Detyrosination of tubulin regulates the interaction of intermediate filaments with microtubules in vivo via a kinesin-dependent mechanism

Posttranslationally modified forms of tubulin accumulate in the subset of stabilized microtubules (MTs) in cells but are not themselves involved in generating MT stability. We showed previously that stabilized, detyrosinated (Glu) MTs function to localize vimentin intermediate filaments (IFs) in fibroblasts. To determine whether tubulin detyrosination or MT stability is the critical element in the preferential association of IFs with Glu MTs, we microinjected nonpolymerizable Glu tubulin into cells. If detyrosination is critical, then soluble Glu tubulin should be a competitive inhibitor of the IF-MT interaction. Before microinjection, Glu tubulin was rendered nonpolymerizable and nontyrosinatable by treatment with iodoacetamide (IAA). Microinjected IAA-Glu tubulin disrupted the interaction of IFs with MTs, as assayed by the collapse of IFs to a perinuclear location, and had no detectable effect on the array of Glu or tyrosinated MTs in cells. Conversely, neither IAA-tyrosinated tubulin nor untreated Glu tubulin, which assembled into MTs, caused collapse of IFs when microinjected. The epitope on Glu tubulin responsible for interfering with the Glu MT-IF interaction was mapped by microinjecting tubulin fragments of alpha-tubulin. The 14-kDa C-terminal fragment of Glu tubulin (alpha-C Glu) induced IF collapse, whereas the 36-kDa N-terminal fragment of alpha-tubulin did not alter the IF array. The epitope required more than the detyrosination site at the C terminus, because a short peptide (a 7-mer) mimicking the C terminus of Glu tubulin did not disrupt the IF distribution. We previously showed that kinesin may mediate the interaction of Glu MTs and IFs. In this study we found that kinesin binding to MTs in vitro was inhibited by the same reagents (i.e., IAA-Glu tubulin and alpha-C Glu) that disrupted the IF-Glu MT interaction in vivo. These results demonstrate for the first time that tubulin detyrosination functions as a signal for the recruitment of IFs to MTs via a mechanism that is likely to involve kinesin.     

Enhanced stability of microtubules enriched in detyrosinated tubulin is not a direct function of detyrosination level

Interphase cultured monkey kidney (TC-7) cells contain distinct subsets of cellular microtubules (MTs) enriched in posttranslationally detyrosinated (Glu) or tyrosinated (Tyr) alpha tubulin (Gundersen, G. G., M. H. Kalnoski, and J. C. Bulinski. 1984. Cell. 38:779-789). To determine the relative stability of these subsets of MTs, we subjected TC-7 cells to treatments that slowly depolymerized MTs. We found Glu MTs to be more resistant than Tyr MTs to depolymerization by nocodazole in living cells, and to depolymerization by dilution in detergent-permeabilized cell models. However, in cold-treated cells, Glu and Tyr MTs did not differ significantly in their stability. Digestion of permeabilized cell models with pancreatic carboxypeptidase A, to generate Glu MTs from endogenous Tyr MTs, did not significantly alter the resistance of the endogenous Tyr MTs toward dilution-induced depolymerization. Furthermore, in human fibroblasts that contained no distinct Glu MTs, we observed a population of nocodazole-resistant MTs. These data suggest that Glu MTs possess enhanced stability against end-mediated depolymerization, yet detyrosination alone appears to be insufficient to confer this enhanced stability.     

