MSA-35: a protein identified by human autoantibodies that colocalizes with microtubules.

We have identified a putative 35-kilodalton protein that colocalizes with microtubules and displays a unique spatial and temporal distribution during the cell cycle of HeLa cells. This protein has been given the designation MSA-35. MSA-35 first appears in association with microtubules and centrosomes of interphase cells exhibiting centrosome separation as a prelude to cell division. This protein is found in conjunction with kinetochore microtubules throughout their appearance. MSA-35 transiently associates with interpolar microtubules following anaphase and the pattern of MSA-35 reactivity in telophase cells suggests that there are at least seven domains within the intercellular bridge. The distribution of MSA-35 during and following recovery from mitotic arrest with nocodazole suggest that it is also present at low levels in interphase cells, can associate with interphase centrosomes, and colocalizes with nascent microtubules. The complex spatial and temporal distribution of MSA-35 indicates that it may be necessary for a series of events in the mitotic process such as the bundling of microtubules.     

The C-terminal polylysine region and methylation of K-Ras are critical for the interaction between K-Ras and microtubules

After synthesis in the cytosol, Ras proteins must be targeted to the inner leaflet of the plasma membrane for biological activity. This targeting requires a series of C-terminal posttranslational modifications initiated by the addition of an isoprenoid lipid in a process termed prenylation. A search for factors involved in the intracellular trafficking of Ras has identified a specific and prenylation-dependent interaction between tubulin/microtubules and K-Ras. In this study, we examined the structural requirements for this interaction between K-Ras and microtubules. By using a series of chimeras in which regions of the C terminus of K-Ras were replaced with those of Ha-Ras and vice versa, we found that the polylysine region of K-Ras located immediately upstream of the prenylation site is required for binding of K-Ras to microtubules. Studies in intact cells confirmed the importance of the K-Ras polylysine region for microtubule binding, as deletion or replacement of this region resulted in loss of paclitaxel-induced mislocalization of a fluorescent K-Ras fusion protein. The additional modifications in the prenyl protein processing pathway also affected the interaction of K-Ras with microtubules. Removal of the three C-terminal amino acids of farnesylated K-Ras with the specific endoprotease Rce1p abolished its binding to microtubules. Interestingly, however, methylation of the C-terminal prenylcysteine restored binding. Consistent with these results, localization of the fluorescent K-Ras fusion protein remained paclitaxel-sensitive in cells lacking Rce1, whereas no paclitaxel effect was observed in cells lacking the methyltransferase. These studies show that the polylysine region of K-Ras is critical for its interaction with microtubules and provide the first evidence for a functional consequence of Ras C-terminal proteolysis and methylation.     

Immunocytochemistry of the Microtubules of fat-laden cells. Brown fat cells and adrenocortical cells in primary monolayer culture

Cytoplasmic microtubules of fat-laden cells containing fine lipid droplets, such as brown fat cells and adrenocortical cells, were studied in relation to the metabolism of intracellular lipid. In these cells, the amount and distribution of lipid droplets reflect the state of inherent cellular function. Materials used were primary monolayer culture of fetal rat brown fat cells and that of bovine adrenocortical cells. The method was the immunocytochemistry with anti-tubulin antibody. When brown fat cells were being lipolyzed or the steroidogenesis of adrenocortical cells were being stimulated, the cytoplasmic microtubules in the cells were organized in a radial pattern in response to the behavior of the lipid droplets. It is assumed that the microtubules were in the regulation of cellular function in terms of the metabolism of lipid droplets in these cells. We have devised, in the course of the current study, a double fluorescence technique as an observational method whereby microtubules were observed immunocytochemically and lipid droplets by a secondary fluorescence with phosphine E staining.     

Identification with cellular microtubules of one of the co-assemlbing microtubule-associated proteins.

In this paper we describe a procedure for detecting proteins associated with cytoplasmic microtubules in vivo. Detergent-extracted cytoskeletons of NIL8 hamster cells are prepared under conditions which preserve the microtubules. The cytoskeletons are then extracted in the presence of calcium, which depolymerizes the microtubules and quantitatively extracted cytoskeletons are prepared from cells that have been incubated with colchicine. The cytoskeletons from these cells contain no microtubules or tubulin. Electrophoretic analysis of the calcium extracts of the colchicine-treated and untreated cells reveals several radioactively labeled polypeptides. There is, however, no apparent quantitative or qualitative difference between the two extracts other than the tubulin polypeptides. Each of the extracts is mixed with an excess of unlabeled calf brain microtubule protein and carried through cycles of temperature-dependent microtubule assembly. Distinct species from each extract co-assemble at a constant ratio, but only one polypeptide is uniquely derived from cells containing intact microtubules. The molecular weight of this polypeptide is similar to that proposed for the tau species detected in brain microtubule preparations.     

