Flagellar elongation and shortening in Chlamydomonas. III. structures attached to the tips of flagellar microtubules and their relationship to the directionality of flagellar microtubule assembly

Two structures on the distal ends of Chlamydomonas flagellar microtubules are described. One of these, the central microbutule cap, attaches the distal ends of the central pair microtubules to the tip of the flagellar membrane. In addition, filaments, called distal filaments, are observed attached to the ends of the A-tubules of the outer doublet microtubules. Inasmuch as earlier studies suggested that flagellar elongation in vivo occurs principally by the distal addition of sublnits and because it has been shown that brain tubulin assembles in vitro primarily onto the distal ends of both central and outer doublet microtubules, the presence of the cap and distal filaments was quantitated during flagellar resorption and elongation. The results showed that the cap remains attached to the central microtubules throughout flagellar resorption and elongation. The cap was also found to block the in vitro assembly of neurotubules onto the distal ends of the central microtubules. Conversely, the distal filaments apparently do not block the assembly of neurotubules onto the ends of the outer doublets. During flagellar elongation, the distal ends of the outer doublets are often found to form sheets of protofilaments similar to those observed on the elongating ends of neurotubules being assembled in vitro. These results suggest that the outer doublet microtubules elongate by the distal addition of subunits, whereas the two central microtubules assemble by the addition of subunits to the proximal ends.     

Structural polarity and directional growth of microtubules of Chlamydomonas flagella

A basic question concerning microtubule assembly is the polarity of growth, namely, whether subunits can add to either end of a growing microtubule or whether growth proceeds by subunit addition to only one end. To approach this question in an in vitro system, experiments were carried out on the addition of microtubule subunits to isolated flagellar axonemes. Flagella were detached from Chlamydomonas by brief treatment with non-ionic detergent, isolated by differential centrifugation, and incubated with crude high-speed extracts of porcine brain tissue or with purified tubulin (obtained by repetitive temperature-dependent assembly and disassembly). Electron microscopy of negatively stained samples showed as many as 11 long microtubules added at one end of more than 90% of the axonemes. Colchicine (100 μm), CaCl₂ (2.5 mm), and low temperature (0 °C) both prevented and reversed microtubule assembly but had no effect on axonemal length. In crude extracts microtubules formed on both members of the axonemal central pair but on only the A-tubule of the outer doublets. Flagellar fragments, produced by mechanical shearing, were also incubated with microtubule subunit. Single tubules formed at only one end of outer doublet fragments; the appearance of single tubules on one or both members of central pair fragments was predominantly unidirectional. Structural analysis of frayed axonemes and the asymmetry of side-arm attachments permitted the absolute polarity of the axonemal fragments to be determined and revealed that assembly proceeded by addition of subunits to the distal ends of the axonemal microtubules. Using purified brain tubulin, a limited extent of proximal addition and growth on the B-tubule also occurred. The extent of proximal addition increased with increasing protein concentration and temperature. We conclude that the microtubules of flagella have an intrinsic polarity reflected in their side-arm attachments and in their directionality of growth.     

Transport and arrangement of the outer-dynein-arm docking complex in the flagella of Chlamydomonas mutants that lack outer dynein arms

The outer dynein arms of Chlamydomonas flagella are attached to a precise site on the outer doublet microtubules and repeat at a regular interval of 24 nm. This binding is mediated by the outer dynein arm docking complex (ODA-DC), which is composed of three protein subunits. In this study, antibodies against the 83- and 62-kD subunits (DC83 and DC62) of the ODA-DC were used to analyze its state of association with outer arm components within the cytoplasm, and its localization in the axonemes of oda mutants. Immunoprecipitation indicates that DC83 and DC62 are preassembled within the cytoplasm, but that they are not associated with outer arm dynein. Both proteins are lost or greatly diminished in oda1 and oda3, mutants in the structural genes of DC62 and DC83, respectively, demonstrating that their association is necessary for their stable presence in the cytoplasm. Immunoelectron microscopy indicates that DC83 repeats at 24-nm intervals along the length of the doublet microtubules of oda6, which lacks outer arms; thus, outer arm periodicity may be determined by the ODA-DC. Flagellar regeneration and temporary dikaryon experiments indicate that the ODA-DC can be rapidly transported into the flagellum and assembled on the doublet microtubules independently of the outer arms and independently of flagellar growth. Unexpectedly, the intensity of ODA-DC labeling decreased toward the distal ends of axonemes of oda6 but not wild-type cells, suggesting that the outer arms reciprocally contribute to the assembly/stability of the ODA-DC.     