Generation of a stable, posttranslationally modified microtubule array is an early event in myogenic differentiation

Microtubules (MTs) have been implicated to function in the change of cell shape and intracellular organization that occurs during myogenesis. However, the mechanism by which MTs are involved in these morphogenetic events is unclear. As a first step in elucidating the role of MTs in myogenesis, we have examined the accumulation and subcellular distribution of posttranslationally modified forms of tubulin in differentiating rat L6 muscle cells, using antibodies specific for tyrosinated (Tyr), detyrosinated (Glu), and acetylated (Ac) tubulin. Both Glu and Ac tubulin are components of stable MTs, whereas Tyr tubulin is the predominant constituent of dynamic MTs. In proliferating L6 myoblasts, as in other types of proliferating cells, the level of Glu tubulin was very low when compared with the level of Tyr tubulin. However, when we shifted proliferating L6 cells to differentiation media, we observed a rapid accumulation of Glu tubulin in cellular MTs. By immunofluorescence, the increase in Glu tubulin was first detected in MTs of prefusion myoblasts and was specifically localized to MTs that were associated with elongating portions of the cell. MTs in the multinucleated myotubes observed at later stages of differentiation maintained the elevated level of Glu tubulin that was observed in the prefusion myoblasts. When cells at early stages of differentiation (less than 1 d after switching the culture medium) were immunostained for Glu tubulin and the muscle-specific marker, muscle myosin, we found that the increase in Glu tubulin preceded the accumulation of muscle myosin. Thus, the elaboration of Glu MTs is one of the very early events in myogenesis. Ac tubulin also increased during L6 myogenesis; however, the increase in acetylation occurred later in myogenesis, after fusion had already occurred. Because detyrosination was temporally correlated with early events of myogenesis, we examined the mechanism responsible for the accumulation of Glu tubulin in the MTs of prefusion myoblasts. We found that an increase in the stability of L6 cell MTs occurred at the onset of differentiation, suggesting that the early increase in detyrosination that we observed is a manifestation of a decrease in MT dynamics in elongating myoblasts. We conclude that the establishment of an oriented array of microtubules heightened in its stability and its level of posttranslationally modified subunits may be involved in the subcellular remodeling that occurs during myogenesis.     

Microtubule arrays in differentiated cells contain elevated levels of a post-translationally modified form of tubulin

Tyrosinated (Tyr) and detyrosinated (Glu) alpha-tubulins are post-translationally modified species that differ by a single amino acid at their respective C-termini. We have examined the distribution of these two species by immunofluorescence in proliferating and differentiated cells using antisera specifically reactive with each of the forms. In proliferating PtK1 cells, Tyr tubulin was the predominant form in almost every cytoplasmic microtubule (MT); only a few MTs contained detectable Glu tubulin. In contrast, staining of centrioles and primary cilia of PtK1 cells suggested that Glu tubulin was the predominant form in these stable assemblies of MTs. An examination of the distribution (by immunofluorescence) and relative amount (by immunoblot analysis) of the two forms of tubulin in the stable assemblies of MTs present in cultured neuronal cells (neurites), sperm and tracheal cells (axonemes and basal bodies), and platelets and erythrocytes (marginal bands) revealed that, in general, the MTs in these arrays contained substantially elevated levels of Glu tubulin in comparison with the levels in MTs of cultured cells. The one exception, the marginal band of toad erythrocytes, which contained only Tyr tubulin, demonstrates that an elevated level of Glu tubulin is not an obligate feature of a stable array of MTs. Nonetheless, an elevated level of Glu tubulin may be a useful indicator of stable MTs in differentiated cells. It is important to note that commonly used sources of tubulin (e.g., brain or flagella) necessarily yield tubulin that differs strikingly from tubulin of proliferating cells in its content of Glu tubulin.(ABSTRACT TRUNCATED AT 250 WORDS)     

On the relation between distinct components of the cytoskeleton: an epitope shared by intermediate filaments, microfilaments and cytoplasmic foci.

