Where and when is microtubule diversity generated inParamecium? Immunological properties of microtubular networks in the interphase and dividing cells

Summary Ciliates are highly differentiated cells which display extensive deployment of microtubular systems. Because genetic diversity of tubulin is extremely reduced in these cells, microtubule diversity is mostly generated at the post-translational level either through direct modification of tubulin or through the binding of associated proteins to microtubules. We have undertaken a systematic exploration of microtubule diversity in ciliates by way of production of monoclonal antibodies. Previously we reported the biochemical characterization of these antibodies. In addition to antibodies directed against primary sequences, we obtained antibodies directed against post-translational modifications. In this paper, we report a detailed analysis of the distribution of the various epitopes on the microtubular networks ofParamecium, both in interphase cells and during division morphogenesis. Each of these antibodies decorates a subset of microtubules. Acetylation, recognized by antibodies TEU 318 and TEU 348, is detected on stable microtubules early after microtubule assembly. Epitopes recognized by two other antibodies (TAP 952 and AXO 58) are found on a subset of stable microtubules; in addition, the TAP 952 antibody is also found on labile microtubules; both epitopes are detected as soon as microtubule assembly occurs. In contrast, the epitope of the antibody, AXO 49, is associated with only a restricted subset of stable microtubules in the interphase cell, and is detected a lag-time after microtubule assembly during division morphogenesis. These data show that microtubule diversity is generated through a time-dependent sequence and according to a definite spatial pattern.     

Microtubule diversity in ciliated cells: evidence for its generation by post-translational modification in the axonemes of Paramecium and quail oviduct cells.

The diversity of microtubular networks was analyzed in quail oviduct and in Paramecium cells using conventional and confocal immunofluorescence as well as pre- and post-embedding EM immunocytochemistry with a variety of anti-tubulin antibodies. The 6-11B-1 monoclonal antibody, specific for the post-translational acetylation of Lys 40 of alpha-tubulin, and a polyclonal antibody raised against Paramecium axonemal tubulin (anti-PA tubulin antibody) both decorated stable microtubular arrays in Paramecium ie ciliary axonemes and a set of microtubular bundles associated with the cortex, suggesting that the two antibodies may be directed against the same epitope. However, several differences in the immunocytological patterns yielded by each antibody on the two cell types were evident. For example, in quail, as in all other Metazoa, the anti-PA tubulin antibody only decorated axonemes enclosed in normal ciliary membrane while it was unreactive on cytoplasmic tubulins. Immunoblotting of peptide maps of axonemal tubulins demonstrated that the epitopes of the two antibodies were indeed completely different. Double immunolabelling of dividing paramecia using a universal anti-tubulin antibody and the anti-PA tubulin one revealed that all newly assembled microtubular arrays were first detected by the universal antibody and, only shortly afterwards, by the anti-PA tubulin one. This provided a strong indication that the anti-PA tubulin antibody is directed against a post-translational modification taking place on already assembled microtubules (MTs) (as previously known to be the case for acetylation and detyrosination). In taxol-treated quail cells undergoing ciliogenesis, massive assembly of MTs and even axonemes occurred in the cytoplasm. These MTs were not decorated by the anti-PA tubulin antibody however, suggesting that in Metazoa the post-translational modification can only take place within the ciliary lumen. The present work provides one further mechanism for generating MT immunological and biochemical diversity post-translationally; this may account for the high multiplicity of tubulin isoforms observed in ciliates which contain very little if any genetic diversity of tubulin genes.     

Microtubule dynamics in fish melanophores

We have studied the dynamics of microtubules in black tetra (Gymnocorymbus ternetzi) melanophores to test the possible correlation of microtubule stability and intracellular particle transport. X- rhodamine-or caged fluorescein-conjugated tubulin were microinjected and visualized by fluorescence digital imaging using a cooled charge coupled device and videomicroscopy. Microtubule dynamics were evaluated by determining the time course of tubulin incorporation after pulse injection, by time lapse observation, and by quantitation of fluorescence redistribution after photobleaching and photoactivation. The time course experiments showed that the kinetics of incorporation of labeled tubulin into microtubules were similar for cells with aggregated or dispersed pigment with most microtubules becoming fully labeled within 15-20 min after injection. Quantitation by fluorescence redistribution after photobleaching and photoactivation confirmed that microtubule turnover was rapid in both states, t1/2 = 3.5 +/- 1.5 and 6.1 +/- 3.0 min for cells with aggregated and dispersed pigment, respectively. In addition, immunostaining with antibodies specific to posttranslationally modified alpha-tubulin, which is usually enriched in stable microtubules, showed that microtubules composed exclusively of detyrosinated tubulin were absent and microtubules containing acetylated tubulin were sparse. We conclude that the microtubules of melanophores are very dynamic, that their dynamic properties do not depend critically on the state of pigment distribution, and that their stabilization is not a prerequisite for intracellular transport.     