Microtubule reassembly in vitro of Strongylocentrotus purpuratus sperm tail outer doublet tubulin

Strongylocentrotus purpuratus outer doublet microtubules were prepared by extraction of sperm tail axonemes with 0.6 m-KCl. Sonication of the outer doublet microtubules in 5 mm-2-(N-morpholino)ethanesulphonic acid, 1 mm-ethyleneglycol-bis-(β-aminoethyl ether) N,N′-tetraacetic acid, 1 inm-MgSO₄ (pH 6.7) solubilized up to 35% of the outer doublet protein, depending on the power input, in a manner which was non-selective for either subfiber. Tubulin comprised 75 to 85% of the total solubilized protein in a 200,000 g supernatant obtained from the sonicated suspension. Colchicine-binding assays demonstrated that the tubulin was largely in a native form (K_A = 10⁶, liters mole^?; 0.74 mole of colchicine bound per mole of tubulin at infinite concentration of colchicine).Microtubule self-assembly from the 200,000 g supernatants in the absence of added seeds or glycerol was quantitated by light-scattering at 350 nm. The critical protein concentration for assembly was 0.55 mg ml^?1 at 37 °C and the reaction occurred optimally in the presence of 2 mm-GTP and 150 mm-KCl. The solubilized outer doublet tubulin formed singlet microtubules upon reassembly under our in vitro conditions. The authenticity of the microtubules was verified by both negative stain and thin-section electron microscopy. Polymerization was prevented by colchicine and podophyllotoxin, and depolymerization occurred rapidly on cooling the microtubules to 0 °C.The susceptibility of the reassembled microtubules to low temperature suggested that they could be “recycled” by the warm assembly-cold disassembly procedure developed for vertebrate brain (Borisy et al., 1974). Twice recycled outer doublet tubulin was devoid of high molecular weight microtubule-associated proteins, as judged by gel electrophoresis in the presence of sodium dodecyl sulfate. However, trace amounts (less than 5%) of intermediate molecular weight material was visible on heavily overloaded gels. The function of this material is uncertain, but it is not chemically equivalent to the tau factor of vertebrate brain (Weingarten et al., 1975), since it cannot be separated from the tubulin by phosphocellulose adsorption. In addition, phosphocellulose-treated tubulin reassembled to the same extent as untreated tubulin, suggesting that the reassembly of outer doublet tubulin does not require the protein equivalents of brain microtubule-associated proteins or tau factor. If accessory proteins are required for the reassembly of outer doublet tubulin, they are not removed by phosphocellulose under the conditions employed, and they must comprise less than 5% of the total protein.     

The microtubule lattice--20 years on

In 1974, optical diffraction and image analysis indicated that tubulin dimers in the cylindrically complete A-tubule of flagellar doublet microtubules are arranged with helical symmetry, while those in the incomplete B-tubule associate differently. Recently, electron micrographs of reassembled brain microtubules decorated with kinesin heads have shown that the tubulin dimers there are arranged as in the B-tubule. The lack of symmetry of microtubules assembled in vitro prompts Linda Amos to speculate here that the assembly process in vitro may differ from that occurring in the cell.     

Regeneration of mirror symmetrical limbs in the axolotl

Measurements of tubulin exchange into and from bovine brain microtubules at steady state in vitro were made with 3H-GTP as a marker for tubulin addition to or loss from microtubules. Tubulin has an exchangeable GTP binding site that becomes nonexchangeable in the microtubule. We found that tubulin addition to and loss from microtubules under steady state conditions occurred at equivalent rates, that loss and gain were linear, and that exchange rates (percentage of total tubulin in microtubules lost or gained per hour) were dependent upon microtubule length. Furthermore, we found that podophyllotoxin blocked steady state assembly, but did not alter the rate of steady state tubulin loss. When the assembling microtubule end was pulsed with 3H-GTP at steady state, the label was almost completely retained during a subsequent chase. We conclude that the microtubule assembly-disassembly "equilibrium" is a steady state summation of two different reactions which occur at opposite ends of the microtubule, and that assembly and disassembly occur predominantly and perhaps exclusively at the opposite ends under steady state conditions in vitro.     