Monoclonal antibodies were generated against detergent-insoluble cytoskeletal proteins isolated from low-density membrane fractions of rat liver. By immunofluorescence, one of the antibodies stains three distinct structures in cultured rat fibroblast and hepatocyte lines as well as the PtK2 rat-kangaroo kidney epithelial line. These structures are: i) many tangled filaments similar to intermediate filaments (IFs), ii) fewer and variable numbers of straight filaments, and iii) punctate cytoplasmic foci, often most intense around the nucleus. All three of these structures are resistant to extraction by non-ionic detergent. Close examination reveals that the tangled and straight filaments are not stained uniformly, but as a series of bright patches. In cells treated with nocodazole, the antibody reacts strongly with a perinuclear filamentous cage. Very few tangled filaments are detected in these cells, however, the straight filaments and punctate cytoplasmic staining are resistant to nocodazole treatment. Double-label immunofluorescence shows that, even though tangled filament distribution and nocodazole sensitivity are similar to the behavior of vimentin IFs, there is only partial coincidence of staining with either vimentin or cytokeratin IFs. The straight filaments coincide with some actin stress fibers, but the punctate cytoplasmic staining is not related to IFs, actin, or tubulin. Thus, this monoclonal antibody stains a novel group of three seemingly unrelated cytoskeletal structures, including a previously undescribed insoluble nonfilamentous pool. Taken as a whole, two hypotheses are consistent with these data. i) The antigen recognized may be a protein which has a large insoluble cytoplasmic pool and binds both IFs and actin, but only binds to a subset of each class of filaments.(ABSTRACT TRUNCATED AT 250 WORDS)     

A rat monoclonal antibody reacting specifically with the tyrosylated form of alpha-tubulin. I. Biochemical characterization, effects on microtubule polymerization in vitro, and microtubule polymerization and organization in vivo

The antigenic site recognized by a rat monoclonal antibody (clone YL 1/2) reacting with alpha-tubulin (Kilmartin, J.V., B. Wright, and C. Milstein, 1982, J. Cell Biol., 93:576-582) has been determined and partially characterized. YL 1/2 reacts specifically with the tyrosylated form of brain alpha-tubulin from different mammalian species. YL 1/2 reacts with the synthetic peptide Gly-(Glu)3-Gly-(Glu)2- Tyr, corresponding to the carboxyterminal amino acid sequence of tyrosylated alpha-tubulin, but does not react with Gly-(Glu)3-Gly- (Glu)2, the constituent peptide of detyrosylated alpha-tubulin. Electron microscopy as well as direct and indirect immunofluorescence microscopy shows that YL 1/2 binds to the surface of microtubules polymerized in vitro and in vivo. Further in vitro studies show that the antibody has no effect on the rate and extent of microtubule polymerization, the stability of microtubules, and the incorporation of the microtubule-associated proteins (MAP2) and tau into microtubules. In vivo studies using Swiss 3T3 fibroblasts injected with YL 1/2 show that; when injected at low concentration (2 mg IgG/ml in the injection solution), the antibody binds to microtubules without changing their distribution in the cytoplasm. Injection of larger concentration of YL 1/2 (6 mg IgG/ml) induces the formation of microtubule bundles, and still higher concentrations cause the aggregation of microtubule bundles around the nucleus (greater than 12 mg IgG/ml).     

Detyrosination of alpha tubulin does not stabilize microtubules in vivo [published erratum appears in J Cell Biol 1990 Sep;111(3):1325-6]

The relationship between alpha tubulin detyrosination and microtubule (MT) stability was examined directly in cultured fibroblasts by experimentally converting the predominantly tyrosinated MT array to a detyrosinated (Glu) array and then assaying MT stability. MTs in mouse Swiss 3T3 cells displayed an increase in Glu immunostaining fluorescence approximately 1 h after microinjecting antibodies to the tyrosinating enzyme, tubulin tyrosine ligase. Detyrosination progressed to virtual completion after 12 h and persisted for 30-35 h before tyrosinated subunits within MTs were again detected. The stability of these experimentally detyrosinated MTs was tested by first injecting either biotinylated or Xrhodamine-labeled tubulin and then measuring bulk turnover by hapten-mediated immunocytochemistry or fluorescence recovery after photobleaching, respectively. By both methods, turnover was found to be similarly rapid, possessing a half time of approximately 3 min. As a final test of MT stability, the level of acetylated tubulin staining in antibody-injected cells was compared with that observed in adjacent, uninjected cells and also with the staining observed in cells whose MTs had been stabilized with taxol. Although intense Glu staining was observed in both injected and taxol-treated cells, increased acetylated tubulin staining was observed only in the taxol-stabilized MTs, indicating that the MTs were not stabilized by detyrosination. Together, these results demonstrated clearly that detyrosination does not directly confer stability on MTs. Therefore, the stable MTs observed in these and other cell lines must have arisen by another mechanism, and may have become posttranslationally modified after their stabilization.     

A rat monoclonal antibody reacting specifically with the tyrosylated form of alpha-tubulin. II. Effects on cell movement, organization of microtubules, and intermediate filaments, and arrangement of Golgi elements

A rat monoclonal antibody against yeast alpha-tubulin (clone YL 1/2; Kilmartin, J. V., B. Wright, and C. Milstein, 1982, J. Cell Biol., 93:576-582) that reacts specifically with the tyrosylated form of alpha- tubulin and readily binds to tubulin in microtubules when injected into cultured cells (see Wehland, J., M. C. Willingham, and I. V. Sandoval, 1983, J. Cell Biol., 97:1467-1475) was used to study microtubule organization and function in living cells. Depending on the concentration of YL 1/2 that was injected the following striking effects were observed: (a) When injected at a low concentration (2 mg IgG/ml in the injection solution), where microtubules were decorated without changing their distribution, intracellular movement of cell organelles (saltatory movement) and cell translocation were not affected. Intermediate concentrations (6 mg IgG/ml) that induced bundling but no perinuclear aggregation of microtubules abolished saltatory movement and cell translocation, and high concentrations (greater than 12 mg IgG/ml) that induced perinuclear aggregation of microtubules showed the same effect. (b) YL 1/2, when injected at intermediate and high concentrations, arrested cells in mitosis. Such cells showed no normal spindle structures. (c) Injection of an intermediate concentration of YL 1/2 that stopped saltatory movement caused little or no aggregation of intermediate filaments and no dispersion of the Golgi complex. After injection of high concentrations, resulting in perinuclear aggregation of microtubules, intermediate filaments formed perinuclear bundles and the Golgi complex became dispersed analogous to results obtained after treatment of cells with colcemid. (d) When rhodamine-conjugated YL 1/2 was injected at concentrations that stopped saltatory movement and arrested cells in mitosis, microtubule structures could be visualized and followed for several hours in living cells by video image intensification microscopy. They showed little or no change in distribution and organization during observation, even though these microtubule structures appeared not to be stabilized by injected YL 1/2 since they were readily depolymerized by colcemid or cold treatment and repolymerized upon drug removal or rewarming to 37 degrees C, respectively. These results are discussed in terms of the participation of microtubules in cellular activities such as cell movement and cytoplasmic organization and in terms of the specificity of YL 1/2 for the tyrosylated form of alpha-tubulin.     

Distribution of tyrosinated and nontyrosinated alpha-tubulin during mitosis

The C-terminus of alpha-tubulin undergoes a reversible posttranslational tyrosination/detyrosination. The distributions of the tyrosinated (Tyr) and nontyrosinated (Glu) species during mitosis of cultured cells have been investigated by immunofluorescence using antibodies directed against the C-terminus of either Tyr or Glu tubulin. The distribution of Tyr tubulin differed from that of Glu tubulin at each stage of mitosis; in general, the distribution of Tyr tubulin was similar to that of total tubulin, whereas Glu tubulin had a more restricted distribution. The Glu species was found in half-spindle fibers but was not detected in astral fibers at any stage and was seen in the interzone only during telophase. These results were confirmed by a direct comparison of the distributions of Tyr and Glu tubulin in cells double-labeled with the two antibodies. Evidence for the occurrence of Tyr and Glu tubulin in each class of half-spindle fibers (kinetochore and polar) was obtained from the staining patterns of the two antibodies in cold-treated cells. Immunoblots of extracts prepared from synchronous mitotic cells showed that Glu tubulin was a minor species of the total tubulin in the spindle; no changes in the amount of either Tyr or Glu tubulin were detected at any stage of mitosis. These results show that Tyr tubulin is the major species in the mitotic spindle and is found in all classes of spindle fibers, whereas Glu tubulin is present in small amounts and shows a more restricted distribution. The presence of two biochemically distinct forms of alpha-tubulin in the spindle may be important for spindle function.     

Change in the heterogeneous distribution of tubulin isotypes in mitotic microtubules of the sea urchin egg by treatment with microtubule depolymerizing or stabilizing drugs.

In the mitotic sea urchin egg, the spindle microtubules were composed of different tubulin isotypes from those of astral microtubules using monoclonal antibodies [Oka et al. (1990) Cell Motil. Cytoskeleton, 16, 239-250]. Three of the antibodies, D2D6, DM1B, and YL1/2, were specific for spindle microtubules, astral microtubules and reactive with both microtubules, respectively. The mitotic sea urchin egg was treated with microtubule depolymerizing (colcemid and nocodazole) and stabilizing (hexylene glycol) drugs and change in the heterogeneous distribution of the tubulin isotypes was investigated by the immunofluorescence procedure using these three monoclonal anti-tubulin antibodies. We observed that: (1) the microtubule depolymerizing drugs caused quick depolymerization of most mitotic microtubules, and a small number of spindle microtubules remaining were stained with all three antibodies; (2) hexylene glycol induced many microtubules in the mitotic apparatus, which was stained with D2D6 but was not stained with DM1B; (3) hexylene glycol also induced a great number of miniasters in the cytoplasm, and they were stained with three antibodies. These results suggest that these drugs altered the distribution of tubulin isotypes in the mitotic microtubules during depolymerization or polymerization within a short time.     

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

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

Effects of antimitotic and antimitochondrial agents on the cellular distribution of microtubules and mitochondria

Using antibodies to a mitochondrial molecular chaperone class of protein, which is specifically altered in mutants resistant to microtubule (MT) inhibitors, the effect of a number of MT and mitochondrial inhibitors on the cellular distribution of mitochondria and various cytoskeletal filaments was examined. Treatment of Chinese hamster ovary (CHO) or chicken embryo fibroblast (CEF) cells with the MT inhibitors podophyllotoxin, colchicine, nocodazole and vinblastine caused depolymerization of cellular MTs, but had no significant effect on the distribution patterns of mitochondria. This is attributed to the association of mitochondria with intermediate filaments (IFs) which are not destroyed under these conditions. In contrast to MT inhibitors, treatment of CEFs with the potassium ionophores nonactin and valinomycin caused aggregation of mitochondria towards the perinuclear region of the cells, without having any apparent effect on cellular MTs. This observation suggests that mitochondrial membrane potential, which is abolished by these drugs, play a role in the cellular distribution of mitochondria. In cells recovering from the effects of MT inhibitors, mitochondria have been found to surround the MT organizing complexes and upon complete recovery a realignment of MTs with mitochondria takes place. These observations suggest that MT growth in cells does not occur in a completely random manner but that mitochondria may play some role in their directional growth.     

The Involvement of Protein Synthesis Elongation Factor 1α in the Organization of Microtubules on the Perinuclear Region during the Cell Cycle Transition from M Phase to G1 Phase in Tobacco BY-2 Cells

Association of the organization of microtubules (MTs) in the perinuclear region with a 49-kDa protein, that is immunologically cross-reactive to a 51-kDa protein isolated from sea urchin centrosomes and has been shown to play some roles in the organization of MTs in animal cells (Toriyama et al.: Cell Motil. Cytoskeleton 9, 117–128, 1988), was examined during the cell cycle transition from M phase to G₁ phase using the highly synchronized tobacco BY-2 cells under confocal laser scanning microscopy (CLSM). After double staining with an antibody against the 51-kDa protein and with an antibody against tubulin, it was revealed that the 49-kDa protein was closely associated with the organization of MTs on the perinuclear regions during this stage under the CLSM. Notably, microfilaments (MFs) were not associated with the organization of MTs in the perinuclear region. This observation suggests that the 49-kDa protein plays a specific role in the organization of MTs on the perinuclear regions during the cell cycle transition from M phase to G₁ phase. To understand the molecular characteristics of the 49-kDa protein further, the search for cDNA encoding the 49-kDa protein was conducted in a cDNA expression library prepared from rapidly growing tobacco BY-2 cells using monoclonal antibodies against the 51-kDa protein. Determination of the base sequence of the isolated clone revealed that it encodes protein synthesis elongation factor (EF)-1α. Thus the significance of the involvement of the 49-kDa protein as EF-1α in the organization of MTs on the perinuclear regions is discussed in relation to other cellular functions.     

Calmodulin colocalization with cold-stable and nocodazole-stable microtubules in living PtK1 cells

To investigate the association of calmodulin (CaM) with microtubules (MTs) in the mitotic apparatus (MA), the distributions of both CaM and tubulin were examined in mitotic PtK1 cells in which MT subclasses had been selectively removed or altered by treatment with cold or with the MT inhibitor, nocodazole. A fluorescent CaM conjugate with tetramethylrhodamine isothiocyanate (CaM-TRITC) was microinjected into living cells, and the CaM distribution in the living cell was compared to the distribution of MTs indicated by tubulin immunofluorescence. In cells which had been treated for 2 h at 0 to 4 degrees C or with a low (0.03 micrograms/ml) dose of nocodazole, the only MTs remaining appeared to be kinetochore MTs (kMTs). The distribution of microinjected CaM-TRITC in these cells was indistinguishable from that found in untreated cells and appeared to be colocalized with the kMTs. In cells which were treated with a high (3.0 micrograms/ml) dose of nocodazole, only short MTs remained. When CaM-TRITC was injected into these cells, it formed a somewhat punctate distribution near the chromosomes and, after tubulin immunofluorescence processing, colocalized with what appeared to be remnants of kMTs. We believe that these observations support the hypothesis that CaM exists in the MA in a structural association with kMTs.     

Export from Pericentriolar Endocytic Recycling Compartment to Cell Surface Depends on Stable, Detyrosinated (Glu) Microtubules and Kinesin

A significant fraction of internalized transferrin (Tf) concentrates in the endocytic recycling compartment (ERC), which is near the microtubule-organizing center in many cell types. Tf then recycles back to the cell surface. The mechanisms controlling the localization, morphology, and function of the ERC are not fully understood. We examined the relationship of Tf trafficking with microtubules (MTs), specifically the subset of stable, detyrosinated Glu MTs. We found some correlation between the level of stable Glu MTs and the distribution of the ERC; in cells with low levels of Glu MTs concentrated near to the centriole, the ERC was often tightly clustered, whereas in cells with higher levels of Glu MTs throughout the cell, the ERC was more dispersed. The clustered ERC in Chinese hamster ovary cells became dispersed when the level of Glu MTs was increased with taxol treatment. Furthermore, in a temperature-sensitive Chinese hamster ovary cell line (B104-5), the cells had more Glu MTs when the ERC became dispersed at elevated temperature. Microinjecting purified anti-Glu tubulin antibody into B104-5 cells at elevated temperature induced the redistribution of the ERC to a tight cluster. Microinjection of anti-Glu tubulin antibody slowed recycling of Tf to the cell surface without affecting Tf internalization or delivery to the ERC. Similar inhibition of Tf recycling was caused by microinjecting anti-kinesin antibody. These results suggest that stable Glu MTs and kinesin play a role in the organization of the ERC and in facilitating movement of vesicles from the ERC to the cell surface.     

Microinjection of the monoclonal anti-tubulin antibody YL1/2 inhibits cleavage of sand dollar eggs

Two monoclonal antibodies against alpha-tubulin (YL1/2 and D2D6) were microinjected into the egg of the sand dollar Clypeaster japonicus, and their effects on cleavage of the egg were investigated. They had already been shown by immunoblotting to react specifically with egg tubulin and by immunofluorescence to stain the mitotic apparatus [OKA et al., (1990). Cell Motil. Cytoskel. 16:239-250]. Injection of YL1/2 prevented chromosome movement and cleavage, although the cleavage furrow developed in some cases. In all eggs injected at prometaphase, metaphase, or anaphase, the birefringence of the mitotic apparatus disappeared immediately after injection. Injection of D2D6 had no significant effect on mitosis or cleavage of whole eggs injected after nuclear disappearance, although it prevented the disappearance of the nuclear envelope in 54% of the eggs injected before the disappearance. FITC-conjugated D2D6 did not accumulate in the spindle when injected into the dividing sand dollar egg. These results indicate that YL1/2 disassembled microtubules, whereas D2D6 did not bind to microtubules in the living cell.     

10-nm filaments are induced to collapse in living cells microinjected with monoclonal and polyclonal antibodies against tubulin

Cells were microinjected with four mouse monoclonal antibodies that were directed against either alpha- or beta-tubulin subunits, one monoclonal with activity against both subunits, and a guinea pig polyclonal antibody with activity directed against both subunits, to determine the effects on the distribution of cytoplasmic microtubules and 10-nm filaments. The specificities of the antibodies were confirmed by Western blots, solid phase radioimmunoassay, and Western blot analysis of alpha- and beta-tubulin peptide maps. Two monoclonals DM1A and DM3B3, an anti-alpha- and anti-beta-tubulin respectively, and the guinea pig polyclonal anti-alpha/beta-tubulin antibody (GP1T4) caused the 10-nm filaments to collapse into large lateral aggregates collecting in the cell periphery or tight juxtanuclear caps; the other monoclonal antibodies had no effect when microinjected into cells. The filament collapsing was observed to be complete at 1.5-2 h after injection. During the first 30 min after injection a few cytoplasmic microtubules near the cell periphery could be observed by fluorescence microscopy. This observation was confirmed by electron microscopy, which also demonstrated assembled microtubules in the juxtanuclear region. By 1.5 h, when most of the 10-nm filaments were collapsed, the complete cytoplasmic array of microtubules was observed. Cells injected in prophase were able to assemble a mitotic spindle, suggesting that the antibody did not block microtubule assembly. Metabolic labeling with [35S]methionine of microinjected cells revealed that total protein synthesis was the same as that observed in uninjected cells. This indicated that the microinjected antibody apparently did not produce deleterious effects on cellular metabolism. These results suggest that through a direct interaction of antibodies with either alpha- or beta- tubulin subunits, 10-nm filaments were dissociated from their normal distribution. It is possible that the antibodies disrupted postulated 10-nm filament-microtubule interactions.     

Regulation of cytoplasmic tubulin carboxypeptidase activity during neural and muscle differentiation: characterization using a microtubule-based assay.

A cycle of posttranslational modification of alpha-tubulin has previously been described in higher eukaryotes, in which a C-terminal tyrosine residue is removed and replaced by two complementary cytoplasmic enzymes. The activity of the detyrosinating enzyme, tubulin carboxypeptidase (TCP), and its potential for regulating the level of detyrosinated (Glu) subunits in microtubules (MTs) is of great interest, since TCP catalyzes the primary modification of tubulin and since the level of Glu alpha-tubulin in MTs increases during a variety of differentiative and morphogenetic events. As a first step in examining the role of TCP in cellular morphogenesis, it was necessary to develop an assay for TCP with sufficient sensitivity and specificity to detect TCP activity during these events. Unlike previously described assays for TCP, ours makes use of the affinity TCP exhibits for MTs. NGF-induced neurite outgrowth in PC-12 cells was accompanied by a moderate (approximately 2-fold) increase in TCP activity, while myogenesis of L6 cells resulted in an almost insignificant decrease in activity. Measurements of TCP activity during differentiation were correlated with the level of extract Tyr tubulin, which increased (approximately 37%) during neurite outgrowth and was unchanged during myogenic differentiation. Our results suggest that TCP activity is regulated relative to its substrate, Tyr tubulin, and that changes in MT dynamics, rather than enzymatic activities, are the primary determinants of MT posttranslational modification state during differentiation. In addition, the assay we have devised for TCP and the characterization of TCP during differentiation may allow the future delineation of the mechanism(s) of regulation of TCP and the role this enzyme plays in modulating MT function during differentiation.     

Colocalisation of acetylated microtubules, glial filaments, and mitochondria in astrocytes in vitro

We have recently shown that acetylated alpha-tubulin containing microtubules (acetyl-MTs; labeled by antibody 6-11B-1) constitute a cold-stable subset of the microtubule network of nonneuronal cells in rat primary forebrain cultures [Cambray-Deakin and Burgoyne: Cell Motil. 8(3):284-291, 1987b]. In contrast, tyrosinated alpha-tubulin containing MTs (tyr-MTs; labeled by antibody YL1/2) are cold-labile. Here we have examined the distribution of acetyl-MTs and tyr-MTs in cultures of newborn rat forebrain astrocytes and simultaneously investigated the distribution of mitochondria and glial filaments. In double-label immunofluorescence experiments a marked colocalisation of acetyl-MTs and glial filament bundles was observed. Tyr-MTs did not show a similar colocalisation with glial filament bundles. Furthermore, the distribution of mitochondria closely followed that of the acetyl-MT and glial filament bundles. When cells were exposed to short-term (30-min) treatments with MT-disrupting agents such as colchicine and nocodazole, the tyr-MT network was removed but the distributions of acetyl-MTs, glial filaments, and mitochondria were unchanged. Increased exposure to colchicine (9-16 hr) caused a progressive disruption of the acetyl-MTs and the collapse of glial filaments and mitochondria to the perinuclear region. These results suggest that acetyl-MTs and glial filaments but not tyr-MTs may be involved in the intracellular transport of organelles and/or in the control of their cytoplasmic distribution.     

Cellular basis of in vitro anti-DNA antibody production: evidence for T cell dependence of IgG-class anti-DNA antibody synthesis in the (NZB X NZW)F1 hybrid

An in vitro system was designed to measure anti-DNA antibody synthesis, and the cellular basis of this autoantibody production in NZB X NZW (B/W)F1 (B/W F1) mice was analyzed. The spleen cells from old B/W F1 mice contained a number of B cells that spontaneously produced anti-DNA antibodies of both IgM and IgG classes in the absence of stimulants, thereby demonstrating that these B cells had been activated in vivo. These activated B cells could be removed by Sephadex G-10 column (G-10) filtration. Such G-10-passed, homogeneously small B cells were activated by the stimulant lipopolysaccharide (LPS) and produced both IgM and IgG class anti-DNA antibodies. The G-10-passed cells contained both B and T cells, and the cytotoxic treatment of the cells with monoclonal antibodies to T cells, anti-Thy-1 and anti-L3T4, abolished the LPS-induced IgG class, but not IgM class, anti-DNA antibody syntheses. Thus, the LPS-induced production of IgG class anti-DNA antibodies in B/W F1 mice is regulated by T cells. Reconstitution experiments revealed the requirement of T-B cell contact but not of the proliferative response of T cells. Moreover, there was no apparent adherent cell requirement. Such IgG class anti-DNA antibodies were produced only by spleen cells from old B/W F1 mice, but not from young B/W F1, NZB, NZW, and C57BL/6 mice. Like IgM class anti-DNA antibodies, LPS-induced synthesis of polyclonal IgM was T cell-independent. Only a slight reduction in the polyclonal IgG synthesis was observed after the G-10-passed cells had been treated with anti-Thy-1 antibody plus complement. This study should facilitate investigation of cell to cell interactions in the formation of autoantibodies and their correlations to immunologic abnormalities in autoimmune disease.