Rapid rate of tubulin dissociation from microtubules in the mitotic spindle in vivo measured by blocking polymerization with colchicine

At metaphase, the amount of tubulin assembled into spindle microtubules is relatively constant; the rate of tubulin association equals the rate of dissociation. To measure the intrinsic rate of dissociation, we microinjected high concentrations of colchicine, or its derivative colcemid, into sea urchin embryos at metaphase to bind the free tubulin, thereby rapidly blocking polymerization. The rate of microtubule disassembly was measured from a calibrated video signal by the change in birefringent retardation (BR). After an initial delay after injection of colchicine or colcemid at final intracellular concentrations of 0.1-3.0 mM, BR decreased rapidly and simultaneously throughout the central spindle and aster. Measured BR in the central half-spindle decreased exponentially to 10% of its initial value within a characteristic period of approximately 20 s; the rate constant, k = 0.11 +/- 0.023 s-1, and the corresponding half-time, t 1/2, of BR decay was approximately 6.5 +/- 1.1 s in this concentration range. Below 0.1 mM colchicine or colcemid, the rate at which BR decreased was concentration dependent. Electron micrographs showed that the rapid decrease in BR corresponded to the disappearance of nonkinetochore microtubules; kinetochore fiber microtubules were differentially stable. As a control, lumicolchicine, which does not bind to tubulin with high affinity, was shown to have no effect on spindle BR at intracellular concentrations of 0.5 mM. If colchicine and colcemid block only polymerization, then the initial rate of tubulin dissociation from nonkinetochore spindle microtubules is in the range of 180-992 dimers per second. This range of rates is based on k = 11% of the initial polymer per second and an estimate from electron micrographs that the average length of a half-spindle microtubule is 1- 5.5 micron. Much slower rates of tubulin association are predicted from the characteristics of end-dependent microtubule assembly measured previously in vitro when the association rate constant is corrected for the lower rate of tubulin diffusion in the embryo cytoplasm. Various possibilities for this discrepancy are discussed.     

Immunolocalization of tubulin isoforms and post-translational modifications in the protists Tritrichomonas foetus and Trichomonas vaginalis

In the present report we show the distribution of multiple tubulin isoforms in Trichomonas vaginalis and Tritrichomonas foetus, flagellated parasitic protists of the urogenital tracts of human and cattle, respectively, using immunofluorescence and immunoelectron microscopy. We used several monoclonal and polyclonal anti-tubulin antibodies from different sources and recognizing variant tubulin isoforms. Our results demonstrate that: (1) there is a heterogeneous distribution of the different tubulin isoforms in the main microtubular cell structures, such as axostyle, flagella, basal bodies, and mitotic spindle, (2) the axostyle-pelta junction is a structure with high affinity for glutamylated tubulin antibodies in T. foetus, (3) the spindle labeling is positive to anti-glutamylated tubulin and anti-alpha-tubulin (TAT1 and purchased from Amersham) antibodies in T. vaginalis but it is negative in T. foetus, (4) the nuclear matrix and the cytosol presented positive reaction using glutamylated and TAT1 (anti-alpha-tubulin) antibodies only in T. vaginalis, and (5) the Golgi complex exhibited staining using the glutamylated tubulin antibody. The present data corroborate with the idea of the existence of a heterogeneous population of microtubules in these protists and of a subset of intracytoplasmic microtubules. Microtubule diversity may reflect distinct tubulins, diverse microtubule-associated proteins, or a combination of both.     

Identification of multiple microtubule initiating sites in mouse neuroblastoma cells.