THE MECHANISM OF ACTION OF COLCHICINE : Colchicine Binding Properties of Sea Urchin Sperm Tail Outer Doublet Tubulin

The thermal depolymerization procedure of Stephens (1970. J. Mol. Biol. 47:353) has been employed for solubilization of Strongylocentrotus purpuratus sperm tail outer doublet microtubules with the use of a buffer during solubilization which is of optimal pH and ionic strength for the preservation of colchicine binding activity of chick embryo brain tubulin. Colchicine binding values were corrected for first-order decay during heat solubilization at 50°C (t_½ = 5.4 min) and incubation with colchicine at 37°C in the presence of vinblastine sulfate (t_½ = 485 min). The colchicine binding properties of heat-solubilized outer doublet tubulin were qualitatively identical with those of other soluble forms of tubulin. The solubilized tubulin (mol wt, 115,000) bound 0.9 ± 0.2 mol of colchicine per mol of tubulin, with a binding constant of 6.3 x 10⁵ liters/mol at 37°C. The colchicine binding reaction was both time and temperature dependent, and the binding of colchicine was prevented in a competitive manner by podophyllotoxin (K_i = 1.3 x 10^-6 M). The first-order decay of colchicine binding activity was substantially decreased by the addition of the vinca alkaloids, vinblastine sulfate or vincristine sulfate, thus demonstrating the presence of a vinca alkaloid binding site(s) on the outer doublet tubulin. Tubulin contained within the assembled microtubules did not decay. Intact outer doublet microtubules bound less than 0.001 mol of colchicine per mol of tubulin contained in the microtubules, under conditions where soluble tubulin would have bound 1 mol of colchicine per mol of tubulin (saturating concentration of colchicine, no decay of colchicine binding activity). The presence of colchicine had no effect on the rate of solubilization of outer doublet microtubules during incubation at 37°C. Therefore, the colchicine binding site on tubulin is blocked (not available to bind colchicine) when the tubulin is in the assembled outer doublet microtubules.     

Characterization and in vitro polymerization of Tetrahymena tubulin

Tetrahymena tubulin was purified from the cell extract using DEAE-Sephadex A-50 ion-exchanger and ammonium sulfate precipitation. About 2.2% of the total protein in the 20,000 X g supernatant was recovered as DEAE-Sephadex-purified tubulin fraction. Applying the temperature-dependent polymerization-depolymerization method to this fraction in the presence of Tetrahymena outer fibers as a seed, almost pure tubulin was obtained. Tetrahymena tubulin dimer showed different behavior on SDS-polyacrylamide gels from porcine brain tubulin, and showed very low affinity for colchicine, amounting to about one-twentieth of the binding to porcine brain tubulin. The tubulin fraction failed to polymerize into microtubules by itself. Addition of a small amount of the ciliary outer fiber fragment induced polymerization as demonstrated by viscometric measurements, but the reconstituted microtubules were very unstable in the absence of glycerol. Microtubule-depolymerizing agents such as Ca2+ ions, low temperature, or colchicine all inhibited in vitro polymerization. Although Tetrahymena tubulin purified by the polymerization-depolymerization method could copolymerize with porcine brain microtubules, the DEAE-Sephadex-purified tubulin fraction suppressed the initial rate of porcine brain microtubule assembly in vitro. There seemed to be no differences between cytoplasmic tubulin and outer fiber tubulin in colchicine binding activity or SDS-gel electrophoretic behavior, or between the fine structure of both reconstituted microtubules observed by electron microscopy.     

Reassembly of flagellar B (alpha beta) tubulin into singlet microtubules: consequences for cytoplasmic microtubule structure and assembly

B(alpha beta) tubulin was obtained from a homogeneous class of microtubules, the incomplete B subfiber of sea urchin sperm flagellar doublet microtubules, by thermal fractionation. The thermally derived soluble B tubulin fraction (100, 000 g-h) repolymerizes in vitro, yielding microtubule-like structures. The microtubule-associated protein (MAP) composition and certain assembly parameters of thermally derived B tubulin are different from those reported for sonication- derived flageller tubulin and purified vertebrate tubulin. The "microtubules" reassembled from thermally prepared B tubulin are composed of 12-15 protofilaments (73% possess 14 protofilaments). A certain number possess a single "adlumenal component" applied to their inside walls, regardless of the number of protofilaments. Following the first cycle of polymerization, 81% of the B tubulin and essentially 100% of the MAPs remain cold insoluble. Evidence suggests that B tubulin assembles faithfully into a B lattice, creating a j seam between two protofilaments that are laterally bonded in a A-lattice configuration. The significance of these seams is discussed in relation to the mechanism of microtubule assembly, the stability of observed ribbons of protofilaments, and the three-dimensional organization of microtubule-associated components.     

