Microtubules In HeLa Cells Research Articles

Disruption of microtubules leads to glucocorticoid receptor degradation in HeLa cell line

The role of microtubules (MTs) in steroid hormone-dependent human glucocorticoid receptor (hGR) activation/translocation is controversial. It was demonstrated recently that colchicine (COL) down-regulates hGR-driven genes in primary human hepatocytes by a mechanism involving inhibition of hGR translocation to the nucleus. To investigate whether inhibition of hGR translocation is the sole reason for its inactivation, we used human cervical carcinoma cells (HeLa) as a model. Herein we present evidence that perturbation of microtubules in HeLa cells leads to rapid time- and dose-dependent degradation of hGR protein. Degradation is proteasome mediated as revealed by its reversibility by proteasome inhibitor MG132. Moreover, degradation was observed for neither wt-hGR nor hGR mutants S226A and K419A in transiently transfected COS-1 cells. On the other hand, c- jun N-terminal kinase (JNK) seems not to be involved in the process because JNK inhibitor 1,9-Pyrazoloanthrone (SP600125) does not reverse hGR degradation. Similarly, another hGR functional antagonist, nuclear factor kappa beta (NFκB), did not play any role in the degradation process.

MCAK, a Kin I kinesin, increases the catastrophe frequency of steady-state HeLa cell microtubules in an ATP-dependent manner in vitro

Mitotic-centromere-associated kinesin (MCAK) is a member of the KIN I (internal motor domain) subfamily of kinesin related proteins. MCAK and its homologues destabilize microtubules both in cells and in vitro. Here, we analyzed the effects of MCAK in the presence and absence of ATP on the dynamic instability behavior of steady state microtubules assembled from purified HeLa cell tubulin. In the presence of ATP, substoichiometric levels of full length MCAK and a segment (A182) consisting of the motor and neck domains strongly increased the catastrophe frequency of the microtubules. These data demonstrate that MCAK is a microtubule-catastrophe promoting factor in vitro, and support the hypothesis that MCAK may serve as a catastrophe-promoting factor in cells.

Biochemical and cell biological characterization of a mammalian septin, Sept11

Septins are a family of conserved cytoskeletal GTPases implicated in a variety of cellular functions such as cytokinesis and vesicle trafficking. Here, we report identification of an yet uncharacterized septin, Sept11, in septin complexes purified from porcine brain. The transcripts were detected in all tested tissues except leukocytes. A Sept11 mutant with apparently reduced GTPase activity did not form filaments in the transient expression system using COS7 cells. By Western blot analysis using a specific antibody, Sept11 was detected in various cell lines as well as brain tissues. Septin complexes immunoisolated from porcine brain with anti-Sept9 and anti-Sept11 antibodies were found to contain different Sept9 isoforms based on SDS–PAGE analyses followed by silver-staining and Western blotting. Immunofluorescent study revealed cell type-dependent intracellular localization of the protein; Sept11 was colocalized dominantly with microtubules and actin stress fibers in HMEC cells and REF52 cells, respectively, and their filamentous distribution was dependent on the cytoskeleton structures with which the protein is colocalized. Sept11 partially colocalized with stress fibers and microtubules in HeLa cells.

Localization in the human retina of the X-linked retinitis pigmentosa protein RP2, its homologue cofactor C and the RP2 interacting protein Arl3

Mutations in the retinitis pigmentosa 2 (RP2) gene cause a severe form of X-linked retinal degeneration. RP2 is a ubiquitous 350 amino acid plasma membrane-associated protein, which shares homology with the tubulin-specific chaperone cofactor C. RP2 protein, like cofactor C, stimulates the GTPase activity of tubulin in combination with cofactor D. RP2 has also been shown to interact with ADP ribosylation factor-like 3 (Arl3) in a nucleotide and myristoylation-dependant manner. In this study we have examined the relationship between RP2, cofactor C and Arl3 in patient-derived cell lines and in the retina. Examination of lymphoblastoid cells from patients with an Arg120stop nonsense mutation in RP2 revealed that the expression levels of cofactor C and Arl3 were not affected by the absence of RP2. In human retina, RP2 was localized to the plasma membrane of cells throughout the retina. RP2 was present at the plasma membrane in both rod and cone photoreceptors, extending from the outer segment through the inner segment to the synaptic terminals. There was no enrichment of RP2 staining in any photoreceptor organelle. In contrast, cofactor C and Arl3 localized predominantly to the photoreceptor connecting cilium in rod and cone photoreceptors. Cofactor C was cytoplasmic in distribution, whereas Arl3 localized to other microtubule structures within all cells. Arl3 behaved as a microtubule-associated protein: it co-localized with microtubules in HeLa cells and this was enhanced following microtubule stabilization with taxol. Furthermore, Arl3 co-purified with microtubules from bovine brain. Following microtubule depolymerization with nocodazole, Arl3 relocalized to the nuclear membrane. These data suggest that RP2 functions in concert with Arl3 to link the cell membrane with the cytoskeleton in photoreceptors as part of the cell signaling or vesicular transport machinery.