Mouse neuroblastoma N-18 cells can be induced by serum deprivation to sprout multiple neurite-like processes which contain many microtubules. Mitotic drugs such as colcemid and colchicine depolymerize these microtubules and the cells lose their processes. Reappearance of microtubules after removal of the drugs was followed by immunofluorescence microscopy using tubulin specific antibodies. At early recovery times multiple star-like structures which contained tubulin were detected in the perinuclear are and in the cytoplasm of individual cells. The mean number seen per cell as approximately 5. Their formation preceeded the organization of the complex microtubular networks typical of N-18 cells. The probable action of these structures as microtubular organization centers (MTOCs) is discussed. Multiple structures were detected during recovery from the influence of mitotic drugs both in previously induced and non-induced N-18 cells, suggesting that N-18 cells harbour the potential of formation of multiple organization centers even without previous induction. We discuss the possibility that differentiation of neuroblastoma N-18 cells may require microtubular organization centers.     

Dynamic and stable populations of microtubules in cells

Using a new immunocytochemical technique, we have visualized the spatial arrangement of those microtubules in cells that are stable to biotin-tubulin incorporation after microinjection. Cells fixed at various periods of time after injection were exposed to antibody to biotinylated tubulin and several layers of secondary antibodies; these layers prevented reaction of biotin-containing microtubules with antitubulin antibodies. The microtubules that had not incorporated biotin-tubulin could then be stained with anti-tubulin and a fluorescent secondary antibody. In BSC1 cells, most microtubules in the cell exchange with a half-time of 10 min. A separate population of microtubules can be detected, using the above techniques, that are stable to exchange for 1 h or more; these have a characteristic pericentrosomal spatial arrangement as compared to the majority of dynamic microtubules. Unlike the dynamic microtubules, most of the stable microtubules are nongrowing. The average BSC-1 cell contains approximately 700 microtubules: approximately 500 growing at 4 micron min-1, 100 shrinking at approximately 20 micron min-1, and approximately 100 that are relatively more stable to exchange. The potential significance of these stable microtubules is discussed.     

Morphology of the microtubule system in mouse kidney epithelial cells]

The cultured mouse kidney cells forming epithelial sheets were studied using an indirect immunofluorescence microscopy with antibodies against tubulin. These cells, as well as fibroblasts, were found to contain a well developed microtubular system sensitive to colcemid. The assembly of microtubules after washing out of colcemid began from one or two perinuclear centers, associated with the cilium-like structure. There were certain differences between the microtubular systems in epithelial cells and fibroblasts: 1) Microtubules in the fibroblasts penetrated the whole cytoplasm including the peripheral lamella whereas in the epithelial cells the lamellar cytoplasm was often free from microtubules. 2) The orientation of microtubules in the epithelial cells, unlike in the fibroblasts, was not correlated with the stable or active state of the cell margin. A possible role of microtubular system in the epithelial cells and fibroblasts is compared and discussed.     

Individual microtubules viewed by immunofluorescence and electron microscopy in the same PtK2 cell

PtK2 cells were grown on gold grids and treated with Triton X-100 in a microtubule stabilizing buffer. The resulting cytoskeletons were fixed with glutaraldehyde and subjected to the indirect immunofluorescence procedure using monospecific tubulin antibodies. Grids were examined first by fluorescence microscopy, and the display of fluorescent cytoplasmic microtubules was recorded. The grids were then stained with uranyl acetate and the display of fibrous structures recorded by electron microscopy. Thus the display of cytoplasmic microtubular structures in the light microscope and the electron microscope can be compared within the same cytoskeleton. The results show a direct correspondence of the fluorescent fibers in the light microscope with uninterrupted fibers of diameter approximately 550 A in the electron microscope. This is the diameter reported for a single microtubule decorated around its circumference by two layers of antibody molecules. Thus under optimal conditions immunofluorescence microscopy can visualize individual microtubules.     

Assembly and disassembly of axonal microtubules of the toad Xenopus laevis under the effect of temperature.

In toads Xenopus laevis living at 11 degrees (winter), the microtubular density of 4-microns myelinated axons of lumbosacral nerves was assessed with the electron microscope. In controls, the density was 11.2 microtubules/microns2. In nerves incubated at 0 degrees, microtubules decreased following a simple exponential curve with a half time of 4.7 min (k = 0.149 min-1); residual microtubules were 4.5%. After rewarming, the full complement of microtubules reappeared within 60 min. In steady state, the microtubular density exhibited a linear relationship with temperature (range: 0-22 degrees; slope 0.94 microtubules/microns 2 per degree; r, 0.96). After heating the nerve by 11 degrees above the physiological temperature, microtubules increased by 83%, whereby the pool of unpolymerized tubulin was at least 2.7 mg/ml of axoplasm. A seasonal variation of the microtubular density was observed which accorded with the environmental temperature. The macroscopic kinetics of microtubule disassembly in the axoplasm is similar to that reported for purified tubulin but that of assembly is slower. Microtubules of peripheral axons of Xenopus are cold-labile and vary during the annual cycle.     