Microtubule treadmilling in vitro investigated by fluorescence speckle and confocal microscopy.

Whether polarized treadmilling is an intrinsic property of microtubules assembled from pure tubulin has been controversial. We have tested this possibility by imaging the polymerization dynamics of individual microtubules in samples assembled to steady-state in vitro from porcine brain tubulin, using a 2% glycerol buffer to reduce dynamic instability. Fluorescence speckled microtubules were bound to the cover-glass surface by kinesin motors, and the assembly dynamics of plus and minus ends were recorded with a spinning-disk confocal fluorescence microscopy system. At steady-state assembly, 19% of the observed microtubules (n = 89) achieved treadmilling in a plus-to-minus direction, 34% in a minus-to-plus direction, 37% grew at both ends, and 10% just shortened. For the population of measured microtubules, the distribution of lengths remained unchanged while a 20% loss of original and 27% gain of new polymer occurred over the 20-min period of observation. The lack of polarity in the observed treadmilling indicates that stochastic differences in dynamic instability between plus and minus ends are responsible for polymer turnover at steady-state assembly, not unidirectional treadmilling. A Monte Carlo simulation of plus and minus end dynamics using measured dynamic instability parameters reproduces our experimental results and the amount of steady-state polymer turnover reported by previous biochemical assays.     

The mechanism of action of vinblastine. Binding of [acetyl-3H]vinblastine to embryonic chick brain tubulin and tubulin from sea urchin sperm tail outer doublet microtubules.

Tritium-labeled viblastine, specific activity 107 Ci/mol, was prepared by acetylation of desacetylvinblastine with [3H]acetic anhydride, and has been employed in a study of vinblastine binding to tubulin. There are two high affinity vinblastine-binding sites per mole of embryonic chick brain tubulin (KA = 3-5 X 10(5) l./mol). Binding to these sites was rapid, and relatively independent of temperature between 37 and 0degreeC. Vincristin sulfate and desacetylvinblastine sulfate, two other active vinca alkaloid derivatives, competitively inhibited the binding of vinblastine. The inhibition constant for vincristine was 1.7 X 10(-5) M; and for desacetylvinblastine, 2 X 10(-5) M. The vinblastine binding activity of tubulin decayed upon aging, but this property was not studied in detail. Vinblastine did not depolymerize stable sea urchin sperm tail outer doublet microtubules, nor did it bind to these microtubules. However, tubulin solubilized from the B subfiber of the outer doublet microtubules possessed the two high affinity binding sites (KA = 1-3 X 105 l./mol). These data suggest that vinblastine destroys microtubules in cells primarily by inhibition of microtubule polymerization, and does not directly destroy preformed microtubules.     

Monoclonal antibodies specific for an acetylated form of alpha-tubulin recognize the antigen in cilia and flagella from a variety of organisms

Seven monoclonal antibodies raised against tubulin from the axonemes of sea urchin sperm flagella recognize an acetylated form of alpha-tubulin present in the axoneme of a variety of organisms. The antigen was not detected among soluble, cytoplasmic alpha-tubulin isoforms from a variety of cells. The specificity of the antibodies was determined by in vitro acetylation of sea urchin and Chlamydomonas cytoplasmic tubulins in crude extracts. Of all the acetylated polypeptides in the extracts, only alpha-tubulin became antigenic. Among Chlamydomonas tubulin isoforms, the antibodies recognize only the axonemal alpha-tubulin isoform acetylated in vivo on the epsilon-amino group of lysine(s) (L'Hernault, S.W., and J.L. Rosenbaum, 1985, Biochemistry, 24:473-478). The antibodies do not recognize unmodified axonemal alpha-tubulin, unassembled alpha-tubulin present in a flagellar matrix-plus-membrane fraction, or soluble, cytoplasmic alpha-tubulin from Chlamydomonas cell bodies. The antigen was found in protein fractions that contained axonemal microtubules from a variety of sources, including cilia from sea urchin blastulae and Tetrahymena, sperm and testis from Drosophila, and human sperm. In contrast, the antigen was not detected in preparations of soluble, cytoplasmic tubulin, which would not have contained tubulin from stable microtubule arrays such as centrioles, from unfertilized sea urchin eggs, Drosophila embryos, and HeLa cells. Although the acetylated alpha-tubulin recognized by the antibodies is present in axonemes from a variety of sources and may be necessary for axoneme formation, it is not found exclusively in any one subset of morphologically distinct axonemal microtubules. The antigen was found in similar proportions in fractions from sea urchin sperm axonemes enriched for central pair or outer doublet B or outer doublet A microtubules. Therefore the acetylation of alpha-tubulin does not provide the mechanism that specifies the structure of any one class of axonemal microtubules. Preliminary evidence indicates that acetylated alpha-tubulin is not restricted to the axoneme. The antibodies described in this report may allow us to deduce the role of tubulin acetylation in the structure and function of microtubules in vivo.     