Intrinsically Slow Dynamic Instability of HeLa Cell Microtubules in Vitro

The dynamic behavior of mammalian microtubules has been extensively studied, both in living cells and with microtubules assembled from purified brain tubulin. To understand the intrinsic dynamic behavior of mammalian nonneural microtubules, we purified tubulin from cultured HeLa cells. We find that HeLa cell microtubules exhibit remarkably slow dynamic instability, spending most of their time in an attenuated state. The tempered dynamics contrast sharply with the dynamics of microtubules prepared from purified bovine brain tubulin under similar conditions. In accord with their minimal dynamic instability, assembled HeLa cell microtubules displayed a slow treadmilling rate and a low guanosine-5'-triphosphate hydrolysis rate at steady state. We find that unlike brain tubulin, which consists of a heterogeneous mixture of beta-tubulin isotypes (beta(II), beta(III), and beta(IV) and a low level of beta(I)), HeLa cell tubulin consists of beta(I) tubulin ( approximately 80%) and a minor amount of beta(IV) tubulin ( approximately 20%). The slow dynamic behavior of HeLa cell microtubules in vitro differs strikingly from the dynamic behavior of microtubules in living cultured mammalian cells, supporting the idea that accessory factors create the robust dynamics that occur in cells.

Mrnp41 (Rae1p) associates with microtubules in HeLa cells and in neurons

Mrnp41 (hRae1p) is an evolutionarily highly conserved protein, which is a potential component of mRNP particles and plays a role in nuclear mRNA export. The protein is mainly localized at the nuclear pore complex, but is also associated with distinct nuclear domains and with a meshwork of numerous small particles in the cytoplasm (Kraemer and Blobel (1997): Proc. Natl. Acad. Sci. USA 91, 1519-1523). We show that the cytoplasmic pattern of mrnp41 is sensitive to treatment with the microtubule (MT)-depolymerizing drug nocodazole which causes disappearance of mrnp41 from the cell periphery and concentration around the nucleus. By immunofluorescence we demonstrate that mrnp41 colocalizes with MT in HeLa cells and displays an MT-like distribution in cultured neurons. Association of mrnp41 with MT is further demonstrated by copurification with MT from pig brain throughout several steps of polymerization and depolymerization. Separation of MT-associated proteins (MAPs) by phosphocellulose (PC) chromatography showed copurification of mrnp41 with MAPs. These data show an association of mrnp41 with MT and, moreover, demonstrate that an intact MT system is necessary for dispersion of mrnp41-containing particles to the cellular periphery. The essential role of mrnp41 in spindle pole separation and cell cycle progression may also be related to its ability to bind to MTs.

The stathmin phosphoprotein family: intracellular localization and effects on the microtubule network.

Stathmin is a small regulatory phosphoprotein integrating diverse intracellular signaling pathways. It is also the generic element of a protein family including the neural proteins SCG10, SCLIP, RB3 and its two splice variants RB3' and RB3". Stathmin itself was shown to interact in vitro with tubulin in a phosphorylation-dependent manner, sequestering free tubulin and hence promoting microtubule depolymerization. We investigated the intracellular distribution and tubulin depolymerizing activity in vivo of all known members of the stathmin family. Whereas stathmin is not associated with interphase microtubules in HeLa cells, a fraction of it is concentrated at the mitotic spindle. We generated antisera specific for stathmin phosphoforms, which allowed us to visualize the regulation of phosphorylation-dephosphorylation during the successive stages of mitosis, and the partial localization of stathmin phosphorylated on serine 16 at the mitotic spindle. Results from overexpression experiments of wild-type and novel phosphorylation site mutants of stathmin further suggest that it induces depolymerization of interphase and mitotic microtubules in its unphosphorylated state but is inactivated by phosphorylation in mitosis. Phosphorylation of mutants 16A25A and 38A63A on sites 38 and 63 or 16 and 25, respectively, was sufficient for the formation of a functional spindle, whereas mutant 16A25A38A63E retained a microtubule depolymerizing activity. Transient expression of each of the neural phosphoproteins of the stathmin family showed that they are at least partially associated to the Golgi apparatus and not to other major membrane compartments, probably through their different NH2-terminal domains, as described for SCG10. Most importantly, like stathmin and SCG10, overexpressed SCLIP, RB3 and RB3" were able to depolymerize interphase microtubules. Altogether, our results demonstrate in vivo the functional conservation of the stathmin domain within each protein of the stathmin family, with a microtubule destabilizing activity most likely essential for their specific biological function(s).

