Tubulin-specific antibody and the expression of microtubules in 3T3 cells after attachment to a substratum (original) (raw)
Related papers
The Journal of Cell Biology, 1984
Three monoclonal antibodies specific for tubulin were tested by indirect immunofluorescence for their ability to stain cytoplasmic microtubules of mouse and human fibroblastic cells. We used double label immunofluorescence to compare the staining patterns of these antibodies with the total microtubule complex in the same cells that were stained with a polyclonal rabbit antitubulin reagent. Two of the monoclonal antitubulin antibodies bound to all of the cytoplasmic microtubules but Ab 1-6. 1 bound only a subset of cytoplasmic microtubules within individual fixed cells. Differential staining patterns were observed under various fixation conditions and staining protocols, in detergent-extracted cytoskeletons as well as in whole fixed cells. At least one physiologically defined subset of cytoplasmic microtubules, those remaining in cells pretreated for 1 h with 5 microM colcemid, appeared to consist entirely of Ab 1-6. 1 positive microtubules. The same was not true of the microtubules ...
Cellular regulation of microtubule organization
The Journal of cell biology, 1984
Microtubules are constituents of axonemes, mitotic spindles, and elaborate arrays in interphase cells, and, with intermediate filaments and microfilaments, are among the most prevalent structures visualized in the cytomatrix (22, 44). With the exception ofthe A microtubule ofcilia and flagella, the lattice geometry ofmicrotubules is highly conserved. However, each of the major subunits of microtubules, a-and a-tubulin, shows heterogeneity. The number ofa-and f3-tubulin subspecies differs among tissues and organisms, and a number of types of analysis are used to examine how these tubulin variants are related to specific cell functions (1, 9-11, 33, 40). Investigations of the number and complexity of genes coding for these polypeptides have also been initiated (see reference 13 for review). However, the mechanisms that regulate the posttranslational compartmentalization of subunits, the spatial and temporal assembly of subunits into microtubules, and the integration of microtubules in various cellular events are still largely unknown. There are many levels at which the formation and organization of microtubules might be determined. A postulate originating from early analyses of mitotic spindle formation (32) was that a pool of subunits existed in equilibrium with formed microtubules; increases in the subunit concentration could therefore result in a net increase in polymer. With few exceptions, however, a rapid increase in the total tubulin pool does not appear to occur before the elaboration of more extensive microtubule arrays. For example, our studies (42, 50) have demonstrated that mouse neuroblastoma cells possessing microtubule-filled neurites contain four to five times more tubulin polymer than rounded, nondifferentiated cells, but the total tubulin content of these two cell types is the same. On the basis of volume calculations, the equilibrium concentration of subunits in the nondifferentiated cells is at least twice that in differentiated cells. Data such as this indicate that a simple equilibrium between subunit and polymer cannot account for the changes in microtubule formation coordinated with certain cellular events. In addition, recent findings show that an increase in the subunit concentration in cells, brought about either by drug treatment (15) or injection of tubulin (16), results in a depression of tubulin synthesis and the loss of tubulin mRNA. These data suggest that cells autoregulate the total tubulin pool and that this may be effected by "monitoring" of the monomer concentration (14).
Increased visualization of microtubules by an improved fixation procedure
Journal of Histochemistry & Cytochemistry, 1977
We have found that when a buffer utilized for in vitro polymerization of microtubules, i.e., 1 mM guanosine triphosphate, 1 mM MgSO4, 2 mM ethylene glycol bis(beta-aminoethyl ether)-N, N'-tetraacetic acid 100 mM piperazine-N,N'-bis(2-ethanesulfonic acid), pH 6.9 polymerization mix, was used in the glutaraldehyde prefixation regimen instead of classical fixative buffers, i.e., isotonic cacodylate or phosphate buffer, the following features were observed in thin-sections of the cytoplasm of interphase HeLa cells: (a) a greater than 2-fold increase in total microtubule contour length, (b) a 2-fold increase in a number of microtubules greater than or equal to 1 mu long, (c) an enhanced association of microtubules with cytoplasmic organelles, and (d) an increased clustering of 100 A filaments located in a perinuclear region of the cell. Furthermore, we found that after we incubated purified chick brain microtubules on a Sephadex G-25 column pre-equilibrated with polymerization mi...
Evidence for unaltered structure and in vivo assembly of microtubules in transformed cells
Proceedings of the National Academy of Sciences, 1978
By using immunoperoxidase cytochemistry at the light and electron microscopic level, microtubles were visualized in a number of "normal" nontumorigenic and transformed tumorigenic cell lines. A well-defined cytoplasmic microtubule complex exists in both normal and transformed interphase cells. The distribution of this complex closely correlates with the cell shape and the degree of cell spreading. Our data support the idea that these properties determine the pattern of the cytoplasmic microtubule complex, rather than the reverse. Ultrastructural observations of immunoperoxidase-stained tumor cells showed characteristic microtubules in cells in which the microtubules were poorly resolved at the light microscopic level. The results suggest that microtubule assembly and structure are unaltered in transformed cells. However, this conclusion does not exclude the possibility that some of the microtubules' functions might be impaired in a yet-unknown way.