Three-dimensional analysis and ultrastructural design of mitotic spindles from the cdc20 mutant of Saccharomyces cerevisiae.

The three-dimensional organization of mitotic microtubules in a mutant strain of Saccharomyces cerevisiae has been studied by computer-assisted serial reconstruction. At the nonpermissive temperature, cdc20 cells arrested with a spindle length of approximately 2.5 microns. These spindles contained a mean of 81 microtubules (range, 56-100) compared with 23 in wild-type spindles of comparable length. This increase in spindle microtubule number resulted in a total polymer length up to four times that of wild-type spindles. The spindle pole bodies in the cdc20 cells were approximately 2.3 times the size of wild-type, thereby accommodating the abnormally large number of spindle microtubules. The cdc20 spindles contained a large number of interpolar microtubules organized in a "core bundle." A neighbor density analysis of this bundle at the spindle midzone showed a preferred spacing of approximately 35 nm center-to-center between microtubules of opposite polarity. Although this is evidence of specific interaction between antiparallel microtubules, mutant spindles were less ordered than the spindle of wild-type cells. The number of noncore microtubules was significantly higher than that reported for wild-type, and these microtubules did not display a characteristic metaphase configuration. cdc20 spindles showed significantly more cross-bridges between spindle microtubules than were seen in the wild type. The cross-bridge density was highest between antiparallel microtubules. These data suggest that spindle microtubules are stabilized in cdc20 cells and that the CDC20 gene product may be involved in cell cycle processes that promote spindle microtubule disassembly.     

Reorganization of the cytoskeleton during Drosophila oogenesis: implications for axis specification and intercellular transport.

Inhibitor studies have implicated microtubules in at least three important developmental processes during Drosophila oogenesis: oocyte determination and growth during stages 1 through 6, positioning of the anterior determinant bicoid mRNA during stages 9 through 12, and ooplasmic streaming during stages 10b through 12. We have used fluorescence cytochemistry together with laser scanning confocal microscopy to identify distinct microtubule structures at each of the above three periods that are likely to be involved in these processes. During stages 1 through 7, maternal components synthesized in nurse cells are transported through cytoplasmic bridges to the oocyte. At this time, microtubules that appear to originate in the oocyte pass through these cytoplasmic bridges into the adjacent nurse cells; these microtubules are likely to serve as a polarized scaffold on which maternal RNAs and proteins are transported. During stages 7 and 8, microtubules in the oocyte cortex reorganize to form an anterior-to-posterior gradient, suggesting a role for microtubules in the localization of morphogenetic determinants. Finally, when ooplasmic streaming begins during stage 10 b, it is accompanied by the assembly of subsurface microtubule arrays that spiral around the oocyte; these arrays disassemble as the oocyte matures and streaming stops. During ooplasmic streaming, many vesicles are closely associated with the subsurface microtubules, suggesting that streaming is driven by vesicle translocation along microtubules. We believe that actin plays a secondary role in each of these morphogenetic events, based on our parallel studies of actin organization during each of the above stages of oogenesis.     

Structure and function of the microtubular cytoskeleton during megasporogenesis and embryo sac development in Gasteria verrucosa (Mill.) H. Duval

Summary Using immunocytochemical techniques, tubulin distribution in various stages of meiosis and embryo sac development was studied. In the archespore cell some microtubules appeared to be randomly oriented. During zygotene and pachytene, when the cell volume increases, a large number of microtubules in dispersed configurations and bundles were observed. During this stage the nucellar cells divide, and their parallel cortical microtubules play an important role in preparing the direction of cell enlargement. The protoderm cells show anticlinal-directed cortical microtubules. It can be concluded that the enlargement of the meiocyte during these early meiotic stages is influenced both by its own cytoskeleton and by growth of the nucellus. Thereafter, the microtubules function directly in meiosis and disappear for the greater part until the two-nucleate coenocyte is formed. In a four-nucleate coenocyte microtubules reappear around the nucleus; in a young synergid, randomly oriented microtubules are involved in cell shaping during the formation of the filiform apparatus; in the synergids of the mature embryo sac, many parallel arrays of microtubules are present. Microtubules are less abundant in other cells. It is concluded that the cytomorphogenesis of the developing coenocyte and embryo sac are due to cell growth of the nucellar cells together with vacuolation of the coenocyte.     

The display of microtubules in transformed cells.