Aphidicolin induces alterations in Golgi Complex and disorganization of microtubules of HeLa cells upon long‐term administration

Treatment of HeLa cells with aphidicolin at 5 or 0.5 μg/ml induced cell cycle arrest at G1/S or G2/M phase, respectively, and was accompanied by unbalanced cell growth. Long-term administration of aphidicolin (more than 48 h) resulted in noticeable loss of reproductive capacity though cells were viable at the time of treatment. Immunofluorescence with anti-Golgi membrane protein monoclonal antibody (mAbG3A5) showed disfigurement of the characteristic mesh-like configuration when cells were treated for more than 48 h. Interestingly, we found that the fragmented Golgi complex formed a ring around the nucleus in more than 20% of the cells. Immunoelectron microscopy using mAbG3A5 antibody demonstrated that the stack structure of the fragmented Golgi complex in aphidicolin-arrested cells appeared partially broken up and seemed to have converted to a vesicle-like structure. Analysis using an antibody to tubulin and anticentrosome human autoimmune serum showed that alterations in the Golgi complex were induced even by the lower 0.5 μg/ml dose. These alterations were accompanied by both changes in the distribution of microtubules and an increase in the number of centrosomes. These cells lost their distinct perinuclear microtubule organiz-ing center (MTOC). On the other hand, treatment with aphidicolin at 5 μg/ml did not induce multiplication of the centrosome although the loss of distinct MTOC was still evident. No changes took place in the Golgi complex, microtubule, or centrosome of cells treated with 0.5 μg/ml aphidicolin when cycloheximide was added simultaneously to the culture. J. Cell. Physiol. 176:602–611, 1998. © 1998 Wiley-Liss, Inc.

Aphidicolin induces alterations in Golgi complex and disorganization of microtubules of HeLa cells upon long-term administration.

Treatment of HeLa cells with aphidicolin at 5 or 0.5 microg/ml induced cell cycle arrest at G1/S or G2/M phase, respectively, and was accompanied by unbalanced cell growth. Long-term administration of aphidicolin (more than 48 h) resulted in noticeable loss of reproductive capacity though cells were viable at the time of treatment. Immunofluorescence with anti-Golgi membrane protein monoclonal antibody (mAbG3A5) showed disfigurement of the characteristic mesh-like configuration when cells were treated for more than 48 h. Interestingly, we found that the fragmented Golgi complex formed a ring around the nucleus in more than 20% of the cells. Immunoelectron microscopy using mAbG3A5 antibody demonstrated that the stack structure of the fragmented Golgi complex in aphidicolin-arrested cells appeared partially broken up and seemed to have converted to a vesicle-like structure. Analysis using an antibody to tubulin and anticentrosome human autoimmune serum showed that alterations in the Golgi complex were induced even by the lower 0.5 microg/ml dose. These alterations were accompanied by both changes in the distribution of microtubules and an increase in the number of centrosomes. These cells lost their distinct perinuclear microtubule organizing center (MTOC). On the other hand, treatment with aphidicolin at 5 microg/ml did not induce multiplication of the centrosome although the loss of distinct MTOC was still evident. No changes took place in the Golgi complex, microtubule, or centrosome of cells treated with 0.5 microg/ml aphidicolin when cycloheximide was added simultaneously to the culture.

GS-164, a small synthetic compound, stimulates tubulin polymerization by a similar mechanism to that of Taxol.

