We investigated the effects of calcitonin (CT) and parathyroid hormone (PTH) on the distribution of actin, tubulin, vimentin, and on cell size in cultured chick osteoclasts. In addition, we studied the effects of colchicine on intracellular acidity. Osteoclasts were isolated from the endosteum of 2-3-week chick tibias and were maintained under culture conditions for 5 days. The cells were treated with CT for 30 min or PTH for 60 min and were observed after immunocytochemical staining of cytoskeletal proteins. In untreated cells, actin was found in both a filamentous and a punctate staining pattern, with indented or invaginated regions free of punctate spots. The tubulin distribution in untreated cells was characterized by a pattern of microtubules radiating from the cell center and running parallel to the cell edge. Vimentin staining was usually localized to the perinuclear area. There were no changes in cytoskeletal element distribution or morphology attributable to PTH treatment. Osteoclasts treated with CT were more irregularly shaped, contained more retraction fibers, and were more rounded, with a denser array of cytoskeletal elements in the cell center. In addition, the mean area of the CT-treated cells was significantly less than that of the untreated cells. The actin distribution after CT treatment was still characterized by both a filamentous and a punctate pattern. After CT treatment, vimentin staining appeared more centrally localized than in untreated cells and tubulin staining revealed microtubules which now extended to the retracted cell margin. These results indicate that isolated osteoclasts respond to CT by significant morphological changes which are reflected in the distribution of the major cytoskeletal elements. Disruption of the microtubular system by colchicine treatment also resulted in an initial increase in intracellular acidity, suggesting the involvement of microtubules in the movement of acid-laden vesicles to the exterior.     

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.     

Biochemical and Structural Analyses of Microtubules in the Pellicular Membrane of Leishmania tropica1

The structure of the major protein of the pellicular membrane of Leishmania tropica was investigated. This protein is composed of two polypeptides, of ca. 50,000 d molecular weight, that were found to cross-react immunologically with the α and β subunits of pig brain tubulin. The polypeptides and pig brain tubulin subunits were partially digested with S. aureus V8 protease, and the peptides obtained analysed by SDS-polyacrylamide gel electrophoresis. A comparison of the patterns showed that the β subunits of Leishmania and pig tubulin have very similar primary structures, while the α subunits have evolved divergently. These experiments demonstrate that the major polypeptides found in the pellicular membrane of L. tropica are α and β subunits of tubulin. Immuno-electron microscopy indicates that the tubulin is located in the microtubules associated with the pellicular membrane of Leishmania. Arrays of microtubules were prepared by nonionic detergent treatment of the cells and observed by electron microscopy after negative staining. Optical diffraction reveals a 5 nm spacing between protofilaments in the microtubule and a 4 nm axial periodicity corresponding to the tubulin subunits. The pitch of the shallow left-hand three-start helix is 12°. A distance of 47 nm separates each microtubule from the next. These data show that the dimensions and supramolecular organization of the tubulin subunits in the microtubules are identical in the pellicular membrane of L. tropica and in mammalian brain.     

Microtubule-nucleation sites on nuclei of higher plant cells

Summary The nucleation and the elongation of microtubules from isolated nuclei of higher plant cells were investigated. Isolated intact nuclei failed to nucleate microtubules at their surface when they were incubated with purified tubulin from plant or animal sources. However, frozen and thawed nuclei or nuclear particles obtained by gentle nuclei homogenization nucleated microtubules and nucleated microtubules elongated radially from the surface of nuclei or from the nuclear particles. Microtubules radiating from the nuclear particles were very much shorter than those radiating from frozen and thawed nuclei. The washing of the nuclear particles diminished the ability of the particles to nucleate microtubules. The ability of the washed nuclear particles to nucleate microtubules was restored by the addition of the soluble fraction of a nuclear homogenate. The complexes of radiating microtubules could easily be observed under a phasecontrast microscope. Electron microscopy demonstrated that microtubules in the complexes formed bundles. The staining with a monoclonal antibody specific for plant tubulin of the complexes of radiating microtubules, prepared by successive polymerization of animal tubulin and plant tubulin, revealed that microtubules in the complex incorporated tubulin at their proximal ends. This result indicates that the mode of incorporation of tubulin onto frozen and thawed nuclei or onto the nuclear particles is different from that in pericentriolar bodies in animal cells. Mg²⁺ seems to participate in the regulatory mechanism that determines the length of microtubules on the complexes.Abbreviations MTOC microtubule-organizing center - MES 2-(N-morpholino) ethane-sulfonic acid - PIPES piperazine-N,N-bis(2-ethanesulfonic acid) - PMSF phenylmethyl sulfonyl fluoride - EDTA ethylenediaminetetraacetic acid - EGTA ethylene glycol bis (-aminoethylether)-N,N,N,N-tetraacetic acid - GTP guanosine triphosphate - NP-40 Nonidet P-40 - DMSO dimethylsulfoxide - EPC ethyl N-phenylcarbamate - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis - DAPI 4,6-diamidiho-2-phenylindole     