Monospecific tubulin antibodies have been used in indirect immunofluorescence microscopy on a variety of well characterized, transformed cell lines grown in tissue culture. Networks of colcemid-sensitive fibers are seen in SV40-transformed 3T3 cells, SV40-transformed rat embryo cells, HeLa cells and other transformed cell lines. In each case, greater than 90% of the cells contain visible microtubular networks, and where individual microtubules can be distinguished, they run for long distances. Documentation of these metworks is more difficult in transformed than in normal cells, because transformed cells are in general more rounded and have less well spread cytoplasm. In addition, the microtubular networks can be readily visualized in "cytoskeletons" of both normal and transformed cells, obtained by treatment of cells with nonionic detergents in a buffer which stabilizes microtubules in vitro. Addition of calcium to this buffer results in in situ fragmentation and destruction of the microtubular network. In view of these results, we conclude that transformed cells contain significant numbers of microtubules, and that in transformed cells, as in normal cells, microtubules are arranged in networks.     

MICROTUBULES IN THE FORMATION AND DEVELOPMENT OF THE PRIMARY MESENCHYME IN ARBACIA PUNCTULATA : I. The Distribution of Microtubules

Prior to gastrulation, the microtubules in the presumptive primary mesenchyme cells appear to diverge from points (satellites) in close association with the basal body of the cilium; from here most of the microtubules extend basally down the lateral margins of the cell. As these cells begin their migration into the blastocoel, they lose their cilia and adopt a spherical form. At the center of these newly formed mesenchyme cells is a centriole on which the microtubules directly converge and from which they radiate in all directions. Later these same cells develop slender pseudopodia containing large numbers of microtubules; the pseudopodia come into contact and fuse to form a "cable" of cytoplasm. Microtubules are now distributed parallel to the long axis of the cable and parallel to the stalks which connect the cell bodies of the mesenchyme cells to the cable. Microtubules are no longer connected to the centrioles in the cell bodies. On the basis of these observations we suggest that microtubules are a morphological expression of a framework which opeartes to shape cells. Since at each stage in the developmental sequence microtubules appear to originate (or insert) on different sites in the cytoplasm, the possibility is discussed that these sites may ultimately control the distribution of the microtubules and thus the developmental sequence of form changes.     

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.     

Relationship between Freezing Tolerance of Root-Tip Cells and Cold Stability of Microtubules in Rye (Secale cereale L. cv Puma)

The response of cortical microtubules to low temperature and freezing was assessed for root tips of cold-acclimated and non-acclimated winter rye (Secale cereale L. cv Puma) seedlings using indirect immunofluorescence microscopy with antitubulin antibodies. Roots cooled to 0 or −3°C were fixed for immunofluorescence microscopy at these temperatures or after an additional hour at 4°C. Typical arrays of cortical microtubules were present in root-tip cells of seedlings exposed to the cold-acclimation treatment of 4°C for 2 days. Microtubules in these cold-acclimated cells were more easily depolymerized by a 0°C treatment than microtubules in root-tip cells of nonacclimated, 22°C-grown seedlings. Microtubules were still present in some cells of both nonacclimated and cold-acclimated roots at 0 and −3°C; however, the number of microtubules in these cells was lower than in controls. Microtubules remaining during the −3°C freeze were shorter than microtubules in unfrozen control cells. Repolymerization of microtubules after both the 0 and −3°C treatments occurred within 1 h. Root tips of nonacclimated seedlings had an LT-50 of −9°C. Cold acclimation lowered this value to −14°C. Treatment of 22°C-grown seedlings for 24 h with the microtubule-stabilizing drug taxol caused a decrease in the freezing tolerance of root tips, indicated by a LT-50 of −3°C. Treatment with D-secotaxol, an analog of taxol that was less effective in stabilizing microtubules, did not alter the freezing tolerance. We interpret these data to indicate that a degree of depolymerization of microtubules is necessary for realization of maximum freezing tolerance in root-tip cells of rye.     