During our search for new microtubule effectors as anticancer agents, we have found that a small synthetic molecule designated GS-164 interferes with the assembly of porcine microtubule proteins and has cytotoxic activity against a wide range of human tumor cell lines. In this study, we investigated mode of action of the compound in comparison with Taxol and colcemid. To gain an insight into the mode of action of GS-164, we used an in vitro microtubule polymerization assay and a flow-cytometric measurement technique. Microtubule organization and the level of tubulin polymerization in HeLa cells were also examined by immunofluorescence microscopy and cytoskeletal protein analyses, respectively. GS-164 stimulated assembly of microtubule proteins in vitro in a concentration-dependent and a GTP-independent manner. Furthermore, as with Taxol, the microtubule polymerization induced by GS-164 was antagonized by podophyllotoxin, a tubulin polymerization inhibitor, and microtubules formed by GS-164 were resistant to disassembly by calcium or low temperatures. GS-164 in the micromolar range arrested the cell cycle of HeLa cells in the mitotic phase leading to cell death. GS-164 also increased the amounts of cellular microtubules in HeLa cells, resulting in the formation of microtubule bundles. These results indicate that GS-164 stimulates microtubule assembly by a similar mechanism to that of Taxol. A comparative conformational analysis of GS-164 and Taxol suggested that the structure of the former mimics the minimum essential sites of Taxol required to exert the Taxol-like activities described above. Although the cytotoxicity of GS-164 against human tumor cells was 1000-fold lower than that of Taxol and GS-164 was one-tenth as active as Taxol in vitro, these findings pave the way for synthesizing clinically useful anticancer agents using GS-164 as a lead compound.

Photodynamic damage to HeLa cell microtubules induced by thiazine dyes.

The aim of this study was to analyze possible alterations of the microtubule cytoskeleton of cultured cells subjected to photodynamic treatments with the thiazine dyes methylene blue or toluidine blue. Indirect immunofluorescence labeling of alpha-tubulin was performed in HeLa cells after 1 or 18 h of incubation with thiazines followed by red-light irradiation for 15 min [leading to surviving fractions (SF) of about 65% (SF65) or 1% (SF1), respectively]. Untreated control cells showed the normal distribution of interphase microtubules, whereas considerable or severe disorganization of the microtubule network was observed after SF65 or SF1 photodynamic treatments, respectively. A great amount of blebs showing homogeneous fluorescence was also found on the cell surface after SF1 treatments. Possible mechanisms responsible for the photodamage to microtubules induced by thiazine dyes are briefly discussed.

Photodynamic effects of the cationic porphyrin, mesotetra(4 N-methylpyridyl)porphine, on microtubules of HeLa cells

The treatment of HeLa human carcinoma cells with mesotetra(4 N-methylpyridyl)porphine (T 4MPyP) and blue light led to damage of the microtubules (MTs). The morphologies of interphase MTs and the mitotic spindle apparatus were analysed by immunofluorescence staining of α-tubulin. The extent of MT damage depended on the light dose and the time after photodynamic treatment. After a period of 1 h after irradiation with doses of 0.3 or 1.5 J cm −2 (sublethal conditions, corresponding to survival rates of 90% and 60% respectively), the normal MT network arrangement of interphase cells and the mitotic spindle apparatus of many cells were clearly affected. However, these effects were found to be transient, and several hours after irradiation most MTs resumed control morphology. Higher irradiation doses (4.5 J cm −2, lethal conditions, less than 10% cell survival) resulted in the irreversible alteration of interphase and mitotic MTs. The change in MT organization appeared to be the reason for the observed increase in the mitotic index (MI) after sublethal doses. The largest increase in MI was detected 6 h after treatment (twofold increase over untreated cells) for both sublethal light doses. Most of the cells in mitosis corresponded to metaphase, the number of ana-telophase cells being greatly reduced for the first hours after irradiation with a dose of 1.5 J cm −2. The results, which resemble those observed with inhibitors of MT assembly, suggest that MTs might represent an important target for T 4MPyP action.

Generation of antisera that discriminate among mammalian alpha-tubulins: introduction of specialized isotypes into cultured cells results in their coassembly without disruption of normal microtubule function.