Expression of tubulin polyglycylation in Giardia lamblia

By means of immunofluorescence, immunoelectron microscopy and immunoblotting, we show that polyglycylation, a posttranslational modification of tubulin widely spread among eukaryotes, is present in the diplomonad, Giardia lamblia, a putative ancestral cell possessing a highly developed microtubular cytoskeleton. This modification was recently discovered in the ciliated protist, Paramecium, and was not found in the Euglenozoa, a lineage considered as ancient. We used two monoclonal antibodies (mAbs), TAP 952 and AXO 49, specifically recognizing mono- and polyglycylated tubulin isoforms, to detect this modification in Giardia extracts and to localize it in the different classes of microtubules within the cell. The alpha- and beta-tubulin subunits were recognized by the two mAbs, indicating that both tubulin subunits are glycylated, in agreement with lately reported mass spectrometry results. Noticeably, Giardia tubulin was much more reactive with AXO 49 than with TAP 952. In situ, AXO 49 intensely labeled the microtubules present in the four pairs of flagella and the median body, and lightly decorated the microtubules from the adhesive disc. In contrast, TAP 952 intensely labeled only the microtubules of the median body. The results indicate a differential expression of glycylated isoforms within various microtubular structures of Giardia lamblia. They also suggest that the complete set of enzymes required for polyglycylation is expressed in very divergent eukaryotes.     

Quantitative analysis of tubulin and microtubule compartments in isolated rat hepatocytes

A combined morphometric and biochemical approach has been used to identify and quantitate microtubules and tubulin in isolated hepatocytes. The total soluble pool of microtubule protein was estimated by specific high affinity binding to radiolabeled colchicine. Scatchard analysis of the data identified two populations of binding sites: high affinity-low capacity sites resembling tubulin and low affinity-high capacity sites believed to represent nonspecific colchicine-binding sites. Data from these studies indicate that tubulin represents 1% of the soluble protein of the cell, that 9.0 X 10(-14) dimers of tubulin are present per microgram soluble hepatocyte protein, and that the average hepatocyte contains 3.1 X 10(7) tubulin dimers. Our calculations suggest that this amount of tubulin would form a microtubule 1.9 cm in length if totally assembled. However, stereological measurements indicate that the actual length of microtubules in the cytosolic compartment of the average hepatocyte is only 0.28 cm. Thus, these experiments suggest that only 15% of the available tubulin in hepatocytes of postabsorptive rats is assembled in the form of microtubules.     

Organization of microtubules in stabilized meristematic plant cells revealed by a rat monoclonal antibody reacting only with the tyrosinated form of alpha-tubulin

A rat monoclonal antibody against yeast tubulin (clone YL 1/2; Kilmartin et al., 1982) that reacts specifically with mammalian alpha-tubulin carrying a carboxyterminal tyrosine residue (Wehland et al., 1983) was used to localize microtubules in plant cells derived from onion root apices (Allium cepa L.). YL 1/2 reacted with all types of microtubular arrays known to occur in higher plant meristematic cells such as interphase cortical microtubules, pre-prophase bands, the mitotic spindle and phragmoplast microtubules. The specific labeling of microtubules in isolated cells from onion root tips by YL 1/2 indicates that plant cells like animal cells contain tubulin tyrosine ligase, the enzyme which posttranslationally modifies alpha-tubulin. This enzyme could be involved in the dynamic regulation of microtubular arrays in all eukaryotic cells.     