Dynamics of microtubules bundled by microtubule associated protein 2C (MAP2C)

MAP2C is a microtubule-associated protein abundant in immature nerve cells. We isolated a cDNA clone encoding whole mouse MAP2C of 467 amino acid residues. In fibroblasts transiently transfected with cDNA of MAP2C, interphase microtubule networks were reorganized into microtubule bundles. To reveal the dynamic properties of microtubule bundles, we analyzed the incorporation sites of exogenously introduced tubulin by microinjection of biotin-labeled tubulin and the turnover rate of microtubule bundles by photoactivation of caged fluorescein- labeled tubulin. The injected biotin-labeled tubulin was rapidly incorporated into distal ends of preexisting microtubule bundles, suggesting a concentration of the available ends of microtubules at this region. Although homogenous staining of microtubule bundles with antibiotin antibody was observed 2 h after injection, the photoactivation study indicated that turnover of microtubule bundles was extremely suppressed and < 10% of tubulin molecules would be exchanged within 1 h. Multiple photoactivation experiments provided evidence that neither catastrophic disassembly at the distal ends of bundles nor concerted disassembly due to treadmilling at the proximal ends could explain the observed rapid incorporation of exogenously introduced tubulin molecules. We conclude that microtubules bundled by MAP2C molecules are very stable while the abrupt increase of free tubulin molecules by microinjection results in rapid assembly from the distal ends within the bundles as well as free nucleation of small microtubules which are progressively associated laterally with preexisting microtubule bundles. This is the first detailed study of the function of MAPs on the dynamics of microtubules in vivo.     

Promotion of MAP/MAP interaction by taxol

The effects of taxol on microtubule-associated proteins of high molecular weight (MAPs) were studied in vitro. After negative staining, microtubules reconstituted in the presence of taxol from preparations of partially purified tubulin and MAPs, besides being bundled, displayed prominent elongated or globular extensions without apparent regularity. These extensions, but not the tubulin polymer, were heavily decorated after immuno-gold-labeling using antibodies to MAP-1 and MAP-2. Microtubules reconsituted in the absence of taxol showed a much more regular, and apparently helical, arrangement of MAPs along their surfaces. The formation of polymeric structures was also observed when preparation of MAPs free of tubulin were incubated with taxol. In this case in addition to large network-type aggregates with little apparent substructure, more regular structures seemingly consisting of approximately 5-nm-thick filaments arrayed in parallel were observed. Taxol-induced MAP aggregation occurred rapidly and was directly proportional to the concentration of protein, as revealed by optical density measurements. It is concluded that taxol, aside from promoting the assembly of tubulin and stabilizing microtubules, promotes MAP/MAP interaction.     

Origin of the mitotic spindle in onion root cells

Summary Immunofluorescence studies on microtubule arrangement during the transition from prophase to metaphase in onion root cells are presented. The prophase spindle observed at late preprophase and prophase is composed of microtubules converged at two poles near the nuclear envelope; thin bundles of microtubules are tracable along the nuclear envelope. Prior to nuclear envelope breakdown diffuse tubulin staining occurs within the prophase nuclei. During nuclear envelope breakdown the prophase spindle is no longer identifiable and prominent tubulin staining occurs among the prometaphase chromosomes. Patches of condensed tubulin staining are observed in the vicinity of kinetochores. At advanced prometaphase kinetochore bundles of microtubules are present in some kinetochore regions. At metaphase the mitotic spindle is mainly composed of kinetochore bundles of microtubules; pole-to-pole bundles are scarce. Our observations suggest that the prophase spindle is decomposed at the time of nuclear envelope breakdown and that the metaphase spindle is assembled at prometaphase, with the help of kinetochore nucleating action.