33K protein--an inhibitory factor of tubulin polymerization in porcine brain

A factor (33K protein) that modulates tubulin polymerization in vitro has been purified to homogeneity from porcine brain by ammonium sulfate fractionation and Whatman DE52, Toyo-pearl HW65C and Bio-Gel A 0.5 m column chromatographies. The purified fraction was free of nucleic acids and sugars. The activity of the purified 33K protein is pronase E sensitive but apparently heat- and trypsin-resistant though it undergoes tryptic digestion. The 33K protein inhibits polymerization of brain microtubule proteins in a dose-dependent manner and partially depolymerizes preformed microtubules. It also inhibits polymerization of purified starfish tubulin and microtubule elongation involving fragellar outer doublet microtubules and purified porcine brain tubulin. This suggests that the target of the 33K protein is tubulin rather than microtubule-associated proteins. The 33K protein causes incomplete depolymerization of microtubules and a new steady state is quickly attained which is apparently independent of microtubule mass concentration. Divalent cations such as calcium and magnesium do not modulate the inhibitory activity of the 33K protein.     

CLIP-170/tubulin-curved oligomers coassemble at microtubule ends and promote rescues

BACKGROUND: CLIP-170 is a microtubule binding protein specifically located at microtubule plus ends, where it modulates their dynamic properties and their interactions with intracellular organelles. The mechanism by which CLIP-170 is targeted to microtubule ends remains unclear today, as well as its precise effect on microtubule dynamics. RESULTS: We used the N-terminal part of CLIP-170 (named H2), which contains the microtubule binding domains, to investigate how it modulates in vitro microtubule dynamics and structure. We found that H2 primarily promoted rescues (transitions from shrinkage to growth) of microtubules nucleated from pure tubulin and isolated centrosomes, and stimulated microtubule nucleation. Electron cryomicroscopy revealed that H2 induced the formation of tubulin rings in solution and curved oligomers at the extremities of microtubules in assembly conditions. CONCLUSIONS: These results suggest that CLIP-170 targets specifically at microtubule plus ends by copolymerizing with tubulin and modulates microtubule nucleation, polymerization, and rescues by the same basic mechanism with tubulin oligomers as intermediates.     

Polarity of flagellar assembly in Chlamydomonas.

During mating of the alga Chlamydomonas, two biflagellate cells fuse to form a single quadriflagellate cell that contains two nuclei and a common cytoplasm. We have used this cell fusion during mating to transfer unassembled flagellar components from the cytoplasm of one Chlamydomonas cell into that of another in order to study in vivo the polarity of flagellar assembly. In the first series of experiments, sites of tubulin addition onto elongating flagellar axonemes were determined. Donor cells that had two full-length flagella and were expressing an epitope-tagged alpha-tubulin construct were mated (fused) with recipient cells that had two half-length flagella. Outgrowth of the shorter pair of flagella followed, using a common pool of precursors that now included epitope-tagged tubulin, resulting in quadriflagellates with four full-length flagella. Immunofluorescence and immunoelectron microscopy using an antiepitope antibody showed that both the outer doublet and central pair microtubules of the recipient cells' flagellar axonemes elongate solely by addition of new subunits at their distal ends. In a separate series of experiments, the polarity of assembly of a class of axonemal microtubule-associated structures, the radial spokes, was determined. Wild-type donor cells that had two full-length, motile flagella were mated with paralyzed recipient cells that had two full-length, radial spokeless flagella. Within 90 min after cell fusion, the previously paralyzed flagella became motile. Immunofluorescence microscopy using specific antiradial spoke protein antisera showed that radial spoke proteins appeared first at the tips of spokeless axonemes and gradually assembled toward the bases. Together, these results suggest that both tubulin and radial spoke proteins are transported to the tip of the flagellum before their assembly into flagellar structure.     