Expression of microtubule networks in normal cells, transformed cells, and their hybrids
The Journal of Cell Biology, 1979
Microtubules play an important role in several cellular functions including cellular architecture and chromosome movement in cell division. Tubulin which polymerizes to form mictobules can be purified to homogeneity and used to raised antisera. Antisera prepared against porcine or chicken tubulin reacts well with mammalian tubulin. We have examined normal and transformed cells of mouse and human origin for microtubules by indirect immunofluorescence methods. Extensive networks of microtubules (MN) are easily detectable in normal and some transformed cells. The fixation procedure employed and the morphology and the cellular attachment properties seem to determine the ease of detection of MN in these cells. Cells derived from tumors and exhibiting several transformed phenotypes contained MN comparable to those of normal cells. Hybrids between transformed mouse cells and normal human cells were examined. They showed a variability in morphology, but all contained MN. These hybrids exhib...
Cell Motility and The Cytoskeleton, 2001
Little is known about the presence and distribution of tubulin isotypes in MDCK cells although essential epithelial functions in these monolayers are regulated by dynamic changes in the microtubule architecture. Using specific antibodies, we show here that the βI, βII, and βIV isotypes are differentially distributed in the microtubules of these cells. Microtubules in subconfluent cells radiating from the perinuclear region contain βI and βII tubulins, while those extending to the cell edges are enriched in βII. Confluent cells contain similar proportions of βI and βII along the entire microtubule length. βIV is the less abundant isotype and shows a similar distribution to βII. The effect of modifying tubulin isotype ratios in the microtubules that could affect their dynamics and function was analyzed by stably expressing in MDCK cells βI tubulin from CHO cells. Three recombinant clones expressing different levels of the exogenous βI tubulin were selected and subcloned. Clone 17-2 showed the highest expression of CHO β1 tubulin. Total βI tubulin levels (MDCK+CHO) in the clones were approximately 1.8 to 1.1-fold higher than in mock-transfected cells only expressing MDCK β1 tubulin. In all the cells, βII tubulin levels remained unchanged. The cells expressing CHO β1 tubulin showed defective attachment, spreading, and delayed formation of adhesion sites at short times after plating, whereas mock-transfected cells attached and spread normally. Analysis of cytoskeletal fractions from clone 17-2 showed a MDCK βI/CHO βI ratio of 1.89 at 2 h that gradually decreased to 1.0 by 24 h. The ratio of the two isotypes in the soluble fraction remained unchanged, although with higher values than those found for the polymerized βI tubulin. By 24 h, the transfected cells had regained normal spreading and formed a confluent monolayer. Our results show that excess levels of total βI tubulin, resulting from the expression of the exogenous β1 isotype, and incorporation of it into microtubules affect their stability and some cellular functions. As the levels return to normal, the cells recover their normal phenotype. Regulation of βI tubulin levels implies the release of the MDCK βI isotype from the microtubules into the soluble fraction where it would be degraded. Cell Motil. Cytoskeleton 50:147–160, 2001. © 2001 Wiley-Liss, Inc.
Membrane & cell biology
Indirect immunofluorescence and digital videomicroscopy were used to study gamma-tubulin distribution in normal mitotic and interphase HeLa cells and after their treatment with microtubule-stabilizing (taxol) and depolymerizing (nocodazole) drugs. In interphase HeLa cells, the affinity-purified antibodies against gamma-tubulin and monoclonal antibodies against acetylated tubulin stain one or two neighboring dots, centrioles. The gamma-tubulin content in two centrioles from the same cell differs insignificantly. Mitotic poles contain fourfold amount of gamma-tubulin as compared with the centrioles in interphase. The effect of nocodazole (5 microg/ml) on interphase cells resulted in lowering the amount of gamma-tubulin in the centrosome, and in 24 h it was reduced by half. Treatment with nocodazole for 2 h caused a fourfold decrease in the gamma-tubulin content in mitotic poles. Besides, the mitotic poles were unevenly stained, the fluorescence intensity in the center was lower than a...
Interphase microtubules in cultured cells: long or short?
Membrane & cell biology, 2000
Presently, the question about the length of microtubules in the interphase cell became actual, since the parameters of dynamic instability of the plus end measured in vivo do not allow one to explain the rapid turnover of the long microtubule system. The problem may be solved if one of the following suppositions is assumed: either microtubules undergo rapid depolymerization from the minus end or they are on the average much shorter than it is usually considered. To check the last hypothesis, we have reconstructed microtubules using stereophotography of electron microscopic sections. Microtubules around the cell center in cultures of epithelial cells (kidney of pig embryo (PK) and bovine trachea (FBT)) and fibroblasts (MEF, primary mouse embryo fibroblasts, and L cells), as well as at the periphery of PK cells were studied. All in all, no less than 200 microtubules were found near the centrosome in each cell culture. From 2.5 to 8% microtubules were beyond the studied volume (4.0 x 5...