Cytoplasmic dynein-mediated assembly of pericentrin and gamma tubulin onto centrosomes

Centrosome assembly is important for mitotic spindle formation and if defective may contribute to genomic instability in cancer. Here we show that in somatic cells centrosome assembly of two proteins involved in microtubule nucleation, pericentrin and gamma tubulin, is inhibited in the absence of microtubules. A more potent inhibitory effect on centrosome assembly of these proteins is observed after specific disruption of the microtubule motor cytoplasmic dynein by microinjection of dynein antibodies or by overexpression of the dynamitin subunit of the dynein binding complex dynactin. Consistent with these observations is the ability of pericentrin to cosediment with taxol-stabilized microtubules in a dynein- and dynactin-dependent manner. Centrosomes in cells with reduced levels of pericentrin and gamma tubulin have a diminished capacity to nucleate microtubules. In living cells expressing a green fluorescent protein-pericentrin fusion protein, green fluorescent protein particles containing endogenous pericentrin and gamma tubulin move along microtubules at speeds of dynein and dock at centrosomes. In Xenopus extracts where gamma tubulin assembly onto centrioles can occur without microtubules, we find that assembly is enhanced in the presence of microtubules and inhibited by dynein antibodies. From these studies we conclude that pericentrin and gamma tubulin are novel dynein cargoes that can be transported to centrosomes on microtubules and whose assembly contributes to microtubule nucleation.     

Immunological and structural evidence for patterned intussusceptive surface growth in a unicellular organism. A postulated role for submembranous proteins and microtubules

The surface complex of Euglena has been examined intact and after isolation and purification by the use of mild sonication to disrupt cells. In intact cells the surface complex (pellicle complex) is oriented in a series of parallel ridges and grooves, and possesses among other components a characteristic group of four to seven microtubules. Isolated pellicles retain the ridge and groove pattern but no microtubules are present. Isolates yielded at least three major polypeptides on SDS acrylamide gels; one or more of the polypeptides are postulated to be identical with a submembrane layer present in both intact and isolated pellicles; one polypeptide appears to be in or on the surface membrane. Antibodies directed against the isolated pellicles were conjugated directly or indirectly to fluorescein, latex spheres, or ferritin. In appropriate experiments with these antibody conjugates, it has been found that antigenic sites are immobile and that new antigenic sites (daughter strips) are inserted between parental strips in replicating cells. These results together with direct observation of daughter strips by transmission electron microscopy suggest that surface growth in Euglena occurs by intussusception. Microtubules associated with the pellicle complex are postulated to play a role in the development of new daughter strips, and possibly also in cell movements.     

The Spindle Midzone Microtubule-Associated Proteins Ase1p and Cin8p Affect the Number and Orientation of Astral Microtubules in Saccharomyces cerevisiae

The nucleus of the budding yeast S. cerevisiae has to move to the bud neck during mitosis in order for proper DNA segregation to take place. This movement is mediated by spindle and astral microtubules, and it relies on forces generated by microtubule-associated motor proteins. When budding yeast cells express the non-cleavable cohesin subunit, Scc1-RRDD, sister chromatid separation is blocked, preventing the spindle from elongating. Thus, in the presence of Scc1-RRDD nuclear positioning is mediated solely by forces acting through astral microtubules. We have previously shown that under these conditions cells exit mitosis with the nucleus in the mother cells, and that the position of the nucleus is determined, at least in part, by the FEAR pathway, which regulates various aspects of mitotic exit. When the FEAR pathway is inactivated, cells expressing Scc1-RRDD exit mitosis with the nucleus in the daughter cells (referred to as a “daughterly phenotype”). In order to find additional proteins that participate in nuclear positioning, we screened a series of mutant strains for those that displayed a daughterly phenotype when Scc1-RRDD was expressed. The most prominent defects were seen in ase1Δ and cin8Δ mutant cells. Both Ase1p and Cin8p were previously shown to be nuclear and to be involved in spindle function. We show here that deletion of ASE1 or CIN8 causes a defect in SPB separation and leads to an abnormal number of astral microtubules and a change in their orientation within the cell. Taken together, these results suggest that in budding yeast Ase1p and Cin8p affect nuclear positioning through astral microtubule-dependent mechanisms.     

Specific association of STOP protein with microtubules in vitro and with stable microtubules in mitotic spindles of cultured cells.

STOP (Stable Tubule Only Polypeptide) is a neuronal microtubule associated protein of 145 kd that stabilizes microtubules indefinitely to in vitro disassembly induced by cold temperature, millimolar calcium or by drugs. We have produced monoclonal antibodies against STOP. Using an antibody affinity column, we have produced a homogeneously pure 145 kd protein which has STOP activity as defined by its ability to induce cold stability and resistance to dilution induced disassembly in microtubules in vitro. Western blot analysis, using a specific monoclonal antibody, demonstrates that STOP recycles quantitatively with microtubules through three assembly cycles in vitro. Immunofluorescence analysis demonstrates that STOP is specifically associated with microtubules of mitotic spindles in neuronal cells. Further, and most interestingly, STOP at physiological temperature appears to be preferentially distributed on the distinct microtubule subpopulations that display cold stability; kinetochore-to-pole microtubules and telophase midbody microtubules. The observed distribution suggests that STOP induces the observed cold stability of these microtubule subpopulations in vivo.     