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.     

A Role for Katanin-mediated Axonemal Severing during Chlamydomonas Deflagellation

Deflagellation of Chlamydomonas reinhardtii, and other flagellated and ciliated cells, is a highly specific process that involves signal-induced severing of the outer doublet microtubules at a precise site in the transition region between the axoneme and basal body. Although the machinery of deflagellation is activated by Ca²⁺, the mechanism of microtubule severing is unknown. Severing of singlet microtubules has been observed in vitro to be catalyzed by katanin, a heterodimeric adenosine triphosphatase that can remove tubulin subunits from the walls of stable microtubules. We found that purified katanin induced an ATP-dependent severing of the Chlamydomonas axoneme. Using Western blot analysis and indirect immunofluorescence, we demonstrate that Chlamydomonas expresses a protein that is recognized by an anti-human katanin antibody and that this protein is localized, at least in part, to the basal body complex. Using an in vitro severing assay, we show that the protein(s) responsible for Ca²⁺-activated outer doublet severing purify with the flagellar-basal body complex. Furthermore, deflagellation of purified flagellar-basal body complexes is significantly blocked by the anti-katanin antibody. Taken together, these data suggest that a katanin-like mechanism may mediate the severing of the outer doublet microtubules during Chlamydomonas deflagellation.     

Mechanism of inhibition of microtubule polymerization by colchicine: inhibitory potencies of unliganded colchicine and tubulin-colchicine complexes.

The tubulin-colchicine binding reaction appears to involve a number of intermediate steps beginning with rapid formation of a transient preequilibrium complex that is followed by one or more slow steps in which conformational changes in tubulin and colchicine lead to formation of a poorly reversible final-state complex. In the present study, we investigated the relative ability of unliganded colchicine and preformed final-stage tubulin-colchicine complex to incorporate at microtubule ends and to inhibit addition of tubulin at the net assembly ends of bovine brain microtubules in vitro. Addition of 0.1 microM final-stage tubulin-colchicine complex to suspensions of microtubules at polymer-mass steady-state resulted in rapid incorporation of one to two molecules of tubulin-colchicine complex per microtubule net assembly end concomitant with approximately 50-60% inhibition of tubulin addition. Incorporation of colchicine-tubulin complex continued slowly with time, without significant additional change in the rate of tubulin addition. In contrast, addition of unliganded colchicine to microtubule suspensions resulted in incorporation of small numbers of colchicine molecules at microtubule ends and inhibition of tubulin addition only after periods of time that varied from several minutes to approximately 20 min depending upon the concentration of colchicine. Inhibition of tubulin addition beginning with unliganded colchicine increased slowly with time, concomitant with increases in the concentration of final-state tubulin-colchicine complex and the amount of colchicine bound per microtubule end. The results indicate that inhibition of tubulin incorporation at microtubule ends is caused by colchicine-liganded tubulin in the form of a final-state complex.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Polymerization of tubulin in vivo: direct evidence for assembly onto microtubule ends and from centrosomes

Microtubule assembly in vivo was studied by hapten-mediated immunocytochemistry. Tubulin was derivatized with dichlorotriazinylaminofluorescein (DTAF) and microinjected into living, interphase mammalian cells. Sites of incorporation were determined at the level of individual microtubules by double-label immunofluorescence. The haptenized tubulin was localized by an anti-fluorescein antibody and a second antibody conjugated with fluorescein. Total microtubules were identified by anti-tubulin and a secondary antibody conjugated with rhodamine. Contrary to recent studies (Salmon, E. D., et al., 1984, J. Cell Biol., 99:2165-2174; Saxton, W. M., et al., 1984, J. Cell Biol., 99:2175-2186) which suggest that tubulin incorporates all along the length of microtubules in vivo, we found that microtubule assembly in interphase cells was in vivo, as in vitro, an end-mediated process. Microtubules that radiated out toward the cell periphery incorporated the DTAF-tubulin solely at their distal, that is, their plus ends. We also found that a proportion of the microtubules connected to the centrosomes incorporated the DTAF-tubulin along their entire length, which suggests that the centrosome can nucleate the formation of new microtubules.