To assay the functional significance of the multiple but closely related alpha-tubulin polypeptides that are expressed in mammalian cells, we generated three specific immune sera, each of which uniquely recognizes a distinct alpha-tubulin isotype. All three isotypes are expressed in a tissue-restricted manner: one (M alpha 3/7) only in mature testis, one (M alpha 4) mainly in muscle and brain, and the third (M alpha 6) in several tissues at a very low level. A fourth specific antiserum was also generated that distinguishes between the tyrosinated and nontyrosinated form of a single alpha-tubulin isotype. Because individual tubulin isotypes cannot be purified biochemically, these sera were raised using cloned fusion proteins purified from host Escherichia coli cells. To suppress the immune response to shared epitopes, animals were first rendered tolerant to fusion proteins encoding all but one of the known mammalian alpha-tubulin isotypes. Subsequent challenge with the remaining fusion protein then resulted in the elicitation of an immune response to unique epitopes. Three criteria were used to establish the specificity of the resulting sera: (a) their ability to discriminate among cloned fusion proteins representing all the known mammalian alpha-tubulin isotypes; (b) their ability to uniquely detect alpha-tubulin in whole extracts of tissues; and (c) their capacity to stain microtubules in fixed preparations of cells transfected with sequences encoding the corresponding isotype. The transfection experiments served to demonstrate (a) the coassembly of M alpha 3/7, M alpha 4, and M alpha 6 into both interphase and spindle microtubules in HeLa cells and NIH 3T3 cells, and (b) that the M alpha 4 isotype, which is unique among mammalian alpha-tubulins in that it lacks an encoded carboxy-terminal tyrosine residue, behaves like other alpha-tubulin isotypes with respect to the cycle of tyrosination/detyrosination that occurs in most cultured cells.

Immunofluorescence localization of HeLa cell microtubule-associated proteins on microtubules in vitro and in vivo.

Rabbit antisera were prepared against the two major groups of microtubule-associated proteins (MAPs) from HeLa cells, proteins of approximately 210,000 molecular weight (210k MAPs), and 125,000 mol wt (125k MAPs). These antisera were characterized by a sensitive antigen detection technique that employs immunofluorescence to localize cross-reactive material in polyacrylamide gels. Antisera prepared against the 210k MAPs showed no cross-reactivity with extract proteins of other molecular weights or with bran MAPs, but did react with proteins of 210,000 mol wt and with a minor HeLa MAP of approximately 255,000 mol wt. Antibodies prepared against the 125k HeLa MAPs, likewise, reacted specifically with proteins of 125,000 mol wt, showing no cross-reactivity with other HeLa extract proteins or porcine brain MAPs. Immunofluorescence with the 210k and 125k MAP antisera was used to demonstrate the association of each of the MAPs with fixed HeLa microtubules in vitro. In addition, immunofluorescence with these antisera revealed a physical association of 210k and 125k MAPs with a Colcemid-sensitive fiber network in fixed interphase and mitotic HeLa cells. Thus, using specific, well-characterized antisera to the two major groups of HeLa MAPs, we have shown that these proteins are components of microtubules in HeLa cells.

Purification and reconstitution of HeLa cell microtubules.

Microtubules from suspension cultures of HeLa cells have been purified by carrying them through four complete cycles of polymerization at 37 degrees C and depolymerization at 4 degrees C. These microtubules show, in addition to the major alpha- and beta-tubulin components, major proteins with molecular weights of 201 000-206 000 (comprising 4.5% of the total protein), proteins with molecular weights of 97 000, 100 000, 104 000, and 114 000 (together comprising approximately 2% of the total protein), and minor components with molecular weights of 68 000 and 151 000. HeLa microtubules have also been reconstituted from purified HeLa tubulin and proteins from HeLa microtubules separated from tubulin by DEAE-cellulose column chromatography. Experiments on the fractionation and reconstitution of both two- and four-cycle microtubules suggest that the 201 000-206 000-dalton proteins are incorporated into microtubules and promote tubulin polymerization. Microtubules formed by fractionationand reconstitution of two-cycle microtubules also contain several other proteins with molecular weights of 132 000, 146 000, 151 000, 160 000, and 284 000, although these are not present in microtubules carried through four assembly-disassembly cycles. Evidence is also presented which shows that a 68 000-dalton protein which is a prominent component of HeLa microtubules after two polymerization-depolymerization cycles does not stoichiometrically copurify with tubulin through repeated assembly--disassembly cycles and does not stimulate tubulin polymerization. On the other hand, the sedimentation of this 68 000-dalton protein is apparently influenced by the presence of polymerized microtubules, suggesting that this protein may be a component of a system whjich interacts weakly with microtubules. Finally, evidence is presented suggesting that two-cycle microtubules contain a proteolytic activity that can digest the 201 000-206 000-dalton proteins.