The distribution of tau and HMW microtubule-associated proteins in different cell types

To investigate the distribution of the tau and HMW microtubule-associated proteins (MAPS) and their relationship to microtubules in vivo, we have examined a wide variety of avian and mammalian cell types by immunofluorescence with antisera to these two proteins. Anti-HMW serum stains cytoplasmic microtubules in all mammalian cell types so far examined. However, anti-tau serum did not stain cytoplasmic microtubules in rat glial cells or in pig kidney cells. In mammalian neurons, fibroblasts and neuroblastoma cells, the staining of microtubules with both sera was similar. Anti-HMW serum did not stain primary cilia or cilia on isolated tracheal epithelial cells, whereas anti-tau serum did stain these ciliary microtubules. We believe these results indicate that some types of microtubules may be associated with only the tau or the HMW protein, whereas others may be associated with both tau and HMW protein. With respect to avian cells, anti-HMW serum did not stain microtubules in any of the three cell types examined, whereas the anti-tau serum stained them in two cell types. Furthermore, double diffusion tests indicated that anti-pig tau serum will precipitate both pig brain tau and tau protein isolated from chick brain, whereas anti-HMW serum will precipitate only pig brain and not chick brain HMW protein. We believe tau protein is antigenically similar in both avian and mammalian cells, whereas the HMW protein from these two sources is antigenically distinct.     

Bundling of microtubules in transfected cells does not involve an autonomous dimerization site on the MAP2 molecule.

We have searched for putative dimerization sites in microtubule-associated protein 2 (MAP2) that may be involved in the bundling of microtubules. An overlapping series of fragments of the embryonic form MAP2c were created and immunologically "tagged" with an 11 amino acid sequence from human c-myc. Nonneuronal cells were transfected simultaneously with one of these myc-tagged fragments and with full-length native MAP2c. Immunolabeling with site-specific antibodies allowed the two transgene products to be located independently within the cytoplasm of a single double-transfected cell. All transfected cells contained bundled microtubules to which the full-length native MAP2 was bound. The distribution of the tagged MAP2 fragment relative to these MAP2-induced bundles was determined by the anti-myc staining. None of the fragments tested, representing all of the MAP2c sequence in overlapping pieces, were associated with MAP2-induced microtubule bundles. These results suggest that MAP2-induced bundle formation in cells does not involve an autonomous dimerization site within the MAP2 sequence.     

Disruption of microtubules in living cells and cell models by high affinity antibodies to beta-tubulin.

Polyclonal antibodies with high affinity for beta-tubulin were found to disrupt cytoplasmic microtubules efficiently after microinjection into tissue culture cells. The degree of microtubular fragmentation was directly proportional to the amount of the injected antibody. At molar ratios of 1 antibody per 100 tubulin dimers, most microtubules were disrupted within 90 min after injection. In contrast, the time course of disintegration was relatively independent of the antibody concentration. Within the range of 1 antibody per 10(2)-10(4) tubulin dimers, the maximal values for microtubular disintegration were reached approximately 1-1.5 h after injection. Mitotic microtubules were found to be resistant to all antibody concentrations used. In living cells, microtubules recovered within a few hours after antibody-induced decay. The time course of recovery, like the extent of disintegration, was a function of the antibody concentration. The antibody acted also on microtubules in detergent-extracted cell models and on microtubules polymerised in vitro. When added to microtubular protein, the bivalent antibody as well as its Fab fragments prevented polymerisation. The data suggest that these antibodies disrupt microtubules because their affinity to tubulin is at least 100 times higher than the affinities found for tubulin:tubulin interaction. Fragmented microtubules are probably unstable and decompose into smaller units.     

A stereoscopic analysis of the centrosome structure in the cells of continuous and primary cell cultures]

A 3D reconstruction of the centrosome region was made based on series of semithick sections in tissue culture cells. It was shown that: 1) the total number of microtubules attached to the centrosome is about 30-50 of which only 20% or less run farther than 2 microns away from the centrosome; 2) a certain number of short microtubules (less than 1 micron length) is present in the vicinity of the centrosome, the majority of them are attached to the centrosome; 3) many microtubules around the centrosome have no direct contact with either centrioles, or other microtubule-convergent structures; 4) the majority of free microtubules are comparatively long (more than 1 micron length); 5) almost all the microtubules running closer than 2 microns to the centrosome are oriented towards it with their proximal ends. The radial distribution of free microtubules around the centrosome support the supposition that they may appear as a result of their detachment from the microtubule-nucleating centres.