Microtubule initiation at kinetochores and centrosomes in lysed mitotic cells. Inhibition of site-specific nucleation by tubulin antibody

A lysed cell system was developed to determine whether tubulin antibody can block the nucleation of exogenous tubulin at kinetochores and centrosomes. Mitotic PtK2 cells were pretreated with colcemid to remove all endogenous microtubules and were lysed with Triton X-100 in PIPES-EGTA-Mg++ buffer. This procedure left centrosomes, chromosomes, and kinetochores intact as determined by electron microscopy of thin-sectioned cells. Exposure of the lysed cells to phorphocellulose-purified tubulin dimers at 37 degrees C in the presence of 1 mM GTP resulted in site-specific nucleation of microtubules at centrosomes and kinetochores. Treatment of the lysed cell preparations with tubulin antibody before subsequent exposure to the exogenous tubulin resulted in almost complete blockage of microtubule nucleation, especially at kinetochores. Pretreatment of the lysed cell preparations with control antibody or buffer without antibody had no effect on the ability of centrosomes and kinetochores to initiate microtubule assembly. The implications of these results with respect to the molecular composition of centrosomes and kinetochores are discussed.     

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

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

Tubulin diversity in trophozoites of<Emphasis Type="Italic"> Giardia lamblia</Emphasis>

Giardia lamblia is a diplomonad that parasitizes the small intestine of vertebrates. The trophozoite is multiflagellar and its cytoskeleton presents a complex organization of microtubular structures. One of these, the adhesive disk, consists of a microtubular spiral. The median body, whose function is not yet determined, is also composed by microtubules. The cell has eight flagella and two microtubule sheets, known as the funis. In this study we used several antibodies and immunofluorescence microscopy to help in the characterization of these structures. We observed that Giardia tubulin reacts with antibodies raised against very distinct immunogens. The antibodies used were against: (1) alpha-tubulin from chicken embryo brain, Trypanosoma brucei, sea urchin sperm, Paramecium, acetylated alpha-tubulin from Paramecium, and tyrosinated alpha-tubulin, (2) beta-tubulin from chicken embryo brain and Physarum polycephalum, and (3) an antibody with specificity to beta-tubulin having as immunogen the FtsZ bacterial protein. Each cytoskeletal structure of Giardia presented a distinct pattern of labeling by the several antibodies used. These data indicate that even being considered one of the most ancient of organisms, Giardia shares similarities (at least in relation to tubulin) with other organisms. They also open some questions about the organization and composition of its microtubular structures.     

Acetylated alpha-tubulin in Physarum: immunological characterization of the isotype and its usage in particular microtubular organelles

We have used monoclonal antibodies specific for acetylated and unacetylated alpha-tubulin to characterize the acetylated alpha-tubulin isotype of Physarum polycephalum, its expression in the life cycle, and its localization in particular microtubular organelles. We have used the monoclonal antibody 6-11B-1 (Piperno, G., and M. T. Fuller, 1985, J. Cell Biol., 101:2085-2094) as the probe for acetylated alpha-tubulin and have provided a biochemical characterization of the monoclonal antibody KMP-1 as a probe for unacetylated tubulin in Physarum. Concomitant use of these two probes has allowed us to characterize the acetylated alpha-tubulin of Physarum as the alpha 3 isotype. We have detected this acetylated alpha 3 tubulin isotype in both the flagellate and in the myxameba, but not in the plasmodium. In the flagellate, acetylated tubulin is present in both the flagellar axonemes and in an extensive array of cytoplasmic microtubules. The extensive arrangement of acetylated cytoplasmic microtubules and the flagellar axonemes are elaborated during the myxameba-flagellate transformation. In the myxameba, acetylated tubulin is not present in the cytoplasmic microtubules nor in the mitotic spindle microtubules, but is associated with the two centrioles of this cell. These findings, taken together with the apparent absence of acetylated alpha-tubulin in the ephemeral microtubules of the plasmodium suggest a natural correspondence between the presence of acetylated alpha-tubulin and microtubule organelles that are intrinsically stable or cross-linked.     

Polymerization of tubulin in the presence of colchicine or podophyllotoxin. Formation of a ribbon structure induced by guanylyl-5'-methylene diphosphonate

GTP-dependent in vitro polymerization of rat brain microtubular protein is inhibited to 50% by substoichiometric concentrations of the antimitotic drugs colchicine (0.12 mol/mol of tubulin) and podophyllotoxin (0.14 mol/mol of tubulin). Substitution of pp(CH₂)pG² for GTP, however, results in an extensive microtubular protein polymerization at such concentrations. In the presence of pp(CH₂)pG, suprastoichiometric concentrations of podophyllotoxin (19 mol/mol of tubulin) are required to inhibit the polymerization process by 50%. Colchicine is very ineffective since 3 × 10⁵ moles/mole of tubulin are required to give a 50% inhibition. Electron microscopical analysis shows that the polymers formed by microtubular protein in the presence of suprastoichiometric concentrations of drugs are not the normal short microtubules typical of pp(CH₂)pG-driven polymerization, but are ribbons with three or four protofilaments. The colchicine content of the harvested ribbons has been measured directly and found to be approximately 0.8 moles colchicine/mole of tubulin. Treatment of microtubular protein with substoichiometric concentrations of drugs results in an increase in the number of protofilaments forming the ribbons. Many of the ribbons can close into morphologically normal microtubules when microtubular protein is treated with only 0.05 moles of either colchicine or podophyllotoxin per mole of tubulin.     

Acoel spermatozoa: ultrastructure and immunocytochemistry of tubulin

Acoel spermatozoa are filiform and contain two parallel axonemes, which do not show the trepaxonematan 9 + ‘1’ pattern, but instead, another kind of 9 + ‘1’ pattern, or a 9 + 0 or 9 + 2 pattern. Spermatozoa have either cortical singlet microtubules or central microtubules. Identification of these groups of microtubules and recognition of homologies between species is difficult with electron microscopy. In addition to conventional electron microscopy, indirect immunofluorescence of tubulin was performed on three species (Symsagittifera schultzei, Symsagittifera psammophila, and Actinoposthia beklemischevi). This technique facilitated understanding of the general morphology of the filiform spermatozoon and of the arrangement of the microtubular organelles along its length. We have found that different monoclonal antibodies (anti-alpha-, anti-alpha-acetylated- and anti-beta-tubulin) can distinguish distinct subcellular populations of microtubules. The axonemes were labelled by the three antibodies in all species. The cortical microtubules (in Actinoposthia beklemischevi) were labelled by the three antibodies. The central microtubules (in Symsagittifera schultzei and S. psammophila) were labelled with the anti-beta-tubulin antibody and not labelled by the anti-alpha- and anti-alpha-acetylated-tubulin. Similar experiments were performed on other Platyhelminthes and indicated that immunocytochemistry of spermatozoa may provide new characters for phylogenetic studies. This revised version was published online in July 2006 with corrections to the Cover Date.     

A radiolabeled monoclonal antibody binding assay for cytoskeletal tubulin in cultured cells

To detect changes in the extent of tubulin polymerization in cultured cells, we have developed a radioactive antibody binding assay that can be used to quantitate total cytoskeletal tubulin or specific antigenic subsets of polymerized tubulin. Fibroblastic cells, grown to confluence in multiwell plates, were permeabilized and extracted with 0.5% Triton X-100 in a microtubule-stabilizing buffer. These extracted cytoskeletons were then fixed and incubated with translationally radiolabeled monoclonal antitubulin antibody (Ab 1-1.1), an IgM antibody specific for the beta subunit of tubulin. Specific binding of Ab 1-1.1 to the cytoskeletons was saturable and of a single apparent affinity. All specific binding was blocked by preincubation of the radiolabeled antibody with excess purified brain tubulin. Specific Ab 1-1.1 binding appeared to represent binding to cytoskeletal tubulin inasmuch as: pretreatment of cells with colchicine decreased Ab 1-1.1 binding in a dose-dependent manner which correlated with the amount of polymerized tubulin visualized in parallel cultures by indirect immunofluorescence, taxol pretreatment alone caused an increase in Ab 1-1.1 binding and prevented in a dose-dependent manner the colchicine-induced decrease in antibody binding, in cells pretreated with colcemid and returned to fresh medium, Ab 1-1.1 binding decreased and recovered in parallel with the depolymerization and regrowth of microtubules in these cells, and comparison of maximal antibody binding per cell between primary mouse embryo, 3T3, and human foreskin fibroblasts correlated with immunofluorescence visualization of microtubules in these cells. Thus, this assay can be used to measure relative changes in the level of polymerized cytoskeletal tubulin. Moreover, by Scatchard-type analysis of the binding data it is possible to estimate the total number of antibody binding sites per cell. Therefore, depending on the stoichiometry of antibody binding, this type of assay may be used for quantitating total cytoskeletal tubulin, specific antigenic subsets of cytoskeletal tubulin, or other cytoskeletal proteins.