Association of adenovirus with the microtubule organizing center

Adenoviruses (Ad) must deliver their genomes to the nucleus of the target cell to initiate an infection. Following entry into the cell and escape from the endosome, Ad traffics along the microtubule cytoskeleton toward the nucleus. In the final step in Ad trafficking, Ad must leave the microtubule and establish an association with the nuclear envelope. We hypothesized that in cells lacking a nucleus, the capsid moves to and associates with the microtubule organizing center (MTOC). To test this hypothesis, we established an experimental system to examine Ad trafficking in enucleated cells compared to Ad trafficking in intact, mock-enucleated cells. Enucleation of a monolayer of A549 human lung epithelial cells was accomplished by depolymerization of the actin cytoskeleton followed by centrifugation. Upon infection of enucleated cells with Cy3-labeled Ad, the majority of Ad capsid trafficked to a discrete, centrally located site which colocalized with pericentrin, a component of the MTOC. MTOC-associated Ad had escaped from endosomes and thus had direct access to MTOC components. Ad localization at this site was sensitive to the microtubule-depolymerizing agent nocodazole, but not to the microfilament-depolymerizing agent cytochalasin B, indicating that intact microtubules were required to maintain the localization with the MTOC. Ad localization to the MTOC in the enucleated cells was stable, as demonstrated by continuing Ad localization with pericentrin for more than 5 h after infection, a strong preference for Ad arrival at rather than Ad departure from the MTOC, and minimal redistribution of Ad between MTOCs within a single cell. In summary, the data demonstrate that the Ad capsid establishes a stable interaction with the MTOC when a nucleus is not present, suggesting that dissociation of Ad from microtubules likely requires nuclear factors.     

Regulation of microtubule dynamics and nucleation during polarization in MDCK II cells

MDCK cells form a polarized epithelium when they reach confluence in tissue culture. We have previously shown that concomitantly with the establishment of intercellular junctions, centrioles separate and microtubules lose their radial organization (Bacallao, R., C. Antony, C. Dotti, E. Karsenti, E.H.K. Stelzer, and K. Simons. 1989. J. Cell Biol. 109:2817-2832. Buendia, B., M.H. Bre, G. Griffiths, and E. Karsenti. 1990. 110:1123-1136). In this work, we have examined the pattern of microtubule nucleation before and after the establishment of intercellular contacts. We analyzed the elongation rate and stability of microtubules in single and confluent cells. This was achieved by microinjection of Paramecium axonemal tubulin and detection of the newly incorporated subunits by an antibody directed specifically against the Paramecium axonemal tubulin. The determination of newly nucleated microtubule localization has been made possible by the use of advanced double-immunofluorescence confocal microscopy. We have shown that in single cells, newly nucleated microtubules originate from several sites concentrated in a region localized close to the nucleus and not from a single spot that could correspond to a pair of centrioles. In confluent cells, newly nucleated microtubules were still more dispersed. The microtubule elongation rate of individual microtubules was not different in single and confluent cells (4 microns/min). However, in confluent cells, the population of long lived microtubules was strongly increased. In single or subconfluent cells most microtubules showed a t1/2 of less than 30 min, whereas in confluent monolayers, a large population of microtubules had a t1/2 of greater than 2 h. These results, together with previous observations cited above, indicate that during the establishment of polarity in MDCK cells, microtubule reorganization involves both a relocalization of microtubule-nucleating activity and increased microtubule stabilization.     

Paxillin localizes to the lymphocyte microtubule organizing center and associates with the microtubule cytoskeleton

Paxillin is a focal adhesion-associated protein that functions as a multi-domain adapter protein, binding several structural and signaling molecules. alpha-Tubulin was identified as an interacting protein in a two-hybrid screen using the paxillin C-terminal LIM domain as a bait. In vitro binding assays with glutathione S-transferase-paxillin demonstrated an interaction of alpha-tubulin with the C terminus of paxillin. Another member of the tubulin family, gamma-tubulin, bound to both the N and the C terminus of paxillin. The interaction between paxillin and both alpha- and gamma-tubulin in vivo was confirmed by co-immunoprecipitation from human T lymphoblasts. Immunofluorescence studies revealed that, in adherent T cells, paxillin localized to sites of cell-matrix interaction as well as to a large perinuclear region. Confocal microscopy revealed that this region corresponds to the lymphocyte microtubule organizing center, where paxillin colocalizes with alpha- and gamma-tubulin. The localization of paxillin to this area was observed in cells in suspension as well as during adhesion to integrin ligands. These data constitute the first characterization of the interaction of paxillin with the microtubule cytoskeleton, and suggest that paxillin, in addition to its well established role at focal adhesions, could also be associated with the lymphocyte microtubule network.     

SETDB1 regulates microtubule dynamics

ObjectivesSETDB1 is a methyltransferase responsible for the methylation of histone H3‐lysine‐9, which is mainly related to heterochromatin formation. SETDB1 is overexpressed in various cancer types and is associated with an aggressive phenotype. In agreement with its activity, it mainly exhibits a nuclear localization; however, in several cell types a cytoplasmic localization was reported. Here we looked for cytoplasmic functions of SETDB1.MethodsSETDB1 association with microtubules was detected by immunofluorescence and co‐sedimentation. Microtubule dynamics were analysed during recovery from nocodazole treatment and by tracking microtubule plus‐ends in live cells. Live cell imaging was used to study mitotic kinetics and protein–protein interaction was identified by co‐immunoprecipitation.ResultsSETDB1 co‐sedimented with microtubules and partially colocalized with microtubules. SETDB1 partial silencing led to faster polymerization and reduced rate of catastrophe events of microtubules in parallel to reduced proliferation rate and slower mitotic kinetics. Interestingly, over‐expression of either wild‐type or catalytic dead SETDB1 altered microtubule polymerization rate to the same extent, suggesting that SETDB1 may affect microtubule dynamics by a methylation‐independent mechanism. Moreover, SETDB1 co‐immunoprecipitated with HDAC6 and tubulin acetylation levels were increased upon silencing of SETDB1.ConclusionsTaken together, our study suggests a model in which SETDB1 affects microtubule dynamics by interacting with both microtubules and HDAC6 to enhance tubulin deacetylation. Overall, our results suggest a novel cytoplasmic role for SETDB1 in the regulation of microtubule dynamics.

SETDB1 association with microtubules inhibits microtubule polymerization and enhances their instability. SETDB1 may affect the microtubules by interacting with HDAC6 to enhance HDAC6 tubulin deacetylation activity.     

Hypophosphorylated and inactive Pyk2 associates with paxillin at the microtubule organizing center in hematopoietic cells

Pyk2 is a non-receptor tyrosine kinase that regulates cellular adhesion. We generated antibodies to a peptide corresponding to the N-terminus (NT) of Pyk2 and another to a portion of the C-terminal (CT) domain. Only the CT antiserum recovered paxillin-associated Pyk2. These antibodies recognized overlapping but biochemically distinct molecular species of Pyk2 since the CT antiserum recovered Pyk2 after NT antibody immunodepletion. Furthermore, the CT antibody could not immunoblot NT antibody-captured Pyk2. Phosphorylation partially accounts for the differential binding of these antibodies as dephosphorylation of Pyk2 recovered with the NT antibodies allows for recognition by the CT antibody. Additionally, Pyk2 recovered with the NT antibody displays increased serine/threonine phosphorylation. We suggest that the NT epitope is inaccessible to the antibody because Pyk2 is in a closed confirmation in association with paxillin. Upon induction of serine and/or threonine phosphorylation of Pyk2, it opens to a confirmation that allows for antibody binding to the NT epitope but at the same time no longer binds paxillin or the CT antiserum. These antibodies also display differential staining of Pyk2 in both T cells and macrophages. Pyk2 recognized by the CT antibody, but not the NT antibody, colocalized with paxillin at the microtubule-organizing center (MTOC). The MTOC-bound Pyk2 was not tyrosine phosphorylated upon T cell activation. We hypothesize that a reservoir of primarily inactive Pyk2 associates with paxillin at the MTOC, which may allow for rapid delivery of Pyk2 to specific sites of adhesion.     

CAMSAP3-dependent microtubule dynamics regulates Golgi assembly in epithelial cells

The Golgi assembly pattern varies among cell types. In fibroblast cells, the Golgi apparatus concentrates around the centrosome that radiates microtubules; whereas in epithelial cells, whose microtubules are mainly noncentrosomal, the Golgi apparatus accumulates around the nucleus independently of centrosome. Little is known about the mechanisms behind such cell type-specific Golgi and microtubule organization. Here, we show that the microtubule minus-end binding protein Nezha/CAMSAP3 (calmodulin-regulated spectrin-associated protein 3) plays a role in translocation of Golgi vesicles in epithelial cells. This function of CAMSAP3 is supported by CG-NAP (centrosome and Golgi localized PKN-associated protein) through their binding. Depletion of either one of these proteins similarly induces fragmentation of Golgi membranes. Furthermore, we find that stathmin-dependent microtubule dynamics is graded along the radial axis of cells with highest activity at the perinuclear region, and inhibition of this gradient disrupts perinuclear distribution of the Golgi apparatus. We propose that the assembly of the Golgi apparatus in epithelial cells is induced by a multi-step process, which includes CAMSAP3-dependent Golgi vesicle clustering and graded microtubule dynamics.     

Mid1ip1b modulates apical reorientation of non-centrosomal microtubule organizing center in epithelial cells

In most kinds of animal cells, the centrosome serves as the main microtubule organizing center (MTOC) that nucleates microtubule arrays throughout the cytoplasm to maintain cell structure, cell division and intracellular transport. Whereas in epithelial cells, non-centrosomal MTOCs are established in the apical domain for generating asymmetric microtubule fibers and cilia in epithelial cells for the organ morphogenesis during embryonic development. However, the mechanism by which MTOCs localize to the apical domain in epithelial cells remains largely unknown. Here, we show that Mid1ip1b has a close interaction with γ-tubulin protein, the central component of MTOC, and modulates lumen opening of the neural tube, gut, intestine, and kidney of zebrafish. Knockdown or dominant negative effect of Mid1ip1b resulted in failure of lumen formation of the organs as aforementioned. Moreover, the non-centrosomal MTOCs were unable to orientate to the apical domain in Mid1ip1b knockdown epithelial cells, and the centrosomal MTOCs were inaccurately placed in the apical domain, resulting in defective formation of asymmetric microtubules and misplacement of cilia in the apical domain. These data uncover a molecule that controls the proper localization of MTOCs in the apical domain in epithelial cells for organ morphogenesis during embryonic development.     

Yeast ubiquitin-like genes are involved in duplication of the microtubule organizing center

KAR1 is required for duplication of the Saccharomyces cerevisiae microtubule organizing center, the spindle pole body (SPB) (Rose, M.D., and G.R. Fink, 1987. Cell. 48:1047-1060). Suppressors of a kar1 allele defective for SPB duplication were isolated in two genes, CDC31 and DSK2 (Vallen, E.A., W.H., M. Winey, and M.D. Rose. 1994. Genetics. 137:407-422). To elucidate the role of DSK2 in SPB duplication, we cloned the gene and found it encodes a novel ubiquitin-like protein containing an NH2 terminus 36% identical to ubiquitin. The only other known yeast ubiquitin-like protein is encoded by the nucleotide excision repair gene RAD23 (Watkins, J.F.,P. Sung, L. Prakash, and S. Prakash. 1993. Mol. Cell. Bio. 13:7757-7765). Unlike ubiquitin, the NH2- terminal domain of Dsk2p is not cleaved from the protein, indicating that Dsk2p is not conjugated to other proteins. Although the DSK2-1 mutation alters a conserved residue in the Dsk2p ubiquitin-like domain, we detect no differences in Dsk2p or Cdc31p stability. Therefore, DSK2 does not act by interfering with ubiquitin-dependent protein degradation of these proteins. Although DSK2 is not essential, a strain deleted for both DSK2 and RAD23 is temperature sensitive for growth due to a block in SPB duplication. In addition, overexpression of DSK2 is toxic, and the DSK2-1 allele causes a block in SPB duplication. Therefore, DSK2 dosage is critical for SPB duplication. We determined that CDC31 gene function is downstream of DSK2 and KAR1. Dsk2p is a nuclear-enriched protein, and we propose that Dsk2p assists in Cdc31 assembly into the new SPB.     

Protein complexes at the microtubule organizing center regulate bipolar spindle assembly

Bipolar spindle assembly is essential to genomic stability in dividing cells. Centrosomes or spindle pole bodies duplicated earlier at G1/S remain adjacent until triggered at mitotic onset to become bipolar. Pole reorientation is stabilized by microtubule interdigitation but mechanistic details for bipolarity remain incomplete. To investigate the contribution of spindle pole microtubule organizing center (MTOC) proteins in bipolarity, we applied genetic, structural and molecular biochemical analysis along with timelapse microscopy. Spindle formation was followed by an in vivo growth assay with the conditional allele cut7-22ts, encoding fission yeast mitotic Kinesin-5, essential for bipolarity. By analysis of double and triple mutant strains of MTOC alleles and cut7-22ts we found that stabilized microtubules or increased bundling can rescue cut7-22ts associated bipolarity defects. These changes to microtubule dynamics and organization occurred through two surface domains on γ-tubulin, a helix 11 domain and an adjacent site for binding MTOC protein Alp4. We demonstrate that Kinesin-14 Pkl1, known to oppose bipolarity, can bind to γ-tubulin at helix 11 and that mutation of either of two conserved residues in helix 11 can impair Kinesin-14 binding. Altering the Alp4/γ-tubulin interaction, conserved residues in helix 11 or deletion of pkl1 each are sufficient to rescue bipolarity in our cut7-22ts strain. Our findings provide novel insights into regulation of the bipolar mechanism through the MTOC complex.     

Fission yeast Mto1 regulates diversity of cytoplasmic microtubule organizing centers

Microtubule nucleation by the γ-tubulin complex occurs primarily at centrosomes, but more diverse types of microtubule organizing centers (MTOCs) also exist, especially in differentiated cells. Mechanisms generating MTOC diversity are poorly understood. Fission yeast Schizosaccharomyces pombe has multiple types of cytoplasmic MTOCs, and these vary through the cell cycle. Cytoplasmic microtubule nucleation in fission yeast depends on a complex of proteins Mto1 and Mto2 (Mto1/2), which localizes to MTOCs and interacts with the γ-tubulin complex. Localization of Mto1 to prospective MTOC sites has been proposed as a key step in γ-tubulin complex recruitment and MTOC formation, but how Mto1 localizes to such sites has not been investigated. Here we identify a short conserved C-terminal sequence in Mto1, termed MASC, important for targeting Mto1 to multiple distinct MTOCs. Different subregions of MASC target Mto1 to different MTOCs, and multimerization of MASC is important for efficient targeting. Mto1 targeting to the cell equator during division depends on direct interaction with unconventional type II myosin Myp2. Targeting to the spindle pole body during mitosis depends on Sid4 and Cdc11, components of the septation initiation network (SIN), but not on other SIN components.     

DIAPH1 regulates chromosomal instability of cancer cells by controlling microtubule dynamics

Chromosomal instability (CIN) is a hallmark of cancer, resulting from misalignment and missegregation of chromosomes during meta- and anaphase, due to non-precise regulation of spindle-MT dynamics. Diaphanous Related Formin 1 (DIAPH1) is an actin nucleator and also binds microtubule (MT) with high affinity. In this study, we analyzed the role of DIAPH1 in regulation of spindle MT-dynamics and CIN in HT29 and HCT-116 colorectal cancer (CRC) cells. Our data show that down-regulation of DIAPH1 in these cell lines decreased spindle-MT speed by 50 % and the fraction of cells with misaligned and missegregated chromosomes was significantly increased. Furthermore, in HCT-116 DIAPH1 depleted cells deviation of chromosome number was elevated and the number of cells with micronuclei and cytosolic DNA was increased in both DIAPH1-knock down cell lines. In line with these results, database analysis revealed a significant correlation with low DIAPH1 mRNA expression and aneuploidy. Thus, DIAPH1 is substantially involved in the control of CIN in CRC cells. Since in vitro, DIAPH1 directly increased MT-polymerization, we assume that DIAPH1 controls CIN by regulating spindle-MT dynamics.     

Spindle assembly and the art of regulating microtubule dynamics by MAPs and Stathmin/Op18

The way that microtubules reorganize from their long, stable interphase configuration to form the mitotic spindle remains a challenging and unsolved question. It is now widely recognized that microtubule polymerization during the cell cycle is regulated by a balance between microtubule-stabilizing and-destabilizing factors. Stabilizing factors include a large group of microtubule-associated proteins (MAPs; e.g. MAP4, XMAP215, XMAP230/XMAP4 and XMAP310) and the destabilizing factors are a growing family of proteins (e.g. Stathmin/Op18 and XKCM1). Recent studies have allowed a mechanistic dissection of how these stabilizing and destabilizing factors regulate microtubule dynamics and spindle assembly.     

EB1 regulates microtubule dynamics and tubulin sheet closure in vitro

End binding 1 (EB1) is a plus-end-tracking protein (+TIP) that localizes to microtubule plus ends where it modulates their dynamics and interactions with intracellular organelles. Although the regulating activity of EB1 on microtubule dynamics has been studied in cells and purified systems, the molecular mechanisms involved in its specific activity are still unclear. Here, we describe how EB1 regulates the dynamics and structure of microtubules assembled from pure tubulin. We found that EB1 stimulates spontaneous nucleation and growth of microtubules, and promotes both catastrophes (transitions from growth to shrinkage) and rescues (reverse events). Electron cryomicroscopy showed that EB1 induces the initial formation of tubulin sheets, which rapidly close into the common 13-protofilament-microtubule architecture. Our results suggest that EB1 favours the lateral association of free tubulin at microtubule-sheet edges, thereby stimulating nucleation, sheet growth and closure. The reduction of sheet length at microtubule growing-ends together with the elimination of stressed microtubule lattices may account for catastrophes. Conversely, occasional binding of EB1 to the microtubule lattice may induce rescues.     

Cytoplasmic transfer of microtubule organizing centers in mouse tissue culture cells

A chloramphenicol-resistant, aminopterin-sensitive cell line (AMT) derived from a mouse mammary tumor MT-29240 was enucleated, and the cytoplasts were fused with nucleated chloramphenicol-sensitive, HAT-resistant SV40 3T3 mouse cells. The resulting cytoplasmic hybrids (cybrids) were selected for their resistance to chloramphenicol and the chromosome complement of the SV40 3T3 cells. In addition to transfer of chloramphenicol resistance, these cybrid clones, as studied in the electron microscope, contained the intracisternal A particle phenotype characteristic of only the AMT cells. The cytoplasmic microtubule complex (CMTC) in these cybrids was also studied and appears to resemble the elaborate CMTC of the AMT cells more closely than the more reduced CMTC of the SV40 3T3. When treated with a colcemid block and then a brief reverse, the microtubule organizing centers (MTOC) appear as bright fluorescent foci when tubulin antibody and indirect immunofluorescence techniques are used. When AMT or SV40 3T3 cells are treated in this manner, only one MTOC is present in interphase cells. One clone of these cybrids, however, contained two MTOCs in interphase cells. This CMTC and MTOC phenotype has persisted in this cybrid clone for over 3 months of continuous culture.     

Structural and immunocytochemical characterization of microtubule organizing centers in pteridophyte spermatogenous cells

Summary During the development of the spermatogenous cells, the pteridophyteCeratopteris richardii produces three structurally well-defined microtubule organizing centers (MTOCs). The blepharoplast, a spherical body that occurs during the last two spermatogenous divisions, organizes two microtubule (MT) arrays, one associated with a nuclear indentation and the other that organizes the spindle apparatus for the final divisions. After the last spermatogenous division, the blepharoplast reorganizes to produce two new putative MTOCs: the lamellar strip (LS) of the multilayered structure (MLS), which apparently organizes the spline microtubule array, and an amorphous zone (AM), that connects the basal bodies. Thin and semi-thin sections of this tissue were probed with antisera which recognize MTOCs in lower eukaryotes and animals to determine if any of these structures contain MTOC-associated proteins or epitopes recognized by monoclonal antisera. Gamma tubulin antibodies, which recognizeonly the minus ends of MTs in mammalian cells, label along the MT in all arrays found in the pteridophyte spermatogenous cells. Kinetochore MTs are unlabelled near the kinetochore, however. The monoclonal antibodies MPM-2 and C-9, that recognize centrosomal and nuclear epitopes in mammalian cells, label the interphase nucleus, the cytoplasm of mitotic cells, and the blepharoplast during both nuclear indentation and spindle formation. Double labelling of the blepharoplast-containing cells with anti-tubulin and either MPM-2 or C-9 reveals that the blepharoplast-associated fluorescence is the focus of the tubulin arrays. Centrin labels the reorganizing blepharoplast, the MLS, the AM, and a stellate pattern in the transition region of the flagella. These data indicate the usefulness of the structurally well-recognized MTOCs in pteridophyte spermatogenous cells in investigation of land plant MTOCs.     

Distribution of microtubule organizing centers in migrating sheets of endothelial cells

This study was designed to investigate the relationship between the position of the microtubule organizing center (MTOC) and the direction of migration of a sheet of endothelial cells (EC). Using immunofluorescence and phase microscopy the MTOC's of migrating EC were visualized as the cells moved into an in vitro experimental wound produced by mechanical denudation of part of a confluent monolayer culture. Although the MTOC's in nonmigrating EC were randomly positioned in relation to the nucleus, in migrating cells the position of the MTOC's changed so that 80% of the cells had the MTOC positioned in front of the nucleus toward the direction of movement of the endothelial sheet. This repositioning of the MTOC occurred within the first 4 h after wounding and was associated with the beginning of migration of EC's into the wounded area as seen by time-lapse cinemicrophotography. These studies focus attention on the MTOC as a cytoskeletal structure that may play a role in determining the direction